Structure-Function Analysis of the EsaR N-terminal Domain

Geissinger, Jared Scott

24 January 2012

The LuxR protein family is a class of quorum-sensing regulated bacterial transcription factors that alter gene expression as a function of ligand detection. This coincides with a high population density and/or a low rate of signal ligand diffusion. The majority of LuxR proteins are activated only in the presence of the signal ligand, an acyl-homoserine lactone (AHL). EsaR, from the corn pathogen Pantoea stewartii, represents a subset of LuxR homologues that are active in the absence of AHL and deactivated by its presence. The mechanism by which EsaR responds to AHL in a manner opposite to that of the majority of LuxR homologues remains elusive. Unlike the majority of LuxR homologues, which require AHL for purification, EsaR can be purified and biochemically investigated in the absence and presence of AHL. This work sought to answer questions regarding the structure-function relationship of the LuxR homologue, EsaR. Fluorescence anisotropy was used to determine the relative DNA-binding affinity of wild type EsaR and three AHL-independent EsaR variants in the presence and absence of AHL. This enabled for quantitative analysis of the relative binding affinities of these AHL-independent variants for the EsaR binding site, the esa box. The results demonstrate that one AHL-independent EsaR variant has a slightly higher affinity for the esa box in the presence, rather than the absence of AHL. The affinity of the other two for the DNA is not impacted by AHL, potentially due to an inability to transduce the signal of ligand detection to the DNA binding domain. Constructs containing only the EsaR N-terminal domain (NTD) were also developed. These constructs circumvented solubility issues associated with the full-length protein, allowing for additional biochemical analysis. It was determined that the EsaR NTD alone is sufficient for multimerization and ligand binding. Additionally, preliminary X-ray crystallography efforts have established some of the early parameters required to solve the crystal structure of the EsaR ligand binding domain in both the presence and absence of AHL. If pursued, these structures would be the first solved of a LuxR homologue ligand binding domain in both the presence and absence of the native AHL, potentially demonstrating the conformational change that occurs as a result of ligand binding. Collectively, these findings have established some of the groundwork required to resolve the question of what sort of conformational changes occur in EsaR as a result of ligand binding. / Master of Science

EsaR

LuxR homologue

Pantoea stewartii

quorum sensing

transcriptional repressor

Development of Methods for Structural Characterization of Pantoea stewartii Quorum-Sensing Regulator EsaR

Pennerman, Kayla Kara

04 February 2014

The LuxR family of proteins serves as quorum-sensing transcriptional regulators in proteobacteria. At high population densities, a small acyl-homoserine lactone (AHL) molecule, produced by a LuxI homologue, accumulates in the environment. The LuxR proteins bind to their respective AHL when the ligand accumulates to sufficient levels. Once bound to AHL, the holoproteins usually become functional as transcriptional activators. However, there is a subset of LuxR homologues, the EsaR subfamily, which is active without the AHL ligand and becomes inactivated once bound to it. EsaR is the best understood member of this subfamily. It controls virulence in the corn pathogen Pantoea stewartii ssp. stewartii. Solubility issues have previously limited structural studies of LuxR homologues as the proteins could not be purified without the AHL ligand. A soluble recombinant EsaR protein, HMGE, is biologically active and can be purified in the absence and presence of AHL, unlike most other LuxR homologues. Using HMGE, amino acid substitutions and Förster resonance energy transfer (FRET), experimental methods were designed for determining the dimerization interface of EsaR and for testing the hypothesis that EsaR undergoes a conformational shift when presented with the AHL ligand. To identify residues of the dimerization interface, heterodimerization assays were designed, involving either coexpression or coincubation of wild-type EsaR and variant HMGE proteins. In this assay, the inability of the proteins to copurify by nickel affinity chromatography would indicate that the modified residue(s) are important for dimerization of EsaR. To determine the conformational change that EsaR undergoes when bound to the AHL ligand, a FRET assay was developed to estimate the distances between amino acid residues in the absence and presence of AHL. Future work will have to include a few modifications to the methods and/or control experiments. This study provides the basis upon which the present methods can be further developed and later used for structural studies of EsaR. / Master of Science

EsaR

LuxR homologue

Pantoea stewartii

quorum sensing

FRET