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用于土壤传播蠕虫的重组亚单位疫苗。

Recombinant subunit vaccines for soil-transmitted helminths.

作者信息

Noon Jason B, Aroian Raffi V

机构信息

Program in Molecular Medicine,University of Massachusetts Medical School,Worcester,MA 01605,USA.

出版信息

Parasitology. 2017 Dec;144(14):1845-1870. doi: 10.1017/S003118201700138X. Epub 2017 Aug 3.

DOI:10.1017/S003118201700138X
PMID:28770689
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5729844/
Abstract

Soil-transmitted helminths (STHs) collectively infect one fourth of all human beings, and the majority of livestock in the developing world. These gastrointestinal nematodes are the most important parasites on earth with regard to their prevalence in humans and livestock. Current anthelmintic drugs are losing their efficacies due to increasing drug resistance, particularly in STHs of livestock and drug treatment is often followed by rapid reinfection due to failure of the immune system to develop a protective response. Vaccines against STHs offer what drugs cannot accomplish alone. Because such vaccines would have to be produced on such a large scale, and be cost effective, recombinant subunit vaccines that include a minimum number of proteins produced in relatively simple and inexpensive expression systems are required. Here, we summarize all of the previous studies pertaining to recombinant subunit vaccines for STHs of humans and livestock with the goal of both informing the public of just how critical these parasites are, and to help guide future developments. We also discuss several key areas of vaccine development, which we believe to be critical for developing more potent recombinant subunit vaccines with broad-spectrum protection.

摘要

土源性蠕虫(STH)感染了全球四分之一的人口以及发展中世界的大部分家畜。就其在人类和家畜中的流行程度而言,这些胃肠道线虫是地球上最重要的寄生虫。由于耐药性不断增加,目前的驱虫药物正在失去效力,特别是在家畜的土源性蠕虫中,而且由于免疫系统无法产生保护性反应,药物治疗后往往会迅速再次感染。针对土源性蠕虫的疫苗具有药物单独无法实现的作用。由于此类疫苗必须大规模生产且具有成本效益,因此需要重组亚单位疫苗,该疫苗包含在相对简单且廉价的表达系统中产生的最少数量的蛋白质。在此,我们总结了以前所有关于人类和家畜土源性蠕虫重组亚单位疫苗的研究,目的是让公众了解这些寄生虫的严重性,并帮助指导未来的发展。我们还讨论了疫苗开发的几个关键领域,我们认为这些领域对于开发更有效的具有广谱保护作用的重组亚单位疫苗至关重要。

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