Project description:gene expression was measured in five independent heat resistance selected replicate lines and five control lines. The genetic architecture underlying heat resistance remains partly unclear despite the well documented involvement of heat shock proteins (Hsps). It was previously shown that factors besides Hsps are likely to play an important role for heat resistance. In this study, gene expression arrays were used to make replicate measurements of gene expression before and up to 64h after a mild heat stress treatment, in flies selected for heat resistance and unselected control flies, to identify genes differentially expressed in heat resistance selected flies. We found 108 genes upregulated and 10 downregulated using the Affymetrix gene expression platform. Among the upregulated genes, a substantial number are involved in the phototransduction process. Another group of genes upregulated in selected flies is characterized by also responding to heat shock treatment several hours after peak induction of known Hsps revert to non-stress levels. These findings suggest phototransduction genes to be critically involved in heat resistance, and support a role for components of the phototransduction process in stress sensing mechanisms. In addition the results suggest yet uncharacterized genes responding to heat stress several hours after treatment to be involved in heat stress resistance. These findings mark an important increase in the understanding of heat resistance. see:; Cell Stress and Chaperones, vol. 11, Issue 4 (2006), pp 325-334,; DOI: 10.1379/CSC-207.1 Experiment Overall Design: gene expression was measured in five independent heat resistance selected replicate lines and five control lines

Project description:Gene expression was measured in control and heat resistance selected adult female flies before and at 8 time points after heat stress for 1h @ 36 degrees,Abstract The availability of full genome sequences has allowed the construction of microarrays, with which screening,of the full genome for changes in gene expression is possible. This method can provide a wealth of information about,biology at the level of gene expression and is a powerful method to identify genes and pathways involved in various,processes. In this study, we report a detailed analysis of the full heat stress response in Drosophila melanogaster,females, using whole genome gene expression arrays (Affymetrix Inc, Santa Clara, CA, USA). The study focuses on,up- as well as downregulation of genes from just before and at 8 time points after an application of short heat hardening,(368C for 1 hour). The expression changes were followed up to 64 hours after the heat stress, using 4 biological,replicates. This study describes in detail the dramatic change in gene expression over time induced by a short-term,heat treatment. We found both known stress responding genes and new candidate genes, and processes to be involved,in the stress response. We identified 3 main groups of stress responsive genes that were earlyâ??upregulated, earlyâ??,downregulated, and lateâ??upregulated, respectively, among 1222 differentially expressed genes in the data set. Comparisons,with stress sensitive genes identified by studies of responses to other types of stress allow the discussion of,heat-specific and general stress responses in Drosophila. Several unexpected features were revealed by this analysis,,which suggests that novel pathways and mechanisms are involved in the responses to heat stress and to stress in,general. The majority of stress responsive genes identified in this and other studies were downregulated, and the,degree of overlap among downregulated genes was relatively high, whereas genes responding by upregulation to heat,and other stress factors were more specific to the stress applied or to the conditions of the particular study. As an,expected exception, heat shock genes were generally found to be upregulated by stress in general.

Project description:gene expression was measured in control and heat resistance selected adult female flies before and at 8 time points after heat stress for 1h @ 36 degrees Abstract The availability of full genome sequences has allowed the construction of microarrays, with which screening of the full genome for changes in gene expression is possible. This method can provide a wealth of information about biology at the level of gene expression and is a powerful method to identify genes and pathways involved in various processes. In this study, we report a detailed analysis of the full heat stress response in Drosophila melanogaster females, using whole genome gene expression arrays (Affymetrix Inc, Santa Clara, CA, USA). The study focuses on up- as well as downregulation of genes from just before and at 8 time points after an application of short heat hardening (368C for 1 hour). The expression changes were followed up to 64 hours after the heat stress, using 4 biological replicates. This study describes in detail the dramatic change in gene expression over time induced by a short-term heat treatment. We found both known stress responding genes and new candidate genes, and processes to be involved in the stress response. We identified 3 main groups of stress responsive genes that were early–upregulated, early– downregulated, and late–upregulated, respectively, among 1222 differentially expressed genes in the data set. Comparisons with stress sensitive genes identified by studies of responses to other types of stress allow the discussion of heat-specific and general stress responses in Drosophila. Several unexpected features were revealed by this analysis, which suggests that novel pathways and mechanisms are involved in the responses to heat stress and to stress in general. The majority of stress responsive genes identified in this and other studies were downregulated, and the degree of overlap among downregulated genes was relatively high, whereas genes responding by upregulation to heat and other stress factors were more specific to the stress applied or to the conditions of the particular study. As an expected exception, heat shock genes were generally found to be upregulated by stress in general. Keywords: Time series

Project description:Environmental stress, such as oxidative or heat stress, induces the activation of the heat shock response (HSR) and leads to an increase in the heat shock proteins (HSPs) level. These HSPs act as molecular chaperones to maintain cellular proteostasis. Controlled by highly intricate regulatory mechanisms, having stress-induced activation and feedback regulations with multiple partners, the HSR is still incompletely understood. In this context, we propose a minimal molecular model for the gene regulatory network of the HSR that reproduces quantitatively different heat shock experiments both on heat shock factor 1 (HSF1) and HSPs activities. This model, which is based on chemical kinetics laws, is kept with a low dimensionality without altering the biological interpretation of the model dynamics. This simplistic model highlights the titration of HSF1 by chaperones as the guiding line of the network. Moreover, by a steady states analysis of the network, three different temperature stress regimes appear: normal, acute, and chronic, where normal stress corresponds to pseudo thermal adaption. The protein triage that governs the fate of damaged proteins or the different stress regimes are consequences of the titration mechanism. The simplicity of the present model is of interest in order to study detailed modelling of cross regulation between the HSR and other major genetic networks like the cell cycle or the circadian clock. Sivéry, A., Courtade, E., Thommen, Q. (2016). A minimal titration model of the mammalian dynamical heat shock response. Physical biology, 13(6), 066008.

Project description:A study evaluating the effect of stress resistance selection of Drosophila melanogaster. Abstract; Here, we report a detailed analysis of changes in gene expression in Drosophila melanogaster selected for multiple ecologically relevant environmental stress resistance traits. We analyzed females from three biological replicates from seven selection regimes and one control regime using whole genome gene expression arrays. Replicated selection lines were selected for resistance to acute heat survival, high temperature knock down, constant 30 degress C during development, cold shock survival, desiccation and starvation, respectively. Additionally, a set of replicated lines was selected for increased longevity. When compared to gene expression profiles of control lines, we were able to detect consistent selection responses at the transcript level in each specific selection regime and also found a group of differentially expressed genes that were generally changed among all selected lines. Replicated selection lines clustered together, i.e. showed similar changes in gene expression (compared to controls) and thus showed that 10 generations of artificial selection gives a clear signal among gene expression profiles. The changes in gene expression in lines selected for increased longevity, desiccation and starvation resistance, respectively, showed high similarities. Cold resistance selected lines showed little differentiation from controls. Different methods of heat selection (heat survival, heat knock down and constant 30 degrees C) showed little similarity verifying that different mechanism are involved in high temperature adaptation. The direction of change in gene expression in the selected lines showed a consistent pattern for each selection regime. For most selection regimes and in the comparison of all selected lines and controls exclusively up- or down regulation of gene expression among significant differentially expressed genes was found. The different responses to selection expressed in individual selection regimes and among all selected lines indicate that we have identified genes involved in stress specific and general stress response mechanisms. Experiment Overall Design: gene expression was measured in biological triplicates of control flies and flies selected for resistance to various stressors.

Project description:Heat shock proteins (Hsps) are molecular chaperones primarily involved in maintenance of protein homeostasis. Their function has been best characterized in heat stress (HS) response during which Hsps are transcriptionally controlled by heat stress transcription factors (Hsfs). The role of Hsfs and Hsps in HS-response in tomato was initially examined by transcriptome analysis using the Massive Analysis of cDNA Ends (MACE) method. Approximately 9.6% of all genes expressed in leaves are enhanced in response to HS, including a subset of Hsfs and Hsps. The underlying Hsp-Hsf networks with potential functions in stress responses or developmental processes were further explored by meta-analysis of existing microarray datasets. We identified clusters with differential transcript profiles with respect to abiotic stresses, plant organs and developmental stages. The composition of two clusters points toward two major chaperone networks. One cluster consisted of constitutively expressed plastidial chaperones and other genes involved in chloroplast protein homeostasis. The second cluster represents genes strongly induced by heat, drought and salinity stress, including HsfA2 and many stress-inducible chaperones, but also potential targets of HsfA2 not related to protein homeostasis. This observation attributes a central regulatory role to HsfA2 in controlling different aspects of abiotic stress response and tolerance in tomato. 2 samples

Project description:Heat shock proteins (Hsps) are molecular chaperones primarily involved in maintenance of protein homeostasis. Their function has been best characterized in heat stress (HS) response during which Hsps are transcriptionally controlled by heat stress transcription factors (Hsfs). The role of Hsfs and Hsps in HS-response in tomato was initially examined by transcriptome analysis using the Massive Analysis of cDNA Ends (MACE) method. Approximately 9.6% of all genes expressed in leaves are enhanced in response to HS, including a subset of Hsfs and Hsps. The underlying Hsp-Hsf networks with potential functions in stress responses or developmental processes were further explored by meta-analysis of existing microarray datasets. We identified clusters with differential transcript profiles with respect to abiotic stresses, plant organs and developmental stages. The composition of two clusters points toward two major chaperone networks. One cluster consisted of constitutively expressed plastidial chaperones and other genes involved in chloroplast protein homeostasis. The second cluster represents genes strongly induced by heat, drought and salinity stress, including HsfA2 and many stress-inducible chaperones, but also potential targets of HsfA2 not related to protein homeostasis. This observation attributes a central regulatory role to HsfA2 in controlling different aspects of abiotic stress response and tolerance in tomato.

Project description:Heat stress occurrence during endosperm development and seed filling forms chalky portion in the limited zone of starchy endosperm of rice grains. In this study, isolation of aleurone, dorsal, central and lateral tissues of developing endosperm by laser-microdissection (LM) coupled with gene expression analysis of 44K microarray was performed to identify key regulatory genes involved in the formation of milky-white (MW) and white-back (WB) chalky grains during heat stress. Gene regulatory network analysis classified the genes changed under heat stress into five modules. the modules of genes changed in developing starchy endosperm corresponding to MW and WB portion under heat stress suggested different regulatory genes involved in each type of grain chalk. The most distinct expression pattern was observed in a M1 and M2 modules where most of the small heat shock proteins and cellular organisation genes being upregulated under heat stress in dorsal aleurone cells and dorsal starchy endosperm zones The histological observation supported the significant increase in cell number and size of dorsal aleurone cells in WB grains. With regard to the central zone of starchy endosperm, preferential downregulation of high molecular weight heat shock proteins (HMW HSPs) including a prominent member encoding for endoplasmic reticulum (ER) chaperones by heat stress were observed, while expression of starch-biosynthesis genes remained unaffected. Characterization of transgenic plants supressing endosperm lumenal binding protein (BiP1), an ER chaperone preferentially downregulated at MW portion under heat stress, showed an evidence of forming the chalky grains without disturbing the expression of starch-biosynthesis genes. The present LM-based comprehensive expression analyses provides novel inferences that HMW HSPs play important role in controlling the redox, nitrogen and amino aicd metabolism in endosperm leading to the formation of MW and WB chalky grains.Keywords ; developing endosperm, gene expression, grain chalkiness, heat stress, laser-microdissection, Oryza sativa.

Project description:Epigenetic alteration is a hallmark of aging, but it remains unclear if perturbation of transcription machineries may affect longevity. NELF-mediated pausing of RNA polymerase II (RNAPII) constitutes an important step in transcription regulation. We found that halving NELF-A level in heterozygous mutants or via neuronal-specific depletion of NELF-A improves locomotor activity, stress resistance and lifespan of Drosophila significantly. Mechanistically, lower NELF-A releases paused RNAPII to facilitate productive transcription of the heat-shock protein (Hsp) genes. Elevated HSPs attenuate the level of protein aggregation, reactive oxidative species, DNA damage and systemic inflammation in the brains of NELF-A depleted flies. This protection is conserved in human cells where NELF-A depletion confers improved resistance against oxidative stress. Reduced oxidative DNA damage allows the maintenance of H3K9me2-enriched heterochromatin, which represses the activation of specific retrotransposons during aging. Therefore, by regulating transcription of Hsp genes in the brains, NELF-A controls multiple aspects of aging in Drosophila.

Project description:Pollen development is central for plant reproduction and is assisted by changes of the transcriptome and the proteome. At the same time, pollen is largely heat sensitive, particularly at early developmental stages. To define the changes during development and the response of different stages to elevated temperatures we investigated the transcriptome and proteome of pollen at tetrad, post-meiotic and mature stage before and after application of elevated temperatures. We used Solanum lycopersicum as an economically important crop. We demonstrate that the number of transcripts declines from tetrad to mature stage, while the protein content shows the opposite trend. Comparison of the transcriptome and proteome led to the discovery of two translational modes assigned as direct translation – transcripts increased in a specific pollen stage lead to increased translation in the same stage – and delayed translation – transcripts are produced for translation in later stages. The response to elevated temperatures is with ~5% of all genes being upregulated comparable to general plant behavior. The alteration at proteome level marked the mature pollen as least responsive and the post-meiotic stages as most responsive with altered levels of 40% of the identified proteins. For a subset of the genes with direct translation we observed a downregulation of protein levels after heat stress, whereas some of the genes with delayed translation showed a shift from delayed to direct translation when heat stress is applied. Further, Hsps, proteasome subunits, ribosomal proteins as well as eukaryotic initiation factors are the most drastically affected groups. On the example of Hsps we document that the response at transcriptome and proteome levels in e.g. the post-meiotic and mature stage does not correlate. Moreover, while all stages respond to heat stress with regulation of transcript abundance of Hsps in a comparable manner, changes at proteome level are distinct. Thus, we demonstrate that the difference in heat stress response in different stages of pollen development is rather manifested by significant changes of protein than transcript abundance.