Andrew C. Cuming's research works | University of Leeds and other places

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Genetic validation of YFP-TM-ERD2 by stable transformation in Nicotiana benthamiana and Physcomitrium patens
a Schematic of N. benthamiana ERD2ab antisense (AS) construct driven by the strong constitutive CaMV35S promoter (35S), combined with YFP constructs expressed under the weak TR2 promoter on the same T-DNA. b Confocal laser scanning microscopy (CLSM) of stably transformed N. benthamiana tissues, expressing all three fusions in regenerating shoots in tissue culture. Only YFP-TM-ERD2 led to fertile plants allowing us to image this fusion in root cortex cells from next-generation seedlings. Notice that ST-YFP-HDEL labels the ER, ERD2-YFP labels the ER and weak Golgi bodies, while YFP-TM-ERD2 only labels Golgi bodies. In roots, Golgi-stacks are either viewed from the side (arrow heads) or from top/bottom (stars), giving rise to the typical donut shapes. Even with high detector gain, YFP-TM-ERD2 cannot be detected in the ER. Size marker 10 μm. c Schematic of YFP-TM targeted gene knock-in onto PpERD2B-1 (Pp3c9_13230V3.9), leading to expression of a YFP-TM-ERD2 derivative under the transcriptional control of the native promoter in P. patens. d Schematic of PpERDB2-2 (Pp3c15_12830) knockout by complete deletion of the second ERD2 gene. e YFP-TM-PpERD2 expression under its native promoter in P. patens. (e1) Notice stronger expression near growing tips and newly formed cell plates (white stars). Size marker 50 μm. (e2) At high magnification, distinguish punctate structures (white arrow heads) from weak autofluorescence of chloroplasts (Chl.). Size marker 10 μm.

ERD2 function and Golgi residency is conserved amongst eukaryotes
a Retention assay using protoplasts showing the secretion index (ratio extra/intracellular Amy-HDEL activity) with cargo alone (either Amy-HDEL or Amy-KDEL) or with co-expressed A. thaliana ERD2b (At) and 12 further ERD2 orthologs from the eukaryotes Ostreococcus lucimarinus (Oi), Acanthamoeba castellanii (Ac), Phytophthora infestans (Pi), Chondrus crispus (Cc), Galdieria sulphuraria (Gs), Homo sapiens (HsERD2), Hypsibius dujardini (Hd), Thalassiosira pseudonana (Tp), Puccinia graminis (Pg), Kluyveromyces lactis (KlERD2), Trypanosoma brucei (Tb) and Saccharomyces cerevisiae (Sc). Transfection efficiencies were normalised by the internal marker GUS established at 5 standard OD units as described in materials and methods. Percentages in brackets refer to the sequence identity with AtERD2b. Error bars are standard errors. Source data are provided as a Source Data file. b CLSM analysis of two separate Arabidopsis thaliana ERD2b fluorescent fusions (YFP-TM-AtERD2 and AtERD2-YFP, shown in green), each co-expressed with the ER marker RFP-KDEL (shown in red) in HeLa cells. The endogenous cis-Golgi marker GM130 was detected via immunocytochemistry (shown in light blue) and the nucleoplasm is stained with DAPI (dark blue). Notice that in contrast to the C-terminal AtERD2-YFP fusion, YFP-TM-AtERD2 is not detected in the ER and shows the best co-localisation with GM130. The size marker bar is 10 microns. c CLSM analysis at higher magnification to compare YFP-TM-AtERD2 with two different Golgi markers. Notice that the trans-Golgi marker TGN46 is clearly distinct from the ERD2-fusion and GM130. Size marker 10 microns. d As in (b), but fluorescent fusions contain human ERD2 (HsERD2). Size marker 10 microns.

Analysis of C-terminal residues and sensitivity to C-terminal epitope tagging in Hs and At ERD2
a CLSM analysis of two human ERD2 fusions (YFP-TM-HsERD2 and HsERD2-YFP constructed as described (Silva-Alvim et al., 2018) imaged in tobacco leaf epidermis cells. Notice that only the C-terminal YFP fusion causes partial ER localisation. Size marker 10 microns. b Amy-HDEL retention assays as in Fig. 2a but either comparing the two HsERD2 fluorescent variants from panel (a), or a comparison of untagged HsERD2 (WT) with the point–mutations in the HsERD2 C-terminus indicated above each lane. Notice that the C-terminal YFP fusion has completely lost biological activity. Notice also that only the LLGG mutant has lost biological activity when untagged HsERD2 is analysed. Error bars are standard deviations from 3 biological replicas. A full dose response for KKAA is provided in Supplementary Fig. 3. c C-terminal amino acid sequences of human (KDELR2) and A. thaliana ERD2B. Conserved residues are highlighted grey and the conserved di-leucine motif is highlighted bold. d CLSM analysis of selected mutants from (b) but in the YFP-TM-HsERD2 configuration. Silent mutations in panel (b) retain the Golgi localisation, while the inactive LLGG mutant displays partial ER localisation. e Schematic of C-terminal fusions to At and Hs ERD2 for functional assays (upper) and the fluorescent derivative for CLSM analysis (lower schematic). f Secretion index of Amy-HDEL, co-expressed with either wild type human or plant ERD2 compared to the three different C-terminal modifications (FLAG, c-myc, HA) in each case. Constant levels of ERD2 encoding plasmids were co-transfected (yielding 5 standard OD units). In both instances, the addition of a FLAG or c-myc tag strongly reduced function, whilst most of the activity was maintained for each ortholog after adding the HA tag. Error bars are standard deviations from 3 biological replicas. Source data are provided as a Source data file. g Localisation of human and plant ERD2 fluorescent fusions with C-terminal FLAG, c-myc and HA tags. Notice that FLAG and c-myc additions cause an ER-Golgi localisation, whilst the addition of an HA tag does not affect the Golgi localisation of YFP-TM-ERD2 for both orthologs.

FRAP and redistribution assays identify a Golgi-retention signal at the ERD2 C-terminus
a Fluorescence recovery after photobleaching (FRAP) comparing wild type ERD2 and the LLGG mutant. ERD2 recovery to 50% (400 s) took almost twice the time of the LLGG mutant (240 s). LLGG mutant recovery reached 85%, whereas wild type ERD2 remained at around 50%. Error bars are standard deviations from at least 6 biological replicas. Source data are provided as a Source data file. b Schematic of dual expression T-DNA constructs used to co-express fluorescent ERD2 fusions with either secreted Amy or the ERD2-ligand Amy-HDEL. c Golgi localisation of YFP-TM-ERD2 co-expressed with Amy and Amy-HDEL. Distribution remains unchanged for both cargo. Size bars 10 microns. d Dual ER-Golgi localisation of YFP-TM-ERD2ΔC5 co-expressed with Amy and a more prominent ER localisation when co-expressed with Amy-HDEL. Size bars 10 microns. e Dual ER-Golgi localisation of ERD2-YFP co-expressed with Amy. The re-distribution of ERD2-YFP to the ER by co-expressed Amy-HDEL is even more drastic compared to that of the deletion mutant in panel (d). Size bars 10 microns. f Schematic including the T-DNA construct used to study ERD2-YFP localisation, which is variable depending on expression levels. Golgi bodies (arrows) are labelled by ERD2-YFP more visibly during high cellular expression, whereas punctae are much fainter relative to the ER fluorescence at low expression levels (imaged at higher detector gain). Size bars 10 microns.

A canonical COPI transport motif (KKXX) causes ER Localisation and abolishes Amy-HDEL retention of ERD2
a C-terminal amino acid sequences of ERD2 wild type (WT) and two variants in which the last 9 amino acids of ERD2 is replaced by the corresponding region of p24 (underlined). The proposed COPII ER export signal of p24 (Contreras et al., 2004b) is in bold, as is the dileucine motif in the WT sequence, the relevant lysines of the canonical COPI transport motif in the p24 variant and finally the mutant serines in the KKSS variant. Size bars 10 microns. b Dose–response assay measuring the influence of co-transfected C-terminal ERD2 variants (given in standard GUS OD units below each lane) on Amy-HDEL secretion. ERD2-WT mediates strong cell retention whilst the p24 fusion shows no retention activity. The KKSS mutant of the p24 fusion restores the retention activity at the highest dose. Error bars are standard deviations from at least 4 biological replicas. c The effect of Brefeldin A on the transport of RFP-TM-ERD2 compared to ST-YFP. Notice that both fusions have re-distributed to the ER after 3 h of Brefeldin A treatment. Size bars 10 microns. d Sequence of the ERD2 C-terminus, the p24 fusion and the KKSS mutant thereof. e Amy-HDEL retention activity of constructs presented in (d). Fusing the p24 C-terminus renders ERD2 completely inactive, yet mutating the KKXX motif restores the bulk of biological activity. However, KKSS cannot meet the activity of the wild type ERD2 at lower doses. Error bars are standard deviations from at least 4 biological replicas. Source data are provided as a Source data file. f Localisation of p24 and KKSS hybrids incorporated into fluorescent ERD2 fusion proteins. The p24 C-terminus mediates complete ER localisation of the resulting ERD2 fusion whilst the KKSS mutant shows high steady-state levels at the Golgi. Size bars 10 microns.

The K/HDEL receptor does not recycle but instead acts as a Golgi-gatekeeper

March 2023

150 Reads

8 Citations

Nature Communications

[...]

Accurately measuring the ability of the K/HDEL receptor (ERD2) to retain the ER cargo Amy-HDEL has questioned earlier results on which the popular receptor recycling model is based upon. Here we demonstrate that ERD2 Golgi-retention, rather than fast ER export supports its function. Ligand-induced ERD2 redistribution is only observed when the C-terminus is masked or mutated, compromising the signal that prevents Golgi-to-ER transport of the receptor. Forcing COPI mediated retrograde transport destroys receptor function, but introducing ER-to-Golgi export or cis-Golgi retention signals re-activate ERD2 when its endogenous Golgi-retention signal is masked or deleted. We propose that ERD2 remains fixed as a Golgi gatekeeper, capturing K/HDEL proteins when they arrive and releasing them again into a subdomain for retrograde transport back to the ER. An in vivo ligand:receptor ratio far greater than 100 to 1 strongly supports this model, and the underlying mechanism appears to be extremely conserved across kingdoms.

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The K/HDEL receptor does not recycle, but instead acts as a Golgi-gatekeeper

June 2022

58 Reads

[...]

The K/HDEL receptor (ER retention defective 2 or ERD2) does not recycle between compartments when sorting ER chaperones, contrary to the favoured model. A conserved C-terminal di-leucine motif specifically prevents ERD2 Golgi-to-ER transport and is not required for ER export. The Golgi-retention mechanism strips Golgi-membranes of the GTPase ARF1 so that ERD2 avoids accompanying its ligands in retrograde transport. When this motif is deleted or masked, introducing a fast ER-to-Golgi export signal or an alternative cis- Golgi retention signal re-activates ERD2. Meanwhile, forcing retrograde transport renders the receptor non-functional. We have established an in vivo ligand/receptor ratio far greater than 100 to 1, and propose a gatekeeper model to explain how few receptors at the Golgi can prevent the secretion of highly abundant soluble ER proteins. The underlying mechanism is conserved across kingdoms and will yield valuable insight into Golgi-mediated cargo sorting and cisternal compartment maintenance.

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Plant peptidoglycan precursor biosynthesis: Conservation between moss chloroplasts and Gram negative bacteria

April 2022

72 Reads

5 Citations

Plant Physiology

Dowson Amanda

Adrian Lloyd

Andrew C Cuming

[...]

Christopher Gerard Dowson

Accumulating evidence suggests that peptidoglycan, consistent with a bacterial cell wall, is synthesised around the chloroplasts of many photosynthetic eukaryotes, from glaucophyte algae to early-diverging land plants including pteridophyte ferns, but the biosynthetic pathway has not been demonstrated. Here, we employed mass spectrometry and enzymology in a twofold approach to characterize the synthesis of peptidoglycan in chloroplasts of the moss Physcomitrium (Physcomitrella) patens. To drive the accumulation of peptidoglycan pathway intermediates, P. patens was cultured with the antibiotics fosfomycin, D-cycloserine, and carbenicillin, which inhibit key peptidoglycan pathway proteins in bacteria. Mass spectrometry of the TCA-extracted moss metabolome revealed elevated levels of five of the predicted intermediates from UDP-GlcNAc through the UDP-MurNAc-D,L-diaminopimelate (DAP)-pentapeptide. Most Gram negative bacteria, including cyanobacteria, incorporate meso-diaminopimelic acid (D,L-DAP) into the third residue of the stem peptide of peptidoglycan, as opposed to L-lysine, typical of most Gram positive bacteria. To establish the specificity of D,L-DAP incorporation into the P. patens precursors, we analyzed the recombinant protein UDP-N-acetylmuramoyl-L-alanyl-D-glutamate-2,6-diaminopimelate ligase (MurE) from both P. patens and the cyanobacterium Anabaena sp. (Nostoc sp. strain PCC 7120). Both ligases incorporated D,L-DAP in almost complete preference to L-Lys, consistent with the mass spectrophotometric data, with catalytic efficiencies similar to previously documented Gram negative bacterial MurE ligases. We discuss how these data accord with the conservation of active site residues common to DL-DAP-incorporating bacterial MurE ligases and of the probability of a horizontal gene transfer event within the plant peptidoglycan pathway.

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Caulonemal tip cells are likely sites of CLAVATA (CLV)/ENDOSPERM SURROUNDING REGION (ESR)‐related (CLE) peptide production and perception in Physcomitrium patens. (a) Micrographs showing expression patterns of newly generated PpCLE::NGG lines in whole plants, with signal in gametophores and protonemal tissues. Bar, 1 mm. (b) Micrographs of sporelings which comprised mainly chloronemata. PpCLE3::NGG, PpCLE9::NGG and PpCLV1a::NGG lines showed expression. The numbers in each panel indicate the proportion of sporelings displaying a similar expression pattern. Bar, 50 µm. (c) Micrographs of sporelings comprising a mix of chloronemata and caulonemata. All lines showed CLAVATA expression. The signal was absent or weak in chloronemal cells, but stronger and more frequently detected in caulonemal tip cells (black arrowheads). Numbers in each panel indicate the proportion of sporelings displaying a similar expression pattern. Bar, 50 µm. (d) Stitched light micrographs showing promoter::NGG reporter expression in foraging filaments. Although no signal was detected in the majority of PpCLE1::NGG, PpCLE8::NGG and PpCLV1a::NGG filaments, all other lines accumulated signal in caulonemal tip cells. Stain also was detected in a subset of lines in other caulonemal cells (PpCLE4::NGG, PpCLE5::NGG, PpCLE6::NGG, PpCLE9::NGG, PpCLV1b::NGG, PpRPK2::NGG), in new branch initials (PpCLE5::NGG, PpCLE7::NGG, PpCLE9::NGG, PpCLV1b::NGG, PpRPK2::NGG) or in chloronemal branch cells (PpCLE4::NGG, PpCLE9::NGG) (RPK, RECEPTOR‐LIKE KINASE). Both PpCLV1b::NGG and PpRPK2::NGG accumulated stain in caulonemal tip cells and new branch/bud initials but PpRPK2::NGG stained more strongly in caulonemal tip cells, and a subset of samples showed only this signal (4 of 37), whereas a subset of PpCLV1B::NGG samples accumulated signal only in the branch initials (12 of 56). Numbers in each panel indicate the proportion of filaments displaying a similar expression pattern. Tissue was stained for 7.5 h (PpCLE3::NGG, PpCLE4::NGG, PpCLE5::NGG, PpCLE6::NGG, PpCLE8::NGG, PpCLV1b::NGG and PpRPK2::NGG), 15 h (PpCLE2::NGG, PpCLE9::NGG and PpCLV1a::NGG) or 21 h (PpCLE1::NGG and PpCLE7::NGG). Black arrowheads indicate the strongest expression, grey arrows indicate weaker expression. Purple frames indicate lines with strong expression in caulonemal tip cells. Bar, 200 µm.

CLAVATA pathway components regulate plant shape and protonemal identity in Physcomitrium patens. (a) Images of 4‐wk‐old plants grown in continuous light showing overall morphology. Bar, 5 mm. (b) Plant spread in PpcleAmiR4‐7, Pprpk2 and Ppclv1a1brpk2 mutants was greater than wild‐type (WT) plant spread, and triple mutants were larger than Pprpk2 mutants (CLE, CLAVATA (CLV)/ENDOSPERM SURROUNDING REGION (ESR)‐related; RPK, RECEPTOR‐LIKE KINASE). Pprpk2 and Ppclv1a1brpk2 mutants had a higher perimeter ratio than WT plants. Data from one of three experimental replicates are shown (n = 32). In the boxplot, horizontal lines represent median values, boxes represent the interquartile range, whiskers represent largest and smallest values within 1.5× above or below 75th and 25th percentiles, respectively, and black circles represent outliers. Asterisks indicate significant difference from the WT (one‐way ANOVA and Tukey’s honestly significant difference test; P < 0.05). (c) Light micrographs of toluidine blue stained and dissected protonemal filaments, showing differences in apical dominance and cell morphology between genetic backgrounds. Insets show typical unstained subapical and branch cells from each line. Bars: 200 µm (main); 50 µm (inset). (d) Subapical cells (pale blue dots; caulonemal cells in WT) and branch cells (dark blue dots; chloronemal cells in WT) have distinct shapes in Wt plants, PpcleAmiR4‐7, Ppclv1a, Ppclv1b, Ppclv1a1b, Pprpk2 and Ppclv1a1brpk2 mutants, but PpcleAmiR1‐3 mutant cell types are less distinct. Subapical cell and branch cell measurements partially overlap in all lines except Pprpk2. Different letters indicate significant difference in cell length or division plane orientation, bars indicate SD (n ≥ 28; two‐way ANOVA P < 0.05).

Cytokinin treatment disproportionally affects protonemal growth in Physcomitrium patens clavata mutants. (a) Micrographs of 4‐wk‐old plants grown on media containing a solvent control (EtOH) or cytokinin (100 nM 6‐Benzylaminopurine (BAP)). Bar, 5 mm. (b) Whilst Ppclv1a1b plant area was not significantly affected by cytokinin treatment, wild‐type, (WT) PpcleAmiR1‐3, PpcleAmiR4‐7, Pprpk2 and Ppclv1a1brpk2 plants showed decreased area, with the decrease being more conspicuous in Pprpk2 and Ppclv1a1brpk2 mutants (CLV, CLAVATA; (CLE, CLAVATA (CLV)/ENDOSPERM SURROUNDING REGION (ESR)‐related; RPK, RECEPTOR‐LIKE KINASE). The perimeter ratio did not change in response to cytokinin treatment in WT, PpcleAmiR1‐3, PpcleAmiR4‐7 or Ppclv1a1b plants, but strongly decreased in Pprpk2 and Ppclv1a1brpk2 mutants. In the boxplot, horizontal lines represent median values, boxes represent the interquartile range, whiskers represent largest and smallest values within 1.5× above or below 75th and 25th percentiles, respectively, and black circles represent outliers. Asterisks indicate significant difference to EtOH control (multi‐way ANOVA and Tukey's honestly significant difference (HSD) test; P < 0.05; n ≥ 30). (c) Graphs showing a reduction in subapical cell length in response to cytokinin application in WT and Ppclv1a1b plants, and a strong reduction in subapical cell length and division plane angles in PpcleAmiR4‐7, Pprpk2 and Ppclv1a1brpk2 mutants grown on 100 nM BAP. Letters indicate significant differences between groups, error bars indicate SD (n ≥ 90; multi‐way ANOVA and Tukey's HSD test; P < 0.05). (d) Micrographs of caulonemal filaments dissected from WT or Pprpk2 mutants grown on plates containing a solvent control (EtOH) or 100 nM BAP. Pprpk2 mutants treated with BAP produced a near constitutive overbudding phenotype. Bar, 200 µm.

Physcomitrium patens rpk2 and clv1a1brpk2 mutant phenotypes depend on auxin synthesis, and mutants have synthesis defects (CLV, CLAVATA; RPK, RECEPTOR‐LIKE KINASE). (a) Micrographs of 4‐wk‐old plants grown on media containing a solvent control (DMSO) or a pharmacological inhibitor of auxin synthesis (10 µM l‐Kynurenine (L‐Kyn)). Bar, 5 mm. (b) Plant spread in all lines diminishes in response to L‐Kyn, but perimeter ratio values decreased only in Pprpk2 and Ppclv1a1brpk2 mutants (two‐way ANOVA and Tukey's honestly significant difference (HSD) test; n ≥ 30; *, P < 0.05 between treatment and control). (c) L‐Kyn treatment suppresses subapical cell length in Ppclv1a1b and Pprpk2 mutants, and suppresses oblique cell divisions in PpAmiR4‐7, Ppclv1a1b and Pprpk2 mutants. Letters indicate significant differences between groups, error bars indicate SD (multi‐way ANOVA and Tukey's HSD test, n ≥ 90, P < 0.05). (d) Quantification of auxin metabolites from wild‐type, Ppclv1a1b, Pprpk2 and Ppclv1a1brpk2 protonemal cultures showed that auxin levels were depleted in Ppclv1a1b and Pprpk2 mutants in 4 of 5 biological replicates. IAA, Indole‐3‐acetic acid; ANT, Anthranilate; TRP, Tryptophan; IPyA, Indole‐3‐pyruvic acid; OxIAA, 2‐oxindole‐3‐acetic acid; IAGlu, IAA‐glucose; Student’s T‐test; n = 5; *, P < 0.05.

Physcomitrium patens rpk2 and clv1a1brpk2 mutants manifest an abnormal auxin response (CLV, CLAVATA; RPK, RECEPTOR‐LIKE KINASE). (a) Micrographs of 4‐wk‐old plants grown on media containing a solvent control (EtOH) or auxin (1 µM 1‐naphthaleneacetic acid (NAA)). Bar, 1 mm. (b) Quantitative analyses showed that Pprpk2 and Ppclv1a1brpk2 mutant plants show an auxin‐dependent decrease in plant spread and perimeter ratio, whilst all other backgrounds increased in area in response to auxin treatment and showed no change in perimeter ratio (two‐way ANOVA and Tukey's honestly significant difference (HSD) test. n ≥ 30; *, P < 0.05 between treatment and control). (c) Wild‐type (WT), PpcleAmiR4‐7 and Ppclv1a1brpk2 subapical cell division angles diminished following 1 µM NAA treatment, and Ppclv1a1b and Pprpk2 subapical cell lengths decreased, but branch cells and PpcleAmiR1‐3 mutant cells showed no change in length or cell division plane angle. Letters indicate significant differences between groups, error bars indicate SD (multi‐way ANOVA and Tukey's HSD test; n ≥ 90 for all other genotypes; P < 0.05). (d) Micrographs of 4‐wk‐old plants grown on media containing a solvent control (0.07% EtOH + 0.01% DMSO), 10 µM l‐Kynurenine (L‐Kyn), 1 µM NAA or a combination of 10 µM L‐Kyn and 1 µM NAA. Bar, 5 mm. (e) Quantitative analyses showed that whilst WT plant spread showed little response to exogenously applied auxin (1 µM NAA), auxin synthesis inhibitors (10 µM L‐Kyn) or a combination of 1 µM NAA and 10 µM L‐Kyn, Pprpk2 mutant spread strongly decreased in all treatments and the combined treatment led to the strongest decrease. The response of Ppclv1a1b and Ppclv1a1brpk2 mutants varied between experimental replicates, as did perimeter ratios. Asterisks above data indicate significant difference from untreated controls, asterisks above bars indicate significant difference between treatments of interest (n ≥ 30; one‐way ANOVA and Tukey’s HSD test on each genotype; P < 0.05). In boxplots, horizontal lines represent median values, boxes represent the interquartile range, whiskers represent largest and smallest values within 1.5× above or below 75th and 25th percentiles, respectively, and black circles represent outliers.

CLAVATA modulates auxin homeostasis and transport to regulate stem cell identity and plant shape in a moss

February 2022

319 Reads

23 Citations

New Phytologist

[...]

The CLAVATA pathway is a key regulator of stem cell function in the multicellular shoot tips of Arabidopsis, where it acts via the WUSCHEL transcription factor to modulate hormone homeostasis. Broad‐scale evolutionary comparisons have shown that CLAVATA is a conserved regulator of land plant stem cell function, but CLAVATA acts independently of WUSCHEL‐like (WOX) proteins in bryophytes. The relationship between CLAVATA, hormone homeostasis and the evolution of land plant stem cell functions is unknown. Here we show that in the moss, Physcomitrella (Physcomitrium patens), CLAVATA affects stem cell activity by modulating hormone homeostasis. CLAVATA pathway genes are expressed in the tip cells of filamentous tissues, regulating cell identity, filament branching, plant spread and auxin synthesis. The receptor‐like kinase PpRPK2 plays the major role, and Pprpk2 mutants have abnormal responses to cytokinin, auxin and auxin transport inhibition, and show reduced expression of PIN auxin transporters. We propose a model whereby PpRPK2 modulates auxin gradients in filaments to determine stem cell identity and overall plant form. Our data indicate that CLAVATA‐mediated auxin homeostasis is a fundamental property of plant stem cell function, probably exhibited by the last shared common ancestor of land plants.

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Figure 1 Schematic of the fundamental cytoplasmic and periplasmic enzyme steps in peptidoglycan (murein) biosynthesis. Enzymes: MurA-J, murein synthases A-J; Ddl, D-Ala--D-Ala ligase; MraY, phospho-N-acetylmuramoyl-pentapeptide-transferase and PBP, transglycosylase and transpeptidase activities of penicillin-binding proteins. Superscript numbers indicate targets for the following antibiotics: 1, phosphomycin, 2, D-cycloserine, 3, pacidamycin, 4, tunicamycin, 5, murgocil, 6, bacitracin, 7, penicillins and 8, vancomycin. The cytoplasmic Mur proteins MurA and MurB catalyze the formation of UDP-N-acetylmuramic acid (UDP-MurNAc), Mur ligases (MurC, D, E and F) sequentially append amino acids to form UDP-MurNAc-pentapeptide. The transmembrane protein MraY attaches MurNAc-pentapeptide to C55-P to yield C55-PP-MurNAc-pentapeptide (lipid I) and MurG GlcNAc transferase creates C55-PP-MurNAc-(pentapeptide)-GlcNAc (lipid II). Finally, the disaccharide pentapeptide monomer is flipped into the periplasm, polymerized by the transglycosylase activities of penicillin-binding-proteins (PBPs), or functionally related shape, elongation, division and sporulation (SEDS) proteins, and the peptides are 4-3 cross-linked to pre-existing peptidoglycan by the transpeptidase activities of PBPs or 3-3 cross-linked by L,D-transpeptidases. C55-PP is then subject to pyrophosphatase activity and C55-P recycled.

Figure 2 Confocal microscope images showing the effects of antibiotics on P. patens chloronemata. Chlorophyll autofl uorescence (red) reveals macrochloroplasts consequent on growth on phosphomycin, D-cycloserine, vancomycin, bacitracin, ampicillin and A22. A. untreated, B. phosphomycin (500 µg.ml -1 ), C. vancomycin (25 µg.ml -1 ), D. D-cycloserine (20 µg.ml -1, two images), E. bacitracin (100 µg.ml -1 ), F. murgocil (10 µg.ml -1 ), G. ampicillin (100 µg.ml -1 ), H. A22 (2.5 µg.ml -1 ) and I. A22 (10 µg.ml -1 ). Sequential fl uorescence and transmitted light images, from a Leica SP5 with 63 x oil immersion lens, were processed using LAS AF lite to optimise intensity and combined as hyperstacks using Fiji on Image J. Scale bars 10µm.

Plant peptidoglycan precursor biosynthesis: Conservation between moss chloroplasts and Gram negative bacteria

January 2022

90 Reads

Dowson Amanda

Adrian Lloyd

Andrew C. Cuming

[...]

Christopher Gerard Dowson

An accumulation of evidence suggests that peptidoglycan, consistent with a bacterial cell wall, is synthesised around the chloroplasts of many photosynthetic eukaryotes, from glaucophyte algae to land plants at least as evolved as pteridophyte ferns, but the biosynthetic pathway has not been demonstrated. We employed mass spectrometry and enzymology in a twofold approach to characterize the synthesis of peptidoglycan in chloroplasts of the moss Physcomitrium (Physcomitrella) patens . To drive the accumulation of peptidoglycan pathway intermediates, P.patens was cultured with the antibiotics phosphomycin, D-cycloserine and carbenicillin, which inhibit key peptidoglycan pathway proteins in bacteria. Mass spectrometry of the TCA-extracted moss metabolome revealed elevated levels of five of the predicted intermediates from UDP-Glc N Ac through to the UDP-Mur N Ac-D,L-diaminopimelate (DAP)-pentapeptide. Most Gram negative bacteria, including cyanobacteria, incorporate meso -diaminopimelate (D,L-DAP) into the third residue of the stem peptide of peptidoglycan, as opposed to L-lysine, typical of most Gram positive bacteria. To establish the specificity of D,L-DAP incorporation into the P.patens precursors, we analysed the recombinant protein, UDP-Mur N Ac-tripeptide ligase ( MurE ), from both P.patens and the cyanobacterium Anabaena sp. strain PCC 7120. Both ligases incorporated D,L-DAP in almost complete preference to L-Lys, consistent with the mass spectrophotometric data, with catalytic efficiencies similar to previously documented Gram negative bacterial MurE ligases. We discuss how these data accord with the conservation of active site residues common to DL-DAP-incorporating bacterial MurE ligases and of the probability of a horizontal gene transfer event within the plant peptidoglycan pathway.

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A group of mutants showing reversed gravitropic responses in Physcomitrella patens
a Schematic diagram of the screening protocol for identifying gravitropic mutants in P. patens. Protoplasts of P. patens were isolated and treated with UV. Next, protonemata were regenerated in light and then grown on vertically oriented culture plates in the dark to record phenotypes. b Gravitropic phenotype of P. patens protonemata. Wild-type Gransden (Gd) strains of P. patens and UV-derived mutants were grown for around 3 weeks vertically in the dark. Scale bars, 3 mm. c Quantification of bending angles of protonemata growing in the dark for 3 weeks and then gravistimulated for 2 weeks. The schematic diagram shows how the angles were measured, and the bending angles are shown in circular histograms. Source data are provided as a Source Data file. In (a–c), arrows labeled with “g” indicate the directions of gravity vectors.

Genetic mapping of the GTRC locus
a Mapping the gtrC-5 mutant. Left, segregants from a gtrC-5/Vx hybrid spore capsule. Right: The genetic interval containing the gtrC-5 locus was identified to a 840 kb region (GoldenGate: between 61.605 and 64.69 cM,) in the first round of mapping, and reduced to the interval of 283 kb distance in the second round of manual genotyping. A candidate gene with a nonsense mutation was identified in this reduced interval. Source data are provided as a Source Data file. b Mapping the gtrC-16 mutants. Left, segregants from gtrC-16/Vx hybrids. Right, Gd/Vx SNP ratios in chromosome 2 derived from 48 gtrC-16/Vx hybrid progeny whose protonemata grew downwards. They were mixed and DNA was extracted for whole-genome sequence. Red lines are plots of mean values of Gd/Vx SNP ratios in a 0.5 Mb region with the sliding window set to 0.25 Mb. A candidate gene with nonsense mutation was identified. Source data are provided as a Source Data file. In a, b, the arrows with “g” show the direction of the gravity vector. The segregants were divided into three groups based on the growth direction of dark-grown protonemata: Up, Down, or Undetermined (Undet.). Scale bars, 10 mm. The numbers (No.) of each phenotype were shown in the tables below each image. c Gene structure and mutation sites of the GTRC locus. Purple box, untranslated region; orange box, coding exons. X indicates stop codon. d Protein structure and the mutation sites of GTRC. X indicates stop codon. Brown box, CH domain; green box, coiled coil region predicted by COILS program; red box, motor domain; blue box, C terminus of KCH proteins.

Genetic confirmation of the GTRC locus
a–d Targeted mutagenesis of GTRC in wild type. a The native sequence encoding Q⁵⁹⁸ was mutated to reproduce the stop codon (X) mutation identified in the gtrC-5 mutant. WT P. patens was transformed with a linear 1537-bp fragment of DNA comprising the four exons surrounding the Q⁵⁹⁸ codon in exon 14 using a transient selection strategy. The WT and mutant sequences are shown above and below. b Gravitropism in WT, gtrC-5 and gene-targeted WT P. patens. Caulonemal growth in darkness for 3 weeks on vertical BCD agar medium. The untransformed WT and gtrC-5 mutant lines are shown in the upper panel together with a transgenic line A85 that did not alter the Q⁵⁹⁸ residue. The lower panel shows three transgenic lines (B59, D25, and G85) with a Q598X mutation. c Sequence analysis of the mutant locus in the gene-targeted lines, compared with WT and the original gtrC-5 mutant. Lines B59, D25, and G85 contain the targeted mutation (CAGAGT > TAATCA), resulting in Q598X (CAG > TAA). Line A85 contains the targeted mutation of Ser⁵⁹⁹ (AGT > TCA) but unmutated Q⁵⁹⁸ (CAG > CAA). The nucleotides coding these two amino acids were labeled in the black box. d Southern blot analysis of the gene-targeted mutant lines. The genomic DNA was digested by Eco RI and then detected by labeled ssDNA. Only one band of the expected size (ca. 4.64 kb) was detected in each line, confirming that no off-target integration occurred. The experiment was carried out once, and the result is unambiguous. See methods for details, and source data are provided as a Source Data file. e Gravitropic phenotypes of knockout lines of GTRC. GTRC-HRKO was generated via homologous recombination by substituting GTRC genomic region with the NptII cassette. GTRC-Cas9KO was generated by editing the GTRC locus via CRISPR-Cas9 mutagenesis. f Gravitropic phenotypes of complementation lines of GTRC. HARes/gtrC-16 was generated by substituting the mutated nucleotide of gtrC-16 with wild-type genomic nucleotide. ProGTRC::GTRC/gtrC-16 was generated by substituting the mutated genomic DNA of GTRC in gtrC-16 with wild-type GTRC coding sequence. The details of the constructs and genotypes for the P. patens lines in e–f are shown in Supplementary Fig. 1. g Gravitropic phenotypes of knockout lines of KCH family genes. All lines except kchb (gtrC-16) were generated by editing the corresponding KCH loci via CRISPR/Cas9 mutagenesis. Genotypes for these lines are shown in Supplementary Fig. 3. In (b, e, f, g), arrows labeled with “g” indicate the directions of gravity vectors, and the scale bars are 3 mm.

The localization and movement of GTRC proteins
a Localization of GTRC on the microtubules (MT) in the tip cells of P. patens protonemata. RFP-TUB was co-expressed with GFP-GTRC in the protonemata, and fluorescence signals were collected by confocal microscopy. The scatterplots show the Pearson’s correlation coefficient (r) between these two fluorescent signals. Scale bar, 5 μm. b Localization of GTRC was dependent on tubulin but not actin. Images were taken after 10 min of oryzalin or latrunculin B treatments, and oryzalin but not latrunculin B treatment disrupted the regular signal patterns of GTRC. Scale bar, 5 μm. More than 10 cells were studied for each treatment, and the results were similar. Oryzalin and latrunculin B disrupt the microtubules and actin filaments, respectively, as shown in Supplementary Fig. 7. c GTRC moves along MT in the minus-end direction. Left, processive movement of GTRC recorded by time-lapse photography using spinning disk confocal microscopy at 250 ms intervals. Red arrows mark the GFP-GTRC proteins moving along MT. Right, kymographs for the movement of GFP-GTRC. d Velocity of moving GFP-GTRC signals. The mean value is shown with standard deviation and examined sample size. Source data are provided as a Source Data file.

Functional domain analysis of GTRC protein
a Schematic diagrams of full length and truncated constructs of GTRC. GFP was fused to the N-terminus of each fragment. b Complementation and fluorescence analyses of truncated GTRC. Upper, various constructs of GTRC were used to replace the genomic GTRC in gtrC-16 via homologous recombination, and then the protonemata were grown on vertical plates. Scale bars, 3 mm. Lower, subcellular localization of GFP-fused full length or truncated GTRC proteins. Scale bars, 5 μm. White dashed lines depict the contours of the tip cells. For each genotype, the fluorescence of more than 10 tip cells was collected, and the results were similar. c Schematic diagrams of full length and chimeric constructs of GTRC and KCHa. 3×FLAG (F) was fused to the N-terminus of each fragment. d Functional analyses of chimeric proteins between GTRC and KCHa. Various constructs were used to replace the genomic GTRC in gtrC-16 via homologous recombination, and then the protonemata were grown on vertical plates. Scale bars, 2 mm. The details of the constructs and genotypes for the P. patens lines are shown in Supplementary Fig. 6.

A minus-end directed kinesin motor directs gravitropism in Physcomitrella patens

July 2021

205 Reads

8 Citations

Nature Communications

[...]

Gravity is a critical environmental factor regulating directional growth and morphogenesis in plants, and gravitropism is the process by which plants perceive and respond to the gravity vector. The cytoskeleton is proposed to play important roles in gravitropism, but the underlying mechanisms are obscure. Here we use genetic screening in Physcomitrella patens, to identify a locus GTRC, that when mutated, reverses the direction of protonemal gravitropism. GTRC encodes a processive minus-end-directed KCHb kinesin, and its N-terminal, C-terminal and motor domains are all essential for transducing the gravity signal. Chimeric analysis between GTRC/KCHb and KCHa reveal a unique role for the N-terminus of GTRC in gravitropism. Further study shows that gravity-triggered normal asymmetric distribution of actin filaments in the tip of protonema is dependent on GTRC. Thus, our work identifies a microtubule-based cellular motor that determines the direction of plant gravitropism via mediating the asymmetric distribution of actin filaments.

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PpRPK2 modulates auxin homeostasis and transport to specify stem cell identity and plant shape in the moss Physcomitrella

June 2021

227 Reads

2 Citations

[...]

Plant shape is determined by the activity of stem cells in the growing tips, and evolutionary changes in shape are linked to changes in stem cell function. The CLAVATA pathway is a key regulator of stem cell function in the multicellular shoot tips of Arabidopsis, acting via the WUSCHEL transcription factor to modulate hormone homeostasis. Broad scale evolutionary comparisons have shown that CLAVATA is a conserved regulator of land plant stem cell function, but CLAVATA acts independently of WUSCHEL-like (WOX) proteins in bryophytes, raising questions about the evolution of stem cell function and the role of the CLAVATA pathway. Here we show that the moss (Physcomitrella) CLAVATA pathway affects stem cell activity and overall plant shape by modulating hormone homeostasis. CLAVATA pathway components are expressed in the tip cells of filamentous tissues, regulating cell identity, filament branching patterns and plant spread. The PpRPK2 receptor-like kinase plays the major role and is expressed more strongly than other receptor-encoding genes. Pprpk2 mutants have abnormal responses to cytokinin, and auxin transport inhibition and show reduced PIN auxin transporter expression. We propose a model whereby PpRPK2 modulates PIN activity to determine stem cell identity and overall plant form in Physcomitrella. Our data indicate that CLAVATA-mediated auxin homeostasis is a fundamental property of plant stem cell function likely exhibited by the last shared common ancestor of land plants.

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CLAVATA Was a Genetic Novelty for the Morphological Innovation of 3D Growth in Land Plants

July 2020

129 Reads

11 Citations

Current Biology

[...]

Assembly statistics of the three hornwort genomes

Genome organizations in the Anthoceros genomes
a, Circos plot of A. agrestis Bonn showing the densities of repeats, genes and single nucleotide polymorphisms (SNPs) with the A. agrestis Oxford genomes. b–e, Anthoceros genomes lack whole genome duplication. No self-synteny can be found in the three Anthoceros genomes (A. agrestis Bonn (b), A. agrestis Oxford (c) and A. punctatus (d)) nor in M. polymorpha (e). f, P. patens, on the other hand, shows a clear 1:1 and some 1:2 syntenic relationship, suggesting paleopolyploidy. In b–f, the bar graphs show the proportion of the genome at different self syntenic levels, with the dot-plots on the right.

Land plant phylogeny inferred from 742 mostly single-copy genes
The monophyly of bryophytes is supported. The topology shown here is based on the maximum likelihood tree from the concatenated amino acid dataset. Thickened branches received maximal (100) bootstrap and SH-aLRT supports from both the concatenated nucleotide and amino acid datasets, as well as maximal posterior probabilities (1.0) from the Astral species-tree analysis (based on both nucleotide and amino acid gene trees). The inset shows the quartet frequencies among the 742 gene trees supporting monophyletic bryophytes (T1) versus two alternative placements of hornworts (T2 and T3). The dotted line shows the one-third threshold.

Anthoceros genomes illuminate the origin of land plants and the unique biology of hornworts

March 2020

2,641 Reads

210 Citations

Nature Plants

[...]

Hornworts comprise a bryophyte lineage that diverged from other extant land plants >400 million years ago and bears unique biological features, including a distinct sporophyte architecture, cyanobacterial symbiosis and a pyrenoid-based carbon-concentrating mechanism (CCM). Here, we provide three high-quality genomes of Anthoceros hornworts. Phylogenomic analyses place hornworts as a sister clade to liverworts plus mosses with high support. The Anthoceros genomes lack repeat-dense centromeres as well as whole-genome duplication, and contain a limited transcription factor repertoire. Several genes involved in angiosperm meristem and stomatal function are conserved in Anthoceros and upregulated during sporophyte development, suggesting possible homologies at the genetic level. We identified candidate genes involved in cyanobacterial symbiosis and found that LCIB, a Chlamydomonas CCM gene, is present in hornworts but absent in other plant lineages, implying a possible conserved role in CCM function. We anticipate that these hornwort genomes will serve as essential references for future hornwort research and comparative studies across land plants.

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A ligand-independent origin of abscisic acid perception

October 2019

655 Reads

84 Citations

Proceedings of the National Academy of Sciences

Yufei Sun

Ben Harpazi

Akila Wijerathna Yapa

[...]

Assaf Mosquna

Significance Synthesis of abscisic acid (ABA) and proteins required for its downstream signaling are ancient and found in aquatic algae, but these primitive plants do not respond to ABA and lack ABA receptors. The present work traces the evolution of ABA as an allosteric regulatory switch. We found that ancient PYRABACTIN RESISTANCE 1’s homolog proteins have constitutive ABA-independent phosphatase-binding activity that, in land plants, has gradually evolved into an ABA-activated receptor. We propose that ABA-mediated fine-tuning of the preexisting signaling cascade was a key evolutionary novelty that aided these plants in their conquest of land.

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... As an alternative strategy for visualizing KDELR trafficking, Silva-Alvim et al. 4,5 have generated a novel fluorescent ERD2b construct: an N-terminal fluorophore followed by an extra transmembrane domain followed by ERD2b itself. Interestingly, (X)FP-TM-ERD2 can bind HDEL ligands but is exclusively Golgi-localized and did not show any redistribution to the ER even in the presence of HDEL ligands. ...
Reference:
Does the KDEL receptor cycle between the Golgi and the ER?

The K/HDEL receptor does not recycle but instead acts as a Golgi-gatekeeper

Citing Article
Full-text available
March 2023

Nature Communications

[...]

... This does appear to be the case for most chlorophyte and rhodophyte algae, which do not retain the majority of the 11 or so genes essential for peptidoglycan biosynthesis ( Fig. 1; van Baren et al., 2016). However, there is evidence that both the glaucophyte algae and at least some earlydiverging land plants, including P. patens, can synthesise peptidoglycan (Pfanzagl et al., 1996;Dowson et al., 2022) and construct a wall bounding their cyanelles or chloroplasts, respectively (Higuchi et al., 2016;Hirano et al., 2016). Clearly, in all plants where peptidoglycan still encompasses the chloroplast, the mechanism must exist to coordinate its synthesis with the duallayered chloroplast division apparatus. ...
Reference:
A snapshot of the tree of chloroplast evolution

Plant peptidoglycan precursor biosynthesis: Conservation between moss chloroplasts and Gram negative bacteria

Citing Article
Full-text available
April 2022

Plant Physiology

Dowson Amanda

Adrian Lloyd

Andrew C Cuming

[...]

Christopher Gerard Dowson

... For instance, evolutionarily, the function of WUS appears later than that of CLVs. Thus, CLV-cytokinin cross-talk and its mediated auxin homeostasis have recently been proposed to be a more ancient property for SAM homeostasis [110][111][112]. Additionally, the homologs of SPL/NZZ have only been identified in angiosperms. ...
Reference:
Male Germ Cell Specification in Plants

CLAVATA modulates auxin homeostasis and transport to regulate stem cell identity and plant shape in a moss

Citing Article
Full-text available
February 2022

New Phytologist

[...]

... Animal kinesin-14 proteins contain C-terminal motors and exhibit minus-end movement, while most other kinesins are plus-end directed with N-terminal motors (She and Yang 2017). Indeed, some plant kinesin-14 are minusend directed Tseng et al. 2018;Li et al. 2021), but most plant kinesin-14 proteins do not contain C-terminal motors (Reddy and Day 2001;Lee and Liu 2004;Zhu and Dixit 2012). Furthermore, cytoplasmic dynein was lost in the ancestor to green algae, while axonemal dyneins exist in many land plants (Wickstead and Gull 2007;Hodges et al. 2012;Kollmar 2016;Lucas and Geisler 2022). ...
Reference:
Plant Kinesin Repertoires Expand with New Domain Architecture and Contract with the Loss of Flagella

A minus-end directed kinesin motor directs gravitropism in Physcomitrella patens

Citing Article
Full-text available
July 2021

Nature Communications

[...]

... Specification of the shoot initial cell requires both cytokinin and auxin (Ashton et al., 1978;Cove et al., 2006;Bennett et al., 2014). Factors including DEFECTIVE KERNEL 1 (DEK1), NO GAMETOPHORES 1 and 2 (NOG1 and 2) RECEPTOR-LIKE PROTEIN KINASE 2 (RPK2), and CLAVATA (CLV) function through APETALA2-type (AP2type) transcription factors to control the frequency of shoot initial cells (Aoyama et al., 2012;Perroud et al., 2014;Moody et al., 2018Moody et al., , 2021Whitewoods et al., 2018;Demko et al., 2021;Nemec Venza et al., 2021). In P. patens, a shoot initial cell undergoes several rounds of stereotypic, oblique cell divisions that lead to the formation of a tetrahedral shoot apical cell, marking the transition from a so-called 2D to 3D growth mode (Figure 2A; Harrison et al., 2009). ...
Reference:
Leaf Morphogenesis: Insights From the Moss Physcomitrium patens

PpRPK2 modulates auxin homeostasis and transport to specify stem cell identity and plant shape in the moss Physcomitrella

Citing Preprint
File available
June 2021

[...]

... Once a filamentous plant is established, a proportion of caulonemal cells divide asymmetrically to produce three-dimensional (3D) upright leafy shoots, known as gametophores, which bear the reproductive organs (Harrison et al., 2009;Rensing et al., 2020;Thelander et al., 2018). The genetic pathways regulating the chloronemata-to-caulonemata transition and the 2D-to-3D growth transition are well characterised, involving multiple hormone pathways, TFs and their downstream targets (Aoyama et al., 2012;Goss et al., 2012;Jaeger & Moody, 2021;Moody et al., 2018;Moody et al., 2021;Nemec-Venza et al., 2022;Perroud et al., 2014;Pires et al., 2013;Tam et al., 2015;Whitewoods et al., 2018;Whitewoods et al., 2020). ...
Reference:
The TOPLESS corepressor regulates developmental switches in the bryophyte Physcomitrium patens that were critical for plant terrestrialisation

CLAVATA Was a Genetic Novelty for the Morphological Innovation of 3D Growth in Land Plants

Citing Article
Full-text available
July 2020

Current Biology

[...]

... Coupled with its ease of propagation in laboratory conditions, these advantages make M. polymorpha an ideal system for functional gene analysis [15][16][17]. Other more recently developed model bryophyte systems suitable for genomic and evolutionary studies include Ceratodon purpureus and Sphagnum species, as well as model hornworts Anthoceros agrestis and A. punctatus [18][19][20]. ...
Reference:
Telomere Length Variation in Model Bryophytes

Anthoceros genomes illuminate the origin of land plants and the unique biology of hornworts

Citing Article
Full-text available
March 2020

Nature Plants

[...]

... Abscisic acid (ABA) is one of the most essential phytohormones in land plants, and it responds to environmental signals, such as drought and low temperature. The biosynthetic pathway of ABA was elucidated in land plants as a derivative of carotenoids [34]. Although the content of ABA in algae is lower than in land plants, it has been detected in N. yezoensis [35]. ...
Reference:
Functional Characterization of the First Bona Fide Phytoene Synthase in Red Algae from Pyropia yezoensis

Evolution of ABA signaling pathways

Citing Chapter
October 2019

Andrew C. Cuming

... No data are available regarding CK treatments in charophytes. Comparative genomics revealed that the genes coding for auxin and ABA receptors are functionally conserved across land plants but are absent in charophytes 71,72,77,78 , whereas the CK receptor homologs present in charophytes are related to a clade that does not act in CK perception in land plants 12 . Additionally, gene homologs of CK signaling in the charophyte Spirogyra pratensis are not transcriptionally responsive to applied CK 79 . ...
Reference:
Phytohormone profiling in an evolutionary framework

A ligand-independent origin of abscisic acid perception

Citing Article
Full-text available
October 2019

Proceedings of the National Academy of Sciences

Yufei Sun

Ben Harpazi

Akila Wijerathna Yapa

[...]

Assaf Mosquna

... 39 We have selected P. patens SOG1a (previously known as SOL1) for our study, as it is more similar to the SOG1 protein present in higher plants. 18,39 Phylogenetic analyses by Mega XI software using the primary amino acid sequence of 103 SOG1 orthologues retrieved from NCBI and UniProt databases have revealed that SOG1 proteins from various plant species are distributed in three groups (Fig. 1A). Among the three groups, Cluster 1 contains the ancient angiosperm Amborella trichopoda and Cluster 2 contains the lower group of plants including Selaginella moellendorffii and Physcomitrella patens along with other flowering plants. ...
Reference:
Unveiling the structure and interactions of SOG1, a NAC domain transcription factor: An in-silico perspective

Roles of RAD51 and RTEL1 in telomere and rDNA stability in Physcomitrella patens

Citing Article
Full-text available
March 2019

The Plant Journal

Ivana Goffová Petrová

Radka Vágnerová

Vratislav Peška

[...]

Jiří Fajkus

Andrew C. Cuming's research while affiliated with University of Leeds and other places

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