Chi Min Ho scite author profile

The putative Plasmodium translocon of exported proteins (PTEX) is essential for transport of malarial effector proteins across a parasite-encasing vacuolar membrane into host erythrocytes, but the mechanism of this process remains unknown. Here we show that PTEX is a bona fide translocon by determining structures of the PTEX core complex at near-atomic resolution using cryo-electron microscopy. We isolated the endogenous PTEX core complex containing EXP2, PTEX150 and HSP101 from Plasmodium falciparum in the 'engaged' and 'resetting' states of endogenous cargo translocation using epitope tags inserted using the CRISPR-Cas9 system. In the structures, EXP2 and PTEX150 interdigitate to form a static, funnel-shaped pseudo-seven-fold-symmetric protein-conducting channel spanning the vacuolar membrane. The spiral-shaped AAA+ HSP101 hexamer is tethered above this funnel, and undergoes pronounced compaction that allows three of six tyrosine-bearing pore loops lining the HSP101 channel to dissociate from the cargo, resetting the translocon for the next threading cycle. Our work reveals the mechanism of P. falciparum effector export, and will inform structure-based design of drugs targeting this unique translocon.

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Bottom-up structural proteomics: cryoEM of protein complexes enriched from the cellular milieu

Lai

et al. 2019

Nat Methods

137

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X-ray crystallography and recombinant protein production have enabled an exponential increase in atomic structures, but often require non-native constructs involving mutations or truncations, and are challenged by membrane proteins and large multi-component complexes. We present here a bottom-up endogenous structural proteomics approach whereby near-atomic resolution cryoEM maps are reconstructed ab initio from unidentified protein complexes enriched directly from the endogenous cellular milieu, followed by identification and atomic modeling of the proteins. The proteins in each complex are identified using cryoID , a program we developed to identify proteins in ab initio cryoEM maps. As a proof of principle, we applied this approach to the malaria parasite Plasmodium falciparum , an organism that has resisted conventional structural biology approaches, to obtain atomic models of multiple protein complexes implicated in intraerythrocytic survival of the parasite. Our approach is broadly applicable for determining structures of undiscovered protein complexes enriched directly from endogenous sources.

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Protein identification from electron cryomicroscopy maps by automated model building and side-chain matching

Terwilliger¹,

Sobolev²,

Afonine³

et al. 2021

Acta Cryst Sect D Struct Biol

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Using single-particle electron cryo-microscopy (cryo-EM), it is possible to obtain multiple reconstructions showing the 3D structures of proteins imaged as a mixture. Here, it is shown that automatic map interpretation based on such reconstructions can be used to create atomic models of proteins as well as to match the proteins to the correct sequences and thereby to identify them. This procedure was tested using two proteins previously identified from a mixture at resolutions of 3.2 Å, as well as using 91 deposited maps with resolutions between 2 and 4.5 Å. The approach is found to be highly effective for maps obtained at resolutions of 3.5 Å and better, and to have some utility at resolutions as low as 4 Å.

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Multi-color single filter photobleaching analysis for measuring gene expression

Wong

Chun

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Chi Min Ho

Malaria parasite translocon structure and mechanism of effector export

Bottom-up structural proteomics: cryoEM of protein complexes enriched from the cellular milieu

Protein identification from electron cryomicroscopy maps by automated model building and side-chain matching

Multi-color single filter photobleaching analysis for measuring gene expression

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