Breaking and Restoring the Hydrophobic Core of a Centromere-binding Protein

Sadia Saeed,Thomas A Jowitt,Jim Warwicker,Finbarr Hayes

doi:10.1074/jbc.m115.638148

Sadia Saeed, Thomas A Jowitt + Show 2 more

Open Access

https://doi.org/10.1074/jbc.m115.638148

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Abstract

The ribbon-helix-helix (RHH) superfamily of DNA-binding proteins is dispersed widely in procaryotes. The dimeric RHH fold is generated by interlocking of two monomers into a 2-fold symmetrical structure that comprises four α-helices enwrapping a pair of antiparallel β-strands (ribbon). Residues in the ribbon region are the principal determinants of DNA binding, whereas the RHH hydrophobic core is assembled from amino acids in both the α-helices and ribbon element. The ParG protein encoded by multiresistance plasmid TP228 is a RHH protein that functions dually as a centromere binding factor during segrosome assembly and as a transcriptional repressor. Here we identify residues in the α-helices of ParG that are critical for DNA segregation and in organization of the protein hydrophobic core. A key hydrophobic aromatic amino acid at one position was functionally substitutable by other aromatic residues, but not by non-aromatic hydrophobic amino acids. Nevertheless, intramolecular suppression of the latter by complementary change of a residue that approaches nearby from the partner monomer fully restored activity in vivo and in vitro. The interactions involved in assembling the ParG core may be highly malleable and suggest that RHH proteins are tractable platforms for the rational design of diverse DNA binding factors useful for synthetic biology and other purposes.

Highlights

Accurate segregation of antibiotic resistance plasmids requires dedicated centromere-binding proteins
Residues in the ribbon region are the principal determinants of DNA binding, whereas the RHH hydrophobic core is assembled from amino acids in both the ␣-helices and ribbon element
The ParG protein encoded by multiresistance plasmid TP228 is a RHH protein that functions dually as a centromere binding factor during segrosome assembly and as a transcriptional repressor

Summary

Background

Accurate segregation of antibiotic resistance plasmids requires dedicated centromere-binding proteins. Results: Assembly of the hydrophobic core of the ParG centromere-binding protein encoded by multiresistance plasmid TP228 is governed by a triad of key amino acids. Residues in the ribbon region are the principal determinants of DNA binding, whereas the RHH hydrophobic core is assembled from amino acids in both the ␣-helices and ribbon element. The interactions involved in assembling the ParG core may be highly malleable and suggest that RHH proteins are tractable platforms for the rational design of diverse DNA binding factors useful for synthetic biology and other purposes. In view of the important role of ParG in stable maintenance of a multiresistance plasmid, here we characterize positions in the ␣-helices that are especially crucial for ParG function in segregation and in assembly of the protein core. Combined with recent observations that the ribbon element that determines DNA binding by ParG is functionally interchangeable with ribbons from other RHH factors [40], ParG and other RHH proteins may be potent platforms for the rational design of compact transcription factors valuable for synthetic biology and other purposes

EXPERIMENTAL PROCEDURES

RESULTS

DISCUSSION