Project description:A screening process was used to determine hyperosmotic as well as cold stress tolerance of a diverse set of Listeria monocytogenes strains and was based on the capacity to grow at sub lethal levels of NaCl and 4°C. Analysis of gene expression in cells adapted to cold and hyperosmotic stress revealed significant strain specificity in terms of individual gene expression profiles though general patterns of expression within functional gene subsets were largely similar. . Strain ATCC19115 revealed 150 significantly up- and 146 down-regulated genes in cells adapted to both hyperosmotic and cold stress, 82 up- and 56 down-regulated genes were matching in response to both stresses in strain 70-1700, whereas ScottA, a relatively stress-tolerant strain, showed up-regulation of 77 genes whilst 106 genes were significantly down-regulated. Among these homologously expressed genes only 22 were found to be significantly up-regulated and only 7 were down-regulated in all three strains adapted to hyperosmotic stress and cold temperature, suggesting a dominating strain specific response. Overall adaptation to hyperosmotic and low temperature growth conditions in three L. monocytogenes strains were found to have many parallels, especially when examined using a statistically-based ontological approach. Evidence was presented for strong activation of genes associated with protein synthesis, in particular those coding proteins of the ribosome and involved directly in transcription. Genes associated with DNA maintenance; modification to cell envelope, and cell division were also up-regulated. On the other hand strong suppression of genes associated with carbohydrate metabolism and transport as well as flagella assembly was evident in stress adapted cells most likely due to energy preservation via CodY regulon. This suggests that adaptation to these adverse conditions engages similar mechanisms to cope with the induced stressful environments. The microarray component of the experiments had the aim of determining: i) To examine the gene expression responses of three L. monocytogenes strains that had different intrinsic salt resistances following adaptation to hyperosmotic stress. ii) To examine the gene expression responses of three L. monocytogenes strains that had different intrinsic cold tolerances following adaptation to cold stress. iii) To evaluate common pathways of adaptation to hyperosmotic and cold stresses

Project description:Survival of the foodborne pathogen Listeria monocytogenes in acidic environments (e.g., stomach and low pH foods) is vital to its transmission. L. monocytogenes grows at temperatures as low as 2°C, and refrigerated, ready-to-eat foods have been sources of L. monocytogenes outbreaks. The purpose of this study was to determine whether growth at a low temperature (i.e., 7°C) affects the response of L. monocytogenes to sudden acid shock.

Project description:Mrakia psychrophlila is a psychrophilic fungus widely spread all over the world. The cold adaptation mechanism of Mrakia psychrophila is unknown. Using RNA sequencing, differentially expressed genes of Mrakia psychrophila cultured at 4, 12 and 20 degree centigrade are identified. The result may be benefit for understanding cold adaptation of microorganisms.

Project description:Different populations of the same species survive different environments through local adaptation. Temperature is one of the most important driving forces that could result in local adaptation. Here, we studied the influence of extreme low temperature on the survival of two genetically and geographically distinct populations of the free-living Caenorhabditis briggsae. We found that Caenorhabditis briggsae strains of temperate origin had a cold resistant phenotype, while those originating from a tropical climate had reduced survival after cold treatment. Using this phenotypic difference between geographically diverse populations as a model for how species adapt to their local environment, we then analyzed the transcriptional profiles of two Caenorhabditis briggsae strains of tropical and temperate origin to find genes that are involved in survival after extreme cold. In summary, the response to the extreme low temperature that clearly distinguishes the temperate and tropical Caenorhabditis briggsae strains could serve as an excellent example for studying local adaption of species that show genetic separation associated with their geographical distribution.

Project description:A screening process was used to determine hyperosmotic as well as cold stress tolerance of a diverse set of Listeria monocytogenes strains and was based on the capacity to grow at sub lethal levels of NaCl and 4M-BM-0C. Analysis of gene expression in cells adapted to cold and hyperosmotic stress revealed significant strain specificity in terms of individual gene expression profiles though general patterns of expression within functional gene subsets were largely similar. . Strain ATCC19115 revealed 150 significantly up- and 146 down-regulated genes in cells adapted to both hyperosmotic and cold stress, 82 up- and 56 down-regulated genes were matching in response to both stresses in strain 70-1700, whereas ScottA, a relatively stress-tolerant strain, showed up-regulation of 77 genes whilst 106 genes were significantly down-regulated. Among these homologously expressed genes only 22 were found to be significantly up-regulated and only 7 were down-regulated in all three strains adapted to hyperosmotic stress and cold temperature, suggesting a dominating strain specific response. Overall adaptation to hyperosmotic and low temperature growth conditions in three L. monocytogenes strains were found to have many parallels, especially when examined using a statistically-based ontological approach. Evidence was presented for strong activation of genes associated with protein synthesis, in particular those coding proteins of the ribosome and involved directly in transcription. Genes associated with DNA maintenance; modification to cell envelope, and cell division were also up-regulated. On the other hand strong suppression of genes associated with carbohydrate metabolism and transport as well as flagella assembly was evident in stress adapted cells most likely due to energy preservation via CodY regulon. This suggests that adaptation to these adverse conditions engages similar mechanisms to cope with the induced stressful environments. The microarray component of the experiments had the aim of determining: i) To examine the gene expression responses of three L. monocytogenes strains that had different intrinsic salt resistances following adaptation to hyperosmotic stress. ii) To examine the gene expression responses of three L. monocytogenes strains that had different intrinsic cold tolerances following adaptation to cold stress. iii) To evaluate common pathways of adaptation to hyperosmotic and cold stresses Control cultures (four biological replicates; exception strain ATCC19115 for the 10%NaCl stress which had three biological replicates) were labeled with Cy3 (exception strain ATCC19115 for the 10%NaCl-3 dyeswapped, where the control was labeled with Cy5 and sample with Cy3) for each treatment sample for three different L. monocytogenes strains. Sample cultures (four biological replicates; exception strain ATCC19115 for the 10%NaCl which had three biological replicates) were labeled with Cy5 (exception strain ATCC19115 for the 10%NaCl-3 dyeswapped, where the control was labeled with Cy5 and sample with Cy3) for each treatment sample for three different L. monocytogenes strains. Condition one M-bM-^@M-^Ssub-lethal hyperosmotic stress: Control culture (Cy3-labelled RNA, except ATCC19115 for the 10%NaCl-3 dyeswapped , where the control was labeled with Cy5 and sample with Cy3) - strains were grown to mid exponential growth phase at 25M-BM-0C (in a shaking water bath) in brain-heart infusion broth. Test cultures (Cy5-labelled RNA, except ATCC19115 for the 10%NaCl-3 dyeswapped , where the control was labeled with Cy5 and sample with Cy3) M-bM-^@M-^S strains grown to mid exponential growth at 25M-BM-0C phase (in a shaking water bath) in BHI broth supplemented with 8% additional NaCl (strain 701700), 10% additional NaCl (strain ATCC19115) or 12% additional NaCl (ScottA). Condition two M-bM-^@M-^S cold stress: Control culture (Cy3-labelled RNA) - strains were grown to mid exponential growth phase at 25M-BM-0C (in a shaking water bath) in brain-heart infusion broth. Test cultures (Cy5-labelled RNA) M-bM-^@M-^S strains grown to exponential growth phase at 4M-BM-0C in BHI broth.

Project description:Sweetpotato (Ipomoea batatas L.) is a globally important economic food crop. It belongs to Convolvulaceae family and origins in the tropics; however, sweetpotato is sensitive to cold stress during storage. In this study, we performed transcriptome sequencing to investigate the sweetpotato response to chilling stress during storage. A total of 110,110 unigenes were generated via high-throughput sequencing. Differentially expressed genes (DEGs) analysis showed that 18,681 genes were up-regulated and 21,983 genes were down-regulated in low temperature condition. Many DEGs were related to the cell membrane system, antioxidant enzymes, carbohydrate metabolism, and hormone metabolism, which are potentially associated with sweetpotato resistance to low temperature. The existence of DEGs suggests a molecular basis for the biochemical and physiological consequences of sweetpotato in low temperature storage conditions. Our analysis will provide a new target for enhancement of sweetpotato cold stress tolerance in postharvest storage through genetic manipulation.

Project description:CCA-adding enzymes are highly specific RNA polymerases that synthesize and maintain the sequence CCA at the tRNA 3‘-end. Here, we investigated the impact of cold adaptation on the reactivity and specificity of CCA-adding enzymes from psychrophilic bacteria. A comparative study of the corresponding enzymes from closely related psychro-, meso-, and thermophilic Bacillales indicates that the cold-adapted enzymes show a considerable error rate during CCA synthesis, resulting in additional incorporations of C and A residues. It seems that the activity of psychrophilic CCA-adding enzymes is not only achieved at the expense of structural stability, reaction velocity and substrate affinity, but also results in a reduced polymerization fidelity.

Project description:It is well established that Staphylococcus aureus can incorporate exogenous straight-chain unsaturated fatty acids (SCUFAs) into membrane phospho- and glyco-lipids from various sources in supplemented culture media, and when growing in vivo in an infection. Given the enhancement of membrane fluidity when oleic acid (C18:1(9z)) is incorporated into lipids, we were prompted to examine the effect of medium supplementation with C18:1(9z) on growth at low temperatures. C18:1(9z) supported the growth of a cold-sensitive, branched-chain fatty acid (BCFA)-deficient mutant at 12C. Interestingly, we found similar results in the BCFA-sufficient parental strain. We show that incorporation of C18:1(9z) and its elongation product C20:1(9z) into membrane lipids was required for growth stimulation and relied on a functional FakAB incorporation system. Lipidomics analysis of the phosphatidylglycerol (PG) and diglycosyldiacylglycerol (DGDG) lipid classes revealed major impacts of C18:1(9z) and temperature on lipid species. Growth at 12C in the presence of C18:1(9z) also led to increased production of the carotenoid pigment staphyloxanthin; however, this was not an obligatory requirement for cold adaptation. Enhancement of growth by C18:1(9z) is an example of homeoviscous adaptation to low temperatures utilizing an exogenous fatty acid. This may be significant in the growth of S. aureus at low temperatures in foods that commonly contain C18:1(9z) and other SCUFAs in various forms.

Project description:Survival of the foodborne pathogen Listeria monocytogenes in acidic environments (e.g., stomach and low pH foods) is vital to its transmission. L. monocytogenes grows at temperatures as low as 2M-BM-0C, and refrigerated, ready-to-eat foods have been sources of L. monocytogenes outbreaks. The purpose of this study was to determine whether growth at a low temperature (i.e., 7M-BM-0C) affects the response of L. monocytogenes to sudden acid shock. A full genome microarray was used to determine changes in L. monocytogenes 10403S gene expression after exposure to acidified brain-heart infusion (BHI; pH 3.5) for 5 or 15 min. To determine changes in gene transcription after acid treatment, separate competitive hybridizations were performed between cDNA from untreated cells (grown at 7M-BM-0C or 37M-BM-0C to log or stationary phase) and (i) cells acid treated for 5 min or (ii) cells acid treated for 15 min. For L. monocytogenes grown to log or stationary phase, competitive hybridizations were performed between total cDNA from non-acid-treated cells grown to 7M-BM-0C and non-acid-treated cells grown to 37M-BM-0C to determine baseline differences in gene transcription between growth temperatures prior to acid treatment. For each experiment, four biological replications were completed. Hybridizations were carried out with dye swapping (i.e., for each comparison, each cDNA from each condition was labeled with each dye exactly twice) to help minimize dye incorporation bias.

Project description:Understanding the mechanism of low temperature (LT) adaptation is crucial to the development of cold-tolerant crops. To identify the genes involved in the development of LT tolerance in the crown of hexaploid wheat we examined the global changes in genes expression during cold-treatment using the Affymetrix Wheat Genome Chip.