The Rcs phosphorelay is a cell envelope stress response activated by peptidoglycan stress and contributes to intrinsic antibiotic resistance

Gram-negative bacteria possess stress responses to maintain the integrity of the cell envelope. Stress sensors monitor outer membrane permeability, envelope protein folding, and energization of the inner membrane. The systems used by gram-negative bacteria to sense and combat stress resulting from disruption of the peptidoglycan layer are not well characterized. The peptidoglycan layer is a single molecule that completely surrounds the cell and ensures its structural integrity. During cell growth, new peptidoglycan subunits are incorporated into the peptidoglycan layer by a series of enzymes called the penicillin-binding proteins (PBPs). To explore how gram-negative bacteria respond to peptidoglycan stress, global gene expression analysis was used to identify Escherichia coli stress responses activated following inhibition of specific PBPs by the β-lactam antibiotics amdinocillin (mecillinam) and cefsulodin. Inhibition of PBPs with different roles in peptidoglycan synthesis has different consequences for cell morphology and viability, suggesting that not all perturbations to the peptidoglycan layer generate equivalent stresses. We demonstrate that inhibition of different PBPs resulted in both shared and unique stress responses. The regulation of capsular synthesis (Rcs) phosphorelay was activated by inhibition of all PBPs tested. Furthermore, we show that activation of the Rcs phosphorelay increased survival in the presence of these antibiotics, independently of capsule synthesis. Both activation of the phosphorelay and survival required signal transduction via the outer membrane lipoprotein RcsF and the response regulator RcsB. We propose that the Rcs pathway responds to peptidoglycan damage and contributes to the intrinsic resistance of E. coli to β-lactam antibiotics.     

The cytokine balance in the maintenance of a persistent infection with Salmonella enterica serovar Typhimurium in mice

ClpXP, serine protease-disrupted mutant of Salmonella enterica serovar Typhimurium chi3306 exhibits attenuated but persistent infection in mice. During infection with S. enterica serovar Typhimurium ClpXP-disrupted mutant, gamma interferon (IFN-gamma) produced by CD4+ cells was up-regulated on day 10 and tumor necrosis factor-alpha (TNF-alpha) produced by CD8+ cells was up-regulated on day 30 after infection. Treatment of monoclonal antibodies against cytokines showed that IFN-gamma and interleukin 10 (IL-10) were involved in maintenance of growth of S. Typhimurium mutant on day 10 after infection, and IFN-gamma, TNF-alpha and transforming growth factor-beta (TGF-beta) were involved in maintenance of growth of this bacterium on day 30 after infection. During persistent infection of S. Typhimurium mutant, IFN-gamma, TNF-alpha, IL-10 and TGF-beta may play different roles to maintain the persistent infection. The cytokine balance might be important in persistent infection with ClpXP-disrupted S. enterica serovar Typhimurium.     

Repression of the RcsC-YojN-RcsB phosphorelay by the IgaA protein is a requisite for Salmonella virulence

Bacterial pathogenesis relies on regulators that activate virulence genes. Some of them act, in addition, as repressors of specific genes. Intracellular-growth-attenuator-A (IgaA) is a Salmonella enterica membrane protein that prevents overactivation of the RcsC-YojN-RcsB regulatory system. This negative control is critical for growth because disruption of the igaA gene is only possible in rcsC, yojN or rcsB strains. In this work, we examined the contribution of this regulatory circuit to virulence. Viable igaA point mutant alleles were isolated and characterized. These alleles encode IgaA variants leading to different levels of activation of the RcsC-YojN-RcsB system. IgaA-mediated repression of the RcsB-YojN-RcsC system occurred at the post-translational level, as shown by chromosomal epitope tagging of the rcsC, yojN and rcsB genes. The activity of the RcsC-YojN-RcsB system, monitored with the product of a tagged gmd-3xFLAG gene (positively regulated by RcsC-YojN-RcsB), was totally abolished by wild-type bacteria in mouse target organs. Such tight repression occurred only in vivo and was mediated by IgaA. Shutdown of the RcsC-YojN-RcsB system is a requisite for Salmonella virulence since all igaA point mutant strains were highly attenuated. The degree of attenuation correlated to that of the activation status of RcsC-YojN-RcsB. In some cases, the attenuation recorded was unprecedented, with competitive index (CI) values as low as 10(-6). Strikingly, IgaA is a protein absolutely dispensable for virulence in mutant strains having a non-functional RcsC-YojN-RcsB system. To our knowledge, IgaA exemplifies the first protein that contributes to virulence by exclusively acting as a negative regulator upon host colonization.     

Molecular cloning and characterization of supQ/newD, a gene substitution system for the leuD gene of Salmonella typhimurium.

The isopropylmalate isomerase of Salmonella typhimurium and Escherichia coli is a complex of the leuC and leuD gene products. The supQ/new D gene substitution system in S. typhimurium restores leucine prototrophy to leuD mutants of S. typhimurium. Previous genetic evidence supports a model that indicates the replacement of the missing LeuD polypeptide by the newD gene product. This model proposed that this gene substitution is possible when a mutation at the supQ locus (near newD) liberates unaltered newD polypeptide from its normal complex with the supQ protein product. In this study, recombinant plasmids carrying newD, supQ, or both were transformed into E. coli and S. typhimurium strains deleted for the leuD and supQ genes to test the supQ/newD gene substitution model for suppression of leucine auxotrophy. It was determined that the newD gene encodes a 22-kilodalton polypeptide which can restore leucine prototrophy to leuD deletion strains and that a functional supQ gene prevents this suppression. It was also determined that the supQ and newD genes are separated by a gene encoding a 50-kilodalton protein, pB. While there is extensive DNA sequence homology between the leucine operons of S. typhimurium and E. coli, DNA hybridization experiments did not indicate substantial homology between the newD and leuD genes. These data, taken together with previously obtained genetic data, eliminate the possibility that supQ and newD are recently translocated segments of the leucine operon.     

PCR amplification of the fimA gene sequence of Salmonella typhimurium, a specific method for detection of Salmonella spp.

The goal of this study was to evaluate the suitability of the fimA gene amplification by PCR as a specific method for detection of Salmonella strains. Salmonella typhimurium and other pathogenic members of the family Enterobacteriaceae produce morphologically and antigenically related, thin, aggregative, type 1 fimbriae. A single gene, fimA, encodes the major fimbrial unit. In order to obtain higher specificity, we have selected a series of primers internal to the fimA gene sequence and have developed a PCR method for detecting Salmonella strains. A collection of 376 strains of Salmonella comprising over 80 serovars, isolated from animals and humans in Canada, have been used to evaluate this PCR method. Forty non-Salmonella strains were also tested by the same procedure. Cultures were screened by inoculating a single colony of bacteria directly into a PCR mixture containing a pair of primers specific for the fimA gene. The specific PCR product is an 85-bp fragment which was visualized by polyacrylamide gel electrophoresis and ethidium bromide staining. All Salmonella strains gave positive results by the PCR. Feed and milk samples contaminated by Salmonella strains were also detected by this procedure. The detection of all Salmonella strains tested and the failure to amplify the fragment from non-Salmonella strains confirm that the fimA gene contains sequences unique to Salmonella strains and demonstrate that this gene is a suitable PCR target for detection of Salmonella strains in food samples.     

Mig-14 is an inner membrane-associated protein that promotes Salmonella typhimurium resistance to CRAMP, survival within activated macrophages and persistent infection

Salmonella enterica serovar Typhimurium (S. typhimurium) infects a wide variety of mammalian hosts and in rodents causes a typhoid-like systemic disease involving replication of bacteria inside macrophages within reticuloendothelial tissues. Previous studies demonstrated that the mig-14 and virK genes of Salmonella enterica are important in bacterial resistance to anti-microbial peptides and are necessary for continued replication of S. typhimurium in the liver and spleen of susceptible mice after orogastric inoculation. In this work we report that inflammatory signalling via interferon-gamma (IFN-gamma) is crucial to controlling replication of mig-14 mutant bacteria within the liver and spleen of mice after oral infection. Using a Salmonella persistence model recently developed in our laboratory, we further demonstrate that mig-14 contributes to long-term persistence of Salmonella in the spleen and mesenteric lymph nodes of chronically infected mice. Both mig-14 and virK contribute to the survival of Salmonella in macrophages treated with IFN-gamma and are necessary for resistance to cathelin-related anti-microbial peptide (CRAMP), an anti-microbial peptide expressed at high levels in activated mouse macrophages. We also show that both Mig-14 and VirK inhibit the binding of CRAMP to Salmonella, and demonstrate that Mig-14 is an inner membrane-associated protein. We further demonstrate by transmission electron microscopy that the primary locus of CRAMP activity appears to be intracytoplasmic, rather than at the outer membrane, suggesting that Mig-14 may prevent the penetration of the inner membrane by CRAMP. Together, these data indicate an important role for mig-14 in anti-microbial peptide resistance in vivo, and show that this resistance is important to the survival of Salmonella in systemic sites during both acute and persistent infection.     

Increased resistance to Salmonella infection of hypoferremic mice fed a low-protein diet

BALB/c and CBA/CA mice fed a protein-deficient diet developed a plasma hypoferremia corresponding to a 30 percent lowering of serum iron concentration. This hypoferremia persisted as long as the diet was maintained. Hypoferremic CBA/CA mice had increased resistance to Salmonella typhimurium C5 infection, as shown by the reduced lethal activity and the decreased growth of the bacteria in the spleen and in the peritoneal exudate of the deficient animals. This induced resistance was abolished after injection of iron or Desferal into the restricted animals. Such resistance was not observed with BALB/c mice fed a protein-deficient diet, in spite of the plasma hypoferremia. The growth of S. typhimurium C5 in the spleen and in the peritoneal exudate of these animals did not differ from the growth observed in control animals fed a protein-sufficient diet. This study suggests that hypoferremia induced by a protein-deficient diet is probably involved in the enhancement of resistance of CBA/CA mice to Salmonella infection, and that the phenomenon is host-strain dependent.     

The gene cluster inlC2DE of Listeria monocytogenes contains additional new internalin genes and is important for virulence in mice

In this work we identified and characterized a gene cluster containing three internalin genes of Listeria monocytogenes EGD. These genes, termed inlG, inlH and inlE, encode proteins of 490, 548 and 499 amino acids, respectively, which belong to the family of large, cell wall-bound internalins. The inlGHE gene cluster is flanked by two listerial house-keeping genes encoding proteins homologous to the 6-phospho-β-glucosidase and the succinyl-diaminopimelate desuccinylase of E. coli. A similar internalin gene cluster, inlC2DE, localised to the same position on the L. monocytogenes EGD chromosome was recently described in a different isolate (Dramsi S, Dehoux P, Lebrun M, Goossens PL, Cossart P (1997) Infect Immun 65: 1615–1625). Sequence comparison of the two inl gene clusters indicates that inlG is a new internalin gene, while inlH was generated by a site-specific recombination, leading to an in-frame deletion which removed the 3′-terminal end of inlC2 and the 5′-terminal part of inlD. The third gene of the inlGHE cluster, inlE, is almost identical to the previously reported inlE gene. Our data show that the inlGHE gene cluster is probably transcribed from a major PrfA- independent promoter located upstream of inlG. PCR analysis revealed the presence of the newly identified inl genes inlG and inlH in most L. monocytogenes isolates tested. A mutant which has lost inlG, inlH and inlE by an in-frame deletion exhibited, after oral infection of mice, a significant loss in virulence and shows drastically reduced numbers of viable bacteria in both liver and spleen when compared to the wild-type strain. Received: 21 April 1998 / Accepted: 5 June 1998     

FVB mice transgenic for the H-2Db gene become resistant to persistent infection by Theiler's virus.

The DA strain of Theiler's virus causes a persistent infection of the white matter of the spinal cord with chronic inflammation and primary demyelination. Inbred strains of mice differ greatly in their susceptibility to this disease. It has been shown that both viral persistence and demyelination are controlled mainly by a gene located in the H-2D region. This raised the possibility that the H-2D gene itself controls viral persistence, which in turn determines demyelination. In the present work we introduced the H-2Db gene of resistant C57BL/6 mice into the genome of susceptible H-2q FVB mice and showed that the FVB mice become resistant to persistence of the infection and did not develop inflammatory lesions.     

The AMT1 arginine methyltransferase gene is important for plant infection and normal hyphal growth in Fusarium graminearum

Arginine methylation of non-histone proteins by protein arginine methyltransferase (PRMT) has been shown to be important for various biological processes from yeast to human. Although PRMT genes are well conserved in fungi, none of them have been functionally characterized in plant pathogenic ascomycetes. In this study, we identified and characterized all of the four predicted PRMT genes in Fusarium graminearum, the causal agent of Fusarium head blight of wheat and barley. Whereas deletion of the other three PRMT genes had no obvious phenotypes, the Δamt1 mutant had pleiotropic defects. AMT1 is a predicted type I PRMT gene that is orthologous to HMT1 in Saccharomyces cerevisiae. The Δamt1 mutant was slightly reduced in vegetative growth but normal in asexual and sexual reproduction. It had increased sensitivities to oxidative and membrane stresses. DON mycotoxin production and virulence on flowering wheat heads also were reduced in the Δamt1 mutant. The introduction of the wild-type AMT1 allele fully complemented the defects of the Δamt1 mutant and Amt1-GFP fusion proteins mainly localized to the nucleus. Hrp1 and Nab2 are two hnRNPs in yeast that are methylated by Hmt1 for nuclear export. In F. graminearum, AMT1 is required for the nuclear export of FgHrp1 but not FgNab2, indicating that yeast and F. graminearum differ in the methylation and nucleo-cytoplasmic transport of hnRNP components. Because AMT2 also is a predicted type I PRMT with limited homology to yeast HMT1, we generated the Δamt1 Δamt2 double mutants. The Δamt1 single and Δamt1 Δamt2 double mutants had similar defects in all the phenotypes assayed, including reduced vegetative growth and virulence. Overall, data from this systematic analysis of PRMT genes suggest that AMT1, like its ortholog in yeast, is the predominant PRMT gene in F. graminearum and plays a role in hyphal growth, stress responses, and plant infection.     

Salmonella typhimurium proliferates and establishes a persistent infection in the intestine of Caenorhabditis elegans

Genetic analysis of host-pathogen interactions has been hampered by the lack of genetically tractable models of such interactions. We showed previously that the human opportunistic pathogen Pseudomonas aeruginosa kills Caenorhabditis elegans, that P. aeruginosa and C. elegans genes can be identified that affect this killing, and that most of these P. aeruginosa genes are also important for mammalian pathogenesis. Here, we show that Salmonella typhimurium as well as other Salmonella enterica serovars including S. enteritidis and S. dublin can also kill C. elegans. When C. elegans is placed on a lawn of S. typhimurium, the bacteria accumulate in the lumen of the worm intestine and the nematodes die over the course of several days. This killing requires contact with live bacterial cells. The worms die with similar kinetics when placed on a lawn of S. typhimurium for a relatively short time (3-5 hours) before transfer to a lawn of E. coli. After the transfer to E. coli, a high titer of S. typhimurium persists in the C. elegans intestinal lumen for the rest of the worms' life. Furthermore, feeding for 5 hours on a 1:1000 mixture of S. typhimurium and E. coli followed by transfer to 100% E. coli, also led to death after several days. This killing correlated with an increase in the titer of S. typhimurium in the C. elegans lumen, which reached 10,000 bacteria per worm. These data indicate that, in contrast to P. aeruginosa, a small inoculum of S. typhimurium can proliferate in the C. elegans intestine and establish a persistent infection. S. typhimurium mutated in the PhoP/PhoQ signal transduction system caused significantly less killing of C. elegans.     

The LPB1 gene is important for acclimation of Chlamydomonas reinhardtii to phosphorus and sulfur deprivation

Organisms exhibit a diverse set of responses when exposed to low-phosphate conditions. Some of these responses are specific for phosphorus limitation, including responses that enable cells to efficiently scavenge phosphate from internal and external stores via the production of high-affinity phosphate transporters and the synthesis of intracellular and extracellular phosphatases. Other responses are general and occur under a number of different environmental stresses, helping coordinate cellular metabolism and cell division with the growth potential of the cell. In this article, we describe the isolation and characterization of a mutant of Chlamydomonas reinhardtii, low-phosphate bleaching (lpb1), which dies more rapidly than wild-type cells during phosphorus limitation. The responses of this mutant to nitrogen limitation appear normal, although the strain is also somewhat more sensitive than wild-type cells to sulfur deprivation. Interestingly, depriving the cells of both nutrients simultaneously allows for sustained survival that is similar to that observed with wild-type cells. Furthermore, upon phosphorus deprivation, the lpb1 mutant, like wild-type cells, exhibits increased levels of mRNA encoding the PHOX alkaline phosphatase, the PTB2 phosphate transporter, and the regulatory element PSR1. The mutant strain is also able to synthesize the extracellular alkaline phosphatase activity upon phosphorus deprivation and the arylsulfatase upon sulfur deprivation, suggesting that the specific responses to phosphorus and sulfur deprivation are normal. The LPB1 gene was tagged by insertion of the ARG7 gene, which facilitated its isolation and characterization. This gene encodes a protein with strong similarity to expressed proteins in Arabidopsis (Arabidopsis thaliana) and predicted proteins in Oryza sativa and Parachlamydia. A domain in the protein contains some similarity to the superfamily of nucleotide-diphospho-sugar transferases, and it is likely to be localized to the chloroplast or mitochondrion based on programs that predict subcellular localization. While the precise catalytic role and physiological function of the putative protein is not known, it may function in some aspect of polysaccharide metabolism and/or influence phosphorus metabolism (either structural or regulatory) in a way that is critical for allowing the cells to acclimate to nutrient limitation conditions.     

Genetic control of the innate resistance of mice to Salmonella typhimurium: Ity gene is expressed in vivo by 24 hours after infection

The early response of inbred mice to infection with S. typhimurium is controlled by the mouse Chromosome 1 locus, Ity. To better understand the expression of this gene, the initial interactions between the reticuloendothelial system (RES) and i.v. injected salmonellae were compared in resistant (Ityr) and susceptible (Itys) mice. In both mouse strains 99% of the bacteria was cleared from the blood within 2 hr, and uptake of S. typhimurium by splenic and hepatic macrophages was similar regardless of Ity genotype. In vivo phagocytosis of bacteria was followed by a 30 to 60% decline in viable bacteria, which was attributed to the bactericidal activity of RES macrophages. Experiments with radiolabeled S. typhimurium strains TML and TML/TS27 (a temperature-sensitive mutant) confirmed that the efficiency of this early phase killing was not under Ity control. Despite the equivalent uptake and initial bactericidal activity by resident macrophages, bacterial numbers in the RES organs of Itys mice were significantly greater than in Ityr mice by approximately 24 hr after infection. These data suggest that Ity regulates the level of surviving intracellular bacteria that accumulate within resident macrophages of the liver and spleen.