Outer membrane vesicles (OMVs) are membranous structures frequently observed in Gram-negative bacteria that contain bioactive substances. These vesicles are rich in bacterial antigens that can activate the host\'s immune system, making them a promising candidate vaccine to prevent and manage bacterial infections. The aim of this study was to assess the immunogenicity and protective efficacy of OMVs derived from Salmonella enterica serovar Typhimurium and S. Choleraesuis, while also focusing on enhancing OMV production. Initial experiments showed that OMVs from wild-type strains did not provide complete protection against homologous Salmonella challenge, possible due to the presence of flagella in the purified OMVs samples, which may elicit an unnecessary immune response. To address this, flagellin-deficient mutants of S. Typhimurium and S. Choleraesuis were constructed, designated rSC0196 and rSC0199, respectively. These mutants exhibited reduced cell motility and their OMVs were found to be flagellin-free. Immunization with non-flagellin OMVs derived from rSC0196 induced robust antibody responses and improved survival rates in mice, as compared to the OMVs derived from the wild-type UK-1. In order to enhance OMV production, deletions of ompA or tolR were introduced into rSC0196. The deletion of tolR not only increase the yield of OMVs, but also conferred complete protection against homologous S. Typhimurium challenge in mice. Collectively, these findings indicate that the flagellin-deficient OMVs with a tolR mutation have the potential to serve as a versatile vaccine platform, capable of inducing broad-spectrum protection against significant pathogens.

Regulated delayed attenuation is a well-studied strategy for retaining the immunogenicity of Salmonella-vectored vaccines. In this study, this strategy was used to optimize two previously constructed recombinant Salmonella enterica serovar Typhimurium vaccines expressing S. Choleraesuis O-polysaccharides (OPS). The novel vaccine strains SLT31 (Δasd ΔrmlB-rfbP ΔPcrp::T araC PBAD) and SLT33 (Δasd ΔrfbP ΔpagL::T araC PBADrfbP ΔPcrp::T araC PBAD) were constructed by replacement of the native crp promoter with the arabinose-dependent araC PBAD promoter. As controls, two vaccine strains with direct crp mutations were also constructed, namely, SLT30 (Δasd ΔrmlB-rfbP Δcrp) and SLT32 (Δasd ΔrfbP ΔpagL::T araC PBADrfbP Δcrp). Then, the ability to deliver the heterologous S. Choleraesuis OPS on the Asd+ plasmid pCZ1 to the mouse immune system was evaluated in the strains with or without regulated delayed attenuation. The SLT30 (pCZ1) and SLT31 (pCZ1) strains expressed only the heterologous OPS, while the SLT32 (pCZ1) and SLT33 (pCZ1) strains co-expressed the homologous and heterologous OPS. The strain SLT31 (pCZ1) or SLT33 (pCZ1), which exhibited regulated delayed attenuation, colonized mouse tissues significantly better and stimulated stronger antibody responses against S. Choleraesuis LPS post immunization than the SLT30 (pCZ1) or SLT32 (pCZ1) strain. Immunization with SLT31 (pCZ1) or SLT33 (pCZ1) resulted in a significant reduction in bacterial loads in mouse tissues and a greater degree of protection against a lethal S. Choleraesuis dose compared with the effects observed after SLT30 (pCZ1) or SLT32 (pCZ1) immunization (100% vs. 80% or 70% vs. 50%, respectively). In addition, all four vaccines conferred complete protection against S. Typhimurium challenge. Overall, our study demonstrates that regulated delayed attenuation via an araC PBAD-regulated crp gene can enhance the cross-protection by Salmonella-vectored vaccines expressing heterologous OPS, and strain SLT31 (pCZ1) is a good candidate vaccine for preventing both S. Typhimurium and S. Choleraesuis infections.

Salmonella infections remain a big problem worldwide, causing enteric fever by Salmonella Typhi (or Paratyphi) or self-limiting gastroenteritis by non-typhoidal Salmonella (NTS) in healthy individuals. NTS may become invasive and cause septicemia in elderly or immuno-compromised individuals, leading to high mortality and morbidity. No vaccines are currently available for preventing NTS infection in human. As these invasive NTS are restricted to several O-antigen serogroups including B1, D1, C1, and C2, O-antigen polysaccharide is believed to be a good target for vaccine development. In this study, a strategy of O-serotype conversion was investigated to develop live attenuated S. Typhimurium vaccines against the major serovars of NTS infections. The immunodominant O4 serotype of S. Typhimurium was converted into O9, O7, and O8 serotypes through unmarked chromosomal deletion-insertion mutations. O-serotype conversion was confirmed by LPS silver staining and western blotting. All O-serotype conversion mutations were successfully introduced into the live attenuated S. Typhimurium vaccine S738 (Δcrp Δcya) to evaluate their immunogenicity in mice model. The vaccine candidates induced high amounts of heterologous O-polysaccharide-specific functional IgG responses. Vaccinated mice survived a challenge of 100 times the 50% lethality dose (LD50) of wild-type S. Typhimurium. Protective efficacy against heterologous virulent Salmonella challenges was highly O-serotype related. Furthermore, broad-spectrum protection against S. Typhimurium, S. Enteritidis, and S. Choleraesuis was observed by co-vaccination of O9 and O7 O-serotype-converted vaccine candidates. This study highlights the strategy of expressing heterologous O-polysaccharides via genetic engineering in developing live attenuated S. Typhimurium vaccines against NTS infections.