Project description:Background Regulation of transcription is essential for any organism and Rhizobium etli (a multi-replicon, nitrogen-fixing symbiotic bacterium) is no exception. This bacterium is commonly found in the rhizosphere (free-living) or inside of root-nodules of the common bean (Phaseolus vulgaris) in a symbiotic relationship. Abiotic stresses, such as high soil temperatures and salinity, compromise the genetic stability of R. etli and therefore its symbiotic interaction with P. vulgaris. However, it is still unclear which genes are up- or down-regulated to cope with these stress conditions. The aim of this study was to identify the genes and non-coding RNAs (ncRNAs) that are differentially expressed under heat and saline shock, as well as the promoter regions of the up-regulated loci. Results Analysing the heat and saline shock responses of R. etli CE3 through RNA-Seq, we identified 756 and 392 differentially expressed genes, respectively, and 106 were up-regulated under both conditions. Notably, the set of genes over-expressed under either condition was preferentially encoded on plasmids, although this observation was more significant for the heat shock response. In contrast, during either saline shock or heat shock, the down-regulated genes were principally chromosomally encoded. Our functional analysis shows that genes encoding chaperone proteins were up-regulated during the heat shock response, whereas genes involved in the metabolism of compatible solutes were up-regulated following saline shock. Furthermore, we identified thirteen and nine ncRNAs that were differentially expressed under heat and saline shock, respectively, as well as eleven ncRNAs that had not been previously identified. Finally, using an in silico analysis, we studied the promoter motifs in all of the non-coding regions associated with the genes and ncRNAs up-regulated under both conditions. Conclusions Our data suggest that the replicon contribution is different for different stress responses and that the heat shock response is more complex than the saline shock response. In general, this work exemplifies how strategies that not only consider differentially regulated genes but also regulatory elements of the stress response provide a more comprehensive view of bacterial gene regulation.

Project description:Heat-shock (Temp43, 30min, 60 min)

Project description:RNA-Seq analysis of the multipartite genome of Rhizobium etli CE3 shows different replicon contributions under heat and saline shock

Project description:Drosophila S2 cells were treated with Heat-shock protein 90 (Hsp90) inhibitor radicicol for 15min, 30min and 1h. Poly(A) RNA was isolated and sequenced.

Project description:Heat shock response (HSR) is a cellular defense mechanism against various stresses. Both heat shock and proteasome inhibitor MG132 cause the induction of heat shock proteins, a distinct feature of HSR. To better understand the molecular basis of HSR, we subjected the mouse fibrosarcoma cell line, RIF-1, and its thermotolerant variant, TR-RIF-1 cells, to heat shock and MG132. We compared mRNA expressions using microarray analysis during recovery after heat shock and MG132 treatment. This study led us to group the 3,245 up-regulated genes by heat shock and MG132 into three families: genes regulated 1) by both heat shock and MG132 (e.g. chaperones); 2) by heat shock (e.g. DNA-binding proteins including histones); and 3) by MG132 (e.g. innate immunity and defense-related molecules).

Project description:RNA-seq profile of transgenic hindbrains expressing heat-shock induced constitutively activated fgfR1 (Tg(hsp70:ca-fgfr1)) and compared to heat-shocked counterparts Method: 22hpf embryos were heat-shocked for 30min at 38.5°C and then incubated for 2hr at 28.5°C . After hindbrains were microdissected and the RNA was extracted. fgfR1 overexpression was checked by qPCR and samples were selected for sequencing

Project description:Genome-wide transcription profiles analysis of the heat-shocked wild-type strain under moderate (40¡C) and severe heat stress (50¡C) revealed that a large number of genes are differentially expressed after heat shock. 358 genes were up-regulated and 420 were down-regulated in response to moderate heat shock 35 (40¡C) in C. glutamicum. Our results confirmed the HrcA/CIRCE-dependent and HspR/HAIR-dependent up-regulation of chaperones following heat shock. Other genes including COG groups related to macromolecule biosynthesis and several transcriptional regulators (COG class K) were up-regulated, explaining the large number of genes affected by heat shock. Mutants having deletions in the hrcA or hspR regulators were constructed, which allowed the complete identification of the genes controlled by those systems. The up- or down-regulation of several genes observed in the microarray experiments was validated by Northern analyses and quantitative (real-time) PCR. These analyses showed the heat shock intensity-dependent response (differential response) presented by the HspR/HAIR system, in contrast with the non-differential response shown by the HrcA/CIRCE-regulated genes.

Project description:Gene expression during stationary phase and symbiosis of R. etli CFN42 was compared to that of exponentially growing cells. This allowed us to better understand how R. etli adapts to a non-growing lifestyle, both the free-living and symbiotic state, as well as to determine to what extent this adaptation is similar in both states.

Project description:Voit2003 - Trehalose Cycle This model is described in the article: Biochemical and genomic regulation of the trehalose cycle in yeast: review of observations and canonical model analysis. Voit EO. J. Theor. Biol. 2003 Jul; 223(1): 55-78 Abstract: The physiological hallmark of heat-shock response in yeast is a rapid, enormous increase in the concentration of trehalose. Normally found in growing yeast cells and other organisms only as traces, trehalose becomes a crucial protector of proteins and membranes against a variety of stresses, including heat, cold, starvation, desiccation, osmotic or oxidative stress, and exposure to toxicants. Trehalose is produced from glucose 6-phosphate and uridine diphosphate glucose in a two-step process, and recycled to glucose by trehalases. Even though the trehalose cycle consists of only a few metabolites and enzymatic steps, its regulatory structure and operation are surprisingly complex. The article begins with a review of experimental observations on the regulation of the trehalose cycle in yeast and proposes a canonical model for its analysis. The first part of this analysis demonstrates the benefits of the various regulatory features by means of controlled comparisons with models of otherwise equivalent pathways lacking these features. The second part elucidates the significance of the expression pattern of the trehalose cycle genes in response to heat shock. Interestingly, the genes contributing to trehalose formation are up-regulated to very different degrees, and even the trehalose degrading trehalases show drastically increased activity during heat-shock response. Again using the method of controlled comparisons, the model provides rationale for the observed pattern of gene expression and reveals benefits of the counterintuitive trehalase up-regulation. To induce a heat shock, set the parameter heat_shock from 0 to 1. This changes the parameter values of X8 to X19 from 1 to the values given in table 3 of the original publication. As this is an S-systems model, it does not contain any reactions encoded in SBML. This model is hosted on BioModels Database and identified by: BIOMD0000000266. To cite BioModels Database, please use: BioModels Database: An enhanced, curated and annotated resource for published quantitative kinetic models. To the extent possible under law, all copyright and related or neighbouring rights to this encoded model have been dedicated to the public domain worldwide. Please refer to CC0 Public Domain Dedication for more information.

Project description:Drosophila S2 cells were treated with Heat-shock protein 90 (Hsp90) inhibitor radicicol for 15min, 30min and 1h. Poly(A) RNA was isolated and sequenced. Kinetics of transcriptional response to Hsp90 inhibition