Deletion of the lon gene augments expression of Salmonella Pathogenicity Island (SPI)-1 and metal ion uptake genes leading to the accumulation of bactericidal hydroxyl radicals and host pro-inflammatory cytokine-mediated rapid intracellular clearance

ABSTRACT

In the present study, we characterized the involvement of Lon protease in bacterial virulence and intracellular survival in Salmonella under abiotic stress conditions resembling the conditions of a natural infection. Wild type (JOL401) and the lon mutant (JOL909) Salmonella Typhimurium were exposed to low temperature, pH, osmotic, and oxidative stress conditions and changes in gene expression profiles related to virulence and metal ion uptake were investigated. Expression of candidate genes invF and hilC of Salmonella Pathogenicity Island (SPI)-1 and sifA and sseJ of SPI-2 revealed that Lon protease controls SPI-1 genes and not SPI-2 genes under all stress conditions tested. The lon mutant exhibited increased accumulation of hydroxyl (OH·) ions that lead to cell damage due to oxidative stress. This oxidative damage can also be linked to an unregulated influx of iron due to the upregulation of ion channel genes such as fepA in the lon mutant. The deletion of lon from the Salmonella genome causes oxidative damage and increased expression of virulence genes. It also prompts the secretion of host pro-inflammatory cytokines leading to early clearance of the bacteria from host cells. We conclude that poor bacterial recovery from mice infected with the lon mutant is a result of disrupted bacterial intracellular equilibrium and rapid activation of cytokine expression leading to bacterial lysis.     

The crucial role of polymorphonuclear leukocytes in resistance to Salmonella dublin infections in genetically susceptible and resistant mice

Macrophages are considered to be the mediators of resistance to extra-intestinal Salmonella infections. Nevertheless, the initial cellular response to Salmonella infections consists primarily of polymorphonuclear leukocytes (PMN). To determine whether PMN serve an important function for the infected host, we made mice neutropenic with the rat mAb to RB6–8C5 and infected them i.v. with ≈10³ Salmonella dublin or an isogenic derivative that lacks the virulence plasmid (LD842). We infected BALB/c mice, which have a point mutation in the macrophage-expressed gene Nramp1 that makes them susceptible to Salmonella, and BALB/c.D2 congenic mice, which have the wild-type Nramp1 gene that makes them resistant to Salmonella. Both mouse strains were resistant to LD842, and neutropenia made only the BALB/c strain susceptible to this infection. Neutropenic congenic mice, however, were susceptible only to wild-type S. dublin (plasmid+). These results show a complex interplay between plasmid-virulence genes in Salmonella, host macrophages, and PMN. Mice with normal macrophages need PMN to defend against nontyphoid Salmonella that carry a virulence plasmid but not against Salmonella without virulence plasmids. Mice with a mutant Nramp1 gene need PMN to defend against all Salmonella, even those that lack virulence plasmids. These results, plus the evidence that PMN kill Salmonella efficiently in vitro, suggest that Salmonella have adapted to grow inside macrophages where they are relatively sheltered from PMN. The adaptations that allow Salmonella to survive in macrophages do not protect them from PMN.     

Genetic reductionist approach for dissecting individual roles of GGDEF proteins within the c-di-GMP signaling network in Salmonella

Bacteria have developed an exclusive signal transduction system involving multiple diguanylate cyclase and phosphodiesterase domain-containing proteins (GGDEF and EAL/HD-GYP, respectively) that modulate the levels of the same diffusible molecule, 3′-5′-cyclic diguanylic acid (c-di-GMP), to transmit signals and obtain specific cellular responses. Current knowledge about c-di-GMP signaling has been inferred mainly from the analysis of recombinant bacteria that either lack or overproduce individual members of the pathway, without addressing potential compensatory effects or interferences between them. Here, we dissected c-di-GMP signaling by constructing a Salmonella strain lacking all GGDEF-domain proteins and then producing derivatives, each restoring 1 protein. Our analysis showed that most GGDEF proteins are constitutively expressed and that their expression levels are not interdependent. Complete deletion of genes encoding GGDEF-domain proteins abrogated virulence, motility, long-term survival, and cellulose and fimbriae synthesis. Separate restoration revealed that 4 proteins from Salmonella and 1 from Yersinia pestis exclusively restored cellulose synthesis in a c-di-GMP–dependent manner, indicating that c-di-GMP produced by different GGDEF proteins can activate the same target. However, the restored strain containing the STM4551-encoding gene recovered all other phenotypes by means of gene expression modulation independently of c-di-GMP. Specifically, fimbriae synthesis and virulence were recovered through regulation of csgD and the plasmid-encoded spvAB mRNA levels, respectively. This study provides evidence that the regulation of the GGDEF-domain proteins network occurs at 2 levels: a level that strictly requires c-di-GMP to control enzymatic activities directly, restricted to cellulose synthesis in our experimental conditions, and another that involves gene regulation for which c-di-GMP synthesis can be dispensable.     

Genetic basis of multidrug resistance in Salmonella enterica serovars Enteritidis and Typhimurium isolated from diarrheic calves in Egypt

Up to this date, nothing is known about the molecular basis of antimicrobial resistance in Salmonella isolated from animals in Africa. Therefore, this study was carried out to screen the incidence of multidrug-resistant (MDR) strains of Salmonella from neonatal calf diarrhea in Egypt and also to characterize the molecular basis of this resistance. Nine unique Salmonella isolates were obtained from 220 fecal samples, and six of these showed multidrug resistance phenotypes and harbored at least two antimicrobial resistance genes. Four were Salmonellaenterica serovar Typhimurium and two were S.enterica serovar Enteritidis. Class 1 integrons were identified in all MDR Salmonella isolates. The identified gene cassettes within class 1 integrons were as follows; aminoglycoside adenyltransferase type A (aadA1, aadA2 and aadA5), which confer resistance to streptomycin and spectinomycin, and dihydrofolate reductase gene cassettes (dfrA1, dfrA15 and dfrA15), which confer resistance to trimethoprim. A class 2 integron containing dfrA1-sat2-aadA1 gene cassettes was identified in only one isolate of S. enterica serovar Enteritidis. The β-lactamase-encoding gene, bla_TEM-1, was identified in five isolates and the extended-spectrum β-lactamase-encoding genes, bla_CMY-2 and bla_SHV-12, were identified in S. enterica serovar Typhimurium. Furthermore, the plasmid-mediated quinolone resistance genes, qnrB, qnrS and aac(6′)-Ib-cr, were also identified. To the best of our knowledge, this is the first report of qnrS in S. enterica serovar Enteritidis, qnrB in S. enterica serovar Typhimurium, and aac(6′)-Ib-cr in Salmonella of animal origin. Also, this is the first report of the molecular characterization of antimicrobial resistance in Salmonella isolated from animals in Africa.     

Salmonella promotes virulence by repressing cellulose production

Cellulose is the most abundant organic polymer on Earth. In bacteria, cellulose confers protection against environmental insults and is a constituent of biofilms typically formed on abiotic surfaces. We report that, surprisingly, Salmonella enterica serovar Typhimurium makes cellulose when inside macrophages. We determine that preventing cellulose synthesis increases virulence, whereas stimulation of cellulose synthesis inside macrophages decreases virulence. An attenuated mutant lacking the mgtC gene exhibited increased cellulose levels due to increased expression of the cellulose synthase gene bcsA and of cyclic diguanylate, the allosteric activator of the BcsA protein. Inactivation of bcsA restored wild-type virulence to the Salmonella mgtC mutant, but not to other attenuated mutants displaying a wild-type phenotype regarding cellulose. Our findings indicate that a virulence determinant can promote pathogenicity by repressing a pathogen''s antivirulence trait. Moreover, they suggest that controlling antivirulence traits increases long-term pathogen fitness by mediating a trade-off between acute virulence and transmission.Bacterial pathogens encode genes that promote virulence. Virulence genes increase the fitness of pathogens by fostering replication at the expense of their hosts (1). Typically, virulence genes function by providing protection from host antimicrobial products, enabling the synthesis of nutrients that are limiting in host tissues and by manipulating host pathways in ways that favor pathogen survival at preferred sites. Notably, pathogens also may encode antivirulence genes, that is, genes that hamper pathogens'' virulence (2–5). Here we provide a singular example of a virulence protein that promotes pathogenicity by interfering with the production of an antivirulence factor.Cellulose is a polysaccharide composed of β(1→4)-linked d-glucose units. As a major structural component of the cell walls of plants and many eukaryotic microorganisms, cellulose accounts for ∼1.5 × 10¹² tons of the annual biomass on Earth, making it the most abundant organic polymer on the planet (6). In bacteria, cellulose is an exopolysaccharide normally synthesized in the context of organized bacterial communities known as biofilms. Cellulose inhibits bacterial motility by hindering flagellar rotation (7), and provides cohesion and structural integrity to mature biofilms (8–10).The facultative intracellular pathogen Salmonella enterica serovar Typhimurium causes gastroenteriditis in humans and a systemic infection in mice that resembles typhoid fever (11). During systemic infection, Salmonella survives and replicates in specialized membrane-bound mildly acidic vacuoles within host phagocytic cells (12, 13). Growth within these specialized compartments requires the coordinated expression of an array of virulence determinants (14), including the MgtC protein (15). MgtC is a unique virulence factor because it interacts with and inhibits the activity of Salmonella’s F₁F_o ATP synthase (16), a protein complex that is responsible for synthesis of the majority of the ATP in the bacterium (17) and is also required for virulence (18). MgtC’s action prevents a nonphysiological increase in cytosolic ATP and decrease in cytosolic pH taking place during growth in mildly acidic environments, such as that experienced by Salmonella inside a macrophage phagosome (16).In addition to its role in promoting intramacrophage survival, MgtC enables Salmonella (15, 19) and a number of phylogenetically distant intracellular bacterial pathogens (20–24) to grow normally in low-Mg²⁺ laboratory media. In Salmonella, growth in low-Mg²⁺ media also promotes mgtC expression, even when Salmonella experiences a neutral pH (15, 19). Notably, the mgtC mutant harbors higher ATP levels than the wild-type (WT) strain when grown in low-Mg²⁺ media, similar to what it exhibits on mild acidification of its surroundings (16). These findings suggest that a rise in ATP levels leads to physiological alterations that hinder growth in low-Mg²⁺ media and attenuated virulence.We now report that, surprisingly, Salmonella produces cellulose when inside macrophages. We establish that the MgtC protein promotes Salmonella virulence by limiting cellulose production during infection. We determine that MgtC controls both expression of the cellulose synthase complex and the intracellular levels of cyclic diguanylate (c-di-GMP), the cellulose synthase’s allosteric activator. Virulence can be restored to the mgtC mutant simply by preventing cellulose biosynthesis, which does not affect ATP levels. Our findings illustrate how Salmonella uses a virulence protein to repress the expression of an antivirulence trait during infection of a mammalian host, and they define cellulose as an antivirulence determinant. Moreover, they suggest that pathogens use antivirulence traits to balance acute virulence and transmission.     

PREVALENCE OF DRUG RESISTANCE AND VIRULENCE FEATURES IN Salmonella spp. ISOLATED FROM FOODS ASSOCIATED OR NOT WITH SALMONELLOSIS IN BRAZIL

Salmonella is the most common etiological agent of cases and outbreaks of foodborne diarrheal illnesses. The emergence and spread of Salmonella spp., which has become multi-drug resistant and potentially more pathogenic, have increased the concern with this pathogen. In this study, 237 Salmonella spp., associated or not with foodborne salmonellosis in Brazil, belonging mainly to serotype Enteritidis, were tested for antimicrobial susceptibility and the presence of the virulence genes spvC, invA, sefA and pefA. Of the isolates, 46.8% were sensitive to all antimicrobials and 51.9% were resistant to at least one antimicrobial agent. Resistance to more than one antimicrobial agent was observed in 10.5% of the strains. The highest rates of resistance were observed for streptomycin (35.9%) and nalidixic acid (16.9%). No strain was resistant to cefoxitin, cephalothin, cefotaxime, amikacin, ciprofloxacin and imipenem. The invA gene was detected in all strains. Genes spvC and pefA were found in 48.1% and 44.3% of strains, respectively. The gene sefA was detected in 31.6% of the strains and only among S. Enteritidis. Resistance and virulence determinants were detected in Salmonella strains belonging to several serotypes. The high rates of antibiotic-resistance in strains isolated from poultry products demonstrate the potential risk associated with the consumption of these products and the need to ensure good food hygiene practices from farm to table to reduce the spread of pathogens relevant to public health.     

Effects of indole on drug resistance and virulence of Salmonella enterica serovar Typhimurium revealed by genome-wide analyses

Background

Many Gram-positive and Gram-negative bacteria produce large quantities of indole as an intercellular signal in microbial communities. Indole demonstrated to affect gene expression in Escherichia coli as an intra-species signaling molecule. In contrast to E. coli, Salmonella does not produce indole because it does not harbor tnaA, which encodes the enzyme responsible for tryptophan metabolism. Our previous study demonstrated that E. coli-conditioned medium and indole induce expression of the AcrAB multidrug efflux pump in Salmonella enterica serovar Typhimurium for inter-species communication; however, the global effect of indole on genes in Salmonella remains unknown.

Results

To understand the complete picture of genes regulated by indole, we performed DNA microarray analysis of genes in the S. enterica serovar Typhimurium strain ATCC 14028s affected by indole. Predicted Salmonella phenotypes affected by indole based on the microarray data were also examined in this study. Indole induced expression of genes related to efflux-mediated multidrug resistance, including ramA and acrAB, and repressed those related to host cell invasion encoded in the Salmonella pathogenicity island 1, and flagella production. Reduction of invasive activity and motility of Salmonella by indole was also observed phenotypically.

Conclusion

Our results suggest that indole is an important signaling molecule for inter-species communication to control drug resistance and virulence of S. enterica.     

Molecular basis of virulence in clinical isolates of Escherichia coli and Salmonella species from a tertiary hospital in the Eastern Cape, South Africa

Background

Apart from localized gastrointestinal infections, Escherichia coli and Salmonella species are major causes of systemic disease in both humans and animals. Salmonella spp. cause invasive infections such as enteric fever, septicemia, osteomyelitis and meningitis while certain types of E. coli can cause systemic infections, including pyelonephritis, meningitis and septicemia. These characteristic requires the involvement of a myriad of virulence factors.

Methods

This study investigated the virulence factors of Escherichia coli and Salmonella species in clinical specimens from patients with diarrhoea presenting to health care centres in Oliver R. Tambo District Municipality, Eastern Cape Province, Republic of South Africa. Microbiology analysis involved the use of cultural and molecular techniques.

Results

Out of a total of 315 samples screened, Salmonella isolates were obtained in 119 (37.8%) of cases and these comprised: S. choleraesuis (6%), S. enteritidis (4%), S. eppendorf (1%), S. hadar (1%), S. isangi (8%), S. panama (1%), S. typhi (52%), S. typhimurium (25%) and untyped Salmonella spp. (2%). Among the Salmonella species 87 (73.1%) were invasive. Using molecular diagnostic methods, diarrheagenic E. coli were detected in 90 cases (28.6%): the greater proportion of this were enteroaggregative E. coli (EAEC) 37 (41.1%), enteropathogenic E. coli (EPEC) 21 (23.3%) and enterohemorrhagic E. coli (EHEC) 21 (23.3%). The predominant virulence gene among the diarrheagenic E. coli was EAEC heat-stable enterotoxin astA genes while the virulence genes identified in the Salmonella strains were 15 (12.6%) flic and 105 (88.2%) inv genes. The amino acid identity of the representative genes showed 95-100% similarity to corresponding blast searched sequence.

Conclusions

This study showed the diversity of virulence gene expression in two major enteric pathogens. S. typhi and enteroaggregative E. coli were the predominant enteropathogens in our study area with an indication that EAEC is endemic within our study population. It was observed among other things that some diarrheagenic E. coli isolated from apparently asymptomatic subjects expressed some virulence genes at frequency as high as seen in diarrheagenic cases. This study underlines the importance of understanding the virulence composition and diversity of pathogens for enhanced clinico-epidemiological monitoring and health care delivery.     

Control of bacterial iron homeostasis by manganese

Perception and response to nutritional iron availability by bacteria are essential to control cellular iron homeostasis. The Irr protein from Bradyrhizobium japonicum senses iron through the status of heme biosynthesis to globally regulate iron-dependent gene expression. Heme binds directly to Irr to trigger its degradation. Here, we show that severe manganese limitation created by growth of a Mn²⁺ transport mutant in manganese-limited media resulted in a cellular iron deficiency. In wild-type cells, Irr levels were attenuated under manganese limitation, resulting in reduced promoter occupancy of target genes and altered iron-dependent gene expression. Irr levels were high regardless of manganese availability in a heme-deficient mutant, indicating that manganese normally affects heme-dependent degradation of Irr. Manganese altered the secondary structure of Irr in vitro and inhibited binding of heme to the protein. We propose that manganese limitation destabilizes Irr under low-iron conditions by lowering the threshold of heme that can trigger Irr degradation. The findings implicate a mechanism for the control of iron homeostasis by manganese in a bacterium.     

Intronic enhancers coordinate epithelial-specific looping of the active CFTR locus

The regulated expression of large human genes can depend on long-range interactions to establish appropriate three-dimensional structures across the locus. The cystic fibrosis transmembrane conductance regulator (CFTR) gene, which encompasses 189 kb of genomic DNA, shows a complex pattern of expression with both spatial and temporal regulation. The flanking loci, ASZ1 and CTTNBP2, show very different tissue-specific expression. The mechanisms governing control of CFTR expression remain poorly understood, although they are known to involve intronic regulatory elements. Here, we show a complex looped structure of the CFTR locus in cells that express the gene, which is absent from cells in which the gene is inactive. By using chromatin conformation capture (3C) with a bait probe at the CFTR promoter, we demonstrate close interaction of this region with sequences in the middle of the gene about 100 kb from the promoter and with regions 3′ to the locus that are about 200 kb away. We show that these interacting regions correspond to prominent DNase I hypersensitive sites within the locus. Moreover, these sequences act cooperatively in reporter gene constructs and recruit proteins that modify chromatin structure. The model for CFTR gene expression that is revealed by our data provides a paradigm for other large genes with multiple regulatory elements lying within both introns and intergenic regions. We anticipate that these observations will enable original approaches to designing regulated transgenes for tissue-specific gene therapy protocols.