Impact of rpoS Deletion on Escherichia coli Biofilms

Slow growth has been hypothesized to be an essential aspect of bacterial physiology within biofilms. In order to test this hypothesis, we employed two strains of Escherichia coli, ZK126 (ΔlacZ rpoS⁺) and its isogenic ΔrpoS derivative, ZK1000. These strains were grown at two rates (0.033 and 0.0083 h⁻¹) in a glucose-limited chemostat which was coupled either to a modified Robbins device containing plugs of silicone rubber urinary catheter material or to a glass flow cell. The presence or absence of rpoS did not significantly affect planktonic growth of E. coli. In contrast, biofilm cell density in the rpoS mutant strain (ZK1000), as measured by determining the number of CFU per square centimeter, was reduced by 50% (P < 0.05). Deletion of rpoS caused differences in biofilm cell arrangement, as seen by scanning confocal laser microscopy. In reporter gene experiments, similar levels of rpoS expression were seen in chemostat-grown planktonic and biofilm populations at a growth rate of 0.033 h⁻¹. Overall, these studies suggest that rpoS is important for biofilm physiology.     

Differential quantitative proteome analysis of Escherichia coli grown on acetate versus glucose

Relative protein abundances of Escherichia coli MG1655 growing exponentially on minimal medium with acetate or glucose as the sole carbon source were investigated in a quantitative shotgun proteome analysis with TMT6‐plex isobaric tags. Peptides were separated by high resolution high/low pH 2D‐LC, using an optimized fraction pooling scheme followed by mass spectrometric analysis. Quantitative data were acquired for 2099 proteins covering 49% of the predicted E. coli proteins, showing system‐wide effects of growth conditions. In total, 507 proteins showed a fold change of at least 1.5 and 205 proteins changed by more than twofold. Significant differences in abundance were observed for most of the proteins in the central carbon metabolism and in proteins relevant for amino acid and protein synthesis, processing of environmental information and scavenging of a variety of alternate carbon sources. Periplasmic‐binding proteins were also more abundant on acetate, especially proteins involved in scavenging extracellular resources such as sugars. All MS data have been deposited to the ProteomeXchange Consortium via the PRIDE partner repository (dataset identifier PXD003863).     

Contribution of rpoS and bolA genes in biofilm formation in Escherichia coli K-12 MG1655

Flexibility of gene expression in bacteria permits its survival in varied environments. The genetic adaptation of bacteria through systematized gene expression is not only important, but also clinically relevant in their ability to grow biofilms in stress environments. Stress responses enable their survival under more severe conditions, enhanced resistance and/or virulence. In Escherichia coli (E. coli), two of the possible important genes for biofilm growth are rpoS and bolA gene. RpoS is also called as a master regulator of general stress response. Even though many studies have revealed the importance of rpoS in planktonic cells, little is known about the functions of rpoS in biofilms. In contrast, bolA which is a morphogene in E. coli is overexpressed under stressed environments resulting in round morphology. The hypothesis is that bolA could be implicated in biofilm development. This study reviewed the literature with the aim of understanding the stress tolerance response of E. coli in relation with rpoS and bolA genes in different environmental conditions including heat shock, cold shock, and stress in response to oxidation, acidic condition and in presence of cadmium. Knowledge of the genetic regulation of biofilm formation may lead to the understanding of the factors that drive the bacteria to switch to the biofilm mode of growth.     

rmlA 基因缺失影响禽致病性大肠杆菌的生物被膜形成

【目的】构建禽致病性大肠杆菌(Avian pathogenic Escherichia coli,APEC)rmlA基因缺失株,研究该缺失株的生物学特性。【方法】利用Red重组系统构建rmlA缺失株;比较野生株与缺失株在生长特性、运动性和生物被膜形成能力等方面的差异;运用Real-time PCR技术,比较野生株与rmlA缺失株对APEC部分毒力基因转录的影响。【结果】rmlA缺失株,不影响APEC的生长和运动特性,但生物被膜形成能力显著增强,且使luxS、irp2基因转录水平分别上调2倍、1.8倍,iucD、fyuA则下调25倍。【结论】APEC的rmlA基因可以影响禽致病性大肠杆菌的生物被膜形成能力及部分毒力基因的转录水平;而对APEC的生长、运动特性没有影响。     

Polymorphism and selection of rpoS in pathogenic Escherichia coli

Background  

Though RpoS is important for survival of pathogenic Escherichia coli in natural environments, polymorphism in the rpoS gene is common. However, the causes of this polymorphism and consequential physiological effects on gene expression in pathogenic strains are not fully understood.     

Significance of rpoS during maturation of Escherichia coli biofilms

Presence of starved, stationary phase-like zones in biofilms seems to be an important factor for biofilm formation. In this study, roles of rpoS gene in the formation of Escherichia coli biofilms were investigated. E. coli MG1655 wild type (WT) and rpoS mutant (DeltarpoS) strains were used to compare biofilm formation capacity and global gene expression. Even though the DeltarpoS strain could attach and form microcolonies on glass surfaces, it could not establish mature biofilms. DNA microarray analysis revealed that WT biofilms (WBF) showed similar pattern of gene expression with WT planktonic stationary phase, whereas DeltarpoS biofilms (MBF) showed similar pattern of gene expression with WT planktonic exponential phase. Genes involved in energy metabolism (atpIBEFHAG, atpC, cydAB) and flagella synthesis (flgB, flgC, flhD, fliA, fliC, fliY) showed increased expression in the MBF, but not in the WBF. Moreover, genes involved in stress responses (blc, cspG, dinD poxB, wcaF, wcaI, and yfcF) showed increased expression in the WBF compared to the MBF. These results suggested that the rpoS gene contributed in maturation of E. coli biofilms through regulation of global gene expression including energy metabolism, motility, and stress responses.     

Polycrylamide gel electrophoresis analysis of lipopolysaccharide from Pseudomonas aeruginosa growing planktonically and as biofilm

Abstract Lipopolysaccharide (LPS, endotoxin) was extracted from biofilm and planktonically grown monoagglutinable (1118) and polyagglutinable (258 and 15703) strains of Pseudomonas aeruginosa isolated from cystic fibrosis patients with chronic pulmonary infections. Analysis by polyacrylamide gel electrophoresis (PAGE) followed by immune-detection of LPS fractions showed an S-form appearance of strain 1118 and 258 with three distinct clusters of high molecular weight bands, whereas 15703 appeared semi-rough. LPS of semi-rough cells grown planktonically and as biofilm showed a very similar PAGE pattern; however, the core/lipid A R-LPS fraction was more prominent in biofilm-LPS than in planktonic-LPS extracted from the S-form bacteria (1118 and 258). The apparent change in LPS sub-unit components of the bacteria when grown as biofilm may reflect changes in the outer membrane structure that contribute to the altered physico-chemical properties of biofilm bacteria in foreign-device associated infections and chronic P. aeruginosa lung infection in cystic fibrosis patients.     

L-Tryptophan prevents Escherichia coli biofilm formation and triggers biofilm degradation

The effect of deletion of trp operon and tna operon on the Escherichia coli biofilm formation was investigated in order to elucidate the role of L-tryptophan metabolism in biofilm formation. trp operon deletion mutants ΔtrpC, ΔtrpD and ΔtrpE deficient in L-tryptophan biosynthesis showed higher biofilm formation. In addition, ΔtnaC with increased L-tryptophan degradation activity showed higher biofilm formation. On the contrary, ΔtnaA deletion mutant which lost L-tryptophan degradation activity showed low biofilm formation. From these results, it was suggested that decrease of intracellular L-tryptophan level induced biofilm formation and increase of L-tryptophan repressed biofilm formation. So the effect of the addition of L-tryptophan to the medium on the E. coli biofilm formation was investigated. L-Tryptophan addition at starting culture decreased biofilm formation and furthermore L-tryptophan addition after 16 h culture induced the degradation of preformed biofilm. From the above results, it was suggested that maintenance of high intracellular L-tryptophan concentration prevents E. coli biofilm formation and elevation of intracellular L-tryptophan concentration triggers degradation of matured biofilm.     

Role of rpoS in the regulation of glyoxalase III in Escherichia coli

Methylglyoxal is an endogenous electrophile produced in Escherichia coli by the enzyme methylglyoxal synthase to limit the accumulation of phosphorylated sugars. In enteric bacteria methylglyoxal is detoxified by the glutathione-dependent glyoxalase I/II system, by glyoxalase III, and by aldehyde reductase and alcohol dehydrogenase. Here we demonstrate that glyoxalase III is a stationary-phase enzyme. Its activity reached a maximum at the entry into the stationary phase and remained high for at least 20 h. An rpoS- mutant displayed normal glyoxalase I and II activities but was unable to induce glyoxalase III in stationary phase. It thus appears that glyoxalase III is regulated by rpoS and might be important for survival of non-growing E. coli cultures.     

Genotype-by-environment interactions influencing the emergence of rpoS mutations in Escherichia coli populations

Polymorphisms in rpoS are common in Escherichia coli. rpoS status influences a trade-off between nutrition and stress resistance and hence fitness across different environments. To analyze the selective pressures acting on rpoS, measurement of glucose transport rates in rpoS+ and rpoS bacteria was used to estimate the role of F(nc), the fitness gain due to improved nutrient uptake, in the emergence of rpoS mutations in nutrient-limited chemostat cultures. Chemostats with set atmospheres, temperatures, pH's, antibiotics, and levels of osmotic stress were followed. F(nc) was reduced under anaerobiosis, high osmolarity, and with chloramphenicol, consistent with a reduced rate of rpoS enrichment in these conditions. F(nc) remained high, however, with alkaline pH and low temperature but rpoS sweeps were diminished. Under these conditions, F(sp), the fitness reduction due to lowered stress protection, became significant. We also estimated whether the fitness need for the gene was related to its regulation. No consistent pattern emerged between the level of RpoS and the loss of rpoS function in particular environments. This dissection allows an unprecedented view of the genotype-by-environment interactions controlling a mutational sweep and shows that both F(nc) and F(sp) are influenced by individual stresses and that additional factors contribute to selection pressure in some environments.     

Catabolite repression of Escherichia coli biofilm formation

Biofilm formation was repressed by glucose in several species of Enterobacteriaceae. In Escherichia coli, this effect was mediated at least in part by cyclic AMP (cAMP)-cAMP receptor protein. A temporal role for cAMP in biofilm development was indicated by the finding that glucose addition after approximately 24 h failed to repress and generally activated biofilm formation.     

Escherichia coli rpoS gene has an internal secondary translation initiation region

Sigma S (sigma(s)) encoded by rpoS in Escherichia coli is a stationary phase specific sigma subunit of the RNA polymerase holoenzyme. Widespread among the E. coli K12 strains is an amber mutation that prematurely terminates sigma(s). These rpoSAm mutants would be expected to show no sigma(s) activity. However, suppressor free rpoSAm mutants retain an intermediate catalase activity, a sigma S controlled function. By analyzing the sequence of the rpoS gene we hypothesize that a 277 amino acids long delta1-53 sigma(s) of about 30 kDa can be translated from an internal secondary translation initiation region (STIR, AGGGAGN11GUG) that is located downstream of the amber codon. By cloning this rpoSAm gene, following the expression, function, and N-terminal sequence of this mutant protein, we report the presence of a functional internal STIR in E. coli rpoS, from where a truncated but nevertheless functional form of sigma(s) can be synthesized.     

Identification and Classification of Two-component Systems That Affect rpoS Expression in Escherichia coli

The rpoS-encoded σ^S subunit of RNA polymerase regulates the expression of stationary phase and stress response genes in Escherichia coli. Recent study of our DNA microarray analysis suggested that the rpoS expression is affected by multiple two-component systems. In this study, we identified two-component-system mutants in which the rpoS expression increased. The regulatory manner of the systems on rpoS expression is suggested.     

Escherichia coli biofilm: development and therapeutic strategies

Escherichia coli biofilm consists of a bacterial colony embedded in a matrix of extracellular polymeric substances (EPS) which protects the microbes from adverse environmental conditions and results in infection. Besides being the major causative agent for recurrent urinary tract infections, E. coli biofilm is also responsible for indwelling medical device‐related infectivity. The cell‐to‐cell communication within the biofilm occurs due to quorum sensors that can modulate the key biochemical players enabling the bacteria to proliferate and intensify the resultant infections. The diversity in structural components of biofilm gets compounded due to the development of antibiotic resistance, hampering its eradication. Conventionally used antimicrobial agents have a restricted range of cellular targets and limited efficacy on biofilms. This emphasizes the need to explore the alternate therapeuticals like anti‐adhesion compounds, phytochemicals, nanomaterials for effective drug delivery to restrict the growth of biofilm. The current review focuses on various aspects of E. coli biofilm development and the possible therapeutic approaches for prevention and treatment of biofilm‐related infections.     

Identification and classification of two-component systems that affect rpoS expression in Escherichia coli

The rpoS-encoded sigmaS subunit of RNA polymerase regulates the expression of stationary phase and stress response genes in Escherichia coli. Recent study of our DNA microarray analysis suggested that the rpoS expression is affected by multiple two-component systems. In this study, we identified two-component-system mutants in which the rpoS expression increased. The regulatory manner of the systems on rpoS expression is suggested.     

Arabinose-leucine deletion mutants of Escherichia coli B-r

The control of ara gene expression was studied in mutants of Escherichia coli B/r containing deletions which fused the l-arabinose gene complex with the leucine operon (the normal gene order being araDABIOC...leuDCBAO). Complementation experiments with stable merodiploids showed that expression of ara genes cis to araC-leu deletions was controlled by the trans-acting product of the araC gene. Expression of ara genes cis to araB-leu deletions was under leucine control. These studies confirm the existence of a region between genes araC and araB essential for normal activator controlled expression of the ara structural genes. One deletion was characterized as an araO-leu deletion. Its effect on ara gene expression was unique in that ara genes were susceptible to potential regulation by both l-arabinose and leucine. These experiments suggest that two different species of messenger ribonucleic acid (mRNA) may be produced for the ara-leu region as a result of this deletion. One, under l-arabinose-activator control, is initiated in the l-arabinose region; the other, under leucine control, is initiated in the leucine region. The latter indicates that araI can be transcribed. Whether araI is transcribed in the former instance (mRNA made under activator control) remains to be established.