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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.
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Identification of abscisic acid-binding proteins using a bioactive photoaffinity probeGalka, Marek Michal 15 September 2009
This project was expected to contribute to the understanding of abscisic acid (ABA) perception in plants through identification of new ABA-binding proteins. The novel, biotinylated ABA derivative PBI686 (of biological activity comparable to natural ABA) has served as an affinity probe for isolation of ABA-binding proteins. Photoaffinity labeling in conjunction with affinity chromatography (streptavidin-biotin
based) was used for specific identification of target proteins from complex mixtures of cytosolic and membrane-bound proteins. Proteins of interest were identified by Mass Spectrometry through peptide mass fingerprinting and MS/MS ion search.<p>
Ribulose bisphosphate carboxylase/oxygenase (Rubisco) was identified as an ABA binding partner, and its interaction with ABA was initially confirmed by its ability to block the photoaffinity labeling reaction with PBI686. In addition, Surface Plasmon Resonance (SPR) experiments with ABA and Rubisco were performed, which provided further evidence for selective interaction between the two binding partners, with a very small preference towards (+)-ABA over (-)-ABA. SPR has also yielded the value of
equilibrium dissociation constant (KD) being 5 nM for (+)-ABA and 7 nM for (-)-ABA.
This was further confirmed by [3H] (±)-ABA binding assays, which have also shown that
non-radiolabeled (+)-ABA and (-)-ABA (at concentration 1000 fold higher) were able to
displace [3H] (±)-ABA from binding to Rubisco. Compounds other than ABA such as PA
(phaseic acid) or trans-(+)-ABA were not able to displace [3H] (±)-ABA, which has
suggested the selectivity of binding.
Further, Rubisco enzymatic activity in the absence of ABA was compared to that in
the presence of ABA at various concentrations. The results have clearly indicated the
effect of ABA on Rubiscos enzymatic activity. This was reflected on the enzymes Km
values being increased by seven fold in the presence of 10 mM ABA and 1 mM substrate
(RuBP). The interpretation of changes in enzyme kinetics upon inhibition by ABA most
resembles allosteric inhibition.
The biological function of this newly discovered interaction is interpreted as
ABAs ability to regulate plant growth during abiotic stress by its direct action on the
photosynthetic machinery - hypothesis often suggested in the literature.
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The role of cytosolic glutamine synthetases in abiotic stress and development in <i>Arabidopsis thaliana</i>Ji, Yuanyuan 15 April 2011 (has links)
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.
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Identification of abscisic acid-binding proteins using a bioactive photoaffinity probeGalka, Marek Michal 15 September 2009 (has links)
This project was expected to contribute to the understanding of abscisic acid (ABA) perception in plants through identification of new ABA-binding proteins. The novel, biotinylated ABA derivative PBI686 (of biological activity comparable to natural ABA) has served as an affinity probe for isolation of ABA-binding proteins. Photoaffinity labeling in conjunction with affinity chromatography (streptavidin-biotin
based) was used for specific identification of target proteins from complex mixtures of cytosolic and membrane-bound proteins. Proteins of interest were identified by Mass Spectrometry through peptide mass fingerprinting and MS/MS ion search.<p>
Ribulose bisphosphate carboxylase/oxygenase (Rubisco) was identified as an ABA binding partner, and its interaction with ABA was initially confirmed by its ability to block the photoaffinity labeling reaction with PBI686. In addition, Surface Plasmon Resonance (SPR) experiments with ABA and Rubisco were performed, which provided further evidence for selective interaction between the two binding partners, with a very small preference towards (+)-ABA over (-)-ABA. SPR has also yielded the value of
equilibrium dissociation constant (KD) being 5 nM for (+)-ABA and 7 nM for (-)-ABA.
This was further confirmed by [3H] (±)-ABA binding assays, which have also shown that
non-radiolabeled (+)-ABA and (-)-ABA (at concentration 1000 fold higher) were able to
displace [3H] (±)-ABA from binding to Rubisco. Compounds other than ABA such as PA
(phaseic acid) or trans-(+)-ABA were not able to displace [3H] (±)-ABA, which has
suggested the selectivity of binding.
Further, Rubisco enzymatic activity in the absence of ABA was compared to that in
the presence of ABA at various concentrations. The results have clearly indicated the
effect of ABA on Rubiscos enzymatic activity. This was reflected on the enzymes Km
values being increased by seven fold in the presence of 10 mM ABA and 1 mM substrate
(RuBP). The interpretation of changes in enzyme kinetics upon inhibition by ABA most
resembles allosteric inhibition.
The biological function of this newly discovered interaction is interpreted as
ABAs ability to regulate plant growth during abiotic stress by its direct action on the
photosynthetic machinery - hypothesis often suggested in the literature.
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BT2, a BTB Scaffold Protein, Mediates Responses to Multiple Biotic and Abiotic Signals in ArabidopsisMandadi, Kranthi Kiran 2010 August 1900 (has links)
We previously described BT2, a BTB/POZ domain containing protein, as an activator of telomerase in Arabidopsis thaliana. In the current study, I present evidence of its interesting roles in mediating multiple hormone, stress and metabolic responses in plants. Steady-state expression of BT2 mRNA was regulated diurnally and was under the control of circadian clock, with a maximum expression in the dark. BT2 mRNA was responsive to nutrient status and to multiple biotic and abiotic stress signals. Using bt2 loss-of-function and BT2 over-expressing lines, I show that BT2 suppresses sugar and ABA-mediated responses during germination. BT2 is also essential for transcriptional gene activation mediated by CaMV 35S enhancers in Arabidopsis. Loss of BT2 in several well-characterized 35S enhancer activation-tagged lines such as yucca1d, pap1d, jaw1d etc., resulted in suppression of the activation phenotypes. The suppression of the phenotypes was due to decreased transcription of the activation-tagged genes. I further demonstrate that BT2 genetically interacts with CULLIN3. I propose that BT2 and CULLIN3 are components of a ubiquitin ligase complex. Together with associated proteins BET9 and BET10, the BT2 complex is required for CaMV 35S enhancer-mediated activation of gene expression and may regulate expression of target genes involved in multiple responses to fluctuating biotic and abiotic conditions.
I also found that BT2 protein levels are tightly regulated in plants. BT2 protein was primarily localized in the nucleus and was developmentally regulated. BT2 turn-over was regulated in part by the 26S-proteosome, and rare codons present in its open reading frame affected BT2 protein accumulation. In addition to BT2, its orthologs, BT1, BT3, BT4 and BT5, also responded to light, clock and nutrients, with some differences. Moreover, BT1, BT3 and BT4 were also required for 35S enhancer-mediated activation of gene expression. I propose that BT family proteins assemble into multi-protein complexes to mediate multiple responses to changing environmental and nutritional conditions.
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GRAM genes and abscisic acid (ABA) metabolism in the reproductive development of Arabidopsis thalianaBaron, Kevin 06 1900 (has links)
Abscisic acid (ABA) is a key plant hormone regulating agronomically important processes including seed maturation and dormancy, stomatal opening and closure, along with the transcriptional and physiological response of plants to abiotic and biotic stresses. The current study sought to functionally characterize members of an ABA-responsive gene family encoding GRAM (Glucosyltransferases, Rab-like GTPase activators and Myotubularins) domain proteins in Arabidopsis thaliana. Utilizing reverse genetics loss- and gain-of-function lines associated with GEM-RELATED 5 (GER5) were obtained, which displayed several defects in reproductive development. Gene expression profiling, RNA in situ hybridization and immunohistochemical techniques were utilized to evaluate GER5 and two closely related GRAM genes, GEM-RELATED 1 (GER1) and GLABRA2 EXPRESSION MODULATOR (GEM) in reproductive structures. Microarray profiling of seeds from ger5-2 mutants and wild-type plants revealed transcriptional changes in carbohydrate metabolism, hormone signaling and catabolic processes accompanied seed development defects of ger5-2 mutants. Seed germination assays further revealed ger5-2 mutants exhibited reduced sensitivity to ABA.
In assessing GER5, GER1 and GEM as putative ABA-response genes, a second study evaluated the expression of GRAM, AuTophaGy-related (ATG), and ABA-response genes in source and sink organs exposed to abiotic stress or within mutant backgrounds deficient in sugar signaling. Monodansylcadaverine (MDC) staining was also utilized to localize autophagosomes or autophagic bodies within vegetative or reproductive organs during plant development, or in response to carbon starvation or abiotic stress.
In a third study transcriptional differences in ABA metabolism, transport and homeostasis were examined within reproductive organs (cauline leaves, inflorescence meristem, developing siliques) exposed to cold and heat stress. This study revealed reproductive organs are characterized by unique patterns of ABA metabolism which differ from tissues typically associated with classical ABA responses. Together, these studies indicate GER5, an uncharacterized ABA-responsive GRAM domain gene, plays a novel role in the reproductive development of plants and that ABA metabolism and signaling are uniquely regulated in reproductive organs.
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Dissecting the role of pathogenesis related-10 (PR-10) proteins in abiotic stress tolerance of plantsKrishnaswamy, Sowmya Unknown Date
No description available.
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GRAM genes and abscisic acid (ABA) metabolism in the reproductive development of Arabidopsis thalianaBaron, Kevin 06 1900 (has links)
Abscisic acid (ABA) is a key plant hormone regulating agronomically important processes including seed maturation and dormancy, stomatal opening and closure, along with the transcriptional and physiological response of plants to abiotic and biotic stresses. The current study sought to functionally characterize members of an ABA-responsive gene family encoding GRAM (Glucosyltransferases, Rab-like GTPase activators and Myotubularins) domain proteins in Arabidopsis thaliana. Utilizing reverse genetics loss- and gain-of-function lines associated with GEM-RELATED 5 (GER5) were obtained, which displayed several defects in reproductive development. Gene expression profiling, RNA in situ hybridization and immunohistochemical techniques were utilized to evaluate GER5 and two closely related GRAM genes, GEM-RELATED 1 (GER1) and GLABRA2 EXPRESSION MODULATOR (GEM) in reproductive structures. Microarray profiling of seeds from ger5-2 mutants and wild-type plants revealed transcriptional changes in carbohydrate metabolism, hormone signaling and catabolic processes accompanied seed development defects of ger5-2 mutants. Seed germination assays further revealed ger5-2 mutants exhibited reduced sensitivity to ABA.
In assessing GER5, GER1 and GEM as putative ABA-response genes, a second study evaluated the expression of GRAM, AuTophaGy-related (ATG), and ABA-response genes in source and sink organs exposed to abiotic stress or within mutant backgrounds deficient in sugar signaling. Monodansylcadaverine (MDC) staining was also utilized to localize autophagosomes or autophagic bodies within vegetative or reproductive organs during plant development, or in response to carbon starvation or abiotic stress.
In a third study transcriptional differences in ABA metabolism, transport and homeostasis were examined within reproductive organs (cauline leaves, inflorescence meristem, developing siliques) exposed to cold and heat stress. This study revealed reproductive organs are characterized by unique patterns of ABA metabolism which differ from tissues typically associated with classical ABA responses. Together, these studies indicate GER5, an uncharacterized ABA-responsive GRAM domain gene, plays a novel role in the reproductive development of plants and that ABA metabolism and signaling are uniquely regulated in reproductive organs.
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Ureide accumulation in faba bean (Vicia faba, L.)2014 August 1900 (has links)
Faba bean (Vicia faba L.) is a cool season crop that uses symbiotic biological nitrogen fixation to obtain atmospheric nitrogen (N), a limiting macronutrient, for growth and maintenance of the plant. Most cool season legumes like faba bean transport N from the nodules as amides, which are metabolized in destination tissues. Ureide metabolism is a catabolic process that produces N rich compounds from purine rings. Many warm season legumes such as soybean and common bean produce ureides (allantoin and allantoate) in their root nodules and then use these molecules to transport fixed nitrogen from root to shoot. Non-ureide exporting plants such as faba bean also produce ureides in normal purine recycling whereby these compounds may play a role in response to abiotic stress. This research aims to examine possible differences in ureide metabolism across genotypes and to assess the role of ureides in response to water limitation. In field grown faba bean, total ureides were found in highest concentrations in leaf tissue, followed by reproductive parts, stems, and nodules, but were not found to differ significantly among genotypes. Ureide concentrations varied throughout the growing season, decreasing over time as the plants reached physiological maturity. A water limitation experiment of faba bean grown in a controlled environment showed that faba bean accumulated the ureides allantoin and allantoate after six to eight days of water limitation when all data were pooled. However, no consistent trend was observed comparing results by genotype, and inoculated versus non-inoculated plants. Overall, results indicate that faba bean likely does not use ureides to transport symbiotically fixed N and that ureide accumulation in field grown plants is most likely in response to abiotic stress or remobilization of purine N from senescing tissues.
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Dissecting the role of pathogenesis related-10 (PR-10) proteins in abiotic stress tolerance of plantsKrishnaswamy, Sowmya 06 1900 (has links)
Abiotic stress is one of the major factors that affect food production worldwide and, therefore understanding stress responsive proteins and engineering plants for abiotic stress tolerance is very important. In the present study, the biological role of pea pathogenesis-related 10.4 (PR-10.4; also known as abscisic acid responsive 17; ABR17) in abiotic stress tolerance has been investigated. Our investigation on ribonuclease (RNase) activity of ABR17 suggested that highly conserved histidine-69 and glutamic acid-148 are important for RNase activity. In order to further investigate the biological role(s) of ABR17, transcriptional profiling of pea ABR17-mediated gene expression changes in ABR17-transgenic Arabidopsis thaliana plants was carried out using microarrays. Our results indicated that pea ABR17 modulates many plant growth/development genes most of which are cytokinin (CK) responsive. These results agree very well with previously reported enhanced endogenous CKs in these transgenic plants. However, no significant changes in transcript abundance of CK biosynthetic genes were observed between transgenic and wild-type plants, suggesting an alternate source of CK in ABR17-transgenic plants. It is speculated that ABR17 may act as either a CK reservoir (through its reported CK binding property) or may be responsible for isopentenylated-tRNA degradation (through its demonstrated RNase activity) thereby increasing endogenous CK pools. Furthermore, microarray analysis of salinity stressed ABR17-Arabidopsis indicated that ABR17 modulates many stress responsive genes that included four putative AP2 family genes (RAP2.6-At1g43160, RAP2.6L-At5g13330, DREB26-At1g21910 and DREB19-At2g38340). Functional characterization of these genes suggested that they are transcription factors and they play very important roles in abiotic stress response in addition to growth and development. Moreover, overexpression of RAP2.6L and DREB19 genes enhanced salinity and drought tolerance in Arabidopsis. Taken together, our results suggest that pea ABR17 proteins are important in abiotic stress responses as they may act as source of enhanced CKs and they may also modulate expression of stress responsive genes to enhance stress tolerance in plants. However, additional research aimed at deciphering the links between ABR17 and CK biosynthesis as well as the mechanism of ABR17-mediated gene expression changes should be conducted in order to get more insights into the biological roles of PR10 proteins in planta. / Plant Science
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