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A simple specific method for the determination of the hemoglobin content of tissue homogenates
Abstract
A simple, inexpensive and specific method for the determination of hemoglobin in tissue homogenates is described. It is based on the specific binding of hemoglobin by haptoglobin and the stabilizing effect of this binding on the peroxidase activity of hemoglobin. The haptoglobin is added as serum and no purification is needed. The method gives reliable estimates of hemoglobin contents above 10 mg/l.
... The content of cortical tissue hemoglobin was mea sured by Marklund's method (Murklund 1978(Murklund , 1979. This method is based on the specific binding of hemoglobin by haptoglobin and the stabilizing effect of this binding on the peroxidase activity of hemoglobin. ...
A simple method was developed to measure in vivo local oxygen consumption quantitatively in the brain cortex. Reflectance spectra of tissue hemoglobin at the brain's surface were measured for assessment of both local tissue hemoglobin content and its oxygen saturation. Local oxygen consumption was calculated from the spectral changes of tissue hemoglobin during complete cessation of blood flow by compression of the cortical surface in the suprasylvian gyrus with the tip of an optic probe. This procedure was performed without any brain damage and only took approximately 5 s. The calculated local oxygen consumption during this short period of compression remained constant for a few seconds. Then, it decreased rapidly, although the local tissue hemoglobin was not completely deoxygenated. The value of local cerebral oxygen consumption obtained by this method was 3.02 +/- 0.61 mL O2/100 g brain/min; it was not influenced by the change in systemic blood pressure. The effect of pentobarbital on cerebral oxygen consumption was also studied. At the stage of burst and suppression on electrocorticogram, cerebral oxygen consumption decreased significantly (p less than 0.001) to 1.03 +/- 0.07 mL O2/100 g brain/min.
... Differences may be due to race peculiarities as different activity and proportion of fat in the body. Fat contains very little blood (21). ...
Plasma volume and red cell mass of various organs in piglets aged 24 hr (n = 7) and 7 (n = 6), and 14 (n = 6) days were measured using 99mTc-labeled albumin and 51Cr-labeled red blood cells. Organ activities were counted in a whole-body counter. Blood volume and hematocrit were calculated. The blood volumes in microliters/g varied markedly between various organs. The lowest blood volumes at 24 hr of age were found in skin (21.9 +/- 5.0 microliter/g), brain (33.3 +/- 8.4), and skeletal muscle (35.5 +/- 7.4). The highest values at this age were noted in liver (670.0 +/- 89.1), lung (533.8 +/- 80.7), spleen (332.0 +/- 82.8), and kidney (300.6 +/- 55.5). Blood volumes of about 150 microliters/g were observed in heart muscle and thyroid gland and those of about 100 microliters/g in thymus and gastrointestinal tract. The total blood volume was 100.2 +/- 3.9 microliters/g at 24 hr and remained unchanged during the first 2 wk of life. A significant decrease in relative blood volume with growth was noted in liver and lung (P less than 0.01), and in skeleton (P less than 0.05). The blood volume, contained in the great vessels outside the organs, increased from 29.5 +/- 5.5% of total blood volume at 24 hr to 31.2 +/- 5.7% at 7 days and to 38.2 +/- 7.5% at 14 days of life. The total body-venous hematocrit ratio was about 0.84. Accordingly, tissue hematocrits of most organs were below the venous hematocrit. Only in spleen was the tissue/venous hematocrit ratio (TH/VH) higher than 1.0. TH/VH of brain, gastrointestinal tract, thyroid gland, and thymus approached unity. The lowest TH/VH was found in kidney (0.54 +/- 0.08 at day 1). In skin, the TH/VH decreased from 0.98 +/- 0.10 to 0.82 +/- 0.07 during the first 2 wk of life.
... One of these assays was based on the peroxidase activity of haem containing proteins, resulting in the conversion of the colorless ABTS into the blue green ABTS radical (ABTS • ). Originally, this activity was used to determine the haemoglobin content of tissue samples [2]. In this haemoglobin assay reductive compounds such as vitamin C interfere, since they react with ABTS • giving a colorless non-radical product. ...
The Trolox Equivalent Antioxidant Capacity (TEAC) assay is based on the scavenging of the 2,2'-azinobis-(3-ethylbenzothiazoline-6-sulfonic acid) (ABTS) radical (ABTS(*)) converting it into a colorless product. The degree of decolorization induced by a compound is related to that induced by trolox, giving the TEAC value. The assay is frequently used for constructing structure activity relationships (SARs). HPLC analysis of the reaction mixture, obtained after scavenging of ABTS(*) by the flavonoid chrysin, shows that a product is formed that also reacts with ABTS(*). The product has a higher antioxidant capacity and reacts faster with ABTS(*) than the parent compound, chrysin. In contrast to the reaction product of chrysin, the reaction product of trolox, which is formed during scavenging of ABTS(*), i.e. trolox quinone, does not react with ABTS(*). The experiments show that the TEAC is the antioxidant capacity of the parent compound plus the potential antioxidant capacity of the reaction product(s). This means that the TEAC assay does not necessarily reflect the antioxidant effect of only one structure. This hampers the applicability of the assay for the construction of SARs and for ranking antioxidants.
... Previous studies have indicated that tissue MPO activity can be affected by other factors (19,20). and that MPO values may not indicate the true presence of neutrophils. ...
Background
Neutrophil infiltration is one of the critical cellular components of an inflammatory response during peritonitis. The adhesion molecules, P-selectin and intercellular adhesion molecule (ICAM)-1, mediate neutrophil-endothelial cell interactions and the subsequent neutrophil transendothelial migration during the inflammatory response. Despite very strong preclinical data, recent clinical trials failed to show a protective effect of anti-adhesion therapy, suggesting that the length of injury might be a critical factor in neutrophil infiltration. Therefore, the objective of this study was to determine the role of P-selectin and ICAM-1 in neutrophil infiltration into the peritoneal cavity during early and late phases of peritonitis.
Methods
Peritonitis was induced in both male wild-type and P-selectin/ICAM-1 double deficient (P/I null) mice by cecal ligation-puncture (CLP). Peripheral blood and peritoneal lavage were collected at 6 and 24 hours after CLP. The total leukocyte and neutrophil contents were determined, and neutrophils were identified with the aid of in situ immunohistochemical staining. Comparisons between groups were made by applying ANOVA and student t-test analysis.
Results
CLP induced a severe inflammatory response associated with a significant leukopenia in both wild-type and P/I null mice. Additionally, CLP caused a significant neutrophil infiltration into the peritoneal cavity that was detected in both groups of mice. However, neutrophil infiltration in the P/I null mice at 6 hours of CLP was significantly lower than the corresponding wild-type mice, which reached a similar magnitude at 24 hours of CLP. In contrast, in peritonitis induced by intraperitoneal inoculation of 2% glycogen, no significant difference in neutrophil infiltration was observed between the P/I null and wild-type mice at 6 hours of peritonitis.
Conclusions
The data suggest that alternative adhesion pathway(s) independent of P-selectin and ICAM-1 can participate in neutrophil migration during peritonitis and that the mode of stimuli and duration of the injury modulate the neutrophil infiltration.
Catalytic bacterial inactivation mediated by peroxidase nanomimics, which converts hydrogen peroxide (H2O2) to hydroxyl radical (•OH) with high toxicity, has been emerged as a promising solution to combat bacterial infections and antibiotic resistance. However, the bacterial inactivation efficacy was often restricted by the low catalytic activity of peroxidase nanomimics and the short half-life and limited diffusion distance of •OH. Here, we developed a hydrogel microreactor (GHAP) integrated double cascade reactions to sequentially generate •OH and nitric oxide (NO) for synergistic bacterial inactivation, where NO offers a complementary effect to compensate •OH for incomplete bacterial inactivation. The GHAP was fabricated by the coencapsulation of glucose oxidase (GOx), hemoglobin (Hb) and zeolitic imidazolate framework-8 loaded with arginine (Arg) in polyacrylamide (pAAm) hydrogel microsphere. The presence of glucose can trigger GHAP to sequentially generate •OH and NO though the successive coupling of GOx with Hb and Arg. The pAAm microsphere was demonstrated to enhance cascade catalytic efficiencies and shield GHAP against harsh conditions due to its confinement effect. Importantly, compared with single •OH/NO-generated cascade systems, the superiority of GHAP was highlighted by the synergistic antibacterial effects of •OH and NO, which thereby endows GHAP with a greatly enhanced antibacterial performance and an exceptional broad-spectrum antibacterial ability. In vivo experiments in a mouse model demonstrated that GHAP could be used for wound disinfection with minimal side effects. This work opens a new avenue for the rational design of biomimetic reactors for biomedical applications.
Iron-deficiency anemia leads directly to both reduced hemoglobin levels and work performance in humans and experimental animals. In an attempt to observe a direct link between work performance and insufficient iron at the cellular level, we produced severe iron deficiency in female weanling Sprague-Dawley rats following five weeks on a low-iron diet. Deficient rats were compared with normal animals to observe major changes in hematological parameters, body weight, and growth of certain organs and tissues. The overall growth of iron-deficient animals was approximately 50% of normal. The ratio of organ weight: body weight increased in heart, liver, spleen, kidney, brain, and soleus muscle in response to iron deficiency. Further, mitochondria from heart and red muscle retained their iron more effectively under the stress of iron deficiency than mitochondria from liver and spleen.
Metabolism of iron in normal and depleted tissue was measured using tracer amounts of59Fe administered orally. As expected, there was greater uptake of tracer iron by iron-deficient animals. The major organ of iron accumulation was the spleen, but significant amounts of isotope were also localized in heart and brain. In all muscle tissue examined the59Fe preferentially entered the mitochondria. Enhanced mitochondrial uptake of iron prior to any detectable change in the hemoglobin level in experimental animals may be indicative of nonhemoglobin related biochemical changes and/or decrements in work capacity.
General introduction
Free radicals play a crucial role in the pathogenesis of several human
diseases and ageing. They are (by)products of various endogenous
processes or a result of external factors, such as irradiation and
xenobiotics. In food products free radicals are also known to cause
damage, resulting in off taste or a reduced shelf-life.
Antioxidants protect against free radicals and they are therefore essential
in obtaining and preserving good health. In food products they act as
preservatives. Much attention has been given to the flavonoids, a class of
polyphenols with strong antioxidant activities, which are ubiquitously
present in a broad range of dietary products.
In order to identify the most potent antioxidants, the antioxidant profiles of
numerous compounds are frequently compared. For this purpose a wide
array of antioxidant assays is available. One of the most frequently
applied assays is the Trolox Equivalent Antioxidant Capacity (TEAC)
assay.
The aim of this thesis is to study antioxidant activity and to examine the
factors that describe and determine this activity of antioxidants.
Outline of this thesis
• Chapter 2 critically evaluates the assessment of antioxidants in
vitro and in vivo.
• Chapter 3 focuses on the applicability of the TEAC assay to
predict the antioxidant activity of a compound. A comparison of
the TEAC with other antioxidant screenings assays is made.
• The contribution of reaction products to the TEAC is examined,
as described in Chapter 4. Based on this, the applicability of the
TEAC assay for the construction of structure activity relationships
(SARs) is evaluated.
• The antioxidant activity of reaction products is further studied in
Chapter 5. A modified TEAC procedure, that includes the
scavenging effect of oxidation products, is presented.
• Chapter 6 describes the effect of interactions between different
ingredients in complex mixtures on the TEAC.
• In Chapter 7, the effect of the interaction between flavonoids and
proteins on the antioxidant capacity is examined. The possible
consequences of masking are discussed.
In Chapter 8 the protection against reactive glucose-derived
species (RGS) and reactive oxygen species (ROS) is compared.
A suggestion for the protection against RGS is made.
• An evaluation on the role of oxidative lipid degradation during
mashing is made in Chapter 9. Suggestions are made in order to
minimize oxidative damage and preserve antioxidants in this
phase of the brewing process.
The effect of benzylpenicillin (BPC) pretreatment on the kinetics and brain sensitivity for thiopental was studied in male rats using a previously developed electroencephalgrafic (EEG) threshold method. Thiopental was infused intravenously with constant infusion rate. The rats were killed by decapitation immediately after the first burst suppression of 1 sec. or more (the silent second) which was observed in the EEG-record during the infusion. Thiopental concentration in serum and in different brain regions was determined by a high pressure liquid chromatografic method. After pretreatment with 0.9 g/kg of BPC the dose of thiopental needed to induce the silent second was significantly reduced (- 20 per cent) when compared with saline treated controls. The serum concentration was also reduced (- 30 per cent) after this BPC pretreatment but the concentrations in the different brain regions were the same in both groups. After pretreatment with 1.2 g/kg of BPC almost all animals had convulsions, the dose needed to obtain the silent second was very much reduced and there were reduced concentrations of thiopental in the different brain regions. After both doses of BPC high negative correlations were found between BPC concentrations in brain tissue and thiopental concentrations in hippocampus and brainstem indicating an interaction between the drugs. The most probable site of this interaction is the organic acid transport system out of the CNS which could be used by both substances. Lipid solubility is not the only factor involved in the distribution of thiopental in the rat brain.
A model for oxidative stress is described in which glutathione (GSH) synthesis is selectively blocked in newborn rats by administration of L-buthionine-(S,R)-sulfoximine (BSO). In this model, the normal endogenous physiological formation of reactive oxygen species is largely unopposed, and therefore oxidative tissue damage occurs; because GSH is used for reduction of dehydroascorbate, tissue ascorbate levels decrease. In lung there are decreased numbers of lamellar bodies and decrease of intraalveolar surfactant. Proximal renal tubular, hepatic, and brain damage also occur. A diastereoisomer of BSO that does not inhibit GSH synthesis, L-buthionine-R-sulfoximine, does not produce toxicity; this control experiment renders it unlikely that the observed effects of BSO are produced by the sulfoximine moiety itself. There is correlation between the decrease of mitochondrial GSH levels and mitochondrial and cell damage. Oxidative stress as evaluated by mitochondrial damage and mortality can be prevented by treatment with GSH esters or ascorbate. There is apparent linkage between the antioxidant actions of GSH and ascorbate. This model, which may readily be applied to evaluation of the efficacy of other compounds in preventing oxidative stress, offers an approach to study of other effects of GSH deficiency (e.g., on lipid metabolism, hematopoiesis), and closely resembles oxidative stress that occurs in certain human newborns and in other clinical states.
Glutathione deficiency induced in newborn rats by giving buthionine sulfoximine, a selective inhibitor of gamma-glutamylcysteine synthetase, led to markedly decreased cerebral cortex glutathione levels and striking enlargement and degeneration of the mitochondria. These effects were prevented by giving glutathione monoethyl ester, which relieved the glutathione deficiency, but such effects were not prevented by giving glutathione, indicating that glutathione is not appreciably taken up by the cerebral cortex. Some of the oxygen used by mitochondria is known to be converted to hydrogen peroxide. We suggest that in glutathione deficiency, hydrogen peroxide accumulates and damages mitochondria. Glutathione, thus, has an essential function in mitochondria under normal physiological conditions. Observations on turnover and utilization of brain glutathione in newborn, preweaning, and adult rats show that (i) some glutathione turns over rapidly (t 1/2, approximately 30 min in adults, approximately 8 min in newborns), (ii) several pools of glutathione probably exist, and (iii) brain utilizes plasma glutathione, probably by gamma-glutamyl transpeptidase-initiated pathways that account for some, but not all, of the turnover; thus, there is recovery or transport of cysteine moieties. These studies provide an animal model for the human diseases involving glutathione deficiency and are relevant to oxidative phenomena that occur in the newborn.
Myeloperoxidase (MPO) was used as a marker enzyme for measuring polymorphonuclear leukocyte (PMN) accumulation in tissue samples. The MPO recovery from kidney, liver, myocardium, skeletal muscle (iliopsoas), and skin was measured, and a variation of 5%-100% was found, depending on the tissue analyzed. The recovery could be improved to 100% in all tissues by incubation of the tissue samples at 60 degrees C for 2 hr. This improved method was used to measure PMN accumulation in rabbit myocardium after regional ischemia and reperfusion. The MPO activity increased fivefold in the occluded area as compared with intact myocardium. Treatment with IB4, a monoclonal antibody recognizing the leukocyte adhesion molecule Mac-1, decreased the MPO activity in the occluded area almost to the level in intact myocardium.
Glucocorticoid-binding activities of the granuloma cytosol were compared with those of the liver cytosol and of the serum in vitro. The granuloma cytosol bound cortisol (HC) about 4-fold higher than dexamethasone (DX) and triamcinolone acetonide (TA); the liver cytosol bound these two synthetic agonists more than HC. The kinetic parameters of the glucocorticoid-binding components of the granuloma and the liver cytosols were studied by the Scatchard method. The binding components of the granuloma cytosol had a single class of binding sites with high affinity for these three steroids, whereas the binding site of the liver cytosol had negative cooperativity or consisted of two distinct classes, because its Scatchard plot showed a hyperbolic curve. The granuloma glucocorticoid-binding components will be protein since their binding was prevented by a trypsin treatment and completely lost by heating at 60 C for 5 min. Heating at 25 or 37 degrees C for 30 min did not affect the HC-binding activity of the granuloma cytosol, regardless of prelabeling with the steroid. The binding activity for DX and TA were heat-labile and completely lost by heating the cytosol at 37 degrees C for 30 min without the respective steroid. The results of thermal inactivation and ammonium sulfate fractionation show the granuloma HC-binding protein closely resembles corticosteroid-binding globulin (CBG). From enzymatic determination of hemoglobin in tissue cytosols, attribution of the contaminating blood to the HC-binding activity of the cytosol is considered to be negligible.
Mice treated with buthionine sulfoximine, an inhibitor of glutathione synthesis, showed striking alterations of morphology of lung type 2 cell lamellar bodies (swelling and disintegration) and mitochondria (degeneration) and of lung capillary endothelial cells (mitochondrial swelling). These effects probably may be ascribed to glutathione deficiency; administration of glutathione monoester protects against them. Measurements of arteriovenous plasma glutathione levels across the lung indicate that the net uptake of glutathione by this organ is substantial. Thus, glutathione exported from the liver to the blood plasma is utilized by the lung which, like the liver, kidney, and lymphocytes (and unlike skeletal muscle), exhibits a high overall rate of glutathione turnover. Intraperitoneal injection of glutathione into buthionine sulfoximine-treated mice leads to very high levels of plasma glutathione without significant increase in the glutathione levels of liver, lung, and lymphocytes; on the other hand, administration of glutathione monoester leads to markedly increased tissue and mitochondrial levels of glutathione. Administration of glutathione monoester (in contrast to glutathione) to control mice also increases mitochondrial glutathione levels. The findings indicate that glutathione is required for mitochondrial integrity and that it probably also functions in the processing and storage of surfactant in lamellar bodies. The morphological changes observed after treatment with buthionine sulfoximine and their prevention by glutathione monoester as well as findings on glutathione metabolism indicate that this tripeptide plays an important role in the lung. The previously observed failure of buthionine sulfoximine-treated mice to gain weight is mainly due to glutathione deficiency in the intestinal mucosa.
The effect of benzylpenicillin (BPC) pretreatment on the kinetics and brain sensitivity for thiopental was studied in male rats using a previously developed electroencephalgrafic (EEG) threshold method. Thiopental was infused intravenously with constant infusion rate. The rats were killed by decapitation immediately after the first burst suppression of 1 sec. or more (the silent second) which was observed in the EEG-record during the infusion. Thiopental concentration in serum and in different brain regions was determined by a high pressure liquid chromatografic method. After pretreatment with 0.9 g/kg of BPC the dose of thiopental needed to induce the silent second was significantly reduced (-20 per cent) when compared with saline treated controls. The serum concentration was also reduced (-30 per cent) after this BPC pretreatment but the concentrations in the different brain regions were the same in both groups. After pretreatment with 1.2 g/kg of BPC almost all animals had convulsions, the dose needed to obtain the silent second was very much reduced and there were reduced concentrations of thiopental in the different brain regions. After both doses of BPC high negative correlations were found between BPC concentrations in brain tissue and thiopental concentrations in hippocampus and brainstem indicating an interaction between the drugs. The most probable site of this interaction is the organic acid transport system out of the CNS which could be used by both substances. Lipid solubility is not the only factor involved in the distribution of thiopental in the rat brain.
Reperfusion syndrome and lipid peroxidation due to toxic effects of free oxygen radicals might be one pathophysiological cause of the oedema that develops during the first week after a femoro-popliteal reconstruction. This paper reports the activity of the protecting antioxidant enzymes superoxide dismutase (SOD), glutathione peroxidase and catalase in gastrocnemic muscle before and after reperfusion of chronically ischaemic legs with comparison to activities in non-ischaemic muscle. Furthermore the susceptibility to lipid peroxidation in the muscle was measured as thiobarbituric acid reactive material (TBAR). The activities of CuZn SOD, Mn SOD and glutathione peroxidase were equal in normally perfused and chronically ischaemic muscle and there was no difference after reperfusion. Muscle catalase activity was low compared to activity of red blood cells and could not be reliably estimated. There was no difference in iron-stimulated lipid peroxidation of ischaemic and non-ischaemic muscle but in reliably estimated. There was no difference in iron-stimulated lipid peroxidation of ischaemic and non-ischaemic muscle but in muscle biopsied 10 min after reperfusion there was a significant increase in production of TBAR indicating an increased susceptibility for lipid peroxidation at this time. The finding is compatible with the occurrence of an oxidant insult on the muscle at reperfusion. Ischaemia--or reperfusion--induced reductions in activity of antioxidant enzymes are however not related to this reaction.
Skeletal muscle degeneration associated with mitochondrial damage was found after marked depletion of glutathione produced by administration to mice of buthionine sulfoximine, an irreversible inhibitor of gamma-glutamylcysteine synthetase. No mitochondrial damage was found in heart. These studies show that in the absence of applied stress (such as ischemia, drug toxicity), very marked depletion (to approximately 3% of the controls) of glutathione must occur before skeletal muscle mitochondria are affected and thus suggest that muscle has a large excess of glutathione. Depletion of glutathione followed a biphasic pattern in skeletal muscle and heart, probably reflecting, in the slow phase, loss of glutathione from mitochondria. Skeletal muscle degeneration did not occur when glutathione monoisopropyl ester was given together with buthionine sulfoximine; it did occur, however, when glutathione was given together with buthionine sulfoximine. Administration of the glutathione monoester (but not of glutathione) prevented the marked decline of mitochondrial glutathione produced by buthionine sulfoximine in skeletal muscle and increased the level of glutathione in heart mitochondria to values higher than the controls. The findings suggest that glutathione monoesters may be useful agents for protection of heart and skeletal muscle against toxicity.
A simple and rapid method for determination of catalase activity in small tissue samples is described. Using a new approach, we have exploited the peroxidatic function of catalase for the determination of enzyme activity. The method was based on the reaction of the enzyme with methanol in the presence of an optimal concentration of hydrogen peroxide. The formaldehyde produced was measured spectrophotometrically with 4-amino-3-hydrazino-5-mercapto-1,2,4-triazole (Purpald) as a chromogen. With this method, a detection limit of 12.5 ng of purified catalase from bovine liver was possible, and it was successfully applied to microgram amounts of mouse liver and pancreatic islet homogenates. The catalase activity in liver was about 50 times higher than that in pancreatic islets.
The neurotoxic potential of intravenous administered benzylpenicillin (BPC) was studied in rabbits with intact blood-CNS barriers and rabbits with experimental E. coli meningitis. At onset of epileptogenic EEG activity or seizures, serum, CSF and brain tissue were collected for assay of BPC. Based on the fact that, in tissues, BPC seems to remain extracellularly, brain concentrations of BPC were expressed as brain tissue fluid (BTF) levels, calculated as 10x the concentration in whole brain tissue. Neurotoxicity could be precipitated in all rabbits. In normal rabbits BTF levels of BPC were considerably higher than those in CSF indicating a better penetration across the blood-brain barrier (BBB). BPC penetrated better to CSF and BTF in meningitic rabbits than in normal controls, suggesting some degree of damage of the BBB concomitant with meningeal inflammation. E. coli meningitis did not increase the neurotoxicity of BPC. In control rabbits the intracisternal injection of saline resulted in some degree of pleocytosis. Unmanipulated animals are therefore preferable as controls. Epileptogenic EEG-changes was the most precise of the two variables used for demonstration of neurotoxicity. EEG-changes were therefore used as neurotoxicity criterion in the following rabbit experiments. To evaluate the effect of uraemia alone and uraemia plus meningitis on the neurotoxity of BPC in rabbits, cephaloridine was used to induce uraemia. Meningitis was induced by intracisternal inoculation of a cephalosporin resistant strain of E. cloacae. Untreated rabbits were used as controls. Uraemia resulted in increased BTF penetration of BPC, possibly explained by permeability changes in the BBB and/or decreased binding of BPC to albumin. Uraemia did not result in increased penetration of BPC into the CSF of non-meningitic rabbits. Uraemic non-meningitic rabbits had the highest BTF levels of BPC at the criterion, indicating that cephaloridine-induced renal failure increased the epileptogenic threshold in these rabbits. The combination of uraemia and meningitis increased the neurotoxicity of BPC since the criterion was reached at considerably lower BTF levels of BPC. Meningitis, either alone or together with uraemia, did not increase the neurotoxicity in comparison to control rabbits. Higher BTF levels of BPC were found in meningitic rabbits than in controls with intact blood-CNS barriers at onset of EEG-changes. In all groups of rabbits there was a pronounced variability of BPC levels in the CSF while the intra-group variations in BTF levels were much smaller. Thus, BTF and not CSF levels were decisive for the neurotoxicity of BPC.(ABSTRACT TRUNCATED AT 400 WORDS)
Extracellular-superoxide dismutase (EC-SOD) is heterogenous in the vasculature with regard to heparin affinity and can be separated into three fractions: A, without affinity; B, with weak affinity; and C, with relatively strong heparin affinity. The plasma clearance of intravenously injected 125I-labeled and unlabeled human EC-SOD C was studied in rabbits. About 90% of injected 125I-EC-SOD C was eliminated from the blood within 5-10 min. Injection of heparin after 10 or 20 min led to an immediate release of all sequestered 125I-EC-SOD C back to the blood plasma. Later injections of heparin led to diminished release, although release could still be demonstrated after 72 h. A half-time of approximately 10 h could be calculated for heparin-releasable 125I-EC-SOD C. Unlabeled EC-SOD C, determined as enzymic activity and with ELISA, was likewise sequestered and released to the same degree as 125I-labeled EC-SOD C by heparin as tested at 20 min and 5 h. The immediacy of the heparin-induced release indicates that the sequestered enzyme had been bound to endothelial cell surfaces. The length of the half-time suggests that the putative cell surface binding has a physiological function and is not primarily a step in enzyme degradation. The distribution of sequestered 125I-labeled EC-SOD C to different organs was determined at times between 10 min and 24 h. Of the organs, the liver contained the most 125I-EC-SOD C, followed by kidney, spleen, heart, and lung. At all investigated times, the content in the analyzed organs was nearly as large as the amount that could be promptly released to plasma by intravenous heparin. This indicates that almost all 125I-EC-SOD C in the organs was present on endothelial cell surfaces and was not bound by other tissue cell surfaces, or was present within the cells.
An assay of hemoglobin in tissue homogenates is described. Tissues are homogenized with a 40 mM phosphate buffer (pH 8.0) solution without the use of a polytron or sonicator. The assay should be carried out before fractionations such as centrifugation. By measuring the free-radical intermediates of chlorpromazine, which are formed by the addition of hemoglobin, a linear calibration curve can be obtained within the range of hemoglobin contents between 0.8 and 12.0 micrograms. The present method can be applied to the assay of hemoglobin in several kinds of tissues from rats.
Brain capillaries (microvessels) were isolated from the rabbit and bovine brain. Extensive morphological examinations were performed at the light and electron microscopical levels. The relative contribution of endothelium (52%), basal membrane (32%) and pericytes (16%) to the composition of the microvessel was assessed. The ability of the endothelium from bovine brains to maintain a membrane potential, i.e. to accumulate the lipophilic cation [3H]TPMP, was shown. The transmitter catabolizing enzymes MAO and AchE were shown to be, and COMT and GABA-T not to be associated with the microvessel fraction isolated from rabbits.
The superoxide dismutase (SOD) activity in fetal rat cerebrum was studied on gestational days (gd) 19 and 21 after X-irradiation with 100R on gd 13 or no X-irradiation. Fetuses X-irradiated on gd 13 showed marked microcephalus on gd 19 and 21. Most of the SOD activity was found in the crude mitochondrial fraction in both groups and most of the SOD was Cu,Zn-SOD. The SOD activity increased about two times from gd 19 to 21. The mean SOD activity of the fetal rat cerebrum X-irradiated with 100R showed no significant differences compared to that of the control group with Student's t test. But the activities in the irradiated group were widely distributed with a large standard deviation and so the chi-square test showed a significant difference in SOD activity between the two groups on gd 19. The SOD activity of adult rat cerebrum 6 and 8 days after X-irradiation with 100R was increased compared to that 3 days after X-irradiation. It was suspected that X-irradiation in utero may have some lasting effect on the SOD activity in fetal rat cerebrum.
This report describes the development of superoxide dismutase, glutathione peroxidase, and catalase activities in fetal (days 16-22) and neonatal (day 2 postpartum) lungs of normal rats. Each of the enzymes showed an individual pattern of development in the perinatal period. Glutathione peroxidase activity increased by 135% (p less than 0.001) during the last 3 days before birth, catalase activity by 105% (p less than 0.01) during the first 2 postnatal days, and the activity of superoxide dismutase by 52% (p less than 0.05) from gestational day 19 to 2 days after birth. Contamination by superoxide dismutase from blood in the lung samples accounted for less than 2% of the activity. In contrast, not less than 10-30% of glutathione peroxidase and catalase originated from the blood; and corrections were made for this source of error in each sample.
Brain capillaries (microvessels) were isolated from rabbit brain. Morphological characterization revealed relatively pure fractions of microvessels consisting of the capillary endothelium, the basal membrane, and the pericyte. These fractions of brain capillaries show acetylcholinesterase (AChE) and monoamine oxidase (MAO) activity, but lack catechol-O-methyltransferase and GABA transaminase activity. Isolated brain capillaries together with samples of the brain parenchyma and serum were used to study the role of AChE present in the brain capillary wall in soman intoxication. The results showed this AChE to be less sensitive to soman inhibition than AChE of brain parenchyma. Serum and brain AChE recovered to some extent in soman-intoxicated rabbits given HI-6, whereas AChE present in the microvessel was even further inhibited. It is suggested that soman-induced vasospasm in rabbit brain may explain both the inaccessibility of capillary AChE to soman and also the unfavorable effect of HI-6 on this enzyme.
Enzymes of importance for oxygen dependent leukocyte killing of microorganisms were studied in 14 patients with Down's Syndrome (DS) and 10 controls. As has been reported previously for other cell types, the level of CuZn superoxide dismutase (SOD) was 50% higher in polymorphonuclear leukocytes (PMN) from DS patients than from the controls. The amount of SOD was extremely low in the PMNs from controls, i.e. only about 6% of the levels in other human tissues. The levels of catalase and of the Mn dependent SOD were normal. The myeloperoxidase (MPO) activity of DS PMNs was only 59% of that of the control cells. Previously reported increased levels of CuZnSOD and GSH peroxidase in erythrocytes and CuZnSOD in lymphocytes were confirmed. The increased levels of SOD in DS phagocytes provide a possible partial explanation for previous reports of defective killing of S. aureus in DS. In addition, the MPO deficiency impairs the H2O2-halide-MPO system, which is of particular importance for fungal killing, e.g. of C. albicans, which has also been reported to be deficient in DS. The findings may thus explain some of the mechanisms underlying the increased susceptibility to certain infections in DS.
A method based on measurement of absorbance at 540 or 580 nm is described. The results obtained were closely correlated to the actual level of blood present in different tissues, as determined by use of radiolabeled albumin. The present technique is much simpler than earlier methods used to determine the degree of blood contamination of tissue extracts. Hence, it may find wide application in the life sciences.
Effects of dietary iron deficiency on growth, the distribution of hemoglobin (Hb) at rest and during exercise, the characteristics of muscle fiber types, and glycogen depletion patterns were studied in newly weaned male mice. Forty-eight mice were randomly divided into iron-deficient and control diet groups. Severe iron deficiency impaired general growth, but growth was restored following iron repletion. The mean +/- SEM blood Hb concentrations at rest after 7 weeks were 5.8 +/- 0.7 and 12.5 +/- 0.3 g/dl in iron-deficient and control groups, respectively. The mice fed iron-deficient diet for 7 weeks had an increased Hb level of 10.9 +/- 0.5 g/dl 1 week after an i.p. injection of Imferon (1.25 mg Fe). The Hb contents in brain and gastrocnemius as well as whole body were lowered by iron deficiency. Iron-deficient anemic mice tended to increase the percent distribution of Hb to brain during exercise. This value was significantly greater than in control and iron-treated groups. The iron-deficient group had relatively less glycogen than controls, but no significant tendency in glycogen depletion pattern was observed in any fiber types. It is suggested that decreased Hb content in working muscles due, in part, to greater distribution to brain could be one of the limiting factors for work performance in anemic individuals. It is further suggested that decrease in oxidative muscle fibers as well as the decreased concentration and/or activities of oxidative substances may also be one of the limiting factors.
Exogenous superoxide dismutase, catalase and scavengers of the hydroxyl radical protect pancreatic-islet cells against the toxic actions of alloxan in vitro [Grankvist et al. (1979) Biochem. J. 182, 17--25]. To test whether the extraordinary sensitivity of islet cells to alloxan is due to a deficiency of endogenous enzymes protecting against oxygen-reduction products, we assayed CuZn-superoxide dismutase, Mn-superoxide dismutase, catalase and glutathione peroxidase in mouse islets and other tissues. To correct for any blood contamination, haemoglobin was also measured in the tissue samples. Pancreatic islets were found to belong to tissues with relatively little activity of the protective enzymes. However, the deviation from other tissues in this respect is probably not large enough to explain the especially great susceptibility of islet cells to alloxan.
Copper- and zinc-containing superoxide dismutase, manganese-containing superoxide dismutase, catalase, and glutathione peroxidase form the primary enzymic defense against toxic oxygen reduction metabolites. Such metabolites have been implicated in the damage brought about by ionizing radiation, as well as in the effects of several cytostatic compounds. These enzymes were analyzed in 31 different human normal diploid and neoplastic cell lines and for comparison in 15 normal human tissues. The copper- and zinc-containing superoxide dismutase appeared to be slightly lower in malignant cell lines in general as compared to normal tissues. The content of manganese superoxide dismutase was more variable than the content of the copper- and zinc-containing enzyme. Contrary to what has been suggested before, this enzyme did not appear to be generally lower in malignant cells compared to normal cells. One cell line, of mesothelioma origin (P27), was extremely abundant in manganese-containing superoxide dismutase; the concentration was almost an order of magnitude larger than in the richest normal tissue. Catalase was very variable both among the normal tissues and among the malignant cells, whereas glutathione peroxidase was more evenly distributed. In neither case was a general difference between normal cells and tissues and malignant cells apparent. The myocardial damage brought about by doxorubicin has been linked to toxic oxygen metabolites; particularly, an effect on the glutathione system has been noted. The heart is one of the tissues which have a low concentration of enzymes which protect against hydroperoxides. However, the deviation from other tissues is probably not large enough to provide a full explanation for the high doxorubicin susceptibility. In the present survey, no obvious relationship between generally assumed resistance to ionizing radiation or to radical-producing drugs and cellular content of any of the enzymes could be demonstrated.
Superoxide dismutase (SOD) levels, thought to be the first cellular defence against free radicals, were studied in the nonobese diabetesprone (NOD-p) mouse, an animal model of type 1 diabetes in which about 100% of females and 20% of males become diabetic. Nonobese diabetes nonprone (NON-p) mice were used as controls. Animals were followed from 5th to 22nd week of life. Results show that SOD levels in female NOD-p mice are extremely low. In males, values are considerably higher than in females but still lower than values found in control mice. Moreover, SOD levels did not significantly change with age, degree of insulitis or level of diabetes. Islet beta cells in this strain, therefore, seem to be poorly protected against the negative effects of free radicals and this may predispose to diabetes. Furthermore, alterations of SOD may not be directly related to the development of the disease as the enzyme's activity is not further modified with age or the progression of diabetes.
Alzheimer's disease may arise from or produce oxidative damage in the brain. To assess the responses of the Alzheimer's brain to possible oxidative challenges, we assayed for glutathione, glucose-6-phosphate dehydrogenase, catalase and superoxide dismutase in twelve regions of Alzheimer's disease and aged control brains. In addition, we determined levels of malondialdehyde to evaluate lipid peroxidation in these brain regions. Most brain regions showed evidence of a response to an oxidative challenge, but the cellular response to this challenge differed among brain regions. These data suggest that the entire Alzheimer's brain may be subject to an oxidative challenge, but that some brain areas may be more vulnerable than others to the consequent neural damage that characterizes the disease.
Extracellular-superoxide dismutase C (EC-SOD C) is a secretory tetrameric Cu- and Zn-containing glycoprotein which has high affinity for heparin and heparan sulfate. Upon intravenous injection into rabbits, recombinant human (rh) EC-SOD C was found to be rapidly 97-98% sequestered to the vascular wall, forming an equilibrium with the plasma phase. Recombinant EC-SOD truncation variants with reduced, T216, and without, T213, heparin affinity were found to be sequestered to a reduced extent and not at all, respectively, establishing the importance of the heparin affinity for this behaviour. The halflife of rhEC-SOD C in the vasculature was of the order of 20 h. Injection of large doses resulted in saturation of the binding of rhEC-SOD C to the vascular wall. Scatchard analysis revealed a heterogeneity in affinity of the ligands on the vascular wall. The maximal binding capacity was very high. The equilibration of rhEC-SOD C to the vascular wall of an organ, clamped during enzyme injection, and the primary equilibration phase was studied by comparing binding to a clamped and reperfused kidney with binding to the contralateral control kidney. rhEC-SOD C injected in a low dose was found to equilibrate very slowly to the reperfused kidney with a halftime of about 2 h. With higher rhEC-SOD C doses, at which evidence for saturation is seen, and with the variant rhEC-SOD with reduced heparin affinity. T216, very rapid equilibrations were found.(ABSTRACT TRUNCATED AT 250 WORDS)
When human umbilical vein endothelial cells were prelabeled with [14C]-adenine and then exposed to xanthine oxidase (40 mU/ml) and hypoxanthine (100 microM) for 4 h, cellular adenine nucleotides were depleted (18 +/- 3% of total radioactivity vs. 61 +/- 10% in controls), nucleotides appeared in the culture medium (8 +/- 3% vs. 4 +/- 3%) together with the catabolic products inosine, hypoxanthine, and uric acid (74 +/- 4% vs. 35 +/- 11%). In the presence of H2O2 (100 microM) for 30 min, cellular nucleotides were depleted (46 +/- 25%) and catabolic products appeared in the medium (40 +/- 26%), but radioactive nucleotides in the medium were unaltered. In the presence of an inhibitor of ecto-5'-nucleotidase [alpha, beta-methylene-adenosine 5'-diphosphate (ADP), 0.5 mM], exposure to xanthine oxidase and hypoxanthine resulted in the appearance of three times more nucleotides in the culture medium than in the absence of the inhibitor, but there was no change in medium nucleotides after H2O2 exposure. In the presence of an inhibitor of adenosine deaminase (2-deoxycoformycin, 2 microM), both exposures caused an accumulation of adenosine in the medium, calculated to represent a minimum of 25% of nucleotide catabolism. We conclude that exposure to both a superoxide-generating system (hypoxanthine plus xanthine oxidase) and H2O2 induce catabolism of adenine nucleotides, which mainly takes place through adenosine 5'-monophosphate (AMP) deaminase. However, superoxide but not H2O2 also causes membrane damage and leakage of nucleotides into the medium.
Insulin-dependent diabetes (IDD) in the nonobese diabetic (NOD) mouse is believed to result from the specific autoimmune destruction of pancreatic beta cells. The frequency of diabetes in the NOD mouse is sex-dependent, with approximately 90% of females and 40% of males developing clinical diabetes by 40 weeks of age. Recently, attention has focused on determining possible mechanisms for beta cell destruction. One potential mechanism is the toxic effect of free oxygen radicals produced as a result of the influx of inflammatory cells into the pancreas. A deficiency in available antioxidant enzymes could form a basis for diabetes susceptibility. To test the feasibility of this idea, we have compared the activities of superoxide dismutase, catalase, glutathione peroxidase, and glutathione reductase in isolated islets, pancreas, and other tissues of age- and sex-matched NOD, BALB/c, C57BL/10, and B10.GD mice. Enzyme profiles revealed that female NOD mice do not differ significantly in antioxidant enzyme activity from females of the other inbred strains. However, antioxidant enzyme activity in females was generally lower than in males regardless of mouse strain. While isolated islet cells exhibited somewhat lower levels of enzyme activity than other tissues, the islets of NOD mice proved to be no more deficient than those of BALB/c mice. Therefore, it is unlikely that any toxic effect of free oxygen radicals on the beta cells of NOD mice results directly or solely from an antioxidant enzyme deficiency. Nevertheless, one possible explanation for the lower incidence of diabetes in NOD males versus females may be the inherently higher male antioxidant enzyme activities.
Low-dose streptozocin-treated (LDS) mice were administered an inhibitor of lipid peroxidation, U-83836-E (a derivative of vitamin E), in order to observe its ability to alter the onset of diabetes. Ten or 20 mg/kg body wt. per day of U-83836-E were given to mice for 7 days and they were killed after 21 days. Results revealed that there was a significant increase in glycaemia in treated groups up to day 14 after which no further increase was noticed. Superoxide dismutase (SOD) assay showed that: (1) the LDS treatment significantly reduces SOD activity when compared with untreated controls (P < 0.005); (2) U-83836-E increases SOD levels (when compared with untreated controls); and (3) U-83836-E counteracts LDS treatment, since SOD activity is significantly higher with respect to that found in LDS-controls (P < 0.05), and SOD levels were significantly higher with respect to that found in Group 2 animals (P < 0.05), but significantly lower with respect to those found in groups 3 and 4 (P < 0.005). Moreover, malondialdehyde (MDA), the end-product of lipoperoxidation, was found at much higher levels in LDS controls than in the other groups and the lowest values were found in U-83836-E controls and in normoglycaemic animals treated with both streptozocin and U-83836-E. Morphological observations demonstrated that islet beta cells were of normal appearance in normoglycaemic animals of the treated groups. In conclusion, the in vivo inhibition of lipid peroxidation by this compound produces a limited but significant prevention of the islet beta cell destruction.
We investigated the contribution of the rate of vascular collapse to the early contractile failure and decreased diastolic stiffness induced by ischemia. Isolated rat hearts (n = 8/group), perfused at 37 degrees C with blood through a roller pump and paced at 320 beats/min, were subjected to global ischemia either by switching off the roller pump (slow vascular collapse-group 1) or by reversing the direction of the roller pump for 5 s prior to switch-off (rapid vascular collapse-group 2). In group 1, residual coronary pressure declined progressively over the first 20 s of ischemia whereas in group 2 the pressure had fallen to zero within 2 s. The profile of ischemia-induced contractile failure was however, similar in both groups. Thus, after 2 s of ischemia, when residual perfusion pressure had declined by only 10% in group 1 (60.0 +/- 0.0 to 54.9 +/- 0.8 mmHg) but was virtually non-existent in group 2 (60.0 +/- 0.0 to 0.4 +/- 12.7 mmHg), left ventricular developed pressure had fallen to a similar extent in both groups (86 +/- 2% and 84 +/- 3%, respectively). Curve-fitting analysis for individual hearts showed that the profile of contractile failure was described by a double exponential process that was not significantly affected by the rapid vascular collapse. Left ventricular end-diastolic pressure in group 1 hearts progressively declined over the first 20 s of ischemia, the profile paralleling that of the dissipation of perfusion pressure. In contrast, in group 2 hearts, left ventricular end-diastolic pressure rose rapidly and leaked at 5 s, a period that coincided with the reversed direction of the perfusion pump. Similarly, in a separate study, the analysis of ventricular diastolic stiffness (n = 6/group) showed a rapid decline during the first 20 s of ischemia: this decline could be inhibited by the use of rapid vascular collapse. In additional experiments, hearts (n = 8/group) were paced at 220, 320 or 420 beats/min and ischemia was induced by reversing (5 s) and then stopping the perfusion pump. Myocardial oxygen consumption increased in parallel with heart rate and was matched by commensurate increases in the rate of contractile failure. Curve-fitting analysis showed that slow stimulation rates (220 beats/ min) significantly delayed contractile failure during the first 60 s of ischemia (first time constant = 14.5 +/- 4.1 s compared with 8.1 +/- 1.1 s at 320 beats/min and 6.3 +/- 1.1 s at 420 beats/min; P < 0.05 in both instances). In conclusion, vascular collapse associated with ischemia may contribute to the initial decrease in ventricular diastolic stiffness; however, it does not play a major role in determining the rate of acute contractile failure. Metabolic processes as reflected by oxygen consumption do however, appear to be important.
This study showed that citiolone (CIT), a free radical scavenger, significantly increased superoxide dismutase (P < 0.001 vs. untreated NOD, NMMA-treated, and silica-treated animals), catalase (P < 0.01 vs. untreated NOD), and glutathione peroxidase (P < 0.001 vs. untreated NOD and C57BL6/J) values. Silica treatment was capable of counteracting the plasma antioxidant capacity (TRAP) decrease observed in untreated NOD mice, although it did not block the blood glucose rise and insulitis progression in type 1 diabetes significantly. Conversely, early silica administration was able to deplete macrophages (as demonstrated by immunocytochemistry) and to block the rise in blood glucose levels and insulitis progression significantly. Silica-treated animals in this study showed the highest TRAP levels, demonstrating that depletion of macrophages also was able to improve the antioxidant status. This study suggested that macrophages are essential for type 1 diabetes development and showed that they also are involved when the antioxidant status is affected. The reported findings are significant in view of previous studies indicating that oxygen and/or nitrogen free radicals contribute to the islet beta-cell destruction in type 1 diabetes animal models.
Streptozotocin (STZ) is a widely used diabetogenic agent that damages pancreatic islet beta cells by activating immune mechanisms, when given in multiple low doses, and by alkylating DNA, when given at a single high dose. Actually, STZ contains a nitroso moiety. Incubation of rat islets with this compound has been found to generate nitrite; moreover, photoinduced NO production from STZ has been demonstrated. These reports have suggested that direct NO generation may be a mechanism for STZ toxicity in diabetogenesis. Several other studies have denied such a mechanism of action. This study has shown that (1) the multiple low-dose (MLDS) treatment does not stimulate NO production at the islet level; in fact, nitrite + nitrate levels and aconitase activity (also in the presence of an NO-synthase inhibitor, namely NAME) remain unmodified; RT-PCR analysis demonstrates that this treatment does not stimulate iNOS activity; (2) the high-dose (HDS) treatment does not stimulate NO production; in fact nitrite + nitrate levels remain unmodified and iNOS mRNA levels are not altered, although aconitase activity is significantly decreased. Moreover, we have confirmed that the MLDS treatment is able to decrease SOD activity by day 11 and that STZ, given in a single high dose, transiently increases superoxide dismutase (SOD) values (24 h from the administration), then dramatically lowers SOD levels. On the basis of our results, we conclude that STZ, "in vivo" is unable to generate NO, both as a MLDS or HDS treatment, thus excluding that NO exerts a role in streptozotocin-dependent diabetes mellitus.
Cytokine production is a critical component of ischemia/reperfusion (IR) injury. In the liver, Kupffer cells produce cytokines and chemokines (i.e., cytokines with chemoattractant properties) that are important mediators in neutrophil recruitment and subsequent hepatocellular injury. Therefore, the role of Kupffer cells in chemokine production in hepatic IR injury was investigated.
Adult male C57BL/6 mice underwent 90 min of partial hepatic ischemia followed by various reperfusion times (i.e., 0, 1.5, 3, and 6 h). Gadolinium chloride (GC), which inhibits Kupffer cell activity, was administered to mice 48 and 24 h prior to ischemia. The control group received a corresponding volume of normal saline. Plasma levels of the cytokine macrophage inflammatory protein-2 (MIP-2), KC, and tumor necrosis factor (TNF)-alpha and liver mRNA were measured. Liver injury was assessed by plasma level of alanine transaminase (ALT) and histopathology.
A reperfusion time-dependent liver injury occurred as indicated by increased levels of plasma ALT and histopathology. The injury was associated with increased plasma TNF-alpha, MIP-2, and KC and their hepatic mRNA expression and neutrophil infiltration into ischemic lobes of the liver. GC treatment significantly reduced the number of Kupffer cells as determined by the immunostained liver tissue sections. The extent of liver injury significantly decreased in GC-treated mice that were associated with decreased levels of plasma ALT, TNF-alpha, MIP-2, and KC and neutrophil infiltration.
This study suggests that Kupffer cells are major contributors to cytokine production in hepatic IR and their modulation may serve as a potential target for therapeutic intervention.
Myeloperoxidase (MPO) activity is assessed for the quantification of neutrophil accumulation in tissues. In particular, it may be used to support in vivo data on leukocyte kinetics obtained by intravital microscopy and to clarify whether phenomena observed on the organ surface reflect the situation of the whole organ microcirculation. Previous measurements of MPO activity were limited by interference with other peroxidases and by inhibition of MPO activity by specific enzymes. To circumvent these limitations, a modified assay was devised that combined a two-step tissue homogenization technique with heat incubation in a continuous photometric measurement. MPO activity was quantified in neutrophils isolated from rat and rabbit whole blood, rat brain and rabbit lung and compared with intravital microscopic data on leukocyte accumulation. The modified assay is characterized by high reproducibility, strong correlation of MPO activity with number of neutrophils and full recovery of neutrophils added to tissue homogenate. MPO activity per neutrophil was 342.9 +/- 11.7 mU/10(6) cells in rats and 40.3 +/- 0.8 mU/10(6) cells in rabbits. MPO activity in tissue was significantly lower in rat brains (18.9 +/- 29.7 mU/g) as compared to rabbit lungs (741 +/- 67 mU/g). Whereas global cerebral ischemia/reperfusion did not increase MPO activity in rat brain (18.1 +/- 26.1 mU/g), intravenous infusion of cobra venom factor (1,447 +/- 407 mU/g) or endotoxin (1,439 +/- 285 mU/g), enhanced MPO activity in rabbit lung. These results parallel microcirculatory data from the organ surface. Therefore they supplement the intravital microscopic observations by demonstrating that these are indeed representative of deeper parenchymal tissue areas.
A vast amount of scientific research is directed towards the beneficial effects of antioxidants on health. For this reason, several assays have been developed to determine the total antioxidant capacity of blood.
In this study two procedures based on the use of the green-blue 2,2'-azino-bis(3-ethylbenzthiazoline-6-sulfonic acid) radical (ABTS(*+)) were compared. In the first (commercially available) procedure, ABTS(*+) was generated in the presence of the blood sample. In the second procedure, referred to as the decolorization assay, antioxidants react with preformed ABTS(*+).
It was found that the first procedure leads to greater underestimation of the actual antioxidant capacity and is more prone to artifacts than the second procedure. Therefore, only the latter procedure was evaluated in detail and it appeared that (i) plasma is preferred over serum, (ii) the high background produced by albumin can be circumvented by deproteination, (iii) samples can be stored at -80 degrees C for 12 months, and (iv) the assay has high precision. Due to poor linearity, the procedure has to be standardized to allow sample comparison.
The decolorization assay is a reliable and robust assay that can be applied routinely to predict the antioxidant capacity of blood.
There is mounting evidence that the established paradigm of nitric oxide (NO) biochemistry, from formation through NO synthases, over interaction with soluble guanylyl cyclase, to eventual disposal as nitrite/nitrate, represents only part of a richer chemistry through which NO elicits biological signaling. Additional pathways have been suggested that include interaction of NO-derived metabolites with thiols and metals to form S-nitrosothiols (RSNOs) and metal nitrosyls. Despite the overwhelming attention paid in this regard to RSNOs, little is known about the stability of these species, their significance outside the circulation, and whether other nitros(yl)ation products are of equal importance. We here show that N-nitrosation and heme-nitrosylation are indeed as ubiquitous as S-nitrosation in vivo and that the products of these reactions are constitutively present throughout the organ system. Our study further reveals that all NO-derived products are highly dynamic, have fairly short lifetimes, and are linked to tissue oxygenation and redox state. Experimental evidence further suggests that nitroso formation occurs substantially by means of oxidative nitrosylation rather than NO autoxidation, explaining why S-nitrosation can compete effectively with nitrosylation. Moreover, tissue nitrite can serve as a significant extravascular pool of NO during brief periods of hypoxia, and tissue nitrate/nitrite ratios can serve as indicators of the balance between local oxidative and nitrosative stress. These findings vastly expand our understanding of the fate of NO in vivo and provide a framework for further exploration of the significance of nitrosative events in redox sensing and signaling. The findings also raise the intriguing possibility that N-nitrosation is directly involved in the modulation of protein function.
An easy and reliable (spectro-)photometric procedure is described for the determination of hemoglobin as hemiglobincyanide. The time needed for a determination has been shortened from 20 to 4 min by shifting the ph of the diluent from 8.6 to 7.2. This has been accomplished by substituting (140 mg/l) KH2PO4 for the NaHCO3 in the diluent conventionally used in the HiCN method. Turbidity through precipitation of plasma proteins is prevented by the addition of a small amount of a detergent (Sterox SE) which also promotes rapid lysis of the red cells.
A procedure is described for the determination of plasma or serum haemoglobin employing the peroxidase activity of the haemoprotein using 2,2'-azino-di-(3-ethyl-benzthiazolinsulphonate-6) as chromogen. The method gives equal results for free haemoglobin, methaemoglobin and haemoglobin complexed to haptoglobin. It is designed to measure haemoglobin in the range 0--12 mumol/l. The peroxidase activity of myoglobin is similar to that of haemoglobin, whereas haemin in free solution, bound to haemopexin or to albumin (methaemalbumin) shows much lower activity. The precision within run is satisfactory, +/- 5%.