Project description:The foodborne pathogen Listeria monocytogenes has the ability to develop biofilm in food-processing environment, which becomes a major concern for the food safety. PrfA, a key transcriptional activator that regulates most of the known listerial virulence gene expression, has been shown to promote L. monocytogenes biofilm formation. In this study, the whole genome microarray was used to identify differentially expressed genes associated with the putative interaction between biofilm formation and PrfA in L. monocytogenes. Comparative transcriptome analyses indicated over 21.9% of the L. monocytogenes EGDe genes (627 out of 2857 predicted) were altered in their expression in biofilm cells relative to planktonic cell populations. These genes were classed into different functional categories which cover most of the biochemical functions encountered in bacterial cells, especially involved in ion transport, DNA repair, and cell wall biosynthesis based on significant enrichment of GO terms. Among them, 185 genes were identified to be associated with PrfA and biofilm formation by comparison of the whole gene expression profiles of L. monocytogenes EGDe and its ΔprfA mutant. The expression tendency of these PrfA-associated and biofilm-specific genes were mainly opposite in ΔprfA biofilm, and most of them are involved in phage-related function, membrane bioenergetics, and cell wall. Our results indicated that L. monocytogenes biofilm formation is probably controlled by the complex regulation network involved variable genes required for the different biological pathways. This regulatory network is modified in the prfA deletion mutant in order to maintain its stable biofilm lifestyle.

Project description:The foodborne pathogen Listeria monocytogenes has the ability to develop biofilm in food-processing environment, which becomes a major concern for the food safety. PrfA, a key transcriptional activator that regulates most of the known listerial virulence gene expression, has been shown to promote L. monocytogenes biofilm formation. In this study, the whole genome microarray was used to identify differentially expressed genes associated with the putative interaction between biofilm formation and PrfA in L. monocytogenes. Comparative transcriptome analyses indicated over 21.9% of the L. monocytogenes EGDe genes (627 out of 2857 predicted) were altered in their expression in biofilm cells relative to planktonic cell populations. These genes were classed into different functional categories which cover most of the biochemical functions encountered in bacterial cells, especially involved in ion transport, DNA repair, and cell wall biosynthesis based on significant enrichment of GO terms. Among them, 185 genes were identified to be associated with PrfA and biofilm formation by comparison of the whole gene expression profiles of L. monocytogenes EGDe and its M-NM-^TprfA mutant. The expression tendency of these PrfA-associated and biofilm-specific genes were mainly opposite in M-NM-^TprfA biofilm, and most of them are involved in phage-related function, membrane bioenergetics, and cell wall. Our results indicated that L. monocytogenes biofilm formation is probably controlled by the complex regulation network involved variable genes required for the different biological pathways. This regulatory network is modified in the prfA deletion mutant in order to maintain its stable biofilm lifestyle. Gene expression of planktonic cells and biofilm cells in Listeria monocytogenes EGDe and prfA isogenic deletion strain EGDeM-NM-^TprfA with cultivated in MEM and BHI for 48 hours, were mesasued using Agilent Listeria monocytogenes customized whole-genome microarray 8x15 array. Three replicates.

Project description:The formation of Listeria monocytogenes biofilms contributes to persistent contamination in food processing facilities. A microarray comparison of L. monocytogenes between the transcriptome of the strong biofilm forming strain (Bfms) Scott A and the weak biofilm forming (Bfmw) strain F2365 was conducted to identify genes potentially involved in biofilm formation. Among 951 genes with significant difference in expression between the two strains, a GntR-family response regulator encoding gene (LMOf2365_0414), designated lbrA, was found to be highly expressed in Scott A relative to F2365. A Scott A lbrA-deletion mutant, designated AW3, formed biofilm to a much lesser extent as compared to the parent strain by a rapid attachment assay and scanning electron microscopy. Complementation with lbrA from Scott A restored the Bfms phenotype in the AW3 derivative. A second microarray assessment using the lbrA deletion mutant AW3 and the wild type Scott A revealed a total of 304 genes with expression significantly different between the two strains, indicating the potential regulatory role of LbrA in L. monocytogenes. A cloned copy of Scott A lbrA was unable to confer enhanced biofilm forming potential in F2365, suggesting that additional factors contributed to weak biofilm formation by F2365. Findings from the study may lead to new strategies to modulate biofilm formation. Two comparisons were performed between 1) strong biofilm former Listeria monocytogenes strain ScottA versus weak biofilm former Listeria monocytogenes strain F2365; 2) Listeria monocytogenes ScottA LbrA deletion mutant strain versus Listeria monocytogenes ScottA. Four replicates were loaded for the first comparison and two replicates were loaded for the second comparison.

Project description:To understand the behaviour in terms of special genome components that are expressed by L.monocytogenes in the presence of another bacterium as may be the condition in its natural environments was our objective, for which we have used microarray gene expression at different time intervals of growth from 4hrs to 24 hrs. Expression of L.monocytogenes as co-cultures, both in broth culture state and biofilm state were differentiated to that of 24hrs pure broth culture. Also genes regulated for and during biofilm formation as pure cultures were identified with comparision to 24hrs pure broth culture. Distinguishing features with notable variation in all of the three sample sets as L.monocytogenes in pure culture biofilm, co-culture broth and co-culture biofilm were observable. Genes that are specifically up-regulated at each of growth condition and time interval were identified, genes regulated with ascending and descending patterns in time were also noticable. These variation in the gene expression gives an insight into the alterations in the biosynthetic and metabolic pathways under different states of growth Agilent one-color experiment,Organism: Listeria monocytogenes , Genotypic Technology Pvt. Ltd. designed Custom Microarray Listeria monocytogenes 8x15k (Agilent-30831) , Labeling kit: Agilent Quick-Amp labeling Kit (p/n5190-0442)

Project description:The formation of Listeria monocytogenes biofilms contributes to persistent contamination in food processing facilities. A microarray comparison of L. monocytogenes between the transcriptome of the strong biofilm forming strain (Bfms) Scott A and the weak biofilm forming (Bfmw) strain F2365 was conducted to identify genes potentially involved in biofilm formation. Among 951 genes with significant difference in expression between the two strains, a GntR-family response regulator encoding gene (LMOf2365_0414), designated lbrA, was found to be highly expressed in Scott A relative to F2365. A Scott A lbrA-deletion mutant, designated AW3, formed biofilm to a much lesser extent as compared to the parent strain by a rapid attachment assay and scanning electron microscopy. Complementation with lbrA from Scott A restored the Bfms phenotype in the AW3 derivative. A second microarray assessment using the lbrA deletion mutant AW3 and the wild type Scott A revealed a total of 304 genes with expression significantly different between the two strains, indicating the potential regulatory role of LbrA in L. monocytogenes. A cloned copy of Scott A lbrA was unable to confer enhanced biofilm forming potential in F2365, suggesting that additional factors contributed to weak biofilm formation by F2365. Findings from the study may lead to new strategies to modulate biofilm formation.

Project description:Listeria monocytogenes (Lm) cells can attach to both cantaloupe surface and food contact surfaces and promote biofilm growth. This study was to understand the impact of cantaloupe juice on the physiology and transcriptome of Lm planktonic cells and biofilm cells grown on stainless steel coupons using confocal laser scanning microscopy (CLSM), Cryo-Scanning Electron Microscopy (Cryo-SEM) and RNA Seq technology. Lm showed a strong autoaggregation phenotype when grown in cantaloupe juice at room temperature. It is interesting to note that Lm formed significantly more biofilms on stainless steel (SS) coupons when grown in cantaloupe juice than in TSB. SEM images revealed a different attachment profile of Lm on SS coupons. In TSB, Lm cells were mainly found in scratches/groves of the metal surface, whereas, in cantaloupe juice they attached to the smooth surface as well. Interestingly, Lm planktonic and biofilm cells in cantaloupe juice showed an elongated cell shape which might be a stress-induced phenotype in cantaloupe juice. Cantaloupe juice induced a distinct transcriptional profile of biofilm and planktonic cells of Lm from TSB. Functional annotation indicated that the significantly differentially expressed genes (DEGs, Padj < 0.05, log2foldchange ≥ 1) from the comparison mainly participated in metabolism, signaling and stress response. Notably, certain pathways downregulated for planktonic cells were significantly upregulated for biofilm cells in cantaloupe juice compared to TSB, including ABC transporters, two-component system, quorum sensing, chemotaxis, and flagellar assembly. These data highlighted the interaction of Lm with food matrix (i.e., cantaloupe) and the role of food matrix on Lm survival and adaptation. These results provided the basis for future functional characterization of genes with potential roles in biofilm formation and persistence of Lm in cantaloupe juice, as well as for development of mitigation practices for Lm biofilms on produce and food contact surfaces.

Project description:Persistence of Listeria monocytogenes in retail deli environments is a serious food safety issue, potentially leading to cross-contamination of ready-to-eat foods such as deli meats, salads, and cheeses. We previously discovered strong evidence of L. monocytogenes persistence in delis across multiple states. We hypothesized that this was correlated with isolates’ innate characteristics, such as biofilm-forming capacity or gene differences.We further chose four isolates for RNA-sequencing analysis and compared their global biofilm transcriptome to their global planktonic transcriptome. Analysis of biofilm vs planktonic gene expression did not show the expected differences in gene expression patterns. Overall, L. monocytogenes persistence in the deli environment is likely a matter of poor sanitation and/or facility design, rather than isolates’ biofilm-forming capacity, sanitizer tolerance, or genomic content

Project description:Exploiting genomic differences between Listeria monocytogenes EGDe isolates reveals crucial roles for SigB and wall rhamnosylation in biofilm formation.

Project description:Genetic variation is regarded as a prerequisite for evolution. Theoretical models suggest epigenetic information inherited independently of DNA sequence can also enable evolution. However, whether epigenetic inheritance mediates phenotypic evolution in natural populations is unknown. Here we show that natural epigenetic DNA methylation variation in gene bodies regulates genes expression, and thereby influences the natural variation of complex traits in Arabidopsis thaliana. Notably, the effects of methylation variation on phenotypic diversity and gene expression variance are comparable with those of DNA sequence polymorphism. We also identify methylation epialleles in numerous genes associated with environmental conditions in native habitats, suggesting that intragenic methylation facilitates adaptation to fluctuating environments. Our results demonstrate that methylation variation fundamentally shapes phenotypic diversity in natural populations and provides an epigenetic basis for adaptive Darwinian evolution independent of genetic polymorphism.

Project description:Cellular adaptation during biofilm formation in Gram positive bacteria