IL-10 inhibition during immunization improves vaccine-induced protection against Staphylococcus aureus infection
Alanna M. Kelly, Karen N. McCarthy, Tracey J. Claxton, Simon R. Carlile, Eoin C. O’Brien, Emilio G. Vozza, Kingston H.G. Mills, Rachel M. McLoughlin
Alanna M. Kelly, Karen N. McCarthy, Tracey J. Claxton, Simon R. Carlile, Eoin C. O’Brien, Emilio G. Vozza, Kingston H.G. Mills, Rachel M. McLoughlin
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Research Article Immunology Vaccines

IL-10 inhibition during immunization improves vaccine-induced protection against Staphylococcus aureus infection

Abstract

Staphylococcus aureus is a major human pathogen. An effective anti–S. aureus vaccine remains elusive as the correlates of protection are ill-defined. Targeting specific T cell populations is an important strategy for improving anti–S. aureus vaccine efficacy. Potential bottlenecks that remain are S. aureus–induced immunosuppression and the impact this might have on vaccine-induced immunity. S. aureus induces IL-10, which impedes effector T cell responses, facilitating persistence during both colonization and infection. Thus, it was hypothesized that transient targeting of IL-10 might represent an innovative way to improve vaccine efficacy. In this study, IL-10 expression was elevated in the nares of persistent carriers of S. aureus, and this was associated with reduced systemic S. aureus–specific Th1 responses. This suggests that systemic responses are remodeled because of commensal exposure to S. aureus, which negatively implicates vaccine function. To provide proof of concept that targeting immunosuppressive responses during immunization may be a useful approach to improve vaccine efficacy, we immunized mice with T cell–activating vaccines in combination with IL-10–neutralizing antibodies. Blocking IL-10 during vaccination enhanced effector T cell responses and improved bacterial clearance during subsequent systemic and subcutaneous infection. Taken together, these results reveal a potentially novel strategy for improving anti–S. aureus vaccine efficacy.

Authors

Alanna M. Kelly, Karen N. McCarthy, Tracey J. Claxton, Simon R. Carlile, Eoin C. O’Brien, Emilio G. Vozza, Kingston H.G. Mills, Rachel M. McLoughlin

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Figure 1

Persistent nasal colonization with S. aureus is associated with enhanced IL-10 responses locally within the nasal tissue and altered systemic T cell responses upon S. aureus reexposure.

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Persistent nasal colonization with S. aureus is associated with enhanced...
Persistently colonized individuals were identified as those who had 3 consecutive nasal swab cultures positive for S. aureus over a 6-week period. Individuals who tested negative for each swab culture were classified as “noncolonized.” Nasal mucosa was swabbed, and RNA was extracted. IL10 gene expression levels were assessed using quantitative reverse transcription PCR (A). The mRNA values were expressed as mean relative expression ± SEM and compared with baseline IL-10 expression from noncolonized individuals after normalizing to β-actin RNA expression. (Experimental unit = 1 donor, n = 12/group.) Mucosal lining fluid (MLF) was collected using Nasosorption FX·i devices, and IL-10 concentration was measured using a V-plex multiplex ELISA (B). Results are expressed as mean protein expression ± SEM. (Experimental unit = 1 donor, n = 12/group.) Purified CD4+ T cells were carboxyfluorescein diacetate succinimidyl ester–labeled (CFSE-labeled) and cocultured with autologous irradiated antigen-presenting cells from a subgroup of persistently colonized or noncolonized individuals. Cells were stimulated with media alone, ClfA (0.88 μM), or heat-killed S. aureus Newman strain (1 μg/mL) for 8 days. The proportions of IFN-γ+ (C), TNF+ (D), and IL-17+ (E) proliferating memory CD45RO+CD4+ T cells were then assessed. Values are expressed as mean fold-change ± SEM. (Experimental unit = 1 donor, n = 9/group.) Statistical analysis was carried out by Mann-Whitney U test to analyze variances between groups for gene expression and ELISA data or 2-way ANOVA with Holm-Šídák posttest for flow cytometry data. *P ≤ 0.05; **P ≤ 0.01.