Project description:Boron is an essential micronutrient for plants and is taken up in the form of boric acid (BA). Despite this, a high BA concentration is toxic for the plants, inhibiting root growth and is thus a significant problem in semi-arid areas in the world. In this work, we report the molecular basis for the inhibition of root growth caused by boron. We used microarrays to detail the global gene expression underlying boron toxicity in roots.

Project description:Transcriptional profiling of yeast wild type BY4741, gcn4 and yap1 mutants in response to boron treatment. Transcriptional profiling of yeast wild type BY4741, gcn4 and yap1 mutants in response to boron treatment.

Project description:Here we report, that levels of the micronutrient boron are instrumental for meristem maintenance by integration into specific meristem maintenance pathways. We used RNA-seq analysis of the boron deficient maize mutant tassel-less1 to identify early molecular defects induced by boron deficiency in maize reproductive (tassel) meristems. RNA-seq results were independently verified through downstream in silico, double mutant, microscopy, proteomic, and molecular analyses.

Project description:Boron is an essential micronutrient for plants and is taken up in the form of boric acid (BA). Despite this, a high BA concentration is toxic for the plants, inhibiting root growth and is thus a significant problem in semi-arid areas in the world. In this work, we report the molecular basis for the inhibition of root growth caused by boron. We used microarrays to detail the global gene expression underlying boron toxicity in roots. 5-day-old arabidopsis plants were transferred to medium with high boron concentration (½ MS medium supplemented with 5mM BA) and control conditions (½ MS medium). We determined that 5 mM BA is the minimum concentration that produces the maximum effect, stunting root growth by ~50% after 5 days as compared with control conditions. We analyzed the transcript profiles in roots by microarray analysis (Affymetrix ATH1 Genome Array). We compared the transcripts obtained at 12 hrs of BA treatment.

Project description:Boron (B) is an essential micronutrient for vascular plants. Boron works to build the cell wall structure by forming borate ester cross-links with pectin, and the deficiency of this element brings about oxidative damage and cell death. However, the process via which B deficiency leads to such serious damage has not been well understood. We investigated the temporal changes in metabolism of B-deprived cultured tobacco (Nicotiana tabacum) BY-2 cells by analyzing their gene expression using cDNA microarray.

Project description:Boron (B) is an essential micronutrient for vascular plants. Boron works to build the cell wall structure by forming borate ester cross-links with pectin, and the deficiency of this element brings about oxidative damage and cell death. However, the process via which B deficiency leads to such serious damage has not been well understood. We investigated the temporal changes in metabolism of B-deprived cultured tobacco (Nicotiana tabacum) BY-2 cells by analyzing their gene expression using cDNA microarray.

Project description:Transcriptional profiling of yeast wild type BY4741, gcn4 and yap1 mutants in response to boron treatment.

Project description:Transcriptional profiling of yeast wild type BY4741, gcn4 and yap1 mutants in response to boron treatment.

Project description:Boron (B) is an essential micronutrient for vascular plants. Boron works to build the cell wall structure by forming borate ester cross-links with pectin, and the deficiency of this element brings about oxidative damage and cell death. However, the process via which B deficiency leads to such serious damage has not been well understood. We investigated the temporal changes in metabolism of B-deprived cultured tobacco (Nicotiana tabacum) BY-2 cells by analyzing their gene expression using cDNA microarray. Three-day-old cells were deprived of B by washing with and transferred to B-free growth media ("-B" cells). Cells similarly treated with standard growth media were employed as a control for the effects of mechanical stress ("+B cells"). Cells were sampled at 1, 3, 6, 12 and 36 h after transfer to the B-free or standard media. Cells without washing treatment were also included in the analysis ("before-treatment cells"). Two independent sets of samples were analyzed (replicate 1 and 2).

Project description:Poplars are known to be highly tolerant species to boron toxicity and accumulation. However, genes and molecular networks responsible in boron toxicity tolerance have not been investigated yet. Therefore, we performed a pot experiment with 20 black poplar clones collected from the vicinity of boron mines and polluted areas to investigate its potential role in phytoremediation and to select the most boron toxicity tolerant genotype. Trees were treated with irrigation water containing seven elevated boron concentrations from 0 to 160 ppm. Then a microarray based comparative transcriptome profiling was conducted to identify boron toxicity regulated genes responsible in defence responses of black poplar. The results of the study indicated that black poplar is quite suitable for phytoremediation of boron pollution. It could resist 15 ppm soil B content and < 1600 mg/kg boron accumulation in leaves which are highly toxic concentrations for almost all agricultural plants. Transcriptomics results of study revealed totally 1625 and 1419 altered probe sets under boron toxicity in leaf and root tissues, respectively. The highest induction were recorded for the probes sets annotated to tyrosine aminotransferase, ATP binding cassette transporters, glutathione S transferases and metallochaperone proteins. Strong up regulation of these genes attributed to internal excretion of boron into the cell vacuole and existence of detoxification processes in black poplar. Many candidate genes functional in signalling, gene regulation, antioxidation, boron uptake, transport and detoxification processes were also identified in the current study. This is the first transcriptomic study identifying boron toxicity regulated poplar genes and their potential role in boron toxicity tolerance. Total RNA used in microarray experiment was isolated from the leaves and roots of black poplar clone; N.92.237 which accumulated the highest amount of boron its tissues. Total RNA used in the microarray experiment was isolated from leaves and roots of three black poplar saplings grown in ~ 2 ppm (control) and ~ 15 ppm (toxic) soil B contents. RNA isolation was made according to Lithium chloride precipitation method described in Chang et al. (1993). These three isolated RNAs (biological replicates) for each tissue loaded onto three Affymetrix poplar Gene Chips (technical replicates). Totally, 12 GeneChips (2 tissues Ã? 2 different B treatment Ã? 3 biological replicates) were used for transcriptional analysis.