Project description:HaHB11 is a divergent member of the sunflower homeodomain-leucine zipper I subfamily of transcription factors. A sunflower microarray was hybridized with RNA from HaHB11-transformed leaf-disks and its analysis indicated the regulation of many genes encoding enzymes from fermentative pathways. A 1300 bp sequence exhibiting flooding-responsive cis-acting elements, upstream the transcription initiation site, was isolated and Arabidopsis plants transformed with a construct in which this promoter directs GUS expression. GUS expression was induced after flooding treatments and, in the same sense, HaHB11 expression was induced by flooding stress in sunflower. Furthermore, Arabidopsis plants were transformed with different constructs, varying in the promoter used, able to express HaHB11 cDNA. These transgenic plants exhibited differential phenotypes which the more remarkable traits were a significant increase in the rosette biomass and seeds yield. Moreover these plants exhibited an enhanced tolerance to flooding stress, both to submergence and waterlogging. Starch, sucrose and glucose contents were higher in the transgenics compared to WT and decreased less after submergence treatments. Finally, transcript levels of selected genes, involved in fermentative pathways, and the corresponding enzymatic activities were assessed both in sunflower and transgenic Arabidopsis plants after submergence indicating a general repression of the fermentative pathway which suggested that tolerance occurs via the quiescent strategy. Altogether the results indicated a role for HaHB11 in the flooding response and allowed us to propose this gene as a biotechnological tool to improve crops for increased yield and biomass and flooding tolerance.

Project description:Floodings already have a nearly 60% share in the worldwide damage to crops provoked by natural disasters. Climate change will cause plants to be even more frequently exposed to oxygen limiting conditions (hypoxia) in the near future due to heavy precipitation and concomitant waterlogging or flooding events in large areas of the world. Although the homeostatic regulation of adaptive responses to low oxygen stress in plants is well described, it remained unknown by which initial trigger the molecular response to low-oxygen stress is activated. Here, we show that a hypoxia-induced decline of the ATP level of the cell reduces LONG-CHAIN ACYL-COA SYNTHETASE (LACS) activity, which leads to a shift in the composition of the acyl-CoA pool. High oleoyl-CoA levels release the transcription factor RELATED TO APETALA 2.12 (RAP2.12) from its interaction partner ACYL-COA BINDING PROTEIN (ACBP) at the plasma membrane to induce low oxygen-specific gene expression. We show that different acyl-CoAs provoke unique molecular responses revealing a novel role as cellular signalling component also in plants. In terms of hypoxia signalling, dynamic acyl-CoA levels integrate the cellular energy status into the oxygen signalling cascade with ACBP and RAP2.12 being the central hub. The conserved nature of the ACBP:RAP2.12 module in crops and the novel mechanistic understanding of how low-oxygen stress responses are initiated by oleoyl-CoA in plants provide useful leads for enhancing future food security.

Project description:The capacity of respiring cultures of Saccharomyces cerevisiae to instantaneously switch to fast alcoholic fermentation upon a transfer to anaerobic sugar-excess conditions is a key characteristic of Saccharomyces cerevisiae in many of its industrial applications. This transition was studied by exposing aerobic glucose-limited chemostat cultures grown at a low specific growth rate to two simultaneous perturbations: oxygen depletion and relief of glucose limitation. This shift towards fully fermentative conditions caused a massive transcriptional response, where one third of all genes within the genome were transcribed differentially. During the first 30 min, most of these changes were driven by relief from glucose limitation. An anaerobic induction response was only observed after the initial response to glucose excess. By comparing this study with public datasets representing dynamic and steady conditions, 14 up-regulated and 11 down-regulated genes were determined to be anaerobiosis specific and can therefore be use as “signature” transcripts for anaerobicity under dynamic as well as under steady state conditions Experiment Overall Design: To invoke rapid and full induction of fermentative capacity, respiratory, aerobic glucose-limited chemostat cultures (D=0.1•h-1) were shifted to fully fermentative conditions by sudden depletion of oxygen and addition of glucose. The glucose was added two min after sparging the continuous culture with pure nitrogen, when the dissolved oxygen concentration had decreased from 75-80% to 10-15% of air saturation. Samples for micro-arrays were taken for each time point after the perturbation (5, 10, 30, 60 and 120 min) from two independently cultured replicates, while steady state data were taken from three independent chemostats. The complete dataset therefore comprised 13 samples.

Project description:Global gene expression was compared between roots of cotton plants (variety Sicot 71) flooded for 4 hours and roots of unflooded cotton plants. Global gene expression was also compared between leaves of cotton plants (variety Sicot 71) flooded for 24 hours and leaves of unflooded cotton plants. Waterlogging stress causes yield reductions in cotton (Gossypium hirsutum L.). A major component of waterlogging stress is the lack of oxygen available to submerged tissues. While changes in expressed protein, gene transcription and metabolite levels have been studied in response to low oxygen stress, little research has been done on molecular responses to waterlogging in cotton. We assessed cotton growth responses to waterlogging and assayed global gene transcription responses in root and leaf cotton tissues of partially submerged plants. Waterlogging causes significant reductions in stem elongation, shoot mass, root mass, and leaf number. At the global gene expression level waterlogging significantly alters the expression of 1012 genes (4.2% of genes assayed) in root tissue as early as 4h after flooding. Many of these genes are associated with cell wall modification and growth pathways, glycolysis, fermentation, mitochondrial electron transport and nitrogen metabolism. Waterlogging of plant roots also altered global leaf gene expression, significantly changing the expression of 1305 genes (5.4% of genes assayed) after 24h of flooding. Genes associated with cell wall growth and modification, tetrapyrrole synthesis, hormone response, starch metabolism and nitrogen metabolism were affected in leaf tissues of waterlogged plants. Implications of these results for the development of waterlogging tolerant cotton are discussed. Keywords: Stress Response Plants of cotton cultivar Sicot 71 were grown to the two-leaf stage in tubs. For stress treatments plants were either watered as normal or flooded with water to completely submerge the root system. At four and twenty-four hours post-flooding samples of root or leaf tissue were taken from control and flooded plants. Total RNA was extracted from each tissue sample and assayed on cotton Affymetrix chips. Two biological replications were used for each comparison.

Project description:We found many binding sites for ArcA under glucose fermentative anaerobic growth conditions. Descirbed in the manuscript "The response regulator ArcA uses a diverse binding site architechture to globally regulate carbon oxidation in E. coli"

Project description:Global gene expression was compared between roots of cotton plants (variety Sicot 71) flooded for 4 hours and roots of unflooded cotton plants. Global gene expression was also compared between leaves of cotton plants (variety Sicot 71) flooded for 24 hours and leaves of unflooded cotton plants. Waterlogging stress causes yield reductions in cotton (Gossypium hirsutum L.). A major component of waterlogging stress is the lack of oxygen available to submerged tissues. While changes in expressed protein, gene transcription and metabolite levels have been studied in response to low oxygen stress, little research has been done on molecular responses to waterlogging in cotton. We assessed cotton growth responses to waterlogging and assayed global gene transcription responses in root and leaf cotton tissues of partially submerged plants. Waterlogging causes significant reductions in stem elongation, shoot mass, root mass, and leaf number. At the global gene expression level waterlogging significantly alters the expression of 1012 genes (4.2% of genes assayed) in root tissue as early as 4h after flooding. Many of these genes are associated with cell wall modification and growth pathways, glycolysis, fermentation, mitochondrial electron transport and nitrogen metabolism. Waterlogging of plant roots also altered global leaf gene expression, significantly changing the expression of 1305 genes (5.4% of genes assayed) after 24h of flooding. Genes associated with cell wall growth and modification, tetrapyrrole synthesis, hormone response, starch metabolism and nitrogen metabolism were affected in leaf tissues of waterlogged plants. Implications of these results for the development of waterlogging tolerant cotton are discussed. Keywords: Stress Response

Project description:Plants as obligate aerobic organisms are severely affected by flooding-induced oxygen restriction. As a consequence, they suffer from energy deficits which are counterbalanced by activation of anaerobic metabolism genes through subgroup VII ETHYLENE-RESPONSE FACTOR (ERFVII) transcription factors. Despite the crucial role of ERFVIIs in regulating transcript responses to hypoxia in multiple plant species, it is not understood how these factors mechanistically initiate hypoxic gene expression. Here, we show that the Arabidopsis ERFVIIs RELATED TO APETALA 2.12 (RAP2.12) and RAP2.2 recruit the Mediator complex, present in all higher eukaryotes, in order to convey stress signals to RNA polymerase II. This is achieved by specific interaction with Mediator subunit 25 (AtMED25). Both RAP2.12 and RAP2.2 require AtMED25 for full activity and subsequent induction of target hypoxia core genes. Our findings support an interplay of multiple coactivators under hypoxia and underline the flexible nature of the Mediator complex composition, which both help to meet specific cellular demands under (hypoxic) stress conditions.

Project description:We found many binding sites for ArcA under glucose fermentative anaerobic growth conditions. Descirbed in the manuscript "The response regulator ArcA uses a diverse binding site architechture to globally regulate carbon oxidation in E. coli" Examination of occupancy of ArcA under anaerobic growth conditions.

Project description:In previous temporal studies, we found the anaerobic response was biphasic when cells growing in galactose medium were shifted from aerobiosis to anaerobiosis, consisting of an acute, transitory phase (<60 min) followed by a more chronic but delayed phase (> 1 generation), but largely monophasic (delayed, chronic phase only) when cells were shifted in glucose medium. Gene network and functional analyses revealed the acute phase was comprised of genes associated with the retooling of metabolism (respiro-fermentative to strictly fermentative) and balancing energy supply and demand. A similar pattern of gene expression is seen when cells encounter other “environmentally stressful” conditions. However, cells shifted to anaerobiosis on glucose, in which no catabolic rearrangement is required nor change in growth rate observed, do not exhibit this pattern, suggesting the “stress” encountered is one associated with the abrupt cessation of galactose-dependent respiration and slowing of growth, not oxygen deprivation per se. In order to test this hypothesis, we conducted this genomic study using the respiratory inhibitor, antimycin A, under aerobiosis, which mimicked the retooling of metabolism from respiro-fermentative to strictly fermentative growth. Keywords: time course

Project description:Cocoa is a crop of cultural, nutritional and social importance in Latin America. Cocoa production is mainly supported by smallholders and is central for the food security of these farmer families. Despite being part of their everyday diet and an important source of antioxidants and other healthy bioactive compounds, cocoa cropping is also a solid source of stable incomes supporting the livelihood of farmer families. Water deficit stress is one of the main limiting factors affecting crop yields. The ability of plants to tolerate or recover from the effects associated with this abiotic stress is of immense importance in terms of improvement in the context of climate change. Despite the emergence of functional genomics and phenotyping tools to approach these responses, many of these mechanisms are still little understood for many tropical food crops such as cocoa. For a transcriptomic analysis were selected 2 cocoa genotypes, from a hydric stress assay established in a greenhouse. 5-month-old plants of T. cacao of the genotypes EET 8 and TSH565 were tested for water deficit trial. A divided plot experimental design was applied: the hydric state of the 2 genotypes was evaluated with two levels: field capacity and water deficit by irrigation suspension during a period that generates severe stress (Leaf Water Potential of -3.0 Mpa). The irrigation suspension lasted 52 days.