The crystal structure of the Yersinia pestis iron chaperone YiuA reveals a basic triad binding motif for the chelated metal.

Christopher D Radka,Lawrence J Delucas,Dongquan Chen,Stephen G Aller

doi:10.1107/s2059798317015236

Christopher D Radka, Lawrence J Delucas + Show 2 more

Open Access

https://doi.org/10.1107/s2059798317015236

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Abstract

Biological chelating molecules called siderophores are used to sequester iron and maintain its ferric state. Bacterial substrate-binding proteins (SBPs) bind iron-siderophore complexes and deliver these complexes to ATP-binding cassette (ABC) transporters for import into the cytoplasm, where the iron can be transferred from the siderophore to catalytic enzymes. In Yersinia pestis, the causative agent of plague, the Yersinia iron-uptake (Yiu) ABC transporter has been shown to improve iron acquisition under iron-chelated conditions. The Yiu transporter has been proposed to be an iron-siderophore transporter; however, the precise siderophore substrate is unknown. Therefore, the precise role of the Yiu transporter in Y. pestis survival remains uncharacterized. To better understand the function of the Yiu transporter, the crystal structure of YiuA (YPO1310/y2875), an SBP which functions to present the iron-siderophore substrate to the transporter for import into the cytoplasm, was determined. The 2.20 and 1.77 Å resolution X-ray crystal structures reveal a basic triad binding motif at the YiuA canonical substrate-binding site, indicative of a metal-chelate binding site. Structural alignment and computational docking studies support the function of YiuA in binding chelated metal. Additionally, YiuA contains two mobile helices, helix 5 and helix 10, that undergo 2-3 Å shifts across crystal forms and demonstrate structural breathing of the c-clamp architecture. The flexibility in both c-clamp lobes suggest that YiuA substrate transfer resembles the Venus flytrap mechanism that has been proposed for other SBPs.

Highlights

Prokaryotic cells rely on ATP-binding cassette (ABC) transporters to facilitate substrate transport across cellular membranes
Bacterial ABC transporters are modular nanomachines that are crucial for cell viability and infection, and make up a superfamily of proteins composed of a cytoplasmic nucleotide-binding domain, a homodimer or heterodimer transmembrane permease and a substrate-binding protein (SBP) that localizes to the periplasm in Gram-negative bacteria or is anchored to the cell membrane in Gram-positive bacteria (Maqbool et al, 2015)
We show by structural alignment that YiuA has the greatest degree of structural similarity to cluster A-2 SBPs compared with other metaltransport SBPs, and identify the amino-acid residues that are likely to form a basic triad binding motif

Summary

Introduction

Prokaryotic cells rely on ATP-binding cassette (ABC) transporters to facilitate substrate transport across cellular membranes. The genes that make up the ABC transporter are flanked by a gene encoding an outer membrane receptor for the metal-chelate complex and genes that encode biosynthetic enzymes that synthesize the siderophore that will complex with the metal. An example of this is the Yersinia pestis YsuERABCDGHIJF operon. Some ABC transporters that transport metal-chelate complexes are not adjacent to genes encoding siderophore-biosynthetic enzymes but are still adjacent to a gene encoding an outer membrane receptor An example of this is the HmuRSTUV locus. This binding motif is chemically distinct from the binding motifs of other metal-binding SBPs, which contain glutamate, aspartate, histidine and cysteine amino-acid residues for direct interaction with metal atoms

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