Invasion and egress cascade in intracellular protozoa: Part 2 (T. gondii)

Pub Date : 2021-08-01 DOI:10.21608/puj.2021.86834.1125

S. Abaza

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Abstract

As an apicomplexan member, T. gondii has a complex life cycle that involves multiplication within vertebrate and invertebrate hosts by specialized cell-invasive and egressed life cycle stages, called zoites. They are unique eukaryotic cells with characteristic four main sub-cellular structures. They include a specific inner membrane complex beneath the plasma membrane, an apical “conoid” to sustain parasite micro-tubular cytoskeleton, a plastid responsible for lipids synthesis, and specific secretory organelles; micronemes (MICs), rhoptries (ROs) and dense granules (DGs). The last is involved in maturation of the parasitophorous vacuole (PV), where the parasite multiplies; the first essential step after invasion and before egress. Similar to Plasmodium sp., successful invasion and egress cascade accounts mainly on efficient rapid invasion without alteration of host cell cytoskeleton, and multiplication within host cells inside its PV. However, Plasmodium sp. export proteins into host cell cytoplasm and plasma membrane utilizing PV as a trafficking vehicle. Instead, PV of T. gondii zoites utilized abundantly expressed DGs and ROs proteins to build up the intra-vacuolar membranous network (IVMN) for trafficking. The present editorial aims to clarify roles of proteins released from MICs, ROs and DGs in invasion and egress cascade of T. gondii.

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细胞内原生动物的入侵和输出级联:第2部分(弓形虫)

作为顶复合体的成员，弓形虫有一个复杂的生命周期，包括在脊椎动物和无脊椎动物宿主中通过特殊的细胞入侵和退出生命周期阶段进行繁殖，称为zoite。它们是独特的真核细胞，具有四个主要亚细胞结构的特征。它们包括质膜下的特定内膜复合体、维持寄生虫微管细胞骨架的顶端“圆锥形体”、负责脂质合成的质体和特定的分泌细胞器;微素(mic)、红素(ROs)和致密颗粒(dg)。最后一个过程涉及寄生液泡(PV)的成熟，在那里寄生虫繁殖;这是入侵后和撤离前的第一步。与疟原虫类似，成功的入侵和退出级联反应主要是在不改变宿主细胞骨架的情况下有效地快速入侵，并在宿主细胞内进行PV内增殖。然而，疟原虫利用PV作为运输载体将蛋白质输出到宿主细胞质和质膜中。相反，弓形虫的PV利用大量表达的DGs和ROs蛋白来构建液泡内膜网络(IVMN)进行运输。本文旨在阐明从mic、ROs和dg中释放的蛋白在弓形虫入侵和输出级联中的作用。

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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