Architecture of the Type IV Coupling Protein Complex of Legionella Pneumophila

Overview

Journal Nat Microbiol

Specialties Microbiology
Parasitology

Date 2017 Jul 18

PMID 28714967

Citations 38

Authors

Mi-Jeong Kwak

J Dongun Kim

Hyunmin Kim

Cheolhee Kim

James W Bowman

Seonghoon Kim

Keehyoung Joo

Jooyoung Lee

Kyeong Sik Jin

Yeon-Gil Kim

Nam Ki Lee

Jae U Jung

Byung-Ha Oh

Affiliations

Soon will be listed here.

Abstract

Many bacteria, including Legionella pneumophila, rely on the type IV secretion system to translocate a repertoire of effector proteins into the hosts for their survival and growth. Type IV coupling protein (T4CP) is a hexameric ATPase that links translocating substrates to the transenvelope secretion conduit. Yet, how a large number of effector proteins are selectively recruited and processed by T4CPs remains enigmatic. DotL, the T4CP of L. pneumophila, contains an ATPase domain and a C-terminal extension whose function is unknown. Unlike T4CPs involved in plasmid DNA translocation, DotL appeared to function by forming a multiprotein complex with four other proteins. Here, we show that the C-terminal extension of DotL interacts with DotN, IcmS, IcmW and an additionally identified subunit LvgA, and that this pentameric assembly binds Legionella effector proteins. We determined the crystal structure of this assembly and built an architecture of the T4CP holocomplex by combining a homology model of the ATPase domain of DotL. The holocomplex is a hexamer of a bipartite structure composed of a membrane-proximal ATPase domain and a membrane-distal substrate-recognition assembly. The presented information demonstrates the architecture and functional dissection of the multiprotein T4CP complexes and provides important insights into their substrate recruitment and processing.

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