Project description:The global regulator, H-NS, controls genes related to stress response, biofilm formation, and virulence expression by recognizing the curved DNA and silences gene transcription acquired from lateral gene transfer. Here, we rewired H-NS to control biofilm formation using protein engineering. One H-NS variant, H-NS K57N was obtained to reduce biofilm formation 10-fold compared to H-NS wild-type. Whole-transcriptome analysis (BW25113 hha hns / pCA24N-hns K57N vs. BW25113 hha hns / pCA24N-hns) revealed that H-NS K57N represses biofilm formation through the interactinon with other nucleoid proteins, Cnu and StpA. Remarkably, H-NS K57N enhanced the excision of defective prophage Rac while H-NS wild-type represses it, and H-NS controlled only Rac excision among E. coli prophages. These results imply that the repression of Rac excision is one of the silencing manner for foreign genes by H-NS. Also, the prophage excision not only led to the change of biofilm formation but also resulted in cell lysis through the expression of toxin protein HokD with reduced viability, which are important for cell physiology in response to the change of environmental conditions. Hence, H-NS regulatory system may be evolved easily with specialized functions in terms of biofilm formation, prophage control, and cell lysis. For the whole transcriptome study of BW25113 hha hns / pCA24N-hns K57N versus BW25113 hha hns / pCA24N-hns, cells were grown in 250 mL LB containing 1 mM IPTG for 7 h with 10 g of glass wool (Corning Glass Works, Corning, N.Y.) in 1 L Erlenmeyer flasks to form a robust biofilm. Biofilm cells were obtained by rinsing and sonicating the glass wool in sterile 0.85% NaCl solution at 0°C, and RNALater buffer® (Applied Biosystems, Foster City, CA) was added for RNA stabilization and protection during the RNA preparation steps. Total RNA was isolated from biofilm cells. The E. coli GeneChip Genome 2.0 array (Affymetrix, Lot# 4059655) containing 10,208 probe sets for four E. coli strains (MG1655, CFT073, O157:H7-Sakai, and O157:H7-EDL933) was used for DNA microarray. cDNA synthesis, fragmentation, and hybridizations were performed.

Project description:Previously, we discovered that the global regulator Hha is related to cell death in biofilms and regulates cryptic prophage genes. Here we show Hha induces excision of prophage CP4-57 and DLP12 by inducing excision genes and by reducing SsrA synthesis. SsrA is a tmRNA important for rescuing stalled ribosomes, contains an attachment site for CP4-57, and is shown here to be required for CP4-57 excision. These prophages impact biofilm development as deletion of 35 genes individually of prophage CP4-57 and DLP12 increase biofilm formation up to 17-fold, and 5 genes decrease biofilm formation up to 6-fold. In addition, CP4-57 excises during early biofilm development but not in planktonic cells, whereas DLP12 excision was detected at all the developmental stages for both biofilm and planktonic cells. CP4-57 excision leads to a chromosome region devoid of the prophage and formation of a phage circle (which is lost). These results were corroborated by a whole-transcriptome analysis that showed that complete loss of CP4-57 activated expression of the flg, flh, and fli motility operons and repressed expression of key enzymes in the tricarboxylic acid cycle and enzymes for lactate utilization. Prophage excision also results in the expression of cell lysis genes that reduce cell viability (e.g., alpA, intA, and intD). Hence, defective prophage are involved in host physiology via Hha and in biofilm formation by generating a diversified population with specialized functions in terms of motility and nutrient metabolism.

Project description:Previously, we discovered that the global regulator Hha is related to cell death in biofilms and regulates cryptic prophage genes. Here we show Hha induces excision of prophage CP4-57 and DLP12 by inducing excision genes and by reducing SsrA synthesis. SsrA is a tmRNA important for rescuing stalled ribosomes, contains an attachment site for CP4-57, and is shown here to be required for CP4-57 excision. These prophages impact biofilm development as deletion of 35 genes individually of prophage CP4-57 and DLP12 increase biofilm formation up to 17-fold, and 5 genes decrease biofilm formation up to 6-fold. In addition, CP4-57 excises during early biofilm development but not in planktonic cells, whereas DLP12 excision was detected at all the developmental stages for both biofilm and planktonic cells. CP4-57 excision leads to a chromosome region devoid of the prophage and formation of a phage circle (which is lost). These results were corroborated by a whole-transcriptome analysis that showed that complete loss of CP4-57 activated expression of the flg, flh, and fli motility operons and repressed expression of key enzymes in the tricarboxylic acid cycle and enzymes for lactate utilization. Prophage excision also results in the expression of cell lysis genes that reduce cell viability (e.g., alpA, intA, and intD). Hence, defective prophage are involved in host physiology via Hha and in biofilm formation by generating a diversified population with specialized functions in terms of motility and nutrient metabolism. Experiment Overall Design: Strain: CP4-57-deficient vs. wild-type Experiment Overall Design: Medium: LB Experiment Overall Design: Culture type:OD=0.5, planktonic cells

Project description:Bacterial genomes encode in many instances more than one copy of genes coding for global modulators. In the Enterobacteriaceae, cells express the global modulator H-NS and its paralogue StpA. The enteroaggregative E. coli strain 042 encodes, in addition to the hns and stpA genes, an additional hns gene. We used RNA-seq to compare the transcriptome of the wt strain and its hns, hns2 and double hns hns2 derivatives, as well as of an hha null mutant (hhahha2). It is well known that the Hha protein co-modulates gene expression with H-NS. The results obtained have shown that the main role of H-NS2 is to modulate a subset of H-NS modulated genes, those that also are targeted by Hha, which are mainly HGT genes. When compared with H-NS, H-NS2 also shows a differential expression level and a different regulatory pattern.

Project description:The global transcriptional regulator Hha of Escherichia coli controls hemolysin activity, biofilm formation, and virulence expressions. Earlier, we have reported that Hha represses initial biofilm formation and disperses biofilms as well as controls prophage excision in E. coli. Since biofilm dispersal is a promising area to control biofilms, here we rewired Hha to control biofilm dispersal and formation. The Hha variant Hha13D6 was obtained to have enhanced biofilm dispersal activity along with increased toxicity compared to wild-type Hha (Hha13D6 induces dispersal 60%, whereas wild-type Hha induces dispersal at early biofilms but not at mature biofilms). Toxic Hha13D6 caused cell death probably by the activation of proteases HslUV, Lon, and PrlC, and deletion of protease gene hslV with overproducing Hh13D6 repressed biofilm dispersal, indicating Hha13D6 induces biofilm dispersal through the activity of protease HslV. Furthermore, another Hha variant Hha24E9 was also obtained to decrease biofilm formation 4-fold compared to wild-type Hha by regulation of gadW, glpT, and phnF. However, the dispersal variant Hha13D6 did not decrease biofilm formation, while the biofilm variant Hha24E9 did not induce biofilm dispersal. Hence, Hha may have evolved two ways in response to environmental factors to control biofilm dispersal and formation, but both controlling mechanisms come from different regulatory systems.

Project description:Clinical isolates of the porcine pathogen Actinobacillus pleuropneumoniae often form adherent colonies on agar plates due to expression of an operon, pgaABCD, encoding a poly-N-acetylglucosamine (PGA) extracellular matrix. The adherent colony phenotype, which correlates with the ability to form a biofilm on the surface of polystyrene plates, is lost following serial passage in broth culture, and repeated passage of the non-adherent variants on solid media does not result in reversion to the adherent colony phenotype. In order to investigate the regulation of PGA expression and biofilm formation in A. pleuropneumoniae, we screened a bank of transposon mutants of the non-adherent serovar 1 strain, S4074T, and identified mutations in two genes, rseA and hns, which resulted in formation of the adherent colony phenotype. In other bacteria, including the Enterobacteriaceae, H-NS acts as a global gene regulator, and RseA is a negative regulator of the extracytoplasmic stress response sigma factor, ?E. Transcription profiling of A. pleuropneumoniae rseA and hns mutants revealed that both ?E and H-NS independently regulate expression of the pga operon. Transcription of the pga operon is initiated from a ?E promoter site in the absence of H-NS, and up-regulation of ?E is sufficient to displace H-NS, allowing transcription to proceed. In A. pleuropneumoniae, H-NS does not act as a global gene regulator, but rather specifically regulates biofilm formation via repression of the pga operon. Positive regulation of the pga operon by ?E indicates that biofilm formation in is part of the extracytoplasmic stress response in A. pleuropneumoniae.

Project description:The global transcriptional regulator Hha of Escherichia coli controls hemolysin activity, biofilm formation, and virulence expressions. Earlier, we have reported that Hha represses initial biofilm formation and disperses biofilms as well as controls prophage excision in E. coli. Since biofilm dispersal is a promising area to control biofilms, here we rewired Hha to control biofilm dispersal and formation. The Hha variant Hha13D6 was obtained to have enhanced biofilm dispersal activity along with increased toxicity compared to wild-type Hha (Hha13D6 induces dispersal 60%, whereas wild-type Hha induces dispersal at early biofilms but not at mature biofilms). Toxic Hha13D6 caused cell death probably by the activation of proteases HslUV, Lon, and PrlC, and deletion of protease gene hslV with overproducing Hh13D6 repressed biofilm dispersal, indicating Hha13D6 induces biofilm dispersal through the activity of protease HslV. Furthermore, another Hha variant Hha24E9 was also obtained to decrease biofilm formation 4-fold compared to wild-type Hha by regulation of gadW, glpT, and phnF. However, the dispersal variant Hha13D6 did not decrease biofilm formation, while the biofilm variant Hha24E9 did not induce biofilm dispersal. Hence, Hha may have evolved two ways in response to environmental factors to control biofilm dispersal and formation, but both controlling mechanisms come from different regulatory systems. For the whole-transcriptome study of BW25113 hha/pCA24N-hha13D6 versus BW25113 hha/pCA24N-hha biofilm dispersal, cells were grown in 250 mL of LB glucose (0.2%) for 16 h at 125 rpm with 10 g of glass wool (Corning Glass Works, Corning, NY, USA) in 1 L Erlenmeyer flasks to form a robust biofilm (Ren et al., 2004) and incubated an additional 1 h with 1 mM IPTG to induce wild-type Hha and Hha13D6. Similarly, for the whole transcriptome study of BW25113 hha/pCA24N-hha24E9 versus BW25113 hha/pCA24N-hha biofilm formation, cells were grown in 250 mL of LB glucose (0.2%) containing 1 mM IPTG for 7 h at 250 rpm with 10 g of glass wool to form biofilms. Biofilm cells were obtained by rinsing and sonicating the glass wool in sterile 0.85% NaCl solution at 0°C, and RNALater buffer® (Applied Biosystems, Foster City, CA, USA) was added to stabilize RNA during the RNA preparation steps. Total RNA was isolated from biofilm cells using a bead beater (Biospec, Bartlesville, OK, USA). cDNA synthesis, fragmentation, and hybridizations to the E. coli GeneChip Genome 2.0 array (Affymetrix, Santa Clara, CA, USA; P/N 511302). Genes were identified as differentially expressed if the expression ratio was higher than the standard deviation: 2.0-fold (induced and repressed) cutoff for Hha13D6 DNA microarrays (standard deviation 1.3-fold) and 10.0-fold (induced) or 4.0-fold (repressed) for Hha24E9 DNA microarrays (standard deviation 4.0-fold), and if the p-value for comparing two chips was less than 0.05.

Project description:Aggregatibacter actinomycetemcomitans is a Gram-negative organism, strongly associated with aggressive forms of periodontitis. An important virulence property of A. actinomycetemcomitans is its ability to form tenacious biofilms that can attach to abiotic as well as biotic surfaces. The histone-like (H-NS) family of nucleoid structuring proteins act as transcriptional silencers in many Gram-negative bacteria. To evaluate the role of H-NS in A. actinomycetemcomitans, hns mutant derivatives of the serotype a strain D7S were generated. Characteristics of the hns mutant phenotype included shorter and fewer pili, which were accompanied by substantially lower biofilm formation relative to the wild type. In accordance with this observation, the D7S hns mutant exhibited significantly reduced growth within a seven-species biofilm model. However, no apparent difference was observed regarding the numbers and proportions of the remaining six species in the biofilm regardless co-cultivated with D7S hns or its parental strain. Proteomics analysis of the strains grown in monocultures confirmed the role of H-NS as a repressor of gene expression in A. actinomycetemcomitans. Interestingly, proteomics analysis of the multispecies biofilms indicated that the A. actinomycetemcomitans wildtype and hns mutant imposed different regulatory effects on the pattern of protein expression in the other species, i.e. mainly Streptococcus spp., Fusobacterium nucleatum, and Veillonella dispar. Gene ontology analysis revealed that a large portion of the differentially regulated proteins was related to translational activity. Taken together, our data suggest that, apart from being a negative regulator of gene expression in A. actinomycetemcomitans, H-NS promotes biofilm formation and may be an important factor for survival of this species within a multispecies biofilm.

Project description:Transcriptome comparison of E.coli W3110 (wild type), hha, ydgT, hns, stpA, hha_ydgT double and hns_stpA double mutant cells

Project description:Our results demonstrate that RNase G controls expression levels of H-NS encoded by hns, strongly associated with the pathogenicity of S. Typhimurium. The hns mRNA abundance is mediated by RNase G, which cleaves the 5’-UTR of hns mRNA. In the upstream pathway, the induced expression of RNase G in host environment condition is attributable to reduced RNase III cleavage activity on rng mRNA. Our findings suggest the link between Salmonella pathogenicity and RNase III-RNase G pathway, underlining the importance of posttranscriptional regulation of H-NS in the downstream pathway, which controls Salmonella pathogenicity island-1 type III secretion system for the survival and virulence of S. Typhimurium in host cell.