Project description:Flavonoid biosynthesis in grape berry skin is affected by environmental factors such as light and temperature. However, the components of the light-signaling and low-temperature-induced ABA signaling networks related to flavonoid accumulation in grape berry skin have not been fully elucidated. To clarify details of the possible light- and ABA-related signal transduction networks, we performed comprehensive transcriptome analysis using grape berries cultured under different light and temperature conditions. We identified 40 light-inducible genes, 55 low-temperature-inducible genes, and 34 genes induced by light plus low temperature.

Project description:The OsMyb4 transcription factor of rice represents a more recent example of a regulatory gene used in various attempts to develop stress-tolerant crops by regulon engineering. Although OsMyb4 confers tolerance to low temperature and drought by affecting the biosynthesis of compatible osmolytes and the phenylpropanoid metabolic process, the exact composition and scope of the OsMyb4 network has not been established from the previous analysis of heterologous overexpression in Arabidopsis. Further characterization of the OsMyb4 regulon at the global scale will facilitate understanding of the intricate underpinnings of a pathway independent of the DREB/CBF network. To dissect the OsMyb4 network of rice in relation to chilling stress response mechanisms, we conducted a gene expression profiling using transgenic rice overexpressing the OsMyb4 cDNA.

Project description:1. Primary Endpoints * Biomarker data suggestive of regorafenib-mediated inhibition of the RAS-RAF- MEK-ERK signal transduction pathway,of various tyrosine kinase receptors and/or of angiogenesis. * Evaluation of potential relationships between biomarker data and clinical activity. * Evaluation of a novel biomarker technology (Prometheus COPIA platform) 2. Secondary Endpoints * Biomarker data suggestive of regorafenib-mediated effects on circulating rare cells. * Comparison of tumor genetic profiles obtained using DNA isolated from plasma, tumor biopsies and circulating tumor cells. * Patient safety data * Pharmacokinetics of regorafenib * Changes in tumor metabolic activity as measured by PET CT scan (optional)

Project description:We have previously demonstrated that molecular hydrogen (H2) neutralizes hydroxyl radical (•OH) in cultured-cells and protects cells and tissues against oxidative stress. Growing evidence has confirmed that H2-consumption exhibits preventive and therapeutic effects in patients with various diseases as well as model animals. Moreover, a small amount of H2 modulates signal transduction for regulating the expression of various genes; however, the primary target of H2 for exhibiting a variety of phenotypes was completely unknown. Here we show that H2 at low amounts manipulates oxidized phospholipid mediators to modulate Ca2+-signal transduction and gene expression.

Project description:Plant growth is severely affected by toxic concentrations of the non-essential heavy metal cadmium (Cd). Comprehensive transcriptome analysis by RNA-Seq following cadmium exposure is required to further understand plant responses to Cd and facilitate future systems-based analyses of the underlying regulatory networks. In this study, rice plants were hydroponically treated with 50 µM Cd for 24 hours. In total, ~60,000 transcripts, including transcripts that could not be characterized by microarray-based approaches, were evaluated and ~36,000 transcripts were responsive to Cd exposure. Among multigenic families that may protect cells from generated ROS and reduce Cd toxicity, prominently upregulated antioxidant enzyme genes were identified. Furthermore, 168 different metal ion transporter genes, which might mediate the transport of transition Cd, responded to Cd exposure. qRT-PCR analysis of randomly selected genes indicated that their expression changed obviously after exposure to various heavy metal stresses. The Cd responsive genes included many abiotic stress (drought, high-salinity, low temperature) responsive genes. Based on further investigation into the expression patterns of abiotic stress regulatory genes such as DREB, part of the signal transduction pathway for Cd exposure was determined to cross-talk with abiotic stress signaling pathways. Our results provide useful information for further studies of the molecular mechanisms of plant adaptation to Cd exposure and the improvement of Cd tolerance in crop species.

Project description:IMPACT: Unraveling intracellular signal transduction and pathway crosstalk by exploring pathway landscape

Project description:Water shortage is a major factor that harms agriculture and ecosystems worldwide. Plants display various levels of tolerance to water deficit, but only resurrection plants can survive full desiccation of their vegetative tissues. Haberlea rhodopensis, an endemic plant of the Balkans, is one of the few resurrection plants found in Europe. We performed transcriptomic analyses of this species under slight, severe and full dehydration and recovery to investigate the dynamics of gene expression and associate them with existing physiological and metabolomics data. De novo assembly yielded a total of 142,479 unigenes with an average sequence length of 1,034 nt. Among them, 18,110 unigenes were differentially expressed. Hierarchical clustering of all differentially expressed genes resulted in seven clusters of dynamic expression patterns. The most significant expression changes, involving more than 15,000 genes, started at severe dehydration (~20% relative water content) and were partially maintained at full desiccation (<10% relative water content). More than a hundred pathways were enriched and functionally organized in a GO/pathway network at the severe dehydration stage. Transcriptomic changes in key pathways were analyzed and discussed in relation to metabolic processes, signal transduction, quality control of protein and DNA repair in this plant during dehydration and rehydration. Reprograming of the transcriptome occurs during severe dehydration, resulting in a profound alteration of metabolism toward alternative energy supply, hormone signal transduction, and prevention of DNA/protein damage under very low cellular water content, underlying the observed physiological and metabolic responses and the resurrection behavior of H. rhodopensis.

Project description:The effects of temperature on teleosts have been of strong interest for a long time, particularly because low temperature profoundly influences the physiological and behavioral processes of ectotherms, especially teleosts. However, the cold-tolerance characteristics of fish at a protein level remains unclear. Therefore, in order to shed further light on the molecular mechanisms of low temperature adaptation in fish, we conducted quantitative proteomics on T. fasciatus liver using iTRAQ. Comparing the proteomic profiles of the T. fasciatus liver at 12℃ and 26℃, a total of 3741 proteins were identified, and 160 were differentially expressed. Among the differentially expressed proteins, the most significant changes were noted in those involved in oxidative stress (nine proteins), mitochondrial enzymes (eleven proteins) and signal transduction (thirteen proteins). The KEGG enrichment analysis indicated significant enhancement of D-arginine and D-ornithine metabolism, MAPK signaling, Wnt signaling and Gap junction pathway. Subsequently, three significantly up-regulated (CIRB, HSP90 and GST) and two significantly down-regulated proteins (FLNB and A2ML1) were validated by the parallel reaction monitoring (PRM) assays. Furthermore, the changes in expression of proteins involved in the oxidative stress, mitochondrial enzymes and signal transduction were validated at the transcriptional level using qPCR. These verification results show that the experimental data of iTRAQ are reliable. Our results not only deepen an understanding of the mechanisms underlying low temperature tolerance in fish, but also may contribute to its breeding for enhancement of cold tolerance.

Project description:Calcium is an essential macronutrient and plant requires it in large amounts for normal growth and development. This ion participated in innumerable processes and affects nearly all aspects of plant growth and development such as signal transduction, metabolism of lipids, proteins, and carbohydrates, cell growth, cell wall and membrane stabilization. We used whole genome microarrays to determine the transcriptomic profile of rice seedlings exposed to short-term and long term Ca2+ deficiency followed by Ca2+ resupply. Calcium treated seedlings were used for for RNA extraction and hybridization on Agilent microarray platform. Three biological replicates of each sample were used for microarray analysis. We wanted to know the altered expression patterns of calcium-responsive genes majorly involved in metabolic processes, signal transdction pathways, transcriptional regulation, and transport of multiple molecules including Ca2+. Seeds of indica rice were surface sterilized and grown hydroponically in rice growing medium. Plants were grown in the rice growth room under the condition of 16 h light/8 h dark (28M-BM-0C) photoperiod with 70 % humidity. After 5 days of normal growth, some of the seedlings were transferred to nutrient solution lacking CaCl2 (-Ca2+). After 5 and 14 days, calcium (0.798 mM CaCl2) was resupplied to the plants grown in -Ca2+ medium for 6 h.

Project description:Nutrient-Regulated Antisense and Intragenic RNAs Modulate a Signal Transduction Pathway