Pope Caroline, Oliver Elizabeth H, Ma Jiangtao, Langton Hewer Claire, Mitchell Tim J, Finn Adam
School of Cellular and Molecular Medicine, University of Bristol, Bristol BS8 1TD, UK.
Division of Infection and Immunity, University of Glasgow, Glasgow Biomedical Research Centre, G12 8TA, UK.
Vaccine. 2015 Mar 30;33(14):1711-8. doi: 10.1016/j.vaccine.2015.02.012. Epub 2015 Feb 17.
Streptococcus pneumoniae colonises the upper respiratory tract and can cause pneumonia, meningitis and otitis media. Existing pneumococcal conjugate vaccines are expensive to produce and only protect against 13 of the 90+ pneumococcal serotypes; hence there is an urgent need for the development of new vaccines. We have shown previously in mice that pneumolysin (Ply) and a non-toxic variant (Δ6Ply) enhance antibody responses when genetically fused to pneumococcal surface adhesin A (PsaA), a potentially valuable effect for future vaccines. We investigated this adjuvanticity in human paediatric mucosal primary immune cell cultures. Adenoidal mononuclear cells (AMNC) from children aged 0-15 years (n=46) were stimulated with conjugated, admixed or individual proteins, cell viability and CD4+ T-cell proliferative responses were assessed using flow cytometry and cytokine secretion was measured using multiplex technology. Proliferation of CD4+ T-cells in response to PsaAPly, was significantly higher than responses to individual or admixed proteins (p=0.002). In contrast, an enhanced response to PsaAΔ6Ply compared to individual or admixed proteins only occurred at higher concentrations (p<0.01). Evaluation of cytotoxicity suggested that responses occurred when Ply-induced cytolysis was inhibited, either by fusion or mutation, but importantly an additional toxicity independent immune enhancing effect was also apparent as a result of fusion. Responses were MHC class II dependent and had a Th1/Th17 profile. Genetic fusion of Δ6Ply to PsaA significantly modulates and enhances pro-inflammatory CD4+ T-cell responses without the cytolytic effects of some other pneumolysoids. Membrane binding activity of such proteins may confer valuable adjuvant properties as fusion may assist Δ6Ply to deliver PsaA to the APC surface effectively, contributing to the initiation of anti-pneumococcal CD4+ T-cell immunity.
肺炎链球菌定殖于上呼吸道,可引发肺炎、脑膜炎和中耳炎。现有的肺炎球菌结合疫苗生产成本高昂,且仅能预防90多种肺炎球菌血清型中的13种;因此,迫切需要研发新型疫苗。我们之前在小鼠实验中表明,将肺炎溶血素(Ply)和一种无毒变体(Δ6Ply)与肺炎球菌表面黏附素A(PsaA)进行基因融合时,可增强抗体反应,这对未来疫苗而言可能是一项有价值的作用。我们在人类儿童黏膜原发性免疫细胞培养物中研究了这种佐剂活性。用结合蛋白、混合蛋白或单一蛋白刺激来自0至15岁儿童(n = 46)的腺样体单核细胞(AMNC),使用流式细胞术评估细胞活力和CD4 + T细胞增殖反应,并使用多重技术测量细胞因子分泌。CD4 + T细胞对PsaAPly的增殖反应显著高于对单一或混合蛋白的反应(p = 0.002)。相比之下,与单一或混合蛋白相比,对PsaAΔ6Ply的反应增强仅在较高浓度时出现(p < 0.01)。细胞毒性评估表明,当通过融合或突变抑制Ply诱导的细胞溶解时会出现反应,但重要的是,融合还产生了一种额外的与毒性无关的免疫增强效应。反应依赖于MHC II类,具有Th1/Th17特征。Δ6Ply与PsaA的基因融合可显著调节和增强促炎性CD4 + T细胞反应,而无其他一些肺炎溶素的细胞溶解作用。此类蛋白的膜结合活性可能赋予有价值的佐剂特性,因为融合可能有助于Δ6Ply将PsaA有效递送至抗原呈递细胞表面,从而促进抗肺炎球菌CD4 + T细胞免疫的启动。
