Sequence elements within the PEXEL motif and its downstream region modulate PTEX-dependent protein export in Plasmodium falciparum.

IF 3.6 3区生物学 Q3 CELL BIOLOGY

Traffic Pub Date : 2024-01-01 Epub Date: 2023-11-05 DOI:10.1111/tra.12922

Mikha Gabriela, Claudia B G Barnes, Dickson Leong, Brad E Sleebs, Molly Parkyn Schneider, Dene R Littler, Brendan S Crabb, Tania F de Koning-Ward, Paul R Gilson

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Abstract

The parasite Plasmodium falciparum causes the most severe form of malaria and to invade and replicate in red blood cells (RBCs), it exports hundreds of proteins across the encasing parasitophorous vacuole membrane (PVM) into this host cell. The exported proteins help modify the RBC to support rapid parasite growth and avoidance of the human immune system. Most exported proteins possess a conserved Plasmodium export element (PEXEL) motif with the consensus RxLxE/D/Q amino acid sequence, which acts as a proteolytic cleavage recognition site within the parasite's endoplasmic reticulum (ER). Cleavage occurs after the P₁ L residue and is thought to help release the protein from the ER so it can be putatively escorted by the HSP101 chaperone to the parasitophorous vacuole space surrounding the intraerythrocytic parasite. HSP101 and its cargo are then thought to assemble with the rest of a Plasmodium translocon for exported proteins (PTEX) complex, that then recognises the xE/D/Q capped N-terminus of the exported protein and translocates it across the vacuole membrane into the RBC compartment. Here, we present evidence that supports a dual role for the PEXEL's conserved P₂ ' position E/Q/D residue, first, for plasmepsin V cleavage in the ER, and second, for efficient PTEX mediated export across the PVM into the RBC. We also present evidence that the downstream 'spacer' region separating the PEXEL motif from the folded functional region of the exported protein controls cargo interaction with PTEX as well. The spacer must be of a sufficient length and permissive amino acid composition to engage the HSP101 unfoldase component of PTEX to be efficiently translocated into the RBC compartment.

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PEXEL基序及其下游区域内的序列元件调节恶性疟原虫中PTEX依赖性蛋白的输出。

寄生虫恶性疟原虫会导致最严重的疟疾，并在红细胞（RBCs）中入侵和复制，它通过包裹的寄生液泡膜（PVM）将数百种蛋白质输出到宿主细胞中。输出的蛋白质有助于修饰红细胞，以支持寄生虫的快速生长和避免人类免疫系统。大多数输出的蛋白质具有一个保守的疟原虫输出元件（PEXEL）基序，其具有一致的RxLxE/D/Q氨基酸序列，该序列在寄生虫的内质网（ER）内充当蛋白水解切割识别位点。裂解发生在P1L残基之后，并被认为有助于从内质网释放蛋白质，因此它可以被认为由HSP101伴侣护送到红细胞内寄生虫周围的寄生液泡空间。HSP101及其货物随后被认为与输出蛋白质的疟原虫转运子（PTEX）复合物的其余部分组装，然后识别输出蛋白质的xE/D/Q封端的N末端，并将其穿过液泡膜转运到红细胞隔室。在这里，我们提出的证据支持PEXEL保守的P2’位置E/Q/D残基的双重作用，首先是在内质网中切割纤溶酶原V，其次是PTEX介导的有效出口穿过PVM进入RBC。我们还提出证据表明，将PEXEL基序与出口蛋白质的折叠功能区分离的下游“间隔区”也控制着与PTEX的货物相互作用。间隔区必须具有足够的长度和允许的氨基酸组成，以接合PTEX的HSP101不折叠组分，从而有效地转运到RBC隔室中。

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

Traffic 生物-细胞生物学

CiteScore

8.10

自引率

2.20%

发文量

审稿时长

2 months

期刊介绍： Traffic encourages and facilitates the publication of papers in any field relating to intracellular transport in health and disease. Traffic papers span disciplines such as developmental biology, neuroscience, innate and adaptive immunity, epithelial cell biology, intracellular pathogens and host-pathogen interactions, among others using any eukaryotic model system. Areas of particular interest include protein, nucleic acid and lipid traffic, molecular motors, intracellular pathogens, intracellular proteolysis, nuclear import and export, cytokinesis and the cell cycle, the interface between signaling and trafficking or localization, protein translocation, the cell biology of adaptive an innate immunity, organelle biogenesis, metabolism, cell polarity and organization, and organelle movement. All aspects of the structural, molecular biology, biochemistry, genetics, morphology, intracellular signaling and relationship to hereditary or infectious diseases will be covered. Manuscripts must provide a clear conceptual or mechanistic advance. The editors will reject papers that require major changes, including addition of significant experimental data or other significant revision. Traffic will consider manuscripts of any length, but encourages authors to limit their papers to 16 typeset pages or less.