沙眼衣原体T细胞疫苗的研发。
Development of a Chlamydia trachomatis T cell Vaccine.
作者信息
Karunakaran Karuna P, Yu Hong, Foster Leonard J, Brunham Robert C
机构信息
British Columbia Centre for Disease Control, Vancouver, B.C., Canada.
出版信息
Hum Vaccin. 2010 Aug;6(8):676-80. doi: 10.4161/hv.6.8.12299. Epub 2010 Aug 1.
Abstract
The immune correlates of protection for most of the currently used vaccines are based on long-lived humoral immunity. Vaccines based on humoral immunity alone are unlikely to protect against infections caused by intracellular pathogens and today's most pressing infectious diseases of public health importance are caused by intracellular infections that not only include Chlamydia trachomatis but also tuberculosis, malaria, and HIV/AIDS. For these infections, vaccines that induce cellular immune responses are essential. Major impediments in developing such vaccines include difficulty in identifying relevant T cell antigens and delivering them in ways that elicit protective cellular immunity. In turn this is compounded by the complexity and plasticity of T cell developmental pathways that often correlate with specific aspects of protective immunity. Genomics and proteomics now provide tools to allow unbiased selection of candidate T cell antigens. This review mainly focuses on an immunoproteomic approach used in our laboratory to identify Chlamydia T cell antigens and how these T cell antigens can be developed into a future human Chlamydia vaccine.
摘要
目前大多数常用疫苗的保护性免疫相关因素基于持久的体液免疫。仅基于体液免疫的疫苗不太可能预防由细胞内病原体引起的感染,而当今具有最重要公共卫生意义的紧迫传染病是由细胞内感染引起的,这些感染不仅包括沙眼衣原体,还包括结核病、疟疾和艾滋病毒/艾滋病。对于这些感染,诱导细胞免疫反应的疫苗至关重要。开发此类疫苗的主要障碍包括难以识别相关的T细胞抗原以及以引发保护性细胞免疫的方式递送这些抗原。反过来,这又因T细胞发育途径的复杂性和可塑性而变得更加复杂,而这些途径通常与保护性免疫的特定方面相关。基因组学和蛋白质组学现在提供了工具,可用于无偏见地选择候选T细胞抗原。本综述主要关注我们实验室用于鉴定衣原体T细胞抗原的免疫蛋白质组学方法,以及这些T细胞抗原如何能够被开发成未来的人类衣原体疫苗。
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