In vivo analysis of staphylococcus aureus-infected mice reveals differential temporal and spatial expression patterns of fhuD2

Staphylococcus aureus is an opportunistic human pathogen and a major cause of invasive infections such as bacteremia, endocarditis, pneumonia and wound infections. FhuD2 is a staphylococcal lipoprotein involved in the uptake of iron-hydroxymate and is under the control of the iron uptake regulator Fur. The protein is part of an investigational multi-component vaccine formulation that has shown protective efficacy in several murine models of infection. Even though fhuD2 expression was shown to be upregulated in murine kidneys infected with S. aureus, it is unknown whether the bacterium undergoes increased iron deprivation during prolonged infection. Furthermore, different infection niches of S. aureus might provide different environments and iron availability resulting in different fhuD2 expression pattern within different host organs. To address these questions, we characterized the in vitro expression of the fhuD2 gene and confirmed Fur-dependent iron-regulation of its expression. We further investigated its expression in mice infected with a bioluminescent reporter strain of S. aureus expressing the luciferase operon under the control of the fhuD2 promoter. The emission of bioluminescence in different organs was followed over a seven-day time course, as well as quantitative real-time PCR analysis of the RNA transcribed from the endogenous fhuD2 gene. Using this approach, we could show that fhuD2 expression was induced during infection in all organs analyzed and that differences in expression were observed in the temporal expression profiles, and between infected organs. Our data suggest that S. aureus undergoes increased iron deprivation during progression of infection in diverse host organs and accordingly induces dedicated iron acquisition mechanisms. Since FhuD2 plays a central role in providing the pathogen with the required iron, further knowledge of the patterns of fhuD2 expression in vivo during infection is instrumental in better defining the role of this antigen in S. aureus pathogenesis and as a vaccine antigen

Can we defeat meningococcal disease in low and middle income countries?

The development of multivalent conjugate and protein-based meningococcal vaccines may make global control of meningococcal disease possible. However, achieving control of meningococcal disease in low and middle income countries will be challenging. In low income countries whose vaccination programmes receive financial support from the Global Alliance for Vaccination and Immunisation, the main challenge is lack of sufficient epidemiological information to allow rational decisions on vaccine introduction to be made and, in these countries, enhanced surveillance is needed. In middle income countries, financial challenges predominate. These could be met by demonstration of the cost effectiveness of new meningococcal vaccines and through the introduction of a tiered-pricing system

A stable luciferase reporter plasmid for in vivo imaging in murine models of Staphylococcus aureus infections

In vivo imaging of bioluminescent bacteria permits their visualization in infected mice, allowing spatial and temporal evaluation of infection progression. Most available bioluminescent strains were obtained by integration of the luciferase genes into the bacterial chromosome, a challenging and time-consuming approach. Recently, episomal plasmids were used, which were introduced in bacteria and expressed all genes required for bioluminescence emission. However, the plasmid was progressively lost in vitro and in vivo, if bacteria were not maintained under antibiotic selective pressure. Increased stability could be obtained inserting into the plasmid backbone sequences that assured plasmid partition between daughter bacterial cells, or caused death of bacteria that had lost the plasmid. So far, no detailed analysis was performed of either plasmid stability in vivo or contribution of different stabilizing sequence types. Here we report the construction of a plasmid, which includes the Photorhabdus luminescens lux cassette expressed under the control of a Staphylococcus aureus specific gene promoter, and toxin/antitoxin (T/A) and partition sequences (Par) conferring stability and transmissibility of the plasmid. Following infection of mice with S. aureus carrying this plasmid, we demonstrated that the promoter-lux fusion was functional in vivo, that the plasmid was retained by 70-100% of bacterial cells 7 days post-infection, and that both stabilizing sequence types were required to maximize plasmid retention. These data suggest that the plasmid can be a valuable tool to study gene expression and bacterial spread in small laboratory animals infected with S. aureus or possibly other Gram-positive human pathogens.</p

<i>In vivo</i> analysis of <i>staphylococcus aureus</i>-infected mice reveals differential temporal and spatial expression patterns of fhud2

Staphylococcus aureus is an opportunistic human pathogen and a major cause of invasive infections such as bacteremia, endocarditis, pneumonia, and wound infections. FhuD2 is a staphylococcal lipoprotein involved in the uptake of iron-hydroxymate and is under the control of the iron uptake regulator Fur. This protein is part of an investigational multicomponent vaccine formulation that has shown protective efficacy in several murine models of infection. Even though fhuD2 expression has been shown to be upregulated in murine kidneys infected with S. aureus, it is not known whether the bacterium undergoes increased iron deprivation during prolonged infection. Furthermore, different S. aureus infection niches might provide different environments and levels of iron availability, resulting in different fhuD2 expression patterns among organs of the same host. To address these questions, we characterized the in vitro expression of the fhuD2 gene and confirmed Fur-dependent regulation of its expression. We further investigated its expression in mice infected with a bioluminescent reporter strain of S. aureus expressing the luciferase operon under the control of the fhuD2 promoter. The emission of bioluminescence in different organs was followed over a 7-day time course, and quantitative real-time PCR analysis of the RNA transcribed from the endogenous fhuD2 gene was performed. Using this approach, we were able to show that fhuD2 expression was induced during infection in all organs analyzed and that differences in expression were observed at different time points and in different infected organs. Our data suggest that S. aureus undergoes increased iron deprivation during the progression of infection in diverse host organs and accordingly induces dedicated iron acquisition mechanisms. Since FhuD2 plays a central role in providing the pathogen with the required iron, further knowledge of the patterns of fhuD2 expression in vivo during infection will be instrumental in better defining the role of this antigen in S. aureus pathogenesis and as a vaccine antigen

<i>In vivo</i> analysis of <i>staphylococcus aureus</i>-infected mice reveals differential temporal and spatial expression patterns of fhud2

Staphylococcus aureus is an opportunistic human pathogen and a major cause of invasive infections such as bacteremia, endocarditis, pneumonia, and wound infections. FhuD2 is a staphylococcal lipoprotein involved in the uptake of iron-hydroxymate and is under the control of the iron uptake regulator Fur. This protein is part of an investigational multicomponent vaccine formulation that has shown protective efficacy in several murine models of infection. Even though fhuD2 expression has been shown to be upregulated in murine kidneys infected with S. aureus, it is not known whether the bacterium undergoes increased iron deprivation during prolonged infection. Furthermore, different S. aureus infection niches might provide different environments and levels of iron availability, resulting in different fhuD2 expression patterns among organs of the same host. To address these questions, we characterized the in vitro expression of the fhuD2 gene and confirmed Fur-dependent regulation of its expression. We further investigated its expression in mice infected with a bioluminescent reporter strain of S. aureus expressing the luciferase operon under the control of the fhuD2 promoter. The emission of bioluminescence in different organs was followed over a 7-day time course, and quantitative real-time PCR analysis of the RNA transcribed from the endogenous fhuD2 gene was performed. Using this approach, we were able to show that fhuD2 expression was induced during infection in all organs analyzed and that differences in expression were observed at different time points and in different infected organs. Our data suggest that S. aureus undergoes increased iron deprivation during the progression of infection in diverse host organs and accordingly induces dedicated iron acquisition mechanisms. Since FhuD2 plays a central role in providing the pathogen with the required iron, further knowledge of the patterns of fhuD2 expression in vivo during infection will be instrumental in better defining the role of this antigen in S. aureus pathogenesis and as a vaccine antigen

Antibody-mediated immunity induced by engineered Escherichia coli OMVs carrying heterologous antigens in their lumen

Background: Outer membrane vesicles (OMVs) from Gram-negative bacteria are gaining increasing attention as vaccine platform for their built-in adjuvanticity and for their potential use as carriers of heterologous antigens. These 2 properties offer the opportunity to make highly effective, easy to produce multi-valent vaccines. OMVs can be loaded with foreign antigens by targeting protein expression either to the outer membrane or to the periplasm of the OMV-producing strain. Periplasmic expression is simple and relatively efficient but leads to the accumulation of recombinant antigens in the lumen of OMVs and the ability of OMVs carrying internalized antigens to induce antigen-specific antibody responses has been only marginally investigated and is considered to be sub-optimal. Methods: We have systematically analyzed in qualitative and quantitative terms antibody responses induced by OMVs carrying different heterologous antigens in their lumen. Group A Streptococcus (GAS) Slo, SpyCEP, Spy0269 and Group B Streptococcus (GBS) SAM_1372 were fused to the OmpA leader sequence for secretion and expressed in Escherichia coli. OMVs from the recombinant strains were purified and tested for immunogenicity and protective activity. Results: All proteins were incorporated into the OMVs lumen in their native conformation. Upon mice immunization, OMVs induced high functional antibody titers against the recombinant proteins. Furthermore, immunization with Slo-OMVs and SpyCEP-OMVs protected mice against GAS lethal challenge. Conclusions: The efficiency of antigen delivery to the vesicular lumen via periplasmic expression, and the surprisingly high immunogenicity and protective activity of OMVs carrying internalized recombinant antigens further strengthens the potential of OMVs as vaccine platform

Structure, dynamics and immunogenicity of a catalytically inactive CXC chemokine-degrading protease SpyCEP from Streptococcus pyogene

Over 18 million disease cases and half a million deaths worldwide are estimated to be caused annually by Group A Streptococcus. A vaccine to prevent GAS disease is urgently needed. SpyCEP (Streptococcus pyogenes Cell-Envelope Proteinase) is a surface-exposed serine protease that inactivates chemokines, impairing neutrophil recruitment and bacterial clearance, and has shown promising immunogenicity in preclinical models. Although SpyCEP structure has been partially characterized, a more complete and higher resolution understanding of its antigenic features would be desirable prior to large scale manufacturing. To address these gaps and facilitate development of this globally important vaccine, we performed immunogenicity studies with a safety-engineered SpyCEP mutant, and comprehensively characterized its structure by combining X-ray crystallography, NMR spectroscopy and molecular dynamics simulations. We found that the catalytically-inactive SpyCEP antigen conferred protection similar to wild-type SpyCEP in a mouse infection model. Further, a new higher-resolution crystal structure of the inactive SpyCEP mutant provided new insights into this large chemokine protease comprising nine domains derived from two non-covalently linked fragments. NMR spectroscopy and molecular simulation analyses revealed conformational flexibility that is likely important for optimal substrate recognition and overall function. These combined immunogenicity and structural data demonstrate that the full-length SpyCEP inactive mutant is a strong candidate human vaccine antigen. These findings show how a multi-disciplinary study was used to overcome obstacles in the development of a GAS vaccine, an approach applicable to other future vaccine programs. Moreover, the information provided may also facilitate the structure-based discovery of small-molecule therapeutics targeting SpyCEP protease inhibition