Analysis of the temperature-sensitive mutation of Escherichia coli pantothenate kinase reveals YbjN as a possible protein stabilizer

Pantothenate kinase (PanK), a key regulatory enzyme in the coenzyme A (CoA) biosynthetic pathway, catalyzes the rate-limiting phosphorylation of pantothenic acid to form phosphopantothenate during CoA biosynthesis. Escherichia coli ts9 strain manifests temperature-sensitive phenotype on LB media due to its mutation in the coaA gene (coaA1). Sequencing analysis revealed that coaA1 arises from a single base pair mutation that results in an amino acid change, L236F. This change, located proximate to the ATP binding site of CoaA, destabilizes both enzymatic activity and structural integrity or stability of the mutant protein in vitro. Spontaneously, revertants of ts9 were occasionally found on LB medium plates. Two groups of revertants were isolated: for those that can grow at 40 degrees C, a reversion of the original amino acid mutation L236F to L236L or other amino acid (such as L236C) occurs; for those that can grow at 37 degrees C but not 40 degrees C, a mutation at another gene or intergenic suppression is strongly indicated. Towards genetic identification of genes that might interact with coaA1, ybjN, which encodes a putative sensory transduction regulator protein, and whose over-expression is capable of ameliorating the temperature-sensitive phenotype of the structurally unstable CoaA1 or CoaA[L236F], was isolated. Over-expression of ybjN appears to suppress the temperature-sensitive phenotype of several other temperature-sensitive mutations, including coaA14 (carried by DV51 strain), coaA15 (carried by DV70 strain), and ilu-1, suggesting it not only helps CoaA1, but possibly works as a general stabilizer for some other unstable proteins.     

Enterobactin is required for biofilm development in reduced-genome Escherichia coli

A variety of bacterial cell surface structures and quorum signalling molecules play a role in biofilm development in Escherichia coli. However, here we show that an engineered reduced-genome E. coli mutant that lacks 17.6% of the parental E. coli genome, including the genes involved in the synthesis of various cell surface structures, such as type 1 fimbriae, curli, exopolysaccharide polymers and the autoinducer-2 signalling molecule, is able to develop mature biofilms. Using temporal gene expression profiling, we investigated phenotypic changes in reduced-genome biofilms in relation with the genes encoding the synthesis of different amino acids that were differentially expressed during biofilm formation. We identified and characterized entB, marR, dosC, mcbR and yahK genes, as involved in biofilm formation by the reduced-genome E. coli. Of these, for a first time, we demonstrated that overproduction of entB and yahK, which encode an enterobactin for iron transport and a hypothetical oxidoreductase protein, respectively, promoted biofilm development and maturation. Our results indicate that specific types of genes contribute to phenotypic changes in reduced-genome E. coli biofilms. In addition, this work demonstrates that the functions of biofilm-specific genes could be analysed through experiments using the reduced-genome E. coli.     

Correlation between In Vivo Biofilm Formation and Virulence Gene Expression in Escherichia coli O104:H4

The emergence of novel pathogens poses a major public health threat causing widespread epidemics in susceptible populations. The Escherichia coli O104:H4 strain implicated in a 2011 outbreak in northern Germany caused the highest frequency of hemolytic uremic syndrome (HUS) and death ever recorded in a single E. coli outbreak. Therefore, it has been suggested that this strain is more virulent than other pathogenic E. coli (e.g., E. coli O157:H7). The E. coli O104:H4 outbreak strain possesses multiple virulence factors from both Shiga toxin (Stx)-producing E. coli (STEC) and enteroaggregative E. coli (EAEC), though the mechanism of pathogenesis is not known. Here, we demonstrate that E. coli O104:H4 produces a stable biofilm in vitro and that in vivo virulence gene expression is highest when E. coli O104:H4 overexpresses genes required for aggregation and exopolysaccharide production, a characteristic of bacterial cells residing within an established biofilm. Interrupting exopolysaccharide production and biofilm formation may therefore represent effective strategies for combating future E. coli O104:H4 infections.     

Regulatory roles of spnT, a novel gene located within transposon TnTIR

The transposon TnTIR contains spnIR quorum-sensing system regulating sliding motility and the production of nuclease, biosurfactant, and prodigiosin in Serratia marcescens. Within TnTIR, a gene named spnT is upstream of and co-transcribed with spnI. SpnT is a cytoplasmic protein and its level peaks during early stationary phase. spnT over-expression resulted in inhibition of sliding motility and synthesis of prodigiosin, and biosurfactant similar to spnR. spnT but not spnR over-expression induced cell elongation and aberrant DNA replication in S. marcescens and Escherichia coli strains. In comparison with wild-type E. coli strain, over-expression of spnT in an E. coli priA and dnaC double-mutant strain did not lead to the aberrant cell morphology phenotypes, suggesting SpnT may act through the recombination-dependent DNA replication system. As spnT over-expression inhibited swarming but not swimming motility, SpnT may indirectly function as a negative regulator of surface-dependent migration and secondary metabolite production.     

Initial characterization of yliH in Salmonella typhimurium

Using microarray analysis, we determined those Salmonella genes induced at the entry of stationary phase, and subsequently discovered that uncharacterized yliH was induced most dramatically. We set out to establish the molecular mechanism underlying the stationary phase induction of yliH under the standard culture condition, LB with vigorous aeration, by analyzing its promoter activity in various mutant backgrounds, lacking stationary phase sigma, RpoS-, or stringent signal molecules ppGpp, DeltarelA DeltaspoT. It was found that the stationary phase induction of yliHp was partially dependent on rpoS but entirely dependent on ppGpp. DNA sequence analysis revealed that the Salmonella yliH gene is composed of 381 base-pair nucleotides, with overall amino acid sequence revealing 76.38% amino acid identity and 88.98% similarity with Escherichia coli yliH, although no motif from data base was noted for its possible role. Recently however, it has been reported that yliH in E. coli was implicated in biofilm formation and motility by repressing these activities (Domka et al., 2006). We have constructed a mutant Salmonella deleting yliH gene by allele replacement and examined its phenotype, and found that the yliH in Salmonella more or less affects motility and adherence by enhancing these activities. The effect on biofilm formation in Salmonella was uncertain. Moreover, addition of cloned yliH of E. coli into Salmonella did not reduce motility or adherence. Taken together, it appears that the pathways implicating yliH for biofilm formation and motility in E. coli and in Salmonella are somewhat different.     

Cooperative unfolding of Escherichia coli ribosome recycling factor originating from its domain-domain interaction and its implication for function

Cooperative unfolding of Escherichia coli ribosome recycling factor (RRF) and its implication for function were investigated by comparing the in vitro unfolding and the in vivo activity of wild-type E. coli RRF and its temperature-sensitive mutant RRF(V117D). The experiments show that mutation V117D at domain I could perturb the domain II structure as evidenced in the near-UV CD and tyrosine fluorescence spectra though no significant globular conformation change occurred. Both equilibrium unfolding induced by heat or denaturant and kinetic unfolding induced by denaturant obey the two-state transition model, indicating V117D mutation does not perturb the efficient interdomain interaction, which results in cooperative unfolding of the RRF protein. However, the mutation significantly destabilizes the E. coli RRF protein, moving the thermal unfolding transition temperature range from 50-65 to 35-50 degrees C, which spans the non-permissive temperature for the growth of E. coli LJ14 strain (frr(ts)). The in vivo activity assays showed that although V117D mutation results in a temperature sensitive phenotype of E. coli LJ14 strain (frr(ts)), over-expression of mutant RRF(V117D) can eliminate the temperature sensitive phenotype at the non-permissive temperature (42 degrees C). Taking all the results into consideration, it can be suggested that the mechanism of the temperature sensitive phenotype of the E. coli LJ14 cells is due to inactivation of mutant RRF(V117D) caused by unfolding at the non-permissive temperatures.     

The flhDC gene affects motility and biofilm formation in Yersinia pseudotuberculosis

The flagella master regulatory gene flhDC of Yersinia pseudotuberculosis serotype III (YPIII) was mu- tated by deleting the middle region and replaced by a tetracycline resistant gene, and the subsequent mutant strain named YPIII?flhDC was obtained. Swimming assay showed that the swimming motility of the mutant strain was completely abolished. The promoter region of the flagella second-class regula- tory gene fliA was fused with the lux box, and was conjugated with the mutant and the parent strains respectively for the first cross. LUCY assay result demonstrated that flhDC regulated the expression of fliA in YPIII as reported in E. coli. Biofilm formation of the mutant strain on abiotic and biotic surfaces was observed and quantified. The results showed that mutation of flhDC decreased biofilm formation on both abiotic and biotic surfaces, and abated the infection on Caenorhabdtis elegans. Our results suggest that mutation of the flagella master regulatory gene flhDC not only abolished the swimming motility, but also affected biofilm formation of YPIII on different surfaces. The new function of flhDC identified in this study provides a novel viewpoint for the control of bacterial biofilm formation.     

Biofilm formation by Escherichia coli O157:H7 on stainless steel: effect of exopolysaccharide and Curli production on its resistance to chlorine

The resistance of Escherichia coli O157:H7 strains ATCC 43895-, 43895-EPS (an exopolysaccharide [EPS]-overproducing mutant), and ATCC 43895+ (a curli-producing mutant) to chlorine, a sanitizer commonly used in the food industry, was studied. Planktonic cells of strains 43895-EPS and/or ATCC 43895+ grown under conditions supporting EPS and curli production, respectively, showed the highest resistance to chlorine, indicating that EPS and curli afford protection. Planktonic cells (ca. 9 log(10) CFU/ml) of all strains, however, were killed within 10 min by treatment with 50 microg of chlorine/ml. Significantly lower numbers of strain 43895-EPS, compared to those of strain ATCC 43895-, attached to stainless steel coupons, but the growth rate of strain 43895-EPS on coupons was not significantly different from that of strain ATCC 43895-, indicating that EPS production did not affect cell growth during biofilm formation. Curli production did not affect the initial attachment of cells to coupons but did enhance biofilm production. The resistance of E. coli O157:H7 to chlorine increased significantly as cells formed biofilm on coupons; strain ATCC 43895+ was the most resistant. Population sizes of strains ATCC 43895+ and ATCC 43895- in biofilm formed at 12 degrees C were not significantly different, but cells of strain ATCC 43895+ showed significantly higher resistance than did cells of strain ATCC 43895-. These observations support the hypothesis that the production of EPS and curli increase the resistance of E. coli O157:H7 to chlorine.     

茎瘤固氮根瘤菌环二鸟苷酸代谢相关基因的功能鉴定

【目的】考察茎瘤固氮根瘤菌ORS571中c-di-GMP合成酶AZC-2412的编码基因缺失的突变表型,初步探究其功能机理。【方法】本实验构建基于cre-loxp重组酶系统的根瘤菌基因敲除系统,以及采用三亲接合技术构建突变株。测定野生型和突变株的生长速率、趋化能力、胞外多糖产量、生物膜形成等表型。【结果】突变株与野生型生长速率几乎相同。与野生型相比突变株由于细胞内c-di-GMP水平降低,胞外多糖、生物膜产量等均有所下降。【结论】实验表明,环二鸟苷酸合成酶AZC-2412缺失,使得c-di-GMP水平降低,对胞外多糖生成、细菌的运动能力、生物膜的形成、细胞絮凝、与植物的互作等均有调控作用。     

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.     

AmyR Is a Novel Negative Regulator of Amylovoran Production in Erwinia amylovora

In this study, we attempted to understand the role of an orphan gene amyR in Erwinia amylovora, a functionally conserved ortholog of ybjN in Escherichia coli, which has recently been characterized. Amylovoran, a high molecular weight acidic heteropolymer exopolysaccharide, is a virulent factor of E. amylovora. As reported earlier, amylovoran production in an amyR knockout mutant was about eight-fold higher than that in the wild type (WT) strain of E. amylovora. When a multicopy plasmid containing the amyR gene was introduced into the amyR mutant or WT strains, amylovoran production was strongly inhibited. Furthermore, amylovoran production was also suppressed in various amylovoran-over-producing mutants, such as grrSA containing multicopies of the amyR gene. Consistent with amylovoran production, an inverse correlation was observed between in vitro expression of amyR and that of amylovoran biosynthetic genes. However, both the amyR knockout mutant and over-expression strains showed reduced levan production, another exopolysaccharide produced by E. amylovora. Virulence assays demonstrated that while the amyR mutant was capable of inducing slightly greater disease severity than that of the WT strain, strains over-expressing the amyR gene did not incite disease on apple shoots or leaves, and only caused reduced disease on immature pear fruits. Microarray studies revealed that amylovoran biosynthesis and related membrane protein-encoding genes were highly expressed in the amyR mutant, but down-regulated in the amyR over-expression strains in vitro. Down-regulation of amylovoran biosynthesis genes in the amyR over-expression strain partially explained why over-expression of amyR led to non-pathogenic or reduced virulence in vivo. These results suggest that AmyR plays an important role in regulating exopolysaccharide production, and thus virulence in E. amylovora.     

A LOV protein modulates the physiological attributes of Xanthomonas axonopodis pv. citri relevant for host plant colonization

Recent studies have demonstrated that an appropriate light environment is required for the establishment of efficient vegetal resistance responses in several plant-pathogen interactions. The photoreceptors implicated in such responses are mainly those belonging to the phytochrome family. Data obtained from bacterial genome sequences revealed the presence of photosensory proteins of the BLUF (Blue Light sensing Using FAD), LOV (Light, Oxygen, Voltage) and phytochrome families with no known functions. Xanthomonas axonopodis pv. citri is a Gram-negative bacterium responsible for citrus canker. The in silico analysis of the X. axonopodis pv. citri genome sequence revealed the presence of a gene encoding a putative LOV photoreceptor, in addition to two genes encoding BLUF proteins. This suggests that blue light sensing could play a role in X. axonopodis pv. citri physiology. We obtained the recombinant Xac-LOV protein by expression in Escherichia coli and performed a spectroscopic analysis of the purified protein, which demonstrated that it has a canonical LOV photochemistry. We also constructed a mutant strain of X. axonopodis pv. citri lacking the LOV protein and found that the loss of this protein altered bacterial motility, exopolysaccharide production and biofilm formation. Moreover, we observed that the adhesion of the mutant strain to abiotic and biotic surfaces was significantly diminished compared to the wild-type. Finally, inoculation of orange (Citrus sinensis) leaves with the mutant strain of X. axonopodis pv. citri resulted in marked differences in the development of symptoms in plant tissues relative to the wild-type, suggesting a role for the Xac-LOV protein in the pathogenic process. Altogether, these results suggest the novel involvement of a photosensory system in the regulation of physiological attributes of a phytopathogenic bacterium. A functional blue light receptor in Xanthomonas spp. has been described for the first time, showing an important role in virulence during citrus canker disease.     

天蓝色链霉菌中长链3-酮脂酰ACP合成酶的功能

【背景】链霉菌属于放线菌科,在土壤环境中广泛分布。链霉菌具有复杂的形态分化和多样性的次生代谢网络,能产生大量具有生物活性的次级代谢产物,被广泛深入研究。【目的】天蓝色链霉菌是链霉菌的模式菌株,其脂肪酸合成代谢与次级代谢联系紧密,但目前脂肪酸合成代谢途径还不清楚,其长链3-酮脂酰ACP合成酶还未见报道。【方法】利用大肠杆菌FabF序列进行同源比对,发现天蓝色链霉菌A3(2)的基因组中,SCO2390(ScoFabF1)、SCO1266(ScoFabF2)、SCO0548(ScoFabF3)和SCO5886 (ScoRedR)具有较高的相似性,并具有保守的Cys-His-His催化活性中心,可能具有长链3-酮脂酰ACP合成酶活性。采用PCR扩增方法分别获得以上基因,连入表达载体pBAD24M后分别互补大肠杆菌fabB(ts)突变株和fabB(ts)fabF双突变株,并检测转化子的生长情况。以上基因与pET-28b连接后,在大肠杆菌BL21(DE3)中表达,并利用Ni-NTA纯化获得蛋白,体外测定其催化活性。将以上基因分别互补大肠杆菌fabF突变株后,GC-MS测定互补株的脂肪酸组成。【结果】4个同源基因中,只有ScofabF1能恢复fabB(ts)fabF双突变株42°C时在添加油酸条件下的生长,其他3个基因均不能恢复生长。而这4个基因都不能恢复fabB(ts)突变株42°C时生长。体外活性测定ScoFabF1具有长链3-酮脂酰ACP合成酶活性,其他3个蛋白都不具有该活性。仅ScofabF1能显著提高大肠杆菌fabF突变株的顺-11-十八碳烯酸(C18:1)比例,其他3个基因都不具有该功能。【结论】天蓝色链霉菌中ScofabF1编码长链3-酮脂酰ACP合成酶II,在脂肪酸利用过程中发挥重要作用。天蓝色链霉菌中没有发现编码长链3-酮脂酰ACP合成酶I的基因,其可能通过其他途径合成少量的不饱和脂肪酸。以上研究结果为进一步研究天蓝色链霉菌中脂肪酸合成机制奠定了基础。     

The R1 conjugative plasmid increases Escherichia coli biofilm formation through an envelope stress response

Differential gene expression in biofilm cells suggests that adding the derepressed conjugative plasmid R1drd19 increases biofilm formation by affecting genes related to envelope stress (rseA and cpxAR), biofilm formation (bssR and cstA), energy production (glpDFK), acid resistance (gadABCEX and hdeABD), and cell motility (csgBEFG, yehCD, yadC, and yfcV); genes encoding outer membrane proteins (ompACF), phage shock proteins (pspABCDE), and cold shock proteins (cspACDEG); and phage-related genes. To investigate the link between the identified genes and biofilm formation upon the addition of R1drd19, 40 isogenic mutants were classified according to their different biofilm formation phenotypes. Cells with class I mutations (those in rseA, bssR, cpxA, and ompA) exhibited no difference from the wild-type strain in biofilm formation and no increase in biofilm formation upon the addition of R1drd19. Cells with class II mutations (those in gatC, yagI, ompC, cspA, pspD, pspB, ymgB, gadC, pspC, ymgA, slp, cpxP, cpxR, cstA, rseC, ompF, and yqjD) displayed increased biofilm formation compared to the wild-type strain but decreased biofilm formation upon the addition of R1drd19. Class III mutants showed increased biofilm formation compared to the wild-type strain and increased biofilm formation upon the addition of R1drd19. Cells with class IV mutations displayed increased biofilm formation compared to the wild-type strain but little difference upon the addition of R1drd19, and class V mutants exhibited no difference from the wild-type strain but increased biofilm formation upon the addition of R1drd19. Therefore, proteins encoded by the genes corresponding to the class I mutant phenotype are involved in R1drd19-promoted biofilm formation, primarily through their impact on cell motility. We hypothesize that the pili formed upon the addition of the conjugative plasmid disrupt the membrane (induce ompA) and activate the two-component system CpxAR as well as the other envelope stress response system, RseA-sigma(E), both of which, along with BssR, play a key role in bacterial biofilm formation.