TonB-Dependent Heme/Hemoglobin Utilization by Caulobacter Crescentus HutA

Overview

Journal J Bacteriol

Publisher American Society for Microbiology

Specialty Microbiology

Date 2016 Dec 30

PMID 28031282

Citations 13

Authors

Heloise Balhesteros

Yan Shipelskiy

Noah J Long

Aritri Majumdar

Benjamin B Katz

Naara M Santos

Laura Leaden

Salete M Newton

Marilis V Marques

Phillip E Klebba

Affiliations

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Abstract

Siderophore nutrition tests with strain NA1000 revealed that it utilized a variety of ferric hydroxamate siderophores, including asperchromes, ferrichromes, ferrichrome A, malonichrome, and ferric aerobactin, as well as hemin and hemoglobin. did not transport ferrioxamine B or ferric catecholates. Because it did not use ferric enterobactin, the catecholate aposiderophore was an effective agent for iron deprivation. We determined the kinetics and thermodynamics of [Fe]apoferrichrome and Fe-citrate binding and transport by NA1000. Its affinity and uptake rate for ferrichrome (equilibrium dissociation constant [ ], 1 nM; Michaelis-Menten constant [ ], 0.1 nM; , 19 pMol/10 cells/min) were similar to those of FhuA. Transport properties for Fe-citrate were similar to those of FecA ( , 5.3 nM; , 29 pMol/10 cells/min). Bioinformatic analyses implicated Fur-regulated loci , , , and as TonB-dependent transporters (TBDT) that participate in iron acquisition. We resolved TBDT with elevated expression under high- or low-iron conditions by SDS-PAGE of sodium sarcosinate cell envelope extracts, excised bands of interest, and analyzed them by mass spectrometry. These data identified five TBDT: three were overexpressed during iron deficiency (00028, 02277, and 03023), and 2 were overexpressed during iron repletion (00210 and 01196). CLUSTALW analyses revealed homology of putative TBDT 02277 to FepA and BtuB. A Δ mutant did not transport hemin or hemoglobin in nutrition tests, leading us to designate the structural gene as (for eme/hemoglobin tilization). The physiological roles of the 62 putative TBDT of are mostly unknown, as are their evolutionary relationships to TBDT of other bacteria. We biochemically studied the iron uptake systems of , identified potential iron transporters, and clarified the phylogenetic relationships among its numerous TBDT. Our findings identified the first outer membrane protein involved in iron acquisition by , its heme/hemoglobin transporter (HutA).

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