Proteins with CHADs (Conserved Histidine α-Helical Domains) Are Attached to Polyphosphate Granules and Constitute a Novel Family of Polyphosphate-Associated Proteins (Phosins)

Overview

Journal Appl Environ Microbiol

Specialties Environmental Health
Microbiology

Date 2017 Jan 29

PMID 28130300

Citations 12

Authors

Tony Tumlirsch

Dieter Jendrossek

Affiliations

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Abstract

On the basis of bioinformatic evidence, we suspected that proteins with a CYTH (aB iamine triphosphatase) domain and/or a CHAD (onserved istidine -helical omain) motif might represent polyphosphate (polyP) granule-associated proteins. We found no evidence of polyP targeting by proteins with CYTH domains. In contrast, two CHAD motif-containing proteins from H16 (A0104 and B1017) that were expressed as fusions with enhanced yellow fluorescent protein (eYFP) colocalized with polyP granules. While the expression of B1017 was not detectable, the A0104 protein was specifically identified in an isolated polyP granule fraction by proteome analysis. Moreover, eYFP fusions with the CHAD motif-containing proteins MGMSRV2-1987 from and PP2307 from also colocalized with polyP granules in a transspecies-specific manner. These data indicated that CHAD-containing proteins are generally attached to polyP granules. Together with the findings from four previously polyP-attached proteins (polyP kinases), the results of this study raised the number of polyP-associated proteins in to six. We suggest designating polyP granule-bound proteins with CHAD motifs as phosins (sphate), analogous to sins and sins that are specifically bound to the surface of polyhydroxyalkanoate (PHA) granules in PHA-accumulating bacteria and to oil droplets in oil seed plants, respectively. The importance of polyphosphate (polyP) for life is evident from the ubiquitous presence of polyP in all species on earth. In unicellular eukaryotic microorganisms, polyP is located in specific membrane-enclosed organelles, called acidocalcisomes. However, in most prokaryotes, polyP is present as insoluble granules that have been designated previously as volutin granules. Almost nothing is known regarding the macromolecular composition of polyP granules. Particularly, the absence or presence of cellular compounds on the surface of polyP granules has not yet been investigated. In this study, we identified a novel class of proteins that are attached to the surface of polyP granules in three model species of , , and These proteins are characterized by the presence of a CHAD (onserved istidine -helical omain) motif that functions as a polyP granule-targeting signal. We suggest designating CHAD motif-containing proteins as phosins [analogous to phasins for poly(3-hydroxybutyrate)-associated proteins and to oleosins for oil droplet-associated proteins in oil seed plants]. The expression of phosins in different species confirmed their polyP-targeting function in a transspecies-specific manner. We postulate that polyP granules in prokaryotic species generally have a complex surface structure that consists of one to several polyP kinases and phosin proteins. We suggest differentiating polyP granules from acidocalcisomes by designating them as polyphosphatosomes.

Citing Articles

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Possible Role of CHAD Proteins in Copper Resistance.

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The Histone H1-Like Protein AlgP Facilitates Even Spacing of Polyphosphate Granules in Pseudomonas aeruginosa.

Chawla R, Klupt S, Patsalo V, Williamson J, Racki L mBio. 2022; 13(3):e0246321.

PMID: 35435704 PMC: 9239181. DOI: 10.1128/mbio.02463-21.

The Phosin PptA Plays a Negative Role in the Regulation of Antibiotic Production in .

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