Translational Regulation in Arabidopsis thaliana: Genetic and Functional Characterization of Eukaryotic Initiation Factor 3

Roy, Bijoyita

01 August 2010

Molecular functions of eukaryotic initiation factor 3 (eIF3) in translation are manifold, encompassing events from initiation complex assembly to translation termination. The contribution of the individual subunits of eIF3 to its multiple activities is quite unclear. It has been hypothesized that several of its 13 subunits contribute to mRNA specific regulation. Prior research had established that the h subunit of eIF3 in Arabidopsis was required for translation of specific mRNAs as well as for organ formation and meristem development. This study aims towards understanding the functions of individual subunits of eIF3 in the context of plant development and to further define the role of eIF3h at the molecular level. This dissertation describes an effort to identify mutations affecting each of the 13 eIF3 subunits. Using a panel of pollen-specific fluorescent marker genes, eIF3 subunits e, h and i1 were demonstrated to be essential for normal male gametophyte development. Furthermore, subunits b and c proved to be essential for embryo development. In contrast, a mutation in eIF3k revealed no phenotypic abnormalities. This work represents a systematic effort to attribute functions to many of the eIF3 subunits in growth and development in a multicellular eukaryote. The h subunit of eIF3 is necessary for the efficient translation of specific mRNAs in Arabidopsis. In particular, eIF3h fosters the translation of those mRNAs that harbor multiple upstream open reading frames (uORFs) in their 5’ leader. The specific molecular activity of eIF3h was investigated by structure-function analysis of the 5' leader of the Arabidopsis AtbZip11 mRNA, which harbors a set of four uORFs that is evolutionarily conserved. By pairing extensive mutagenesis of the AtbZip11 5' leader with gene expression analysis in Arabidopsis seedlings, it was revealed that eIF3h helps the ribosome to retain its reinitiation competence during uORF translation. These data establish a function for the h subunit of eIF3 in a special case of translation initiation, reinitiation. Finally, the molecular events during translation reinitiation were investigated further for a functional cooperation between eIF3h and the large subunit of the ribosome, given that the large ribosomal subunit had been implicated in reinitiation in other biological contexts. Reinitiation profiling using the AtbZip11 leader demonstrated that a protein of the large ribosomal subunit, RPL24B, bolsters reinitiation similar to eIF3h. Taken together, there exists a functional cooperation between the large ribosomal subunit and eIF3 that helps ribosomes to reinitiate after translation of uORFs.

Arabidopsis

eIF3

Protein synthesis

Reinitiation

Development

Molecular genetics

The molecular battle between virulence weapons of Pseudomonas syringae and integrated defense responses of Arabidopsis thaliana

Kim, Min Gab,

January 2006

Thesis (Ph. D.)--Ohio State University, 2006. / Title from first page of PDF file. Includes bibliographical references (p. 103-124).

Functional characterisation of NIC2, a member of the MATE family from Arabidopsis thaliana (L.) Heynh.

Dolniak, Blazej

January 2005

The multidrug and toxic compounds extrusion (MATE) family includes hundreds of functionally uncharacterised proteins from bacteria and all eukaryotic kingdoms except the animal kingdom, that function as drug/toxin::Na⁺ or H⁺ antiporters. In <i>Arabidopsis thaliana</i> the MATE family comprises 56 members, one of which is NIC2 (Novel Ion Carrier 2). Using heterologous expression systems including <i>Escherichia coli</i> and <i>Saccharomyces cerevisiae</i>, and the homologous expression system of <i>Arabidopsis thaliana</i>, the functional characterisation of NIC2 was performed. It has been demonstrated that NIC2 confers resistance of <i>E. coli</i> towards the chemically diverse compounds such as tetraethylammonium chloride (TEACl), tetramethylammonium chloride (TMACl) and a toxic analogue of indole-3-acetic acid, 5-fluoro-indole-acetic acid (F-IAA). Therefore, NIC2 may be able to transport a broad range of drug and toxic compounds. In wild-type yeast the expression of NIC2 increased the tolerance towards lithium and sodium, but not towards potassium and calcium. In <i>A. thaliana</i>, the overexpression of NIC2 led to strong phenotypic changes. Under normal growth condtions overexpression caused an extremely bushy phenotype with no apical dominance but an enhanced number of lateral flowering shoots. The amount of rossette leaves and flowers with accompanying siliques were also much higher than in wild-type plants and the senescence occurred earlier in the transgenic plants. In contrast, RNA interference (RNAi) used to silence NIC2 expression, induced early flower stalk development and flowering compared with wild-type plants. In additon, the main flower stalks were not able to grow vertically, but instead had a strong tendency to bend towards the ground. While NIC2 RNAi seedlings produced many lateral roots outgrowing from the primary root and the root-shoot junction, NIC2 overexpression seedlings displayed longer primary roots that were characterised by a 2 to 4 h delay in the gravitropic response. In addition, these lines exhibited an enhanced resistance to exogenously applied auxins, i.e. indole-3-acetic acid (IAA) and indole-3-butyric acid (IBA) when compared with the wild-type roots. Based on these results, it is suggested that the NIC2 overexpression and NIC2 RNAi phenotypes were due to decreased or increased levels of auxin, respectively. The Pro_NIC2:GUS fusion gene revealed that NIC2 is expressed in the stele of the elongation zone, in the lateral root cap, in new lateral root primordia, and in pericycle cells of the root system. In the vascular tissue of rosette leaves and inflorescence stems, the expression was observed in the xylem parenchyma cells, while in siliques it was also in vascular tissue, but as well in the dehiscence and abscission zones. The organ- and tissue-specific expression sites of NIC2 correlate with the sites of auxin action in mature Arabidopsis plants. Further experiments using Pro_NIC2:GUS indicated that NIC2 is an auxin-inducible gene. Additionally, during the gravitropic response when an endogenous auxin gradient across the root tip forms, the GUS activity pattern of the Pro_NIC2:GUS fusion gene markedly changed at the upper side of the root tip, while at the lower side stayed unchanged. Finally, at the subcellular level NIC2-GFP fusion protein localised in the peroxisomes of <i>Nicotana tabacum</i> BY2 protoplasts. Considering the experimental results, it is proposed that the hypothetical function of NIC2 is the efflux transport which takes part in the auxin homeostasis in plant tissues probably by removing auxin conjugates from the cytoplasm into peroxisomes. / &quot;Multidrug and Toxic Compounds Extrusion&quot; (MATE) &ndash; Proteine sind Membranproteine, die eine Vielzahl komplexer und giftiger Substanzen transportieren können. Sie sind weit verbreitet und kommen in Bakterien und Höheren Organismen mit Ausnahme des Tierreichs vor. Insgesamt gibt es hunderte von bisher kaum untersuchten Genen dieser Familie, die eine hohe Sequenzhomologie aufweisen. In der Pflanze Arabidopsis thaliana wurden 56 Gene der MATE - Familie zugeordnet. Eines von ihnen, der &quot;Novel Ion Carrier 2&quot; (NIC2) wurde näher charakterisiert. Dafür wurden heterologe Expressionssysteme wie Bakterien (Escherichia coli) und Hefe (Saccharomyces cerevisiae) genutzt und transgene Pflanzen (Arabidopsis thaliana) hergestellt. Es wurde gezeigt, dass NIC2 Bakterien eine Resistenz gegenüber mehreren giftigen Stoffen verlieh. In Hefe erhöhte NIC2 die Salztoleranz gegenüber Lithium und Natrium, aber nicht gegenüber Kalium und Kalzium. Das deutet darauf hin, dass NIC2 diese Stoffe transportieren kann und so zur Entgiftung beziehungsweise erhöhter Stresstoleranz beiträgt. In Pflanzen führte die Überexpression von NIC2 zu dramatischen Änderungen im Wachstum. Die Pflanzen waren buschig ohne zentralen Blütenstand, hatten jedoch eine höhere Anzahl von Blättern und Blüten und längere Wurzeln mit einer im Vergleich zu den Wildtyppflanzen verzögerten gravitropen Antwort. In Gegensatz dazu entwickelten Pflanzen, in denen die Expression von NIC2 gehemmt wurde, früh einen zentralen Blütenstand, der allerdings nicht gerade wuchs, sondern die Tendenz hatte, sich zum Boden zu biegen. Das Wurzelsystem bestand aus einer Hauptwurzel und vielen sekundären Wurzeln und war im Vergleich zu den Wildtyppflanzen besser entwickelt. Vermutlich kann die Wuchsform auf einen veränderten Gehalt des Pflanzenhormons Auxin zurückgeführt werden. Die Expression von NIC2 wird durch Auxin induziert. Experimente, in denen die Aktivität eines Gens mit Hilfe eines Reportergens nachgewiesen wird, zeigten, dass NIC2 in Wurzeln, Blättern, Blütenstielen, Blüten und Schoten aktiv ist. Innerhalb der Zelle ist NIC2 in Peroxisomen lokalisiert. Peroxisomen sind kleine Organellen, die eine Rolle im Hormonstoffwechsel spielen können, wie z.B. im Fall von Auxinen. Die Daten sprechen dafür, dass NIC2 eine Funktion beim Auxintransport und somit bei der Auxin-Homöostase hat.

Ackerschmalwand

Auxine

Membranproteine

Arabidopsis, membrane protein, auxin

Life sciences

In silico identification of genes regulated by abscisic acid in <i>Arabidopsis thaliana (L.) Heynh</i>.

Gómez-Porras, Judith Lucia

January 2005

Abscisic acid (ABA) is a major plant hormone that plays an important role during plant growth and development. During vegetative growth ABA mediates (in part) responses to various environmental stresses such as cold, drought and high salinity. The response triggered by ABA includes changes in the transcript level of genes involved in stress tolerance. The aim of this project was the In silico identification of genes putatively regulated by ABA in A. thaliana. In silico predictions were combined with experimental data in order to evaluate the reliability of computational predictions.<br><br> Taking advantage of the genome sequence of <i>A. thaliana</i> publicly available since 2000, 1 kb upstream sequences were screened for combinations of cis-elements known to be involved in the regulation of ABA-responsive genes. It was found that around 10 to 20 percent of the genes of <i>A. thaliana</i> might be regulated by ABA.<br><br> Further analyses of the predictions revealed that certain combinations of cis-elements that confer ABA-responsiveness were significantly over-represented compared with results in random sequences and with random expectations. In addition, it was observed that other combinations that confer ABA-responsiveness in monocotyledonous species might not be functional in A. thaliana. It is proposed that ABA-responsive genes in <i>A. thaliana</i> show pairs of ABRE (abscisic acid responsive element) with MYB binding sites, DRE (dehydration responsive element) or with itself.<br><br> The analysis of the distances between pairs of cis-elements suggested that pairs of ABREs are bound by homodimers of ABRE binding proteins. In contrast, pairs between MYB binding sites and ABRE, or DRE and ABRE showed a distance between cis-elements that suggested that the binding proteins interact through protein complexes and not directly.<br><br> The comparison of computational predictions with experimental data confirmed that the regulatory mechanisms leading to the induction or repression of genes by ABA is very incompletely understood. It became evident that besides the cis-elements proposed in this study to be present in ABA-responsive genes, other known and unknown cis-elements might play an important role in the transcriptional regulation of ABA-responsive genes. For example, auxin-related cis elements, or the cis-elements recognized by the NAM-family of transcription factors (Non-Apical meristem).<br><br> This work documents the use of computational and experimental approaches to analyse possible interactions between cis-elements involved in the regulation of ABA-responsive genes. The computational predictions allowed the distinction between putatively relevant combinations of cis-elements from irrelevant combinations of cis-elements in ABA-responsive genes. The comparison with experimental data allowed to identify certain cis-elements that have not been previously associated to the ABA-mediated transcriptional regulation, but that might be present in ABA-responsive genes (e.g. auxin responsive elements). Moreover, the efforts to unravel the gene regulatory network associated with the ABA-signalling pathway revealed that NAM-transcription factors and their corresponding binding sequences are important components of this network. / Pflanzen reagieren auf aeußere Stresseinwirkung (z.B. Trockenheit oder Hitze) u.a. mit der Bildung bestimmter Hormone. Diese Hormone wiederum bewirken eine Vielzahl komplexer Reaktionen (z.B. im Stoffwechsel und in der Genexpression), die zum Ziel haben, die Pflanzen widerstandsfaehiger gegen die Stresssituation zu machen. Ein wichtiges Stresshormon ist die Abzisinsaeure (ABA, fuer engl. „abscisic acid“). Experimentell koennen Pflanzen durch die Gabe von ABA zu Reaktionen gezwungen werden, die normalerweise nur unter Stressbedingungen beobachtet werden. Hierzu zaehlen vor allem eine Reduktion der Spaltoeffnungen in den Blaettern, um den Wasserverlust infolge von Transpiration zu minimieren, und eine massive Umprogrammierung der Genexpression.<br><br> In der vorliegenden Arbeit wurde der Einfluss von ABA auf die Genexpression in der Modellpflanze <i>Arabidopsis thaliana</i> untersucht. Hierzu wurden bioinformatorische und experimentelle Ansaetze verknuepft. Die bioinformatorischen Ansaetze bedienten sich der bekannten Sequenz des Genoms von <i>A. thaliana</i>. Mit Hilfe verschiedener geeigneter Computerprogramme wurden im Genom Gene identifiziert, deren Expression potentiell durch ABA reguliert wird. Die so erhaltenen Vorhersagen der verschiedenen Programme wurden miteinander und mit eigenen als auch mit publizierten experimentellen Daten verglichen, um die Qualitaet der Vorhersagen zu beurteilen. <br><br> Die wichtigste Schlussfolgerung aus den Ergebnissen dieser Arbeit ist, dass gegenwaertig bioinformatorische Ansaetze allein nicht ausreichen, um biologische Prozesse zufriedenstellend zu analysieren. In der vorliegenden Arbeit ermoeglichte erst eine Kombination aus bioinformatorischen und experimentellen Ansaetzen die Generierung neuer, abgesicherter Hypothesen zur ABA-induzierten Umprogrammierung der Genexpression.

Bioinformatik

Abszisinsäure

Promotoren

bioinformatics

regulation

ABA

Arabidopsis

Life sciences

GabiPD : the GABI primary database - a plant integrative "omics" database

Riano-Pachon, Diego Mauricio, Nagel, Axel, Neigenfind, Jost, Wagner, Robert, Basekow, Rico, Weber, Elke, Müller-Röber, Bernd, Diehl, Svenja, Kersten, Birgit

January 2009

The GABI Primary Database, GabiPD (http:// www.gabipd.org/), was established in the frame of the German initiative for Genome Analysis of the Plant Biological System (GABI). The goal of GabiPD is to collect, integrate, analyze and visualize primary information from GABI projects. GabiPD constitutes a repository and analysis platform for a wide array of heterogeneous data from high-throughput experiments in several plant species. Data from different ‘omics’ fronts are incorporated (i.e. genomics, transcriptomics, proteomics and metabolomics), originating from 14 different model or crop species. We have developed the concept of GreenCards for textbased retrieval of all data types in GabiPD (e.g. clones, genes, mutant lines). All data types point to a central Gene GreenCard, where gene information is integrated from genome projects or NCBI UniGene sets. The centralized Gene GreenCard allows visualizing ESTs aligned to annotated transcripts as well as displaying identified protein domains and gene structure. Moreover, GabiPD makes available interactive genetic maps from potato and barley, and protein 2DE gels from Arabidopsis thaliana and Brassica napus. Gene expression and metabolic-profiling data can be visualized through MapManWeb. By the integration of complex data in a framework of existing knowledge, GabiPD provides new insights and allows for new interpretations of the data.

Phosphorylation sites

Arabidopsis thaliana

Information

Proteins

Families

Life sciences

TERMINAL FLOWER2, the Arabidopsis HETEROCHROMATIN PROTEIN1 Homolog, and its Involvement in Plant Development

Landberg, Katarina

January 2007

This thesis describes the characterization of the Arabidopsis thaliana mutant terminal flower2 (tfl2), the cloning of the corresponding gene, and the analysis of TFL2 function in plant development. The tfl2 mutant is pleiotropic, exhibiting early floral induction in both long and short day conditions, a terminating inflorescence and dwarfing. TFL2 was isolated using a positional cloning strategy, and was found to encode a homolog to HETEROCHROMATIN PROTEIN1 (HP1), previously identified in yeast and animals where it is involved in gene regulation at the level of chromatin, as well as in the structural formation of constitutive heterochromatin. Investigating the light response during seedling photomorphogenesis I found that the tfl2 hypocotyl is hypersensitive to red and far-red light and that tfl2 is impaired in phytochrome mediated light responses such as the shade avoidance response. In the tightly regulated transition to flowering, we have shown that tfl2 might contribute to the interpretation of both external signals such as light and temperature as well as endogenous cues, via FCA, in the autonomous pathway. The Arabidopsis inflorescence meristem is indeterminate, and TFL2 possibly acts to maintain this indeterminate fate by repression of the floral meristem genes APETALA1 and AGAMOUS. In yeast two hybrid experiments TFL2 was shown to interact with IAA5, a protein with suggested functions in auxin regulation. Further, in tfl2 mutants the levels of the auxin indole-3-acetic acid decrease with age in aerial tissues, suggesting a function of TFL2 in regulation of auxin homeostasis and response. In summary, TFL2 contributes to regulation of several aspects of plant development, in accordance with the mutant phenotype and the identity of the TFL2 protein.

Biology

Arabidopsis

HETEROCHROMATIN PROTEIN1

flowering

meristem

auxin

Biologi

In vivo Analysis of the Role of FtsZ1 and FtsZ2 Proteins in Chloroplast Division in Arabidopsis thaliana

Johnson, Carol

2012 May 1900

Chloroplasts divide by a constrictive fission process that is regulated by FtsZ proteins. Given the importance of photosynthesis and chloroplasts in general, it is important to understand the mechanisms and molecular biology of chloroplast division. An FtsZ gene is known to be of prokaryotic origin and to have been transferred from a symbiont's genome to host genome via lateral transfer. Subsequent duplication of the initial FtsZ gene gave rise to the FtsZ1 and FtsZ2 genes and protein families in eukaryotes. These proteins co-localize mid-chloroplast to form the Z-ring. Z-ring assembly initiates chloroplast division, and it serves as a scaffold for other chloroplast division proteins. Little is known, however, about the FtsZ protein subunit turnover within the Z-ring, the effects of accessory proteins on Z-ring turnover assemblies, as well as the in vivo ultrastructure of the Z-ring in plants. To investigate the Arabidopsis thaliana FtsZ subunit turnover rate within the Z-ring, a section of the Z-ring in the chloroplasts of living plants expressing fluorescently tagged FtsZ1 or FtsZ2 proteins was photobleached and the recovery rate was monitored. The results show that the fluorescence recovery half times for the FtsZ1 and FtsZ2 proteins are 117s and 325s, respectively. This is significant as these data mirror their differences in GTP hydrolysis rates. To elucidate in vivo structure and ultrastructure of the Z-ring, a protocol was established that maintained fluorescence during high pressure freezing, freeze substitution and low temperature embedding. Afterwards, a correlative microscopy approach was employed to visualize and identify fluorescently labeled puncta, circular structures, at the light microscopy level. These puncta were further resolved as mini-rings using optical microscopy eXperimental (OMX) superresolution microscopy. Electron microscopy (EM) analysis imaged mini-rings and filament assemblies comprised of dense subunits. Electron tomography (ET) showed mini-rings composed of protofilaments.

Arabidopsis thaliana

FtsZ1

FtsZ2

correlative microscopy

chloroplast division

Quantifying Vein Patterns in Growing Leaves

Assaf, Rebecca

16 May 2011

How patterns arise from an apparently uniform group of cells is one of the classical problems in developmental biology. The mechanism is complicated by the fact that patterning occurs on a growing medium. Therefore, changes in an organism’s size and shape affect the patterning processes. In turn, patterning itself may affect growth. This interaction between growth and patterning leads to the generation of complex shapes and structures from simpler ones. Studying such interactions requires the possibility to monitor both processes in vivo. To this end, we developed a new technique to monitor and quantify vein patterning in a growing leaf over time using the leaves of Arabidopsis thaliana as a model system. We used a transgenic line with fluorescent markers associated with the venation. Individual leaves are followed in many samples in vivo through time-lapse imaging. Custom-made software allowed us to extract the leaf surface and vein pattern from images of each leaf at each time point. Then average spatial maps from multiple samples that were generated revealed spatio-temporal gradients. Our quantitative description of wild type vein patterns during leaf development revealed that there is no constant size at which a part of tissue enclosed by vasculature will become irrigated by a new vein. Instead, it seemed that vein formation depends on the growth rate of the tissue. This is the first time that vein patterning in growing leaves was quantified. The techniques developed will later be used to explore the interaction between growth and patterning through a variety of approaches, including mutant analysis, pharmacological treatments and variation of environmental conditions.

growth

Arabidopsis thaliana

network patterns

leaf veins

development

spatial data

Characterization of the four genes encoding cytoplasmic ribosomal protein S15a in Arabidopsis thaliana

Hulm, Jacqueline Louise

31 March 2008

Eukaryotic cytosolic ribosomes are composed of two distinct subunits consisting of four individual ribosomal RNAs and, in Arabidopsis thaliana, 81 ribosomal proteins. Functional subunit assembly is dependent on the production of each ribosomal component. Arabidopsis thaliana r-protein genes exist in multi-gene families ranging in size from two to seven transcriptionally active members. The cytosolic RPS15a gene family consists of four members (RPS15aA, -C, -D and -F) that, at the amino acid level, share 87-100% identity. Using semi-quantitative RT-PCR I have shown that RPS15aC is not expressed and that transcript abundance differs both spatially and temporally among the remaining RPS15a genes in non-treated Arabidopsis tissues and in seedlings following a variety of abiotic stresses. A comprehensive analysis of the RPS15a 5' regulatory regions (RRs) using a series of deletion constructs was used to determine the minimal region required for gene expression and identify putative cis-regulatory elements. Transcription start site mapping using 5' RACE indicated multiple sites of initiation for RPS15aA and -F and only a single site for RPS15aD while all three genes contain a leader intron upstream of the start codon. Analysis of reporter gene activity in transgenic Arabidopsis containing a series of 5' RR deletion::GUS fusions showed that, similar to previous RT-PCR results, there was a trend for mitotically active tissues to stain for GUS activity. Putative cis-elements including the TELO box, PCNA Site II motif and pollen specific elements were identified. However, there was not always a clear correlation between the presence of a putative element and RPS15a transcript abundance or GUS activity. Although variation in transcriptional activity of each RPS15a gene has been observed, subcellular localization of both RPS15aA and -D in the nucleolus has been confirmed in planta by confocal microscopy. The results of this thesis research suggest while all three active RPS15a genes are transcriptionally regulated, additional post-transcriptional and/or translational regulation may be responsible for final RPS15a levels while differential isoform incorporation into ribosomal subunits may be the final point of r-protein regulation.

gene expression

transcriptional regulation

Arabidopsis

S15a

ribosomal protein

ribosome

The role of cytosolic glutamine synthetases in abiotic stress and development in <i>Arabidopsis thaliana</i>

Ji, Yuanyuan

15 April 2011

Glutamine (Gln), a major nitrogen source in plants, is considered a central intermediate that coordinates carbon-nitrogen assembly for plant growth and development. To maintain a sufficient Gln supply, plant cells employ glutamine synthetases (GS), including cytosolic GS1 and plastidic GS2 for Gln production. Previous work has shown that the <i>GS1</i> is responsive to various environmental stresses. This study demonstrated the involvement of <i>GS1</i>s in Gln homeostasis and the role of GS1 in abiotic stress tolerance in <i>Arabidopsis</i>. The <i>GS1</i> family is comprised of five isoforms in <i>Arabidopsis thaliana</i>. Gene expression profiling showed that <i>GLN1;1, GLN1;3</i> and <i>GLN1;4</i> had similar expression patterns and were upregulated by abiotic (salinity and cold) stresses, whereas <i>GLN1;2</i> exhibited constitutive expression and no <i>GLN1;5</i> transcript was detected under any of the conditions tested. Null T-DNA insertion mutants for the five <i>GS1</i> genes were obtained. Only the <i>gln1;1</i> mutant displayed enhanced sensitivity to a GS inhibitor, phosphinothricin, and to cold and salinity treatments, suggesting a nonredundant role for GLN1;1. Increased stress sensitivity in <i>gln1;1</i> was associated with accelerated accumulation of reactive oxygen species (ROS), particularly in chloroplasts. To better understand the role of cytosolic GS isoforms, we generated two different triple mutant combinations. Triple mutant <i>gln1;1/gln1;2/gln1;3</i> showed reduced growth at an early stage. The <i>gln1;1/gln1;3/gln1;4</i> mutant is pollen lethal, indicating an essential role of Gln in plant gametophyte development. Collectively, our results establish a link between cytosolic Gln production, ROS accumulation, plant stress tolerance and development.

Arabidopsis

pollen development

ROS

Glutamine synthetases

abiotic stress