The role of bcsE gene in the pathogenicity of Salmonella

Effects of bcsE, luxS and rfaG genes on the physiology and pathogenicity of Salmonella Typhimurium

In this study, rfaG, luxS, and bcsE gene mutants of S. Typhimurium ATCC 14028 wild-type strain were generated, and their effects on bacterial physiology and pathogenicity were investigated. Biofilm production capacity and mobility of mutant strains were found to be significantly reduced. Immune response stimulation of 6-8 week-old BALB/c mice infected with wild-type and mutants was evaluated on days 0 and 21 for IL-6, IFN-γ, and IgG, and then systemic infection in mice was determined by the amount of Salmonella recovered from the cecum, spleen, and liver organs. The specific IgG antibody level and the expression level of the cytokines IFN-γ and IL-6 were found to be significantly reduced in mice inoculated with mutant strains compared to the control group. The highest level of colonization in the organs was found in the cecum, and the lowest level of colonization was detected in the liver. In the wild-type-infected group, splenomegaly and staining of the liver were detected. In the groups of mice infected with bcsE and luxS mutants, these symptoms were at a low level. In the groups infected with the rfaG mutant, no significant lesions were detected in the organs.

Characterization and Protective Efficacy of a Salmonella Typhimurium ATCC 14028 sptP Mutant as a Live Attenuated Vaccine Candidate

BACKGROUND

Salmonella Typhimurium poses a substantial health risk to both humans and animals. This study evaluated the potential of using the Salmonella Typhimurium ΔsptP mutant as a live-attenuated vaccine candidate by constructing it through homologous recombination and assessing its key biological properties, including growth characteristics, immunogenicity, and protective efficacy.

METHODS

We generated the ΔsptP mutant through targeted gene deletion, ensuring the preservation of the bacterial strain's growth and stability. In vitro and in vivo assays were performed to compare the invasive capabilities between the mutant and the wild-type strains. Specifically, we examined the invasion into RAW264.7 murine macrophages and mice. Furthermore, the virulence of the mutant was evaluated by determining the median lethal dose (LD50). To evaluate immunogenicity and protection, mice were immunized with 2 × 104 CFUs of the ΔsptP mutant, followed by a booster immunization, and then challenged with a virulent strain.

RESULTS

The ΔsptP mutant exhibited no significant changes in growth characteristics or genetic stability compared to the wild-type strain. However, it demonstrated a significantly diminished capacity for invasion in both murine macrophages and mice. The LD50 for the mutant was 39.92-fold higher than that of the wild-type, indicating a marked reduction in virulence. Mice immunized with the ΔsptP mutant and administered a booster immunization exhibited 87.5% protection against challenge with a virulent strain, as compared to the PBS control group. Moreover, the mutant induced IgG antibody levels comparable to those induced by the wild-type strain.

CONCLUSIONS

The ΔsptP mutant of Salmonella Typhimurium exhibits markedly reduced virulence while retaining robust immunogenicity and protective efficacy. These findings suggest that the ΔsptP mutant is a promising candidate for a live-attenuated vaccine, potentially providing an effective strategy to prevent Salmonella Typhimurium infections.

Invasive Non-Typhoidal Salmonella Lineage Biofilm Formation and Gallbladder Colonization Vary But Do Not Correlate Directly with Known Biofilm-Related Mutations

Non-typhoidal Salmonella (NTS) serovars have a broad host range and cause gastroenteritis in humans. However, invasive NTS (iNTS) bloodstream infections have increased in the last decade, causing 60,000 deaths annually. Human-specific typhoidal Salmonella colonizes and forms biofilms on gallstones, resulting in chronic, asymptomatic infection. iNTS lineages are undergoing genomic reduction and may have adapted to person-to-person transmission via mutations in virulence, bile resistance, and biofilm formation. As such, we sought to determine the capacity of iNTS lineages for biofilm formation and the development of chronic infections in the gallbladder in our mouse model. Of the lineages tested (L1, L2, L3 and UK), only L2 and UK were defective for the rough, dry and red (RDAR) morphotype, correlating with the known bcsG (cellulose) mutation but not with csgD (curli) gene mutations. Biofilm-forming ability was assessed in vitro, which revealed a biofilm formation hierarchy of L3 > ST19 > UK > L1 = L2, which did not correlate directly with either the bcsG or the csgD mutation. By confocal microscopy, biofilms of L2 and UK had significantly less curli and cellulose, while L1 biofilms had significantly lower cellulose. All iNTS strains were able to colonize the mouse gallbladder, liver, and spleen in a similar manner, while L3 had a significantly higher bacterial load in the gallbladder and increased lethality. While there was iNTS lineage variability in biofilm formation, gallbladder colonization, and virulence in a chronic mouse model, all tested lineages were capable of colonization despite possessing biofilm-related mutations. Thus, iNTS strains may be unrecognized chronic pathogens in endemic settings.

Characteristics of a Temperature-Sensitive Mutant Strain of Salmonella Enteritidis and Its Potential as a Live Vaccine Candidate

Salmonella Enteritidis is a common foodborne pathogen transmitted through poultry products, which are its main carriers. Poultry are vaccinated against Salmonella Enteritidis in many countries, despite the absence of clinical symptoms, using commercially available live-attenuated vaccines. We previously constructed a highly attenuated temperature-sensitive (ts) Salmonella Enteritidis mutant, 2S-G10. In the present study, we describe the construction and attenuation-associated characteristics of 2S-G10. We infected 1-day-old chicks with 2S-G10 and the parental strains to evaluate the attenuation. One week after infection, 2S-G10 was not detected in the liver, cecum, or cecal tonsil tissues of the orally inoculated chicks, contrary to the parental strain. This indicates that 2S-G10 was highly attenuated when compared to the parental stain. In vitro experiments revealed the inability of 2S-G10 to grow at the normal body temperature of chickens and invade chicken liver epithelial cells. Moreover, single nucleotide polymorphism (SNP) analysis between the complete genome sequence of 2S-G10 and its parental strain revealed SNPs in bcsE, recG, rfaF, and pepD_1 genes, which are involved in epithelial cell invasion and persistence in host systems, growth, lipopolysaccharide core biosynthesis, and cellular survival under heat stress, respectively. These potential characteristics are consistent with the findings of in vitro experiments. Conclusively, chemical treatment-induced random genetic mutations highly attenuated 2S-G10, implying its potential to be developed as a novel live-attenuated vaccine against Salmonella Enteritidis.

What makes another life possible in bacteria? Global regulators as architects of bacterial biofilms

Biofilm structures are the main mode of evolutionary reproductive adaptation of bacteria, and even these features alone, are sufficient to make them the focus of genetic and physiological studies. As this life form is a multicellular-like life form coordinated by genetic and physiological programming, it is quite different from the planktonic form. In bacterial biofilms, which are often composed of more than one species in nature, there is a clear division of labor, nutrient channels, and a language (signaling) established between the cells forming the biofilm. On the other hand, biofilms, especially formed by pathogens, cause important industrial and clinical problems due to their high resistance to environmental stress conditions. Obtaining new data on the molecular basis of bacterial evolution and understanding the intra- and inter-species ecosystem relations in this context, as well as finding permanent solutions to the serious problems they create, are directly related to a detailed understanding of the genetic regulation of bacterial biofilm structures. Today, it is becoming increasingly certain that environmental signals effective in the transition from planktonic form to biofilm form and their receptor/response molecules are generally managed by similar systems and global regulator molecules in bacteria. In this sense; Besides the quorum sensing (QS) systems, cyclic adenosine monophosphate-catabolite suppressor protein (cAMP-CRP) and bis-(3'-5') cyclic dimeric guanosine monophosphate (c-di-GMP) signaling molecules are of critical importance. In this review article, current information on bacterial biofilms is summarized and interpreted based on this framework.