Your search keyword '"Hynson, RMG"' showing total 3 results

1. Binding of transcription factor GabR to DNA requires recognition of DNA shape at a location distinct from its cognate binding site

Author

Al-Zyoud, WA, Hynson, RMG, Ganuelas, LA, Coster, ACF, Duff, AP, Baker, MAB, Stewart, AG, Giannoulatou, E, Ho, JWK, Gaus, K, Liu, D, Lee, LK, Böcking, T, Al-Zyoud, WA, Hynson, RMG, Ganuelas, LA, Coster, ACF, Duff, AP, Baker, MAB, Stewart, AG, Giannoulatou, E, Ho, JWK, Gaus, K, Liu, D, Lee, LK, and Böcking, T

Abstract

Mechanisms for transcription factor recognition of specific DNA base sequences are well characterized and recent studies demonstrate that the shape of these cognate binding sites is also important. Here, we uncover a new mechanism where the transcription factor GabR simultaneously recognizes two cognate binding sites and the shape of a 29 bp DNA sequence that bridges these sites. Small- Angle X-ray scattering and multi- Angle laser light scattering are consistent with a model where the DNA undergoes a conformational change to bend around GabR during binding. In silico predictions suggest that the bridging DNA sequence is likely to be bendable in one direction and kinetic analysis of mutant DNA sequences with biolayer interferometry, allowed the independent quantification of the relative contribution of DNA base and shape recognition in the GabR- DNA interaction. These indicate that the two cognate binding sites as well as the bendability of the DNA sequence in between these sites are required to form a stable complex. The mechanism of GabR-DNA interaction provides an example where the correct shape of DNA, at a clearly distinct location fromthe cognate binding site, is required for transcription factor binding and has implications for bioinformatics searches for novel binding sites.

Published

2016

2. A novel structure of an antikinase and its inhibitor

Author

Jacques, DA, Langley, DB, Hynson, RMG, Whitten, AE, Kwan, A, Guss, JM, Trewhella, J, Jacques, DA, Langley, DB, Hynson, RMG, Whitten, AE, Kwan, A, Guss, JM, and Trewhella, J

Abstract

In Bacillus subtilis, the KipI protein is a regulator of the phosphorelay governing the onset of sporulation. KipI binds the relevant sensor histidine kinase, KinA, and inhibits the autophosphorylation reaction. Gene homologues of kipI are found almost ubiquitously throughout the bacterial kingdom and are usually located adjacent to, and often fused with, kipA gene homologues. In B. subtilis, the KipA protein inhibits the antikinase activity of KipI thereby permitting sporulation. We have used a combination of biophysical techniques in order to understand the domain structure and shape of the KipI-KipA complex and probe the nature of the interaction. We also have solved the crystal structure of TTHA0988, a Thermus thermophilus protein of unknown function that is homologous to a KipI-KipA fusion. This structure, which is the first to be described for this class of proteins, provides unique insight into the nature of the KipI-KipA complex. The structure confirms that KipI and KipA are proteins with two domains, and the C-terminal domains belong to the cyclophilin family. These cyclophilin domains are positioned in the complex such that their conserved surfaces face each other to form a large "bicyclophilin" cleft. We discuss the sequence conservation and possible roles across species of this near-ubiquitous protein family, which is poorly understood in terms of function. © 2010 Elsevier Ltd All rights reserved.

Published

2011

3. Corrigendum to "Human Cardiac Myosin Binding Protein C: Structural Flexibility within an Extended Modular Architecture" [J. Mol. Biol. 414(5) (2011) 735-748].

Author

Jeffries CM, Lu Y, Hynson RMG, Taylor JEN, Ballesteros M, Kwan AH, and Trewhella J

Published

2023