GLYCOLYTIC ENZYMES AS VACCINES AGAINST SCHISTOSOMIASIS: TESTING SCHISTOSOMA MANSONI PHOSPHOGLYCERATE MUTASE IN MICE.

IF 1 4区医学 Q4 PARASITOLOGY

Journal of Parasitology Pub Date : 2024-03-01 DOI:10.1645/23-7

David B Pirovich, Akram A Da'dara, Patrick J Skelly

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Abstract

Schistosomiasis is a globally burdensome parasitic disease caused by flatworms (blood flukes) in the genus Schistosoma. The current standard treatment for schistosomiasis is the drug praziquantel, but there is an urgent need to advance novel interventions such as vaccines. Several glycolytic enzymes have been evaluated as vaccine targets for schistosomiasis, and data from these studies are reviewed here. Although these parasites are canonically considered to be intracellular, proteomic analysis has revealed that many schistosome glycolytic enzymes are additionally found at the host-interactive surface. We have recently found that the intravascular stage of Schistosoma mansoni (Sm) expresses the glycolytic enzyme phosphoglycerate mutase (PGM) on the tegumental surface. Live parasites display PGM activity, and suppression of PGM gene expression by RNA interference diminishes surface enzyme activity. Recombinant SmPGM (rSmPGM) can cleave its glycolytic substrate, 3-phosphoglycerate and can both bind to plasminogen and promote its conversion to an active form (plasmin) in vitro, suggesting a moonlighting role for this enzyme in regulating thrombosis in vivo. We found that antibodies in sera from chronically infected mice recognize rSmPGM. We also tested the protective efficacy of rSmPGM as a vaccine in the murine model. Although immunization generates high titers of anti-SmPGM antibodies (against both recombinant and native SmPGM), no significant differences in worm numbers were found between vaccinated and control animals.

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作为血吸虫病疫苗的糖酵解酶：在小鼠体内测试曼氏血吸虫磷酸甘油酸变异酶。

血吸虫病是一种由血吸虫属扁形虫（血吸虫）引起的全球性寄生虫病。目前治疗血吸虫病的标准药物是吡喹酮，但迫切需要推进疫苗等新型干预措施。一些糖酵解酶已被评估为血吸虫病的疫苗靶点，本文将对这些研究的数据进行综述。虽然这些寄生虫通常被认为是细胞内寄生的，但蛋白质组分析表明，许多血吸虫糖酵解酶还存在于宿主交互表面。我们最近发现，曼氏血吸虫（Sm）的血管内阶段会在被膜表面表达糖酵解酶磷酸甘油酸变异酶（PGM）。活寄生虫显示出 PGM 活性，通过 RNA 干扰抑制 PGM 基因的表达会降低表面酶的活性。重组 SmPGM（rSmPGM）能裂解其糖酵解底物--3-磷酸甘油酸，并能在体外与纤溶酶原结合并促进其转化为活性形式（纤溶酶），这表明这种酶在调节体内血栓形成方面起着兼职作用。我们发现，慢性感染小鼠血清中的抗体能识别 rSmPGM。我们还在小鼠模型中测试了 rSmPGM 作为疫苗的保护效力。虽然免疫可产生高滴度的抗 SmPGM 抗体（针对重组和原生 SmPGM），但接种疫苗的动物与对照组动物在蠕虫数量上没有发现明显差异。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Parasitology 医学-寄生虫学

CiteScore

2.10

自引率

7.70%

发文量

审稿时长

2 months

期刊介绍： The Journal of Parasitology is the official peer-reviewed journal of the American Society of Parasitologists (ASP). The journal publishes original research covering helminths, protozoa, and other parasitic organisms and serves scientific professionals in microbiology, immunology, veterinary science, pathology, and public health. Journal content includes original research articles, brief research notes, announcements of the Society, and book reviews. Articles are subdivided by topic for ease of reference and range from behavior and pathogenesis to systematics and epidemiology. The journal is published continuously online with one full volume printed at the end of each year.