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Serum withdrawal induces a redistribution of intracellular gelsolin towards F-actin in NIH 3T3 fibroblasts preceding apoptotic cell death
Abstract
SummaryThe intracellular distribution of gelsolin in NIH 3T3 cells was examined by immunostaining using affinity-purified polyclonal gelsolin antibodies before and after induction of apoptosis by serum withdrawal. Serum deprivation induced detachment of an increasing number of NIH 3T3 cells, but also apoptosis in attached cells as verified morphologically by chromatin condensation, nuclear fragmentation and labelling of their periphery by FITC-annexin V. Ongoing apoptosis was also demonstrated by activation of caspase-3 activity and chromatin cleavage into high-molecular-mass fragments, although no internucleosomal chromatin degradation (DNA-ladder formation) was detected. When cells were maintained in the presence of 10% foetal calf serum, gelsolin immunoreactivity was evenly distributed in the cytoplasm. No obvious co-localisation of gelsolin and the actin-containing stress fibres was detected under these conditions. At day one after serum withdrawal, a redistribution of gelsolin to actin filaments was detected within a few attached cells by double fluorescence staining. The number of cells exhibiting this redistribution increased at days two to four. In addition, the stress fibres increased in thickness and their length was continuously reduced. At day four, many cells contained shortened stress fibres, which had lost their longitudinal orientation. Additionally, the cytoplasm of a number of attached cells was highly condensed around their nuclei and a homogenous distribution of both gelsolin and actin was detected in the remaining cytoplasmic rim. Up to day two, these effects were reversible after re-addition of serum to attached cells. A similar redistribution of gelsolin immunoreactivity was observed after induction of apoptosis by cycloheximide, but not after initiation of necrosis by hydrogen peroxide. In NIH 3T3 cells no alteration in the expression of gelsolin at the level of protein (Western blot) or specific mRNA (Northern blot) was observed after serum withdrawal. Using Western blotting, no proteolysis of gelsolin was detected up to day 4, although caspase-3 activity was found to have increased fivefold after serum withdrawal. These results suggested that in these cells F-actin severing might occur in the absence or advance of gelsolin cleavage by caspases. Intact gelsolin on its own may be sufficient for the dissolution of the microfilaments, since micro-injection of gelsolin into primary bovine lens cells led to a transient disappearance of the stress fibres and to a reduction of their attachment area to the substratum. In NIH 3T3 cells similar effects of micro-injected gelsolin were only observed at day one after serum withdrawal.
... Serum deprivation induces apoptosis via cell detachment in NIH/3T3 fibroblasts where integrin-mediated signaling suppresses apoptotic processes via activation of intracellular signaling pathways for cell adhesion and survival. 26,27 Activation of signaling can be monitored by analyzing tyrosine 397 FAK phosphorylation (pTyr-397 FAK). 28,29 ...
... Serum deprivation promotes detachment of fibroblast NIH/ 3T3 cells from the surface and apoptosis via morphological changes in attached cells. 26,27 We monitored apoptotic cell death on sample-coated surfaces using Annexin V staining [ Fig. 4(A)]. Externalization of phosphatidylserine of the inner cell membrane is an early event of apoptosis, and apoptotic cells can be detected using binding events of Annexin V to phosphatidylserine. ...
Adhesion of cells to a surface is a basic and important requirement in the fields of cell culture and tissue engineering. Previously, we constructed the cell adhesive, fp-151-RGD, by fusion of the hybrid mussel adhesive protein, fp-151, and GRGDSP peptide, one of the major cell adhesion recognition motifs; fp-151-RGD efficiently immobilized cells on coated culture surfaces with no protein and surface modifications, and apparently enhanced cell adhesion, proliferation, and spreading abilities. In the present study, we investigated the potential use of fp-151-RGD as a biomimetic extracellular matrix material at the molecular level by elucidating its substantial effects on integrin-mediated adhesion and signaling. Apoptosis derived from serum deprivation was significantly suppressed on the fp-151-RGD-coated surface, indicating that RGD-induced activation of integrin-mediated signaling triggers the pathway for cell survival. Analysis of the phosphorylation of focal adhesion kinase clearly demonstrated activation of focal adhesion kinase, a well-established indicator of integrin-mediated signaling, on the fp-151-RGD-coated surface, leading to significantly enhanced cell behaviors, including proliferation, spreading and survival, and consequently, more efficient cell culture.
... When cells were incubated in serum-free DMEM/50 AM BSO to induce endogenous oxidative stress (B), the same three oxidation products were detected, although the presence of hydroxylated C11-BODIPY 581/591 (m/z 519) was less pronounced than in peroxynitrite incubations. When rat fibroblasts were cultured without oxidative stress for 48 h in serum containing DMEM, only a trace of oxidized probe (I) was detected (C). [19,20]. When lipids and concomitantly C11-BOD-IPY 581/591 were extracted from these cells and analyzed for C11-BODIPY 581/591 oxidation products, three BOD-IPY-derived components were identified: the intact C11-BODIPY 581/591 (m/z 503) and the two stable end products with m/z 419 and m/z 445 (Fig. 6B). ...
... C11-BODIPY 581/591 (per)oxidation in endogenously stressed Rat-1 fibroblasts Serum deprivation and GSH depletion are known to result in the generation of copious amounts of endogenous ROS, leading to apoptosis and/or necrosis [13,14,19,20]. After incorporation of C11-BODIPY 581/591 into Rat-1 fibroblast membranes and subsequent incubation under induction of endogenous stress by serum deprivation and the presence of BSO, three oxidized forms of the probe were detectable, mainly at m/z 419 with minor amounts of products at m/z 445 and m/z 519 (see Fig. 6B). ...
C11-BODIPY(581/591) is a fluorescent lipid peroxidation reporter molecule that shifts its fluorescence from red to green when challenged with oxidizing agents, i.e., reactive oxygen species (ROS) or reactive nitrogen species (RNS). To understand the molecular mechanism responsible for this shift, we studied the molecular rearrangements leading to the shift in fluorescence in C11-BODIPY(581/591). Furthermore, we aimed to determine if these rearrangements were dependent on the nature of the applied ROS, in homogenous solution, bilayer vesicles, and living cells. C11-BODIPY(581/591) was challenged with various ROS- or RNS-generating systems, including peroxynitrite, NO(2)(?), peroxides, and hydroxyl, alkoxyl, tyrosyl, and peroxyl radicals. The reaction products were subsequently analyzed by means of mass spectrometry. Our results show that the initial target for free radical-mediated oxidation is the conjugated diene interconnection between the BODIPY core and the terminal phenyl moiety, which already explains the shift in fluorescence properties of the probe. After oxidative challenge, three different stable products were identified, one of which was specific for oxidation by peroxynitrite. The two other stable end products had lost the entire phenyl moiety, irrespective of the type of radical generating system used. These products were also recovered from Rat-1 fibroblasts stressed either by GSH depletion/serum starvation or by exposure to peroxynitrite, and were the only C11-BODIPY(581/591) oxidation products detectable in these cells.
... The mammalian cell cytoskeleton has not been studied under such extreme nutrient deprivation. However, serum deprivation increased actin fiber thickness in mouse and human fibroblasts (Boraldi et al. 2008;Paddenberg et al. 2001) and low glucose redistributed F-actin in a mouse myoblast cell line (C2C12) (Williams et al. 2017). For RTgutGC in L15/salts, F-actin became prominently localized along the edges or circumference of many cells. ...
In order to develop an in vitro system to study the cell biology of starvation in the fish intestine, rainbow trout intestinal epithelial cells were subjected to three kinds of nutrient deprivation and evaluated for 7 days. The RTgutGC cell line was grown into monolayers in Leibovitz’s basal medium supplemented with fetal bovine serum (L15/FBS) and then subjected to deprivation of serum (L15); of serum, amino acids, and vitamin (L15/ex); and of all nutrients (L15/salts). After 7 days of nutrient deprivation, the cells remained attached to the plastic surface as monolayers but changes were seen in shape, with the cells becoming more polygonal, actin and α-tubulin cytoskeleton organization, and in tight junction protein-1 (ZO-1) localization. Two barrier functions, transepithelial electrical resistance (TEER) and Lucifer Yellow (LY) retention, were impaired by nutrient deprivation. In L15/FBS, cells rapidly healed a gap or wound in the monolayer. In L15 and L15/ex, some cells moved into the gap, but after 7 days, the wound remained unhealed, whereas in L15/salts, cells did not even migrate into the gap. Upon nutrient replenishment (L15/FBS) after 7 days in L15, L15/ex, or L15/salts, cells proliferated again and healed a wound. After 7 days of nutrient deprivation, monolayers were successfully passaged with trypsin and cells in L15/FBS grew to again form monolayers. Therefore, rainbow trout intestinal epithelial cells survived starvation, but barrier and wound healing functions were impaired.
... During apoptosis, cells undergo characteristic morphologic changes: cell shrinkage, nuclear shrinkage, chromatin condensation, and formation of apoptotic bodies (Kerr et al, 1972;Ra¡, 1992). These changes require a marked reorganization of the cytoskeleton (Yamazaki et al, 2000;Paddenberg et al, 2001). Micro¢laments have been suggested to be involved in morphologic changes of apoptosis, and indeed the cleavage of cytoskeletal proteins, including actin, by caspases was found in apoptotic cells (Chan and Mattson, 1999;Mashima et al, 1999). ...
To examine the possibility that staurosporine is applicable for the treatment of abnormal scar formation such as hypertrophic scar and keloid, the cellular process during staurosporine-induced apoptosis was analyzed in myofibroblasts isolated from a rat granulation tissue pouch. Staurosporine induced myofibroblast apoptosis in a time- and dose-dependent manner with typical morphologic changes. Staurosporine (1 microM) activated caspase-3 up to 3.6-fold by cleaving pro-caspase-3 (32 kDa) to active forms (17, 19, and 20 kDa). Microfilaments mainly composed of alpha-smooth muscle actin, a contractile protein characterizing myofibroblasts, were degraded during staurosporine-induced apoptosis. The degradation of alpha-smooth muscle actin bundles was detected as early as 1 h after the treatment with staurosporine. Recombinant active caspase-3 and staurosporine-stimulated caspase-3 both cleaved purified alpha-smooth muscle actin in vitro. These results suggested that alpha-smooth muscle actin is directly degraded by caspase-3 in response to apoptotic stimuli in myofibroblasts. In addition, bleomycin (100 ng per ml) and cisplatin (1 mM) also induced myofibroblast apoptosis by activating caspase-3, suggesting that these agents have a potential therapeutic value for abnormal scar formation.
... Both actin and ABPs are implicated as targets for activated caspases. Proteolytic cleavage of actin has been observed in some animal cell types (Brown et al., 1997; Gue Ânal et al., 1997; Korichneva and Ha Èmmerling, 1999; Paddenberg et al., 2001), although this is not a universal phenomenon (Levee et al., 1996; Bursch et al., 2000). Furthermore, there is evidence that several ABPs are also targets for caspase activity (Kothakota et al., 1997; Janmey, 1998; Umeda et al., 2001), including gelsolin. ...
The integration of signals received by a cell, and their transduction to targets, is essential for all cellular responses. The cytoskeleton has been identified as a major target of signalling cascades in both animal and plant cells. Self-incompatibility (SI) in Papaver rhoeas involves an allele-specific recognition between stigmatic S-proteins and pollen, resulting in the inhibition of incompatible pollen. This highly specific response triggers a Ca(2+)-dependent signalling cascade in incompatible pollen when a stigmatic S-protein interacts with it. It has been demonstrated recently that SI induces dramatic alterations in the organization of the pollen actin cytoskeleton. This implicates the actin cytoskeleton as a key target for the SI-stimulated signals. The cytological alterations to the actin cytoskeleton that are triggered in response to SI are described here and there seem to be several stages that are distinguishable temporally. Evidence was obtained that F-actin depolymerization is also stimulated. The current understanding that the actin cytoskeleton is a target for the signals triggered by the SI response is discussed. It is suggested that these F-actin alterations may be Ca(2+)-mediated and that this could be a mechanism whereby SI-induced tip growth inhibition is achieved. The potential for actin-binding proteins to act as key mediators of this response is discussed and the mechanisms that may be responsible for effecting these changes are described. In particular, the parallels between sustained actin rearrangements during SI and in apoptosis of animal cells are considered.
... Gsn, which is activated by Ca 2+ at micromolar levels, acidosis, and cleavage by caspase-3 (Kwiatkowski et al., 1989, modifies this process likely via depolymerization of actin filaments. Interestingly, gsn was shown to be redistributed towards actin filaments during apoptosis (Paddenberg et al., 2001). In turn, actin depolymerization by gsn protects from apoptosis at the mitochondrial level via inhibition of the PT pore. ...
Gelsolin (gsn), an actin-severing protein, protects neurons from excitotoxic cell death via inactivation of membranous Ca(2+) channels. Its role during apoptotic cell death, however, has remained unclear. Using several models of neuronal cell death, we demonstrate that endogenous gelsolin has anti-apoptotic properties that correlate to its dynamic actions on the cytoskeleton. We show that neurons lacking gelsolin (gsn(-/-)) have enhanced apoptosis following exposure to staurosporine, thapsigargin, or the cholinergic toxin ethylcholine aziridinium (AF64A). AF64A-induced loss of mitochondrial membrane potential and activation of caspase-3 was specifically enhanced in gsn(-/-) neurons and could be reversed by pharmacological inhibition of mitochondrial permeability transition. Moreover, increased caspase-3 activation and cell death in AF64A-treated gsn(-/-) neurons were completely reversed by pharmacological depolymerization of actin filaments and further enhanced by their stabilization. In conclusion, actin remodeling by endogenous gelsolin or analogues protects neurons from apoptosis mediated by mitochondria and caspase-3.
... Oregon Green labelled DNase I was employed to specifically stain monomeric actin. The microfilament system was visualised by staining paraformaldehyde fixed cells with TRITC-phalloidin as described (Paddenberg et al., 2001). Fluorescence microscopy and visualisation of microinjected fluorescent thymosin β 4 was achieved either using standard or confocal microscopy with a Zeiss Axiophot equipped with epifluorescence optics, or with a Zeiss LSM510 confocal microscope (Zeiss, Göttingen, Germany). ...
Thymosin beta4 is regarded as the main G-actin sequestering peptide in the cytoplasm of mammalian cells. It is also thought to be involved in cellular events like cancerogenesis, apoptosis, angiogenesis, blood coagulation and wound healing. Thymosin beta4 has been previously reported to localise intracellularly to the cytoplasm as detected by immunofluorescence. It can be selectively labelled at two of its glutamine-residues with fluorescent Oregon Green cadaverine using transglutaminase; however, this labelling does not interfere with its interaction with G-actin. Here we show that after microinjection into intact cells, fluorescently labelled thymosin beta4 has a diffuse cytoplasmic and a pronounced nuclear staining. Enzymatic cleavage of fluorescently labelled thymosin beta4 with AsnC-endoproteinase yielded two mono-labelled fragments of the peptide. After microinjection of these fragments, only the larger N-terminal fragment, containing the proposed actin-binding sequence exhibited nuclear localisation, whereas the smaller C-terminal fragment remained confined to the cytoplasm. We further showed that in digitonin permeabilised and extracted cells, fluorescent thymosin beta4 was solely localised within the cytoplasm, whereas it was found concentrated within the cell nuclei after an additional Triton X100 extraction. Therefore, we conclude that thymosin beta4 is specifically translocated into the cell nucleus by an active transport mechanism, requiring an unidentified soluble cytoplasmic factor. Our data furthermore suggest that this peptide may also serve as a G-actin sequestering peptide in the nucleus, although additional nuclear functions cannot be excluded.
... gelsolin. Redistribution of intact gelsolin to stress fibres and their degradation has been shown to occur after induction of apoptosis (Paddenberg et al., 2001). Gelsolin, which is normally regulated by calcium, is cleaved by caspase-3 (Kothakota et al., 1997): the Nterminal half is active in the absence of calcium and able to disrupt the microfilament system. ...
Etoposide inhibits topoisomerase II and induces apoptosis in human epidermoid cancer cells (A431) and normal rat fibroblasts (NRK) as verified by apoptotic morphology and chromatin degradation. Here we examine changes in the localisation of actin, cofilin and the Arp2/3 complex during the apoptotic process in response to etoposide. Twenty-four hours after etoposide addition, a large number of cells of both lines exhibited nuclear and cytoplasmic fragmentation with the formation of numerous blebs typical of apoptosis. Etoposide exposure induces dissolution of stress fibres and an increase in actin and cofilin in membrane patches and apoptotic blebs. The actin is more peripherally located than the cofilin, similar to that reported for lamellipodia of highly motile keratocytes. By contrast, in control cells, cofilin is evenly distributed throughout the cytoplasm, though often enriched around the nucleus. The active form is inferred to be more peripherally localised and to be present in apoptotic blebs, since an antibody specific for phosphorylated cofilin did not stain the cell periphery nor apoptotic blebs. Although immunoblots of 2D gels demonstrate that the ratio of de-phosphorylated to phosphorylated cofilin does not change after etoposide treatment, this does not mean that there are no changes in the turnover of the active and inactive forms. Transfection of both cell lines with EGFP-containing constructs of wild-type cofilin and mutants resembling its activated (S3A) and inactivated (S3D) forms shows that the active form has a more peripheral localisation and is also present in the membrane blebs with a strong colocalisation with actin. We further show that Arp2/3 also localises in apoptotic blebs and discuss the role of these proteins in apoptosis by analogy with actin-based protrusive motility in lamellipodia.
... Although actin proteolysis during apoptosis is still controversial (Mashima et al., 1997;Hengstenberg and Mannherz, 1998;Song et al., 1997), a number of actin-binding proteins were shown to be substrates of caspase-3, including gelsolin (Kothakota et al., 1997), a-fodrin (non-erythrocyte spectrin; Ja¨nicke et al., 1998) and plectin (Stegh et al., 2000). Recent data have shown that the dissolution of the microfilament system can be elicited either by the caspase-3-generated N-terminal fragment of gelsolin (Kothakota et al., 1997) or by activation of gelsolin itself (Paddenberg et al., 2001). Further candidate actin-binding proteins that modify its state of polymerisation are the members of the cofilin/ADF (actin-depolymerising factor) family, which also sever F-actin (Maciver et al., 1998). ...
The general protein kinase inhibitor staurosporine (STS) has dual effects on human epidermoid cancer cells (A431) and normal rat kidney fibroblasts (NRK). It almost immediately stimulated increased lamellipodial activity of both cell lines and after 2 h induced typical signs of apoptosis, including cytoplasmic condensation, nuclear fragmentation, caspase-3 activation and DNA degradation. In the early phase we observed disruption of actin-containing stress fibres and accumulation of monomeric actin in the perinuclear region and cell nucleus. Increased lamellipodial-like extensions were observed particularly in A431 cells as demonstrated by co-localisation of actin and Arp2/3 complex, whereas NRK cells shrunk and exhibited numerous thin long extensions. These extensions exhibited uncoordinated centrifugal motile activity that appeared to tear the cells apart. Both cofilin and ADF were translocated from perinuclear regions to the cell cortex and, as expected in the presence of a kinase inhibitor, all the cofilin was dephosphorylated. Myosin II was absent from the extensions, and a reduction of phosphorylated myosin light chains was observed within the cytoplasm indicating myosin inactivation. Microtubules and intermediate filaments retained their characteristic filamentous organisation after STS exposure even when the cells became rounded and disorganised. Simultaneous treatment of NRK cells with STS and the caspase inhibitor zVAD did not inhibit the morphological and cytoskeletal changes. However, the cells underwent cell death as verified by positive annexin-V-staining. Thus it seems likely that cell death induced by STS may not only be a consequence of the activation of caspase, instead the disruption of the many motile processes involving the actin cytoskeleton may by itself suffice to induce caspase-independent cell death.
... Several studies have investigated the role of airway epithelial tight junctions in the development of chronic disease. 32 NIH3T3 cells are originated from mouse embryonic fibroblastic cells localized at the cell cortex and adhesion regions, 33 and can provide an in vitro study model. We have examined the chemical properties of SA extract, and found that SA extract is unstable under long-term storage. ...
The raw juice of the young sticks and leaves of Sauropus androgynus (SA) has been widely used as a natural food for body weight reduction and vision protection in Taiwan and Southeast Asia. But as has been reported, SA-associated obliterative bronchiolitis can develop after taking SA for more than 3 months. Lung transplantation was carried out in severe cases.
To study the toxic effect, we separated the SA extract into three parts, namely CHCl3, EtOAc and n-BuOH fractions, using polarity dissection. NIH3T3 fibroblasts were treated with the SA fractions 300 microg/mL and subjected to a series of cytotoxic assays.
The EtOAc fraction exhibited the strongest effect of cell growth inhibition, followed by the CHCl3 and n-BuOH fractions. Features of condensed chromatin and apoptosis were observed in cells exposed to n-BuOH and EtOAc fractions using fluorescence microscopy. Formation of DNA ladders was also observed in the above cells. Instead, the CHCl3 fraction induced DNA smearing. In bivariate dot plots of annexin V and propidium iodide double staining, necrosis and apoptosis appeared in cells treated with CHCl3 and n-BuOH fractions, respectively, and a mixed type of necrosis and apoptosis appeared in EtOAc fraction-treated cells.
Our results indicate that necrosis and apoptosis are involved in the toxic effect of SA in NIH3T3 fibroblasts. More evidence is needed to clarify if necrosis and apoptosis are also related to the pathogenesis of SA-associated obliterative bronchiolitis.
... In striking contrast, Gadd45b expression prevented cell death under these conditions and maintained cell viability and growth ( Figure 6b). As it has been reported that serum deprivation induces classical caspase-dependent apoptosis (Paddenberg et al., 2001), we analysed the presence of cleaved and thus active caspase-3 in these cells (Figure 6c). Cleaved caspase-3 was detectable in all serum-starved NIH3T3 cells, but, consistent with the ability of Bcl-x L but not Gadd45b to block the caspase pathway, levels were significantly reduced in cells expressing Bcl-x L (Figure 6c). ...
Tumors that acquire resistance against death stimuli constitute a severe problem in the context of cancer therapy. To determine genetic alterations that favor the development of stress-resistant tumors in vivo, we took advantage of polyclonal tumors generated after retroviral infection of newborn Elambda-MYC mice, in which the retroviral integration acts as a mutagen to enhance tumor progression. Tumor cells were cultivated ex vivo and exposed to gamma-irradiation prior to their transplantation into syngenic recipients, thereby providing a strong selective pressure for pro-survival mutations. Secondary tumors developing from stress-resistant tumor stem cells were analysed for retroviral integration sites to reveal candidate genes whose dysregulation confer survival. In addition to the gene encoding the antiapoptotic Bcl-x(L) protein, we identified the gadd45b locus to be a novel common integration site in these tumors, leading to enhanced expression. In accord with a thus far undocumented role of Gadd45beta in tumorigenesis, we showed that NIH3T3 cells overexpressing Gadd45beta form tumors in NOD/SCID mice. Interestingly and differently to other known 'classical' antiapoptotic factors, high Gadd45beta levels did not protect against MYC-, UV- or gamma-irradiation-induced apoptosis, but conferred a strong and specific survival advantage to serum withdrawal.
... In contrast, in quiescent cultures, serum starvation has been described to cause cell death [4,5] and to favour the occurrence of a fibrotic response [6]. There are several reports in the literature concerning the effects of serum withdrawal on the expression of single proteins in different cell types [7][8][9], but a comprehensive analysis of changes occurring in the protein profile upon serum starvation has been never approached. ...
The effect of serum deprivation on proliferating cells is well known, in contrast its role on primary cell cultures, at confluence, has not been deeply investigated. Therefore, in order to explore the response of quiescent cells to serum deprivation, ubiquitous mesenchymal cells, as normal human dermal fibroblasts, were grown, for 48 h after confluence, in the presence or absence of 10% FBS. Fibroblast behaviour (i.e. cell morphology, cell viability, ROS production and elastin synthesis) was evaluated morphologically and biochemically. Moreover, the protein profile was investigated by 2-DE and differentially expressed proteins were identified by MS. Serum withdrawal caused cell shrinkage but did not significantly modify the total cell number. ROS production, as evaluated by the dihydroethidium (DH2) probe, was increased after serum deprivation, whereas elastin synthesis, measured by a colorimetric method, was markedly reduced in the absence of serum. By proteome analysis, 41 proteins appeared to significantly change their expression, the great majority of protein changes were related to the cytoskeleton, the stress response and the glycolytic pathway. Data indicate that human dermal fibroblasts in primary cell culture can adapt themselves to environmental changes, without significantly altering cell viability, at least after a few days of treatment, even though serum withdrawal represents a stress condition capable to increase ROS production, to influence cell metabolism and to interfere with cell behaviour, favouring the expression of several age-related features.
The use of (nanostructured lipid carries) NLC to disperse curcumin in aqueous media is widely found in literature. However, few studies systematically analyze the influence of the lipid matrix composition and the presence of curcumin on the physicochemical characteristics of NLC. Thus, the present work aimed to verify the influence of the NLC composition on its structure. Different solid lipid (SL) to liquid lipid (LL) ratios were evaluated, yielding NLC < 600 nm and <400 nm with the use of MCT and castor oil, respectively. The addition of Tween 80 favored the formation of smaller structures. Thermal analysis data confirmed the formation of different structures due to their different composition and also after the incorporation of curcumin. The present study also describes a correlation between the rheology of the NLC dispersion and the degree of structural organization of the NLC, indicating the formation of structures with a differentiated degree of organization. Photomicrographs showed the formation of two different structures, multiple types and amorphous, with drug concentrated in nucleus. In vitro studies have not shown significant IC50 differences between the systems developed with curcumin; however, the time and effectiveness of internalization were different for the two developed systems. The interaction between SL and LL demonstrated to be an important parameter that should be considered before the development of NLC, also the molecular characteristics of each component must be verified in order to develop NLC on a desirable type.
Formation of different protrusive structures by migrating cells is driven by actin polymerization at the plasma membrane region. Gelsolin is an actin binding protein controlling the length of actin filaments by its severing and capping activity. The main goal of this study was to determine the effect of gelsolin expression on the migration of human colon adenocarcinoma LS180 and melanoma A375 cells.
Colon adenocarcinoma cell line LS180 was stably transfected with plasmid containing human cytoplasmic gelsolin cDNA tagged to enhanced green fluorescence protein (EGFP). Melanoma A375 cells were transfected with siRNAs directed against gelsolin. Real-time PCR and Western blotting were used to determine the level of gelsolin. The ability of actin to inhibit DNase I activity was used to quantify monomeric and total actin level and calculate the state of actin polymerization. Fluorescence confocal microscopy was applied to observe gelsolin and vinculin distribution along with actin cytoskeleton organization.
Increased level of gelsolin expression leads to its accumulation at the submembranous region of the cell accompanied by distinct changes in the state of actin polymerization and an increase in the migration of LS180 cells. In addition, LS180 cells overexpressing gelsolin form podosome-like structures as indicated by vinculin redistribution and its colocalization with gelsolin and actin. Downregulation of gelsolin expression in melanoma A375 cells significantly reduces their migratory potential.
Our experimental data indicate that alterations in the expression level of gelsolin and its subcellular distribution may be directly responsible for determining migration capacity of human cancer cells.
Lamellipodial extension depends essentially on the polymerisation cycle of actin. In this cellular compartment the rate and extent of actin polymerisation is tightly regulated by a large number of actin-binding proteins. The main regulators comprise proteins of the actin-depolymerising factor (ADF)/cofilin family, which stimulate actin cycling, but there are also minor constituents like gelsolin and certain variants of tropomyosin that have so far not been considered to be lamellipodial constituents. A number of cell lines express ADF and cofilin simultaneously as shown here for the fibroblastic normal rat kidney (NRK) cell line. Both proteins co-localise in the lamellipodial region. We furthermore demonstrate the presence of gelsolin in lamellipodia by immunostaining with anti-gelsolin antibodies and transfection with EGFP-tagged gelsolin constructs. The presence of tropomyosins in lamellipodia has recently been reported (Hillberg et al., 2006. Tropomyosins are present in lamellipodia of motile cells. Eur. J. Cell Biol. 85, 399-409). In order to evaluate the effect of the simultaneous presence of ADF and cofilin together with tropomyosin and/or gelsolin on the polymerisation cycle of actin, we analysed their effect or combinations of these actin-binding proteins on the steady-state F-actin-ATPase activity in biochemical assays. Our results demonstrate stimulatory effects of ADF/cofilin on actin cycling and a further modulation of ADF/cofilin-stimulated F-actin-ATPase activity by gelsolin and tropomyosin in a complex manner.
Methotrexate is a widely used drug in treatments of various types of malignancies and in the therapy of rheumatoid arthritis. The goal of our study was to look at the effect of this dihydrofolate reductase inhibitor on the actin cytoskeleton, since actin plays an important role in cancer transformation and metastasis. For this reason we compared results obtained from experiments on CaSki (human uterine cervix cancer) and NRK (normal fibroblastic rat kidney) cells treated with methotrexate. It has been shown previously that methotrexate can induce apoptosis. Therefore we first examined whether methotrexate induces apoptosis in our model cells. For this aim we applied several assays like Caspase Glo 3/7, DNA fragmentation and binding of phosphatidylserine by annexin V-fluorescein. The data obtained indicated that methotrexate induces programmed cell death in CaSki and NRK cells. However, differences between CaSki and NRK cells were observed in the morphological alterations and dynamics of apoptosis induced by methotrexate. It seemed that cancer cells were more sensitive towards the cell death inducing activity at lower concentrations of methotrexate. Analysis by confocal microscopy of methotrexate-treated cells demonstrated that treatment with this folate antagonist affected the actin cytoskeleton, although the dis-organization of the actin cytoskeleton after treatment with methotrexate differed between cancer and normal cells.
The in vitro interaction between the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and cytoskeletal elements is well documented. To verify this association within cells, the intracellular distribution of GAPDH under various metabolic conditions has been investigated in immunostained cells or cells expressing GAPDH as a GFP fusion protein. GAPDH was homogeneously distributed in the cytoplasm and no interaction of GAPDH with cytoskeletal elements, neither with microfilaments nor microtubules or intermediate filaments, was detectable. In living cells expressing GFP-GAPDH, stress fibres were excluded from the fluorescence. In contrast to proliferating cells, the cytoplasmic GAPDH of serum-depleted cells was not homogeneously distributed, but colocalised with stress fibres. The mechanism for stimulating this actin-binding affinity was independent of the NO-signalling pathway. The results support the idea of a specialised function for the interaction of GAPDH and cytoskeletal elements, rather than a general function, as e.g. microcompartmentalization of glycolytic enzymes.
To examine the possibility that staurosporine is applicable for the treatment of abnormal scar formation such as hypertrophic scar and keloid, the cellular process during staurosporine-induced apoptosis was analyzed in myofibroblasts isolated from a rat granulation tissue pouch. Staurosporine induced myofibroblast apoptosis in a time- and a dose-dependent manner with typical morphological changes. Staurosporine activated caspase-3 up to 3.6-fold by cleaving pro-caspase-3 to active forms. Alpha-smooth muscle actin was degraded during staurosporine-induced apoptosis. The degradation of alpha-smooth muscle actin was detected at an early stage of staurosporine-induced apoptosis. Recombinant active caspase-3 and staurosporine-stimulated caspase-3 both cleaved purified alpha-smooth muscle actin in vitro. These results suggested that alpha-smooth muscle actin is directly degraded by caspase-3 in response to apoptotic stimuli in myofibroblasts.
The relationship between apoptotic progression and cell cycle perturbation induced by microtubule-destabilising (vinblastine, Colcemid) and -stabilising (taxol) drugs was studied in two mesenchyme-derived neoplastic cell lines, growing as suspension (Jurkat) and monolayer (SGS/3A) culture, by morphocytochemical and biochemical approaches. The same kind of drug induced different effects on the cell kinetics (proliferation, polyploidisation, death) of the two cell lines. In floating cells, the drugs appeared more effective during the S phase, while in adherent cells they were more effective during the G2/M phase. Moreover two distinct neoplasia-associated apoptotic phenotypes emerged: the first pattern was the typical one and was found in cells with a low transition through the S/G2 phase (Jurkat), and the second one was mainly characterised by a cell death derived from micronucleated and mitotic cells, as a consequence of a low transition through the M/G1 phase (SGS/3A). Our data show that the machinery required for the trigger and progression of apoptosis is present in every cell cycle phase, also in conditions of karyological alterations (aneugenic micronucleations). On the other hand, a different sensitivity of the two microtubular components (interphasic network and mitotic spindle) appears to be related to the anchorage-dependence or -independence during the cell growth disturbances after exposure to antimicrotubular drugs.
To investigate the ability of insulin-like growth factor (IGF)-1 to prevent apoptosis in lens epithelial cells and the involvement of phosphatidylinositol 3-kinase (PI-3K)/Akt and PI-3K/p70 S6 kinase (p70 S6K) signaling in the cell-survival process.
Apoptosis in rabbit lens epithelial cell cultures was induced by staurosporine (10 ng/mL). Cellular apoptosis was detected by identifying the characteristic ladder-like fragmentation of genomic DNA in agarose gels and the intense blue fluorescence exhibited by apoptotic nuclei of cells in live cultures in the presence of Hoechst 33,258 dye. Proliferation of lens epithelial cells grown in culture was measured with a DNA-binding fluorescent dye. Overexpression of the constitutively active Akt (CA-Akt) in epithelial cells was achieved by the transfection of cells using Fugene 6 reagent with a plasmid carrying Akt cDNA. Western immunoblotting was performed to identify various proteins of interest.
IGF-1 (5 to 50 nM) and insulin (100 to 400 nM) suppressed lens epithelial cell apoptosis in a dose-dependent manner, as determined by a significant inhibition of genomic DNA fragmentation and the decreased number of intense blue fluorescent Hoechst stain-positive apoptotic nuclei in live cultures. DNA degradation was almost completely inhibited in the presence of 50 nM IGF-1 or 400 nM insulin. PI-3K inhibitors wortmannin and LY294002 blocked the IGF-1 effect on cell survival. Stimulation of lens epithelial cells with IGF-1 for 10 minutes to 24 hours resulted in the sustained activation of both Akt and p70 S6K. IGF-1 also induced the phosphorylation of Bad (a pro-apoptotic protein of the Bcl-2 family), which was inhibited by PI-3K inhibitors, but not by the p70 S6K inhibitor rapamycin. Furthermore, activation of Akt but not p70 S6K signaling by IGF-1 resulted in the inhibition of caspase-3 endogenous substrate poly (ADP-ribose) polymerase (PARP) degradation and apoptosis. The overexpression of CA-Akt in lens epithelial cells inhibited PARP breakdown and suppressed apoptosis. Inhibition of p70 S6K activation by rapamycin blocked IGF-1-promoted lens epithelial cell proliferation but not the cell-survival effect.
These studies demonstrated a role for IGF-1 in the prevention of the lens epithelial cell apoptosis process. Furthermore, these studies indicated that anti-apoptotic and proliferative signals from IGF-1 bifurcate downstream of PI-3K. Whereas IGF-1-mediated PI-3K/Akt signaling plays a pivotal role in cell survival by inactivating proapoptotic Bad protein and suppressing caspase activation, its stimulation of the PI-3K/p70 S6K cascade promotes proliferation.
Apoptosis is essential in embryonic development, clonal selection of cells of the immune system and in the prevention of cancer. Apoptotic cells display characteristic changes in morphology that precede the eventual fragmentation of nuclear DNA resulting in cell death. Current evidence implicates DNase I as responsible for hydrolysis of DNA during apoptosis. In vivo, it is likely that cytoplasmic actin binds and inhibits the enzymatic activity and nuclear translocation of DNase I and that disruption of the actin-DNase I complex results in activation of DNase I. In this report we demonstrate that the N-terminal fragment of gelsolin (N-gelsolin) disrupts the actin-DNase I interaction. This provides a molecular mechanism for the role of the N-gelsolin in regulating DNase I activity. We also show that cofilin stabilises the actin-DNase I complex by forming a ternary complex that prevents N-gelsolin from releasing DNase I from actin. We suggest that both cofilin and gelsolin are essential in modulating the release of DNase I from actin.
Cell-extracted valvular tissues (acellular scaffolds, or aScaffolds) offer unique advantages over synthetic polymers for cardiac valve engineering applications in that they retain extracellular matrix molecules to support cellular ingrowth. The extracellular matrix is important in directing many cellular pathways, such as adhesion, proliferation, migration, differentiation, and survival. However, repopulating this type of scaffold often requires high seeding densities or recurrent cell delivery. The optimization of valvular interstitial cell (VIC) seeding onto aScaffolds is reported herein. VICs (the most prevalent cell type in valve leaflets) have maximal growth in 15-20% serum concentrations on tissue-culture polystyrene. Interestingly, after VIC seeding onto aScaffolds, a reduction of serum content, from 15% serum to 5% or less, was found to increase significantly the number of adherent cells, as well as induce transfer of VICs from a tissue-culture polystyrene surface to the aScaffold. aScaffolds seeded and cultured with periods of reduced serum levels were shown to support and enhance VIC viability and attachment, as well as accelerate VIC migration into the aScaffold, leading to a uniformly repopulated valve leaflet construct after 4 weeks of static culture.
We demonstrate that global induction of apoptosis in primary bovine lens epithelial (LEC) or fibroblastic mouse NIH-3T3 cells by staurosporine, puromycin, cycloheximide, or etoposide is accompanied by a decrease in coupling by gap junctions. Cell coupling as tested by neurobiotin spreading was maintained when the LEC or NIH-3T3 cells were pre-incubated with the pan-caspase inhibitor zVAD or the caspase-3 inhibiting tetrapeptide DEVD. Immunohistochemistry using anti-connexin-43 antibodies showed a reduction of plasma membrane integrated connexin-43 in both cell lines when undergoing apoptosis. Western blotting indicated degradation of connexin-43 that was inhibited by zVAD or DEVD. Cell coupling at single cell level was tested by direct microinjecting into LEC apoptosis-inducing agents of low molecular mass like staurosporine, etoposide and puromycin or the high molecular mass proteins caspase-3 and -8 in activated state. Microinjection of puromycin or etoposide induced apoptotic morphological changes of only the injected cell within 90 or 180 min, but did not affect adjacent cells. In contrast, microinjection of staurosporine led to a rapid induction of apoptosis of the injected and a number of adjacent cells suggesting spreading of staurosporine most probably through gap junction pores held open by dephosphorylation of connexin-43 as verified by immunoblotting and staining using a phospho-serine368-specific anti-connexin-43 antibody. Microinjection of active caspase-8 led after 3 h to morphological apoptotic alterations of only the injected cell, but did not inhibit spreading of co-injected neurobiotin to neighboring cells during the first hour. In contrast, microinjection of active caspase-3-induced apoptosis only of the injected cell after 60 min and rapidly and completely suppressed coupling to neighboring cells.
Multiple isoforms of tropomyosin (TM) of rat cultured cells show differential effects on actin-severing activity of gelsolin. Flow birefringence measurements have revealed that tropomyosin isoforms with high Mrvalues (high MrTMs) partially protect actin filaments from fragmentation by gelsolin, while tropomyosins with low Mrvalues (low MrTMs) have no significant protection even when the actin filaments have been fully saturated with low MrTMs. We have also examined effect of nonmuscle caldesmon on the severing activity of gelsolin because 83-kDa nonmuscle caldesmon stimulates actin binding of rat cell TMs (Yamashiro-Matsumura, S., and Matsumura, F. (1988) J. Cell Biol. 106, 1973–1983). While nonmuscle caldesmon alone or low MrTMs alone show no significant protection against fragmentation by gelsolin, the low MrTMs coupled with 83-kDa protein are able to protect actin filaments. Further, high MrTMs together with 83-kDa protein appear to block the severing activity completely. Electron microscopic analyses of length distribution of actin filaments have confirmed the results. The average length of control actin filaments is measured as 1.46 ± 1.0 µM, and gelsolin shortens the average length to 0.084 ± 0.039 µM. Similar short average lengths are obtained when gelsolin severs actin complexed with low MrTMs (0.080 ± 0.045 µM) or with nonmuscle caldesmon (0.11 ± 0.072 µM) while longer average length (0.22 ± 0.18 µM) is measured in the presence of high MrTMs. The simultaneous addition of nonmuscle caldesmon makes the average length considerably longer, i.e. 0.61 ± 0.37 µM in the presence of low MrTMs and 1.57 ± 0.97 µM in the presence of high MrTMs. Furthermore, the actin binding of gelsolin is strongly inhibited by co-addition of high MrTMs and nonmuscle caldesmon. These results suggest that TM and gelsolin share the same binding site on actin molecules and that the differences in the actin affinities between TMs are related to their abilities of protection against gelsolin.
A new method of total RNA isolation by a single extraction with an acid guanidinium thiocyanate-phenol-chloroform mixture is described. The method provides a pure preparation of undegraded RNA in high yield and can be completed within 4 h. It is particularly useful for processing large numbers of samples and for isolation of RNA from minute quantities of cells or tissue samples.
After androgen ablation by castration, the epithelial cells of the rat ventral prostate are eliminated by apoptosis. The number of cells showing apoptotic chromatin degradation increases with time up to day 3 after castration as verified by in situ end labeling of fragmented DNA. Apoptotic chromatin degradation is catalyzed by a Ca2+, Mg2+-dependent endonuclease. Recently, evidence has been presented that suggests deoxyribonuclease I (DNase I) is identical or very closely related to the apoptotic endonuclease (Peitsch, M.C., B. Polzar, H. Stephan, T. Crompton, H.R. MacDonald, H.G. Mannherz, and J. Tschopp. 1993. EMBO [Eur. Mol. Biol. Organ.] J. 12:371–377). Therefore, the expression of DNase I in the ventral prostate of the rat was analyzed before and after androgen ablation at the level of protein, enzymatic activity, and gene transcripts using immunohistochemical and biochemical techniques. DNase I immunoreactivity was detected only in a few single epithelial cells before androgen ablation. After castration, a time-dependent increase in DNase I immunoreactivity was observed within the epithelial cells. It first appeared after about 12 h in the apical region of a large number of epithelial cells. Up to day 3 after castration, the intracellular DNase I antigenicity continuously increased, and the cell nuclei gradually became DNase I positive. At day 5, almost all nuclei of the epithelium were stained by anti–DNase I. DNase I immunoreactivity was particularly concentrated in cells showing morphological signs of apoptosis, like nuclear fragmentation, and in many cases was found to persist in apoptotic bodies. DNase I gene transcripts were detected in control animals using dot and Northern blotting as well as RNase protection assay. After androgen ablation, the amount of DNase I gene transcripts in total extractable RNA was found unchanged or only slightly decreased up to day 5. Their exclusive localization within the epithelial cells was verified by in situ hybridization. Before castration, the DNase I gene transcripts were homogeneously distributed in all epithelial cells. At day 3, DNase I–specific mRNA was found to be highly concentrated in cells of apoptotic morphology. Using the zymogram technique, a single endonucleolytic activity of about 32 kD was detected in tissue homogenates before castration. After androgen ablation, the endonucleolytic activity increased about four- to sevenfold up to day 3. At day 5, however, it had dropped to its original level. At day 1, three new endonucleolytic variants of higher molecular mass were expressed. At day 3, the predominant endonucleolytic activity exhibited an apparent molecular mass of 32 kD. Enzymatic analysis of the endonucleases present in prostate homogenates before and after castration demonstrated properties identical to DNase I. They were inhibited by chelators of divalent cations, Zn2+ ions and monomeric actin. Immunodepletion was achieved by immobilized antibodies specific for rat parotid DNase I. A polyclonal antibody raised against denatured DNase I was shown by Western blotting to stain a 32-kD band after enrichment of the endonuclease from day 0 and 3 homogenates by preparative gel electrophoresis. The data thus indicate that androgen ablation leads to translational upregulation of an endonucleolytic activity with properties identical to DNase I in rat ventral prostate, followed by its intracellular retention and final nuclear translocation in those epithelial cells that are destined to apoptotic elimination.
The induction of cell death along with cell-cycle arrest is one of the foremost mechanisms regulating cell growth. In the human breast carcinoma cell line MCF-7 we investigated two chemotherapeutic agents, the antiestrogen tamoxifen and the DNA-damaging drug cisplatin, for the relative contribution of these mechanisms to growth inhibition in culture. Growth kinetics and flow cytometry confirmed that tamoxifen at 1 M acts mainly by arresting cells in the G0/G1 phase of the cell cycle. Compared to untreated controls, only a few more cells were detached from the monolayer and dead after a 5-day incubation. On the other hand, cisplatin at 1 M did not induce the well-defined G2/M-arrest reported for other cell types, but resulted in a marked increase in the rate of cell death. A morphological feature observed, especially with cisplatin-treated MCF-7 cells, was the formation of numerous micronuclei (in up to 30% of the cells) and an increase in the number of binucleate cells (up to 20%). In both tamoxifen- and cisplatin-treated cultures, cell death appeared to occur by apoptosis, as indicated morphologically by cellular and nuclear shrinkage accompanied by DNA-condensation and ultimately the formation of DNA containing apoptotic bodies. However, no internucleosomal DNA degradation or endogenous endonuclease activity could be detected in the cells of the monolayer or in the mainly dead and detached cells of the culture supernatant. DNA fragmentation was only observed when isolated MCF-7 nuclei were incubated with exogenous endonucleases. However, as determined by reverse transcriptase/polymerase chain reaction amplification, MCF-7 cells do express the mRNA for DNase I, an endonuclease known to be involved in apoptosis. Thus, apoptosis is part of the growth-inhibitory process and occurs without apparent internucleosomal DNA fragmentation in MCF-7 cell cultures.
To date, apoptosis has been characterized biochemically by the production of 180-200 bp internucleosomal DNA fragments resulting from the activation of an endonuclease(s). The principal morphological feature of apoptosis is the condensation of chromatin and it has been assumed that this may reflect the oligonucleosomal fragmentation pattern. We have re-examined this dogma by comparing the biochemical and morphological features of cell death in several epithelial cell types (HT-29-I1 colon adenocarcinoma, CC164 mink lung, DU-145 human prostatic carcinoma and MCF-7 human breast adenocarcinoma) and one mesenchymal cell line (H11ras-R3 ras-transformed rat fibroblasts). Cell death was induced either by serum deprivation, TGF-beta 1 or etoposide, or by leaving cells to reach confluence. Cell death was assessed with respect to detachment from monolayers, morphological changes and DNA integrity. The DNA-binding fluorophore Hoechst 33258 revealed chromatin condensation patterns consistent with apoptotic cell death in all cell types except MCF-7 cells. Using field inversion gel electrophoresis in conjunction with conventional 2% agarose gel electrophoresis, cleavage of DNA to 50 kbp fragments was observed in all cases except MCF-7 cells. This preceded the appearance of oligonucleosomal fragments in HT-29-I1, CC164 and H11ras-R3 cells. Although the DNA of DU-145 cells fragmented into 50 kbp units, and although the cells exhibited classical apoptotic morphology, no subsequent internucleosomal cleavage was observed. These results suggest that changes in the integrity of DNA indicative of the release of chromatin loop domains occur before cleavage at internucleosomal sites is initiated and that the latter is not an essential step in the apoptotic process.
Rac, a member of the rho family of GTPases, when activated transmits signals leading to actin-based membrane ruffling in fibroblasts. Compared with wild-type fibroblasts, gelsolin null (Gsn-) dermal fibroblasts have a markedly reduced ruffling response to serum or EGF stimulation, which signal through rac. Bradykinin-induced filopodial formation, attributable to activation of cdc42, is similar in both cell types. Wild-type fibroblasts exhibit typical lamellipodial extension during translational locomotion, whereas Gsn- cells move 50% slower using structures resembling filopodia. Multiple Gsn- tissues as well as Gsn- fibroblasts overexpress rac, but not cdc42 or rho, 5-fold. Re-expression of gelsolin in Gsn- fibroblasts by stable transfection or adenovirus reverts the ruffling response, translational motility and rac expression to normal. Rac migrates to the cell membrane following EGF stimulation in both cell types. Gelsolin is an essential effector of rac-mediated actin dynamics, acting downstream of rac recruitment to the membrane.
Gelsolin is an actin-regulatory protein that modulates actin assembly and disassembly, and is believed to regulate cell motility in vivo through modulation of the actin network. In addition to its actin-regulatory function, gelsolin has also been proposed to affect cell growth. Our present experiments have tested the possible involvement of gelsolin in the regulation of apoptosis, which is significantly affected by growth. When overexpressed in Jurkat cells, gelsolin strongly inhibited apoptosis induced by anti-Fas antibody, C2-ceramide or dexamethasone, without changing the F-actin morphology or the levels of Fas or Bcl-2 family proteins. Upon the induction of apoptosis, an increase in CPP32(-like) protease activity was observed in the control vector transfectants, while it was strongly suppressed in the gelsolin transfectants. Pro-CPP32 protein, an inactive form of CPP32 protease, remained uncleaved by anti-Fas treatment in the gelsolin transfectants, indicating that gelsolin blocks upstream of this protease. The tetrapeptide inhibitor of CPP32(-like) proteases strongly inhibited Fas-mediated apoptosis, but only partially suppressed both C2-ceramide- and dexamethasone-induced apoptosis. These data suggest that the critical target responsible for the execution of apoptosis may exist upstream of CPP32(-like) proteases in Jurkat cells and that gelsolin acts on this target to inhibit the apoptotic cell death program.
A new method of total RNA isolation by a single extraction with an acid guanidinium thiocyanate-phenol-chloroform mixture is described. The method provides a pure preparation of undegraded RNA in high yield and can be completed within 4 h. It is particularly useful for processing large numbers of samples and for isolation of RNA from minute quantities of cells or tissue samples.
Gelsolin, a Ca2+-sensitive protein present in many mammalian cells, regulates actin filament length by multiple mechanisms. In tumor cells, increased amounts of F-actin without change in its total amount have been observed, suggesting a modification in the organisation of this protein. The authors have localized gelsolin, total actin, alpha-smooth muscle actin, and prekeratin in frozen sections of normal human breast and infiltrating duct carcinomas by immunohistochemistry. A positive staining for gelsolin was observed in normal epithelial and myoepithelial cells but not in stromal fibroblasts. In contrast, no staining for gelsolin was detectable in carcinomatous cells, with the exception of remaining myoepithelial cells; myofibroblasts of the stromal reaction displayed an intense positive reaction. The absence of gelsolin staining in the epithelial cells of breast carcinoma may reflect their dedifferentiation or proliferative and invasive activities. The appearance of gelsolin in stromal cells raises the question as to what is its function in this situation. The immunohistochemical detection of gelsolin may be a useful adjunct to the study of mammary gland epithelium malignant transformation.
Multiple isoforms of tropomyosin (TM) of rat cultured cells show differential effects on actin-severing activity of gelsolin. Flow birefringence measurements have revealed that tropomyosin isoforms with high Mr values (high Mr TMs) partially protect actin filaments from fragmentation by gelsolin, while tropomyosins with low Mr values (low Mr TMs) have no significant protection even when the actin filaments have been fully saturated with low Mr TMs. We have also examined effect of nonmuscle caldesmon on the severing activity of gelsolin because 83-kDa nonmuscle caldesmon stimulates actin binding of rat cell TMs (Yamashiro-Matsumura, S., and Matsumura, F. (1988) J. Cell Biol. 106, 1973-1983). While nonmuscle caldesmon alone or low Mr TMs alone show no significant protection against fragmentation by gelsolin, the low Mr TMs coupled with 83-kDa protein are able to protect actin filaments. Further, high Mr TMs together with 83-kDa protein appear to block the severing activity completely. Electron microscopic analyses of length distribution of actin filaments have confirmed the results. The average length of control actin filaments is measured as 1.46 +/- microns, and gelsolin shortens the average length to 0.084 +/- 0.039 micron. Similar short average lengths are obtained when gelsolin severs actin complexed with low Mr TMs (0.080 +/- 0.045 micron) or with nonmuscle caldesmon (0.11 +/- 0.072 micron) while longer average length (0.22 +/- 0.18 micron) is measured in the presence of high Mr TMs. The simultaneous addition of nonmuscle caldesmon makes the average length considerably longer, i.e. 0.61 +/- 0.37 micron in the presence of low Mr TMs and 1.57 +/- 0.97 micron in the presence of high Mr TMs. Furthermore, the actin binding of gelsolin is strongly inhibited by co-addition of high Mr TMs and nonmuscle caldesmon. These results suggest that TM and gelsolin share the same binding site on actin molecules and that the differences in the actin affinities between TMs are related to their abilities of protection against gelsolin.
Human plasma gelsolin has been expressed in high yield and soluble form in Escherichia coli. The protein has nucleating and severing activities identical to those of plasma gelsolin and is fully calcium sensitive in its interactions with monomeric actin. A number of deletion mutants have been expressed to explore the function of the three actin binding sites. Their design is based on the sixfold segmental repeat in the protein sequence. (These sites are located in segment 1, segments 2-3, and segments 4-6). Two mutants, S1-3 and S4-6, are equivalent to the NH2- and COOH-terminal halves of the molecule obtained by limited proteolysis. S1-3 binds two actin monomers in the presence or absence of calcium, it severs and caps filaments but does not nucleate polymerization. S4-6 binds a single actin monomer but only in calcium. These observations confirm and extend current knowledge on the properties of the two halves of gelsolin. Two novel constructs have also been studied that provide a different pairwise juxtaposition of the three sites. S2-6, which lacks the high affinity site of segment 1 (equivalent to the 14,000-Mr proteolytic fragment) and S1,4-6, which lacks segments 2-3 (the actin filament binding domain previously identified using the 28,000-Mr proteolytic fragment). S2-6 binds two actin monomers in calcium and nucleates polymerization; it associates laterally with filaments in the presence or absence of calcium and has a weak calcium-dependent fragmenting activity. S1,4-6 also binds two actin monomers in calcium and one in EGTA, has weak severing activity but does not nucleate polymerization. A model is presented for the involvement of the three binding sites in the various activities of gelsolin.
Gelsolin is a 90,000-mol-wt Ca2+-binding, actin-associated protein that can nucleate actin filament growth, sever filaments, and cap barbed filament ends. Brevin is a closely related 92,000-mol-wt plasma protein with similar properties. Gelsolin has been reported to be localized on actin filaments in stress fibers, in cardiac and skeletal muscle I-bands, and in cellular regions where actin filaments are known to be concentrated. Previous localization studies have used sera or antibody preparations that contain brevin. Using purified brevin-free IgG and IgA monoclonal antibodies or affinity-purified polyclonal antibodies for gelsolin and brevin, we find no preferential stress fiber staining in cultured human fibroblasts or I-band staining in isolated rabbit skeletal muscle sarcomeres. Cardiac muscle frozen sections show no pronounced I-band staining, except in local areas where brevin may have penetrated from adjacent blood vessels. Spreading platelets show endogenous gelsolin localized at the cell periphery, in the central cytoplasmic mass and on thin fibers that radiate from the central cytoplasm. Addition of 3-30 micrograms/ml of brevin to the antibodies restores intense stress fiber and I-band staining. We see no evidence for large-scale severing and removal of filaments in stress fibers in formaldehyde-fixed, acetone-permeabilized cells even at brevin concentrations of 30 micrograms/ml. The added brevin or brevin antibody complex binds to actin filaments and is detected by the fluorescently tagged secondary antibody. Brevin binding occurs in either Ca2+ or EGTA, but is slightly more intense in EGTA suggesting some severing and filament removal may occur in Ca2+. The I-band staining is limited to the region where actin and myosin do not overlap. In addition, brevin does not appear to bind at the Z-line. A comparison of cells double-labeled with fluorescein-phallotoxin, exogenous brevin, and a monoclonal antibody, detected with a rhodamine-labeled secondary antibody, shows almost complete co-localization of F-actin with the brevin-gelsolin-binding sites. A major exception is in the area of the adhesion plaque. A quantitative comparison of the fluorescein-rhodamine fluorescence intensities along a stress fiber and into the adhesion plaque shows that the fluorescein signal, associated with F-actin, increases while the rhodamine signal decreases. We infer that exogenous brevin or endogenous gelsolin can bind to and potentially sever most actin filaments, but that actin-associated proteins in the adhesion plaque can prevent binding and severing.(ABSTRACT TRUNCATED AT 400 WORDS)
Gelsolins are actin-binding proteins that cap, nucleate, and sever actin filaments. Microinjection of cytoplasmic or plasma gelsolin into living fibroblasts and macrophages did not affect the shape, actin distribution, deformability, or ruffling activity of the cells. Gelsolin requires calcium for activity, but the NH2-terminal half is active without calcium. Microinjection of this proteolytic fragment had marked effects: the cells rounded up, stopped ruffling, became soft, and stress fibers disappeared. These changes are similar to those seen with cytochalasin, which also caps barbed ends of actin filaments. Attempts to raise the cytoplasmic calcium concentration and thereby activate the injected gelsolin were unsuccessful, but the increases in calcium concentration were minimal or transient and may not have been sufficient. Our interpretation of these results is that at the low calcium concentrations normally found in cells, gelsolin does not express the activities observed in vitro at higher calcium concentrations. We presume that gelsolin may be active at certain times or places if the calcium concentration is elevated to a sufficient level, but we cannot exclude the existence of another molecule that inhibits gelsolin. Microinjection of a 1:1 gelsolin/actin complex had no effect on the cells. This complex is stable in the absence of calcium and has capping activity but no severing and less nucleation activity as compared with either gelsolin in calcium or the NH2-terminal fragment. The NH2-terminal fragment-actin complex also has capping and nucleating activity but no severing activity. On microinjection it had the same effects as the fragment alone. The basis for the difference between the two complexes is unknown. The native molecular weight of rabbit plasma gelsolin is 82,500, and the extinction coefficient at 280 nm is 1.68 cm2/mg. A new simple procedure for purification of plasma gelsolin is described.
Little is known about the regulation of apoptosis in fibroblasts although several model systems including serum deprivation and treatment with staurosporine or topoisomerase inhibitors have been used to induce apoptosis in vitro. To validate a reproducible in vitro model for the study of apoptosis in fibroblasts, we cultured density-inhibited monolayer cultures of Balb/c 3T3 fibroblasts in Dulbecco's modified essential medium plus 15% fetal calf serum and then withdrew serum. Time-lapse video microscopy demonstrated that within minutes of serum withdrawal, cells lost substrate attachment and floated to the top of the liquid growth medium. There was a time-dependent increase in the number of non-adherent cells. Some of these cells regained attachment and spread momentarily, but they eventually rounded up and lost attachment permanently. In contrast to serum-containing cultures in which similar morphological changes were followed by mitosis, in serum-free cultures repeated attempts at mitosis were followed by permanent attachment loss and presumably cell death. To assess whether all the non-adherent cells were in fact dead, the percentages of cells that continued to proliferate upon return to serum-supplemented conditions was computed. After various periods of serum starvation a decreasing proportion (approx. 75% at 30 minutes; < 2% at 24 hours) of the non-adherent cells could be rescued by addition of serum. Transmission electron microscopy of cells 3 hours after serum withdrawal showed that the majority (approximately 60%) of non-adherent cells exhibited marked intranuclear chromatin condensation but maintained integrity of cell and nuclear membranes and cell organelles, morphological changes consistent with those of apoptotic cell death. Scanning electron microscopy of cultures 3 hours following serum withdrawal showed rounded cells with marked surface blebbing. Fluorescence and confocal microscopy revealed increased intensity of nuclear staining with DAPI while actin filaments became indistinct or collapsed around the nucleus. After cycloheximide treatment to inhibit protein synthesis, there was no reduction of apoptosis. Gel electrophoresis of DNA from both control and 3 hour-serum-deprived cells showed intact DNA with no oligonucleosomal length fragmentation. After serum withdrawal, intracellular calcium was reduced by about 32% over 5 minutes as measured by fura2 ratio fluorimetry in single cells. Serum-starved cells showed a time-dependent shrinkage in mean cell diameter compared to trypsinized, adherent control cells (at 0 hours, mean diameter = 18.0 microns--viable; at 4 hours, mean diameter = 15.5 microns--apoptotic). Flow cytometric analysis showed increased propidium iodide staining and reduced fluorescein diacetate uptake over 3 hours, changes that were contemporaneous with the reduction of cell diameter.(ABSTRACT TRUNCATED AT 400 WORDS)
To date, apoptosis has been characterized biochemically by the production of 180-200 bp internucleosomal DNA fragments resulting from the activation of an endonuclease(s). The principal morphological feature of apoptosis is the condensation of chromatin and it has been assumed that this may reflect the oligonucleosomal fragmentation pattern. We have re-examined this dogma by comparing the biochemical and morphological features of cell death in several epithelial cell types (HT-29-I1 colon adenocarcinoma, CC164 mink lung, DU-145 human prostatic carcinoma and MCF-7 human breast adenocarcinoma) and one mesenchymal cell line (H11ras-R3 ras-transformed rat fibroblasts). Cell death was induced either by serum deprivation, TGF-beta 1 or etoposide, or by leaving cells to reach confluence. Cell death was assessed with respect to detachment from monolayers, morphological changes and DNA integrity. The DNA-binding fluorophore Hoechst 33258 revealed chromatin condensation patterns consistent with apoptotic cell death in all cell types except MCF-7 cells. Using field inversion gel electrophoresis in conjunction with conventional 2% agarose gel electrophoresis, cleavage of DNA to 50 kbp fragments was observed in all cases except MCF-7 cells. This preceded the appearance of oligonucleosomal fragments in HT-29-I1, CC164 and H11ras-R3 cells. Although the DNA of DU-145 cells fragmented into 50 kbp units, and although the cells exhibited classical apoptotic morphology, no subsequent internucleosomal cleavage was observed. These results suggest that changes in the integrity of DNA indicative of the release of chromatin loop domains occur before cleavage at internucleosomal sites is initiated and that the latter is not an essential step in the apoptotic process.
Recent research on F-actin capping proteins has concentrated on three main areas. The discovery that controlled actin polymerization is the driving force for intracellular movement suggests an important role for capping proteins in regulating filament number and length. A capping protein from Dictyostelium (related to heat-shock protein HSP70) has been characterized that is activated by external stimuli. This provides a pivotal connection between extracellular signalling, cytoskeletal reorganization and locomotory behaviour. The roles of individual actin-binding sites in the gelsolin family of severing/capping proteins and binding sites for phosphatidylinositol 4,5-bisphosphate have been identified.
Gelsolin nucleates actin filament assembly, blocks the fast-exchanging ends of actin filaments, and severs filaments, processes that may play an important role in cell motility. We studied the relationship between cell migration, gelsolin content, and actin severing activity in human gingival fibroblasts. These cells were keratin negative and desmin negative but expressed vimentin and myosin II. Cells were separated by their ability to migrate in response to a chemoattractant stimulus. Northern analysis of mRNA, [35S]methionine incorporation into immunoprecipitated gelsolin, immunoblots of cell lysates, and quantitative confocal microscopy showed 1.4-2-fold higher levels of gelsolin in nonmigrant compared with migrant cells. Because the concentration of intracellular gelsolin did not appear to be a central determinant of cell migration, we assessed its requirement for motility. Cells that were electroinjected with a gelsolin antibody that inhibits actin severing by gelsolin in vitro showed a 72% reduction of the number of migrant cells compared with controls treated with an irrelevant antibody. Cells that were electroinjected with free gelsolin exhibited a 33% increase in migration compared with cells electroinjected with bovine serum albumin. Compared with nonmigrant cells, migrant cells contained abundant free gelsolin and exhibited gelsolin-dependent F-actin severing activity, which required Ca2+. Serum stimulation of cell migration required increases in [Ca2+]i because incubation with 3 microM 1,2-bis-(o-aminophenoxy)-ethane-N,N, N',N'-tetraacetic acid tetra(acetoxymethyl)-ester blocked calcium flux and cell migration. Serum also stimulated the recruitment of gelsolin into the supernatants of lysates from migrant but not from nonmigrant cells. In fibroblasts, gelsolin concentration alone does not apparently determine migratory capacity. Instead, the Ca2+-dependent actin severing activity of free gelsolin appears to be a major determinant of cell migration.
A small number of cellular proteins present in the nucleus, cytosol, and membrane fraction are specifically cleaved by the interleukin-1beta-converting enzyme (ICE)-like family of proteases during apoptosis. Previous results have demonstrated that one of these, the cytoskeletal protein actin, is degraded in rat PC12 pheochromocytoma cells upon serum withdrawal. Extracts from etoposide-treated U937 cells are also capable of cleaving actin. It was assumed that cleavage of actin represented a general phenomenon, and a mechanism coordinating proteolytic, endonucleolytic, and morphological aspects of apoptosis was proposed. We demonstrate here that actin is resistant to degradation in several different human cells induced to undergo apoptosis in response to a variety of stimuli, including Fas ligation, serum withdrawal, cytotoxic T-cell killing, and DNA damage. On the other hand, cell-free extracts from these cells and the ICE-like protease CPP32 were capable of cleaving actin in vitro. We conclude that while actin contains cleavage sites for ICE-like proteases, it is not degraded in vivo in human cells either because of lack of access of these proteases to actin or due to the presence of other factors that prevent degradation.
Interleukin-1beta-converting enzyme (ICE)/ced-3 family proteases play key roles in apoptosis. However, cellular substrates for ICE family proteases involved in apoptosis are not well understood. We previously showed that actin is cleaved in vitro by an ICE family protease, distinct from ICE itself, which is activated during VP-16-induced apoptosis. In this report, we demonstrate that the actin-cleaving ICE-family protease in the apoptotic cell extract is the activated CPP-32/apopain. CPP-32 effectively cleaves actin protein to 15 kDa and 31 kDa fragments. Studies with an antibody raised against Gly-Gln-Val-Ile-Thr peptide, the N-terminal sequence of the cleaved 15 kDa actin fragment, showed that actin is also cleaved in vivo during the development of apoptosis. Moreover, Benzyloxycarbonyl-Glu-Val-Asp-CH2OC(O)-2,6,-dichlorobenzene (Z-EVD-CH2-DCB), a selective inhibitor of CPP-32(-like) protease, efficiently inhibited the cleavage of actin and the apoptosis of VP-16-treated U937 cells. Our present results indicate that actin is the substrate of CPP-32/apopain(-like) protease both in vitro and in vivo and suggest the role of actin in the control of cell growth and apoptosis.
The caspase-3 (CPP32, apopain, YAMA) family of cysteinyl proteases has been implicated as key mediators of apoptosis in mammalian
cells. Gelsolin was identified as a substrate for caspase-3 by screening the translation products of small complementary DNA
pools for sensitivity to cleavage by caspase-3. Gelsolin was cleaved in vivo in a caspase-dependent manner in cells stimulated
by Fas. Caspase-cleaved gelsolin severed actin filaments in vitro in a Ca2+-independent manner. Expression of the gelsolin cleavage product in multiple cell types caused the cells to round up, detach
from the plate, and undergo nuclear fragmentation. Neutrophils isolated from mice lacking gelsolin had delayed onset of both
blebbing and DNA fragmentation, following apoptosis induction, compared with wild-type neutrophils. Thus, cleaved gelsolin
may be one physiological effector of morphologic change during apoptosis.
During normal tissue remodeling, macrophages remove unwanted cells, including those that have undergone programmed cell death, or apoptosis. This widespread process extends to the deletion of thymocytes (negative selection), in which cells expressing inappropriate Ag receptors undergo apoptosis, and are phagocytosed by thymic macrophages. Although phagocytosis of effete leukocytes by macrophages has been known since the time of Metchnikoff, only recently has it been recognized that apoptosis leads to surface changes that allow recognition and removal of these cells before they are lysed. Our data suggest that macrophages specifically recognize phosphatidylserine that is exposed on the surface of lymphocytes during the development of apoptosis. Macrophage phagocytosis of apoptotic lymphocytes was inhibited, in a dose-dependent manner, by liposomes containing phosphatidyl-L-serine, but not by liposomes containing other anionic phospholipids, including phosphatidyl-D-serine. Phagocytosis of apoptotic lymphocytes was also inhibited by the L isoforms of compounds structurally related to phosphatidylserine, including glycerophosphorylserine and phosphoserine. The membranes of apoptotic lymphocytes bound increased amounts of merocyanine 540 dye relative to those of normal cells, indicating that their membrane lipids were more loosely packed, consistent with a loss of membrane phospholipid asymmetry. Apoptotic lymphocytes were shown to express phosphatidylserine (PS) externally, because PS on their surfaces was accessible to derivatization by fluorescamine, and because apoptotic cells expressed procoagulant activity. These observations suggest that apoptotic lymphocytes lose membrane phospholipid asymmetry and expose phosphatidylserine on the outer leaflet of the plasma membrane. Macrophages then phagocytose apoptotic lymphocytes after specific recognition of the exposed PS.
In near-physiological concentrations, glucocorticoid hormones cause the death of several types of normal and neoplastic lymphoid cell, but the mechanisms involved are unknown. One of the earliest structural changes in the dying cell is widespread chromatin condensation, of the type characteristic of apoptosis, the mode of death frequently observed where cell deletion seems to be 'programmed'. It is shown here that this morphological change is closely associated with excision of nucleosome chains from nuclear chromatin, apparently through activation of an intracellular, but non-lysosomal, endonuclease.
A protein determination method which involves the binding of Coomassie Brilliant Blue G-250 to protein is described. The binding of the dye to protein causes a shift in the absorption maximum of the dye from 465 to 595 nm, and it is the increase in absorption at 595 nm which is monitored. This assay is very reproducible and rapid with the dye binding process virtually complete in approximately 2 min with good color stability for 1 hr. There is little or no interference from cations such as sodium or potassium nor from carbohydrates such as sucrose. A small amount of color is developed in the presence of strongly alkaline buffering agents, but the assay may be run accurately by the use of proper buffer controls. The only components found to give excessive interfering color in the assay are relatively large amounts of detergents such as sodium dodecyl sulfate, Triton X-100, and commercial glassware detergents. Interference by small amounts of detergent may be eliminated by the use of proper controls.
Gelsolins are actin-binding proteins that cap, nucleate, and sever actin filaments. Microinjection of cytoplasmic or plasma gelsolin into living fibroblasts and macrophages did not affect the shape, actin distribution, deformability, or ruffling activity of the cells. Gelsolin requires calcium for activity, but the NH2-terminal half is active without calcium. Microinjection of this proteolytic fragment had marked effects: the cells rounded up, stopped ruffling, became soft, and stress fibers disappeared. These changes are similar to those seen with cytochalasin, which also caps barbed ends of actin filaments. Attempts to raise the cytoplasmic calcium concentration and thereby activate the injected gelsolin were unsuccessful, but the increases in calcium concentration were minimal or transient and may not have been sufficient. Our interpretation of these results is that at the low calcium concentrations normally found in cells, gelsolin does not express the activities observed in vitro at higher calcium concentrations. We presume that gelsolin may be active at certain times or places if the calcium concentration is elevated to a sufficient level, but we cannot exclude the existence of another molecule that inhibits gelsolin. Microinjection of a 1:1 gelsolin/actin complex had no effect on the cells. This complex is stable in the absence of calcium and has capping activity but no severing and less nucleation activity as compared with either gelsolin in calcium or the NH2-terminal fragment. The NH2-terminal fragment-actin complex also has capping and nucleating activity but no severing activity. On microinjection it had the same effects as the fragment alone. The basis for the difference between the two complexes is unknown. The native molecular weight of rabbit plasma gelsolin is 82,500, and the extinction coefficient at 280 nm is 1.68 cm2/mg. A new simple procedure for purification of plasma gelsolin is described.
Gelsolin is a 90,000-mol-wt Ca2+-binding, actin-associated protein that can nucleate actin filament growth, sever filaments, and cap barbed filament ends. Brevin is a closely related 92,000-mol-wt plasma protein with similar properties. Gelsolin has been reported to be localized on actin filaments in stress fibers, in cardiac and skeletal muscle I-bands, and in cellular regions where actin filaments are known to be concentrated. Previous localization studies have used sera or antibody preparations that contain brevin. Using purified brevin-free IgG and IgA monoclonal antibodies or affinity-purified polyclonal antibodies for gelsolin and brevin, we find no preferential stress fiber staining in cultured human fibroblasts or I-band staining in isolated rabbit skeletal muscle sarcomeres. Cardiac muscle frozen sections show no pronounced I-band staining, except in local areas where brevin may have penetrated from adjacent blood vessels. Spreading platelets show endogenous gelsolin localized at the cell periphery, in the central cytoplasmic mass and on thin fibers that radiate from the central cytoplasm. Addition of 3-30 micrograms/ml of brevin to the antibodies restores intense stress fiber and I-band staining. We see no evidence for large-scale severing and removal of filaments in stress fibers in formaldehyde-fixed, acetone-permeabilized cells even at brevin concentrations of 30 micrograms/ml. The added brevin or brevin antibody complex binds to actin filaments and is detected by the fluorescently tagged secondary antibody. Brevin binding occurs in either Ca2+ or EGTA, but is slightly more intense in EGTA suggesting some severing and filament removal may occur in Ca2+. The I-band staining is limited to the region where actin and myosin do not overlap. In addition, brevin does not appear to bind at the Z-line. A comparison of cells double-labeled with fluorescein-phallotoxin, exogenous brevin, and a monoclonal antibody, detected with a rhodamine-labeled secondary antibody, shows almost complete co-localization of F-actin with the brevin-gelsolin-binding sites. A major exception is in the area of the adhesion plaque. A quantitative comparison of the fluorescein-rhodamine fluorescence intensities along a stress fiber and into the adhesion plaque shows that the fluorescein signal, associated with F-actin, increases while the rhodamine signal decreases. We infer that exogenous brevin or endogenous gelsolin can bind to and potentially sever most actin filaments, but that actin-associated proteins in the adhesion plaque can prevent binding and severing.(ABSTRACT TRUNCATED AT 400 WORDS)
The homeostasis of animals is regulated not only by the growth and differentiation
of cells, but also by cell death through a process known as apoptosis. Apoptosis
is mediated by members of the caspase family of proteases, and eventually
causes the degradation of chromosomal DNA. A caspase-activated deoxyribonuclease
(CAD) and its inhibitor (ICAD) have now been identified in the cytoplasmic
fraction of mouse lymphoma cells. CAD is a protein of 343 amino acids which
carries a nuclear-localization signal; ICAD exists in a long and a short form.
Recombinant ICAD specifically inhibits CAD-induced degradation of nuclear
DNA and its DNase activity. When CAD is expressed with ICAD in COS cells or
in a cell-free system, CAD is produced as a complex with ICAD: treatment with
caspase 3 releases the DNase activity which causes DNA fragmentation in nuclei.
ICAD therefore seems to function as a chaperone for CAD during its synthesis,
remaining complexed with CAD to inhibit its DNase activity; caspases activated
by apoptotic stimuli then cleave ICAD, allowing CAD to enter the nucleus and
degrade chromosomal DNA.
The ability of two different Jurkat sublines, termed standard and JM, to form DNA ladders was investigated after various apoptotic stimuli. Exposure to a broad spectrum of drugs interfering with signal transduction or cellular metabolism revealed distinct differences between both Jurkat sublines with regard to the pattern of DNA degradation. In standard Jurkat cells, internucleosomal DNA cleavage occurred only after treatment with the protein kinase inhibitor staurosporine. In contrast, the JM subline responded with internucleosomal DNA fragmentation to exposure to gemcitabine, cycloheximide or staurosporine. All drugs induced the formation of DNA fragments of about 50 kb in both sublines, as revealed by pulse field electrophoresis, except H2O2, which caused unspecific DNA degradation. The staurosporine-induced DNA ladder formation was accompanied by an increase in caspase-3 activity in both lines which, however, was considerably lower in Jurkat JM cells after gemcitabine or cycloheximide exposure. When the analysis of internucleosomal DNA degradation was carried out after mycoplasma infection, both Jurkat lines responded with DNA ladder formation after exposure to all drugs used (here only shown for the standard subline). Employing the zymogram technique, nuclease activities of 47 kDa and 54 kDa were detected in culture supernatants, cell homogenates and nuclear extracts only when mycoplasma-infected, whereas the samples obtained from mycoplasma-free sublines were nuclease-negative using this technique, indicating that these endonucleases were of mycoplasmal origin. After drug exposure, the mycoplasmal nucleases must have gained access to the cytoplasm and nuclei of their host cells by an unknown mechanism.
The expression of deoxyribonuclease I (DNase I) in various rat tissues was screened by use of a cDNA-probe of rat parotid DNase I and monospecific polyclonal antibodies. High amounts of DNase I-specific mRNA were found in the parotid gland, kidney and small intestine. Homogenates of these organs also contain elevated levels of DNase I-specific DNA-degrading activity as verified by the zymogram technique and immunoblots. Affinity-purified polyclonal antibodies against rat parotid DNase I were employed in an immunohistochemical study of the cellular distribution of DNase I antigen in rat parotid gland, kidney, small intestine, and a number of stratified epithelia. In the parotid gland the DNase I antigenicity was found to be confined to the secretory cells. Within these cells the secretory granules exhibit the highest immunoreactivity. In contrast, within the small intestine and stratified epithelia we found a preferential localization and concentration of DNase I in cells prone to undergo apoptosis (programmed cell death), i.e., within the migrating enterocytes present at the villar tips and the keratinocytes above the basal cell layer. Within the kidney, the cells lining the convoluted distal tubules and collecting ducts exhibit strong DNase I immunoreactivity which was found to often localize perinuclearly. The cells exhibiting chromatin fragmentation were identified on paraffin-embedded sections by in situ end-labeling of free 3'-OH-ends of cleaved DNA using fluorescent dATP or dUTP and terminal transferase. It was found that only a small fraction of the DNase I positive cells showed signs of apoptotic chromatin degradation. Thus only a few enterocytes at the uppermost villar tips and very few keratinocytes underneath the keratinized layer were in situ end-labeled, i.e., exhibited a high concentration of fragmented DNA. This result is taken as evidence that these cells express DNase I in advance of their apoptotic death and furthermore that the actual apoptosis is a rapid process only detectable in a few cells. In contrast, no in situ end-labeled apoptotic nuclei were detected in rat kidney provided that care was taken to rapidly excise and fix this organ.
The term apoptosis describes the predictable structural changes associated with many forms of programmed cell death. One of the first visible events of apoptosis is the collapse of the nucleus. Nuclear degradation is manifested by digestion of chromatin into nucleosome-sized fragments or multiples of these. This digestion of DNA is enzymatic, and several attempts have been made to characterize apoptosis-specific endodeoxyribonucleases. Although there are strong candidates for such enzymes, direct evidence for their role in apoptosis is yet to be provided.
A protein determination method which involves the binding of Coomassie Brilliant Blue G-250 to protein is described. The binding of the dye to protein causes a shift in the absorption maximum of the dye from 465 to 595 nm, and it is the increase in absorption at 595 nm which is monitored. This assay is very reproducible and rapid with the dye binding process virtually complete in approximately 2 min with good color stability for 1 hr. There is little or no interference from cations such as sodium or potassium nor from carbohydrates such as sucrose. A small amount of color is developed in the presence of strongly alkaline buffering agents, but the assay may be run accurately by the use of proper buffer controls. The only components found to give excessive interfering color in the assay are relatively large amounts of detergents such as sodium dodecyl sulfate, Triton X-100, and commercial glassware detergents. Interference by small amounts of detergent may be eliminated by the use of proper controls.
During normal tissue remodeling, macrophages remove unwanted cells, including those that have undergone programmed cell death, or apoptosis. This widespread process extends to the deletion of thymocytes (negative selection), in which cells expressing inappropriate Ag receptors undergo apoptosis, and are phagocytosed by thymic macrophages. Although phagocytosis of effete leukocytes by macrophages has been known since the time of Metchnikoff, only recently has it been recognized that apoptosis leads to surface changes that allow recognition and removal of these cells before they are lysed. Our data suggest that macrophages specifically recognize phosphatidylserine that is exposed on the surface of lymphocytes during the development of apoptosis. Macrophage phagocytosis of apoptotic lymphocytes was inhibited, in a dose-dependent manner, by liposomes containing phosphatidyl-L-serine, but not by liposomes containing other anionic phospholipids, including phosphatidyl-D-serine. Phagocytosis of apoptotic lymphocytes was also inhibited by the L isoforms of compounds structurally related to phosphatidylserine, including glycerophosphorylserine and phosphoserine. The membranes of apoptotic lymphocytes bound increased amounts of merocyanine 540 dye relative to those of normal cells, indicating that their membrane lipids were more loosely packed, consistent with a loss of membrane phospholipid asymmetry. Apoptotic lymphocytes were shown to express phosphatidylserine (PS) externally, because PS on their surfaces was accessible to derivatization by fluorescamine, and because apoptotic cells expressed procoagulant activity. These observations suggest that apoptotic lymphocytes lose membrane phospholipid asymmetry and expose phosphatidylserine on the outer leaflet of the plasma membrane. Macrophages then phagocytose apoptotic lymphocytes after specific recognition of the exposed PS.
Increasing the content of the actin-binding protein gelsolin in cultured mouse fibroblasts by up to 125 percent by gene transfection
proportionally enhanced the rate at which the cells migrated through porous filters toward a gradient of serum and closed
a wound made on a confluent monolayer of cells in a tissue culture dish. These results provide direct evidence that gelsolin,
which promotes both actin assembly and disassembly in vitro, is an important element in fibroblast locomotion and demonstrate
that the manipulation of intracellular machinery can increase cell motility.
Gelsolin is a Ca2+ and polyphosphoinositol-phospholipid regulated modulator of actin polymerization present in most mammalian cells and in plasma. Cytoplasmic gelsolin was first described in highly motile cells such as leukocytes, where actin polymerization is dynamic; however arterial smooth muscle cells (SMC), despite their stabilized actin bundles, express high levels of gelsolin. We have investigated gelsolin modulation in rat aortic SMC by immunohistochemistry, Western blotting and Northern hybridization using three models which are known to show modulation of actin isoform expression: development, aortic intimal thickening after experimental endothelial injury, and growth in culture. When related to the protein and mRNA content of adult aortic SMC, gelsolin is expressed about 50% in aortic SMC of five-day-old rats, 20-30% in SMC of intimal thickening 15 days after endothelial injury (when SMC are actively replicating) and in SMC growing in culture; in intimal thickening 60 days after injury (when SMC have returned to quiescence), the gelsolin content becomes similar to that of control SMC. The high level of gelsolin in smooth muscle (SM) tissues and the down regulation with proliferation and migration raises the question as to whether gelsolin in these cells has functions other than the dynamic control of actin filament length. The similar modulation patterns of gelsolin and alpha-SM actin suggest a preferential interaction between these two proteins.
Gelsolins, prepared from a number of different sources, showed similar severing activity on F-actin in vitro or on stress fibers of detergent-extracted cells but differed in their effects on actin in stress fibers of microinjected cells. When human gelsolin isolated from plasma was injected into cells in a Ca++-containing buffer, stress fibers were degraded, the cellular morphology was changed, and numerous actin patches appeared. These effects were particularly striking when the Ca++-insensitive N-terminal proteolytic fragment of this gelsolin was injected. By contrast, Ca++-sensitive gelsolins isolated from human platelets, pig stomach smooth muscle and pig plasma showed no comparable activity. Furthermore, the Ca++-independent N-terminal proteolytic fragments prepared from these gelsolins also had no effect despite their in vitro actin severing activity. Most striking was the finding that human plasma gelsolin expressed in E. coli did not degrade stress fibers, in contrast to the same protein isolated from plasma; nor was there any stress fiber disruption observed with the N-terminal half of human gelsolin expressed in Escherichia coli.
The different behavior of these gelsolins in cells cannot be explained by sequence diversity between plasma and cytoplasmic forms, nor by variability in the Ca++ sensitivity of the preparations. It suggests the presence of factors, as yet unidentified, that may regulate gelsolin activity in the cytoplasm of living cells and discriminate between gelsolins of different origin. Such discrimination could be achieved as a result of post-translational modification of the gelsolin; only in this way can differences between apparently identical proteins isolated from human plasma and expressed in E. coli be reconciled.
Receptor-mediated stimulation induces massive actin polymerization and cyto-skeletal reorganization. The activity of a potent actin-modulating protein, gelsolin, is regulated both by Ca2+ and polyphos-phoinositides, and it may have a pivotal role in restructuring the actin cytoskeleton in response to agonist stimulation. Structure-function analysis of gelsolin has (1) indicated that its NH2-terminal half is primarily responsible for modulating actin filament length and polymerization; and (2) elucidated mechanisms by which Ca2+ and phospholipids may regulate such functions. Gelsolin is functionally and structurally similar to villin, another Ca2+-activated actin-severing protein found in microvilli, suggesting that gelsolin may be a prototype of this family of actin-modulating proteins. A molecular variant of gelsolin is secreted and may be involved in the clearance of actin filaments released during tissue damage. The two forms of gelsolin are encoded by a single gene, and distinct messages are derived by alternative message splicing.
Genes whose expression is growth factor regulated are likely to be important components in the mechanisms controlling cell
proliferation and differentiation. With the aim of identifying some of those genes, a lambda cDNA library was prepared with
poly(A)+ RNA from quiescent NIH 3T3 cells stimulated with serum for 4 h in the presence of cycloheximide. Differential screening
of approximately 200,000 recombinant phage plaques revealed 2,540 clones that cross hybridized preferentially with [32P]cDNA
derived from RNA of stimulated cells rather than with cDNA derived from nonstimulated cells. Cross hybridization of these
clones identified 82 independent sequences, including c-fos and c-myc. Seventy-one clones were further studied. Analysis of
the changes in transcription and mRNA levels after serum stimulation demonstrated that the kinetics and extent of the induction
vary dramatically between the different genes. Cycloheximide in all cases superinduced the mRNA levels by two mechanisms,
inhibiting the shutoff of transcription and prolonging the half-lives of the mRNAs. Our results showed that induction of proliferation
is accompanied by the onset of a complex genetic program.
Scatchard analyses of the binding of transforming growth factor-beta (TGF beta) to membranes from rat ventral prostate revealed the presence of high affinity (Kd = 140 pM) saturable binding sites for [125I]TGF beta. The binding of [125I]TGF beta to prostatic membranes, while displaced in the presence of excess unlabeled TGF beta, is unaffected by epidermal growth factor, nerve growth factor, fibroblast growth factor, or insulin, indicating the specificity of binding. Affinity labeling of these membrane receptors by covalent attachment to [125I]TGF beta with bis-(sulfosuccinimidyl)suberate and subsequent electrophoretic analysis of the labeled complexes revealed the specific binding of [125I]TGF beta to a macromolecule that predominantly migrates as a 260,000 mol wt band in 7.5% acrylamide gels. Castration-induced androgen deprivation produced a significant increase in [125I]TGF beta binding to prostatic membranes with no apparent change in the affinity of membrane receptors for TGF beta. TGF beta receptor levels per total gland increased approximately 2-fold by 3 days after castration, reached a peak value by day 4, and then declined during the subsequent 10 days. Androgen administration to 4-day castrated animals decreased the number of TGF beta receptors to a value similar to that in the intact controls. These results demonstrate the presence of specific binding sites for TGF beta in the rat ventral prostate. Furthermore, the TGF beta receptor levels seem to be under negative androgenic regulation, indicating a potential role for this growth factor in the mechanism of activation of castration-induced death of androgen-dependent epithelial cells in the ventral prostate.
The term apoptosis is proposed for a hitherto little recognized mechanism of controlled cell deletion, which appears to play a complementary but opposite role to mitosis in the regulation of animal cell populations. Its morphological features suggest that it is an active, inherently programmed phenomenon, and it has been shown that it can be initiated or inhibited by a variety of environmental stimuli, both physiological and pathological.
The structural changes take place in two discrete stages. The first comprises nuclear and cytoplasmic condensation and breaking up of the cell into a number of membrane-bound, ultrastructurally well-preserved fragments. In the second stage these apoptotic bodies are shed from epithelial-lined surfaces or are taken up by other cells, where they undergo a series of changes resembling in vitro autolysis within phagosomes, and are rapidly degraded by lysosomal enzymes derived from the ingesting cells.
Apoptosis seems to be involved in cell turnover in many healthy adult tissues and is responsible for focal elimination of cells during normal embryonic development. It occurs spontaneously in untreated malignant neoplasms, and participates in at least some types of therapeutically induced tumour regression. It is implicated in both physiological involution and atrophy of various tissues and organs. It can also be triggered by noxious agents, both in the embryo and adult animal.
ImagesFig. 8-10Fig. 1Fig. 2Fig. 3Fig. 4Fig. 6Fig. 7Fig. 11-14Fig. 15-18Fig. 19Fig. 20-22Fig. 23 and 24
Using an improved method of gel electrophoresis, many hitherto unknown
proteins have been found in bacteriophage T4 and some of these have been
identified with specific gene products. Four major components of the
head are cleaved during the process of assembly, apparently after the
precursor proteins have assembled into some large intermediate
structure.
The significance of cell shape variations for growth regulation was studied by culturing anchorage-dependentlens epithelial cells on collagen gels. After being loosened from the bottom of the culture dish, the floating collagen membranes became contracted by the traction forces of the cells, which exert their tension on the collagen fibrils via numerous filopodia. Gel contraction produced by the cells is an active energy-dependent process, which requires intact microfilaments and divalent cations. During gel contraction a transition from a flat into a more spheroid cellular shape occurs. This is accompanied by a steep decline of [3H]uridine and [3H]thymidine incorporation.
In near-physiological concentrations, glucocorticoid hormones cause the death of several types of normal and neoplastic lymphoid cell, but the mechanisms involved are unknown. One of the earliest structural changes in the dying cell is widespread chromatin condensation, of the type characteristic of apoptosis, the mode of death frequently observed where cell deletion seems to be 'programmed'. It is shown here that this morphological change is closely associated with excision of nucleosome chains from nuclear chromatin, apparently through activation of an intracellular, but non-lysosomal, endonuclease.
The classification of cell death can be based on morphological or biochemical criteria or on the circumstances of its occurrence. Currently, irreversible structural alteration provides the only unequivocal evidence of death; biochemical indicators of cell death that are universally applicable have to be precisely defined and studies of cell function or of reproductive capacity do not necessarily differentiate between death and dormant states from which recovery may be possible. It has also proved feasible to categorize most if not all dying cells into one or the other of two discrete and distinctive patterns of morphological change, which have, generally, been found to occur under disparate but individually characteristic circumstances. One of these patterns is the swelling proceeding to rupture of plasma and organelle membranes and dissolution of organized structure—termed “coagulative necrosis.” It results from injury by agents, such as toxins and ischemia, affects cells in groups rather than singly, and evokes exudative inflammation when it develops in vivo. The other morphological pattern is characterized by condensation of the cell with maintenance of organelle integrity and the formation of surface protuberances that separate as membrane-bounded globules; in tissues, these are phagocytosed and digested by resident cells, there being no associated inflammation.
The correlation between cellular growth and microfilament-dependent morphology was investigated. It was found that the proliferative growth of various nontransformed cell lines does not only depend on cell adhesion to a suitable substratum and cell flattening but also on intact microfilaments. Disintegration of microfilaments by cytochalasin D (CD) as well as lactrunculin (LAT)-A and LAT-B is correlated with a strong decline of the number of DNA-synthesizing cells during a period of 8 to 12 h after application of the drug. RNA and protein synthesis are reduced already after a preincubation time of 2 h. Although microinjected rhodamine-phalloin is colocalized with microfilaments there is no stabilizing effect against CD even at high phaloidin concentrations. Microinjection of DNAse I results in a strong alteration of the microfilament system. The disorganization of microfilaments was correlated with a moderate decrease of protein synthesis 2 h after microinjection, whereas RNA synthesis remained unchanged, if RNase-free DNase I was used. The number of DNA-synthesizing cells was somewhat diminished 24 h after microinjection. Furthermore, the microfilament system is disorganized by microinjection of gelsolin and gelsolin segment 1 + 2, respectively. The severing the microfilaments by gelsolin is correlated with a significant restriction of RNA and protein synthesis during a period of 2 to 4 h after injection, but the labeling index remaining unchanged. Therefore, we assume that inhibition of the G0-G1-S transition is only caused by a disintegration of microfilaments lasting longer than 4 h. The significance of microfilament organization for growth regulation is discussed.
We have investigated the binding of gelsolin to thin myofilaments in situ and their stability against severing. Differentiated myotubes from chicken skeletal muscle containing cross-striated myofibrils were permeabilized with Triton X-100 and incubated with gelsolin. Immunofluorescence microscopy localized both endogenous and exogenous gelsolin in the I-Z-I-regions of the sarcomers. The staining pattern suggested a binding of the exogenous gelsolin along the entire length of the thin filaments. This binding was Ca2+ dependent, but gelsolin was not removed after subsequent addition of EGTA. The fluorescence staining for actin remained unchanged after gelsolin incubation, indicating that thin filaments in cross-striated myofibrils were resistant to the severing action of gelsolin, in contrast to the microfilaments in stress fibers. After extraction of the permeabilized cells with high ionic strength to remove tropomyosin and myosin, gelsolin still bound along the entire thin filament and the actin pattern also remained unchanged. After Triton X-100 permeabilization and high ionic strength extraction, the giant protein nebulin was found to be still present as a myofibrillar component. Gelsolin treatment after high salt extraction affected neither actin nor nebulin in the thin filaments. We therefore conclude that nebulin confers the gelsolin resistance to the sarcomeric actin filaments.
Gelsolin, an 82 kDa actin-binding protein, has potent actin filament-severing activity in vitro. To investigate the in vivo function of gelsolin, transgenic gelsolin-null (Gsn-) mice were generated and found to have normal embryonic development and longevity. However, platelet shape changes are decreased in Gsn- mice, causing prolonged bleeding times. Neutrophil migration in vivo into peritoneal exudates and in vitro is delayed. Gsn- dermal fibroblasts have excessive actin stress fibers and migrate more slowly than wild-type fibroblasts, but have increased contractility in vitro. These observations establish the requirement of gelsolin for rapid motile responses in cell types involved in stress responses such as hemostasis, inflammation, and wound healing. Neither gelsolin nor other proteins with similar actin filament-severing activity are expressed in early embryonic cells, indicating that this mechanism of actin filament dynamics is not essential for motility during early embryogenesis.
Gelsolin was localized by immunofluorescence in fibroblasts and skeletal muscle cells using antibodies which eliminated the risk of detecting xenogenic plasma gelsolin. Gelsolin was consistently found to be closely associated with the elements of the microfilament system: In fibroblasts, a preferential labeling of the stress fibers was observed, whereas with myogenic cells and myofibrils isolated from skeletal muscle, a specific staining of the I-Z-I region in the sarcomeres was found. From double labeling of gelsolin and actin it became evident that the staining patterns for both proteins were practically coincident: The width and location of the fluorescent bands varied with the degree of contraction of the myofibrils. The region of cross-bridges in the A-zone, where thick and thin filaments overlap, remained unstained. The gelsolin staining of myofibrils was EGTA-resistant; it persisted after glycerol extraction and extensive washing. The presence of gelsolin in myofibrils after this treatment was also confirmed by immunoblotting. From these observations it was concluded that a significant part of the total gelsolin in skeletal muscle cells is tightly associated with the thin filaments, and is an integral part of the myofibrils even at low Ca(++)-concentrations. From the coincidence of actin and gelsolin staining in myofibrils it was concluded that gelsolin is localized along the whole length of the thin filaments in the sarcomere.(ABSTRACT TRUNCATED AT 250 WORDS)
Gelsolin forms ternary complexes with two actin monomers in the presence of Ca2+, which nucleate actin polymerization and cap the barbed ends of filaments. It has therefore been assumed that the two actins are oriented in a similar manner to the terminal subunits in the genetic helix of F-actin. We have tested this using chemical cross-linking with N,N'-1,4-phenylenedimaleimide. For all conditions tested, we identified as the only cross-linked dimeric species an actin dimer indistinguishable from the lower actin dimer of 86 kDa. This lower dimer was previously identified in the initial phase of actin polymerization and also when actin paracrystals are chemically cross-linked [Millonig, R., Salvo, H. & Aebi, U. (1988) J. Cell Biol. 106, 785-796]. It probably defines a contact between adjacent monomers oriented in an antiparallel orientation. In contrast, when F-actin is cross-linked by the same reagent, an upper dimer of apparent molecular mass 115 kDa is formed, which corresponds to adjacent monomers in the genetic helix. The formation of this upper dimer was specifically inhibited by addition of gelsolin to F-actin. Evidence is presented for a Cys374-Cys374 cross-link in the lower dimer. Isolated lower dimer binds to gelsolin in a 1:1 stoichiometry, but it inhibits nucleation of polymerization by gelsolin. Other gelsolin constructs that bind two actin subunits (e.g. the N-terminal half of the molecule, which has severing and capping but no nucleating activity) also form only lower dimer when cross-linked with N,N'-1,4-phenylenedimaleimide. Only segment 2-6 (gelsolin fragment devoid of the N-terminal segment 1) induces an upper dimer orientation of the two actins under nucleating conditions. Our evidence suggests that the two actins associated with gelsolin are not fixed in the orientation of adjacent subunits in F-actin; instead they have a flexible orientation with respect to each other, which permits cross-linking into a stable antiparallel form that does not correspond to the presumed nucleating conformation.
Actin filament polymerization involves exchange of subunits of filament ends, which can be controlled in vitro and in vivo by other proteins that bind actin filaments and inhibit subunit addition or loss at the ends. Proteins that bind to the barbed end, including capping protein, the gelsolin super-family, tensin, and profilin are discussed, as are proteins that bind to the pointed end, including tropomodulin and spectrin/band 4.1. Some proteins that bind along the sides of filaments and influence assembly at ends are also discussed. Functional roles in vivo are emphasized.
DNA fragmentation is a common biochemical hallmark of apoptosis. It is catalyzed by endogenous Ca2+, Mg(2+)-dependent endonuclease(s). Although the exact identity of the apoptotic endonuclease is still a matter of debate, a number of candidate nucleases have been proposed like NUC18, DNase II and DNase I. Relatively large amounts of nucleases are also expressed by mycoplasmas, cell wall-less bacteria of the class Mollicutes, which are found as contaminants in up to 45% of the continuous cell lines in current use. In order to clarify the effect of these pathogens on the investigation of apoptosis in cell culture systems, we looked for biochemical markers (DNA fragmentation, nuclease expression) and morphological changes characteristic of apoptosis (cell shrinkage, chromatin condensation, apoptotic bodies) in Mycoplasma hyorhinis-free and -infected cultures of the human pancreatic adenocarcinoma cell line PaTu 8902 and of mouse NIH 3T3 fibroblasts. For that purpose we employed cells cultured under standard conditions and cells exposed to the protein synthesis inhibitor cycloheximide, which is known to induce apoptosis in various cell systems. After exposure to cycloheximide only the mycoplasma-positive cells exhibited internucleosomal DNA degradation. In contrast, nuclease activities in the molecular range of 47 to 54 kDa were detected in cell homogenates and culture supernatants of infected cultures of both control and cycloheximide-treated cells, whereas mycoplasma-free cultures were nuclease-negative. The expression of the nucleases and the cycloheximide-induced DNA fragmentation were suppressed by the prokaryote-specific protein synthesis inhibitor chloramphenicol. Moreover, partially purified nucleases from supernatants of infected cells were able to cleave the DNA of isolated substrate nuclei at internucleosomal sites. These data indicate that DNA ladder formation in cell culture systems can also be caused by mycoplasmal nucleases which apparently penetrate the host cells after cycloheximide treatment or more generally after cellular stress. Therefore, internucleosomal DNA fragmentation in established cell lines has to be regarded with care, unless mycoplasmal infection can be excluded, or the existence of endogenous endonucleases can be proven. The presence of endonucleolytic activities of about 47 to 54 kDa molecular mass has now to be regarded as highly indicative of contaminations with M. hyorhinis. In contrast, the expression of an apoptotic morphology was not restricted to infected cells; in both mycoplasma-free and -contaminated cultures, cells with condensed chromatin were observed after staining with the DNA binding dye Hoechst 33342. Electron microscopic studies revealed that most of the cells containing compacted DNA were phagocytosed by unaffected fellow cells. Presumably because of the relatively long exposure (72 h) to cycloheximide we also observed secondary necrosis as indicated by the parallel occurrence of morphological characteristics of apoptosis (chromatin condensation) and necrosis (loss of membrane integrity and organelle swelling).