Structure/Function Analysis of the Quorum-sensing Regulator EsaR from the Plant Pathogen Pantoea stewartii

Schu, Daniel Joseph

24 July 2009

Pantoea stewartii subsp. stewarti is the causative agent of Stewart's wilt disease in maize. Disease symptoms develop after the bacteria grow to high cell densities in the plant xylem and secrete an abundance of exopolysaccharide (EPS). EPS production is regulated by quorum sensing. Two regulatory proteins are key to the process of quorum sensing, the LuxI and LuxR homologues EsaI and EsaR. Most LuxR homologues function as activators of transcription in the presence of their cognate acylated homoserine lactone signal (AHL). EsaR utilizes an AHL-response opposite of the majority of the LuxR homologues. EsaR represses EPS production at low cell densities. However, at high cell densities when high concentrations of AHL are present, EsaR is inactivated and derepression of EPS production occurs. The mechanism that enables EsaR to respond to AHL in a manner opposite to that of most LuxR homologues remains elusive. A comparative study of EsaR and the well characterized quorum-sensing regulators LuxR from Vibrio fischeri and TraR from Agrobacterium tumefaciens was initiated. Previous studies demonstrated that in the absence of AHL, EsaR retains the ability to function as a weak activator of the lux operon in recombinant Escherichia coli. This thesis research further characterized the role of EsaR as an activator. Variant forms of EsaR with deletions or single residue substitutions were generated and their ability to regulate transcription was examined in vivo. Furthermore, a native EsaR-activated promoter has been identified, which controls expression of a putative regulatory sRNA in P. stewartii. It is apparent that EsaR functions as a transcription factor at low concentrations of AHL as demonstrated by its ability to inhibit EPS production. At high concentrations, the AHL appears to bind and cause a conformational shift in the protein leading to its inactivation. The second goal of this study was to further elucidate the mechanism by which AHL regulates EsaR. Pulse-chase experiments demonstrated that EsaR is resistant to proteases with or without AHL in vivo. Limited proteolytic digestions in vitro suggest that the protein does undergo conformational changes in response to AHL. Gel filtration chromatography, sucrose gradient ultracentrifugation, and cross-linking experiments proved that this conformational change does not impact the multimeric state of EsaR. To better understand the mechanism of regulation by AHL, the final goal of this project was to examine the interactions which result in EsaR-responsiveness to AHL. Several individual amino acid substitutions were identified that cause EsaR to function in an AHL-independent manner, by which variants retain the ability to bind and block gene expression in the presence of AHL. These residues have been mapped onto a homology model of EsaR and their role has been examined in vitro. The ability of these EsaR* variants to bind AHL and an analysis of the effects individual mutations have on the overall conformation of the protein was performed. Overall this study has revealed several unique aspects of the quorum-sensing system in P. stewartii whereby gene expression is regulated at both low and high cell density. Studies were also initiated to examine the mechanism of AHL-responsiveness of EsaR. The mechanism by which AHL modulates most LuxR homologues remains elusive. The ability to purify EsaR +/- its cognate AHL may prove critical in elucidating this mechanism. / Ph. D.

activator

Pantoea stewartii subsp. stewartii

quorum sensing

autoinducer responsiveness

EsaR

Genetic Analysis of the Quorum Sensing Regulator EsaR

Koziski, Jessica Marie

20 August 2008

Pantoea stewartii subsp. stewartii is the causative agent of Stewart's wilt disease in maize plants. The bacteria are injected into the plant by corn flea beetles during feeding. They colonize the xylem and overproduce a capsular exopolysaccharide (EPS) at high cell densities. The production of EPS is regulated by an EsaI/EsaR quorum sensing mechanism, homologous to the LuxI/R system. Although activation of the EPS encoding genes by EsaR occurs after it complexes to the AHL (3-oxo-C6-HSL), unlike the LuxI/R system, this activation occurs by a different mechanism. At low cell densities, dimerized EsaR acts as a repressor. At a high cell population, derepression of the EPS genes occurs via an unknown mechanism once the AHL complexes to EsaR. Hence, a random mutagenesis genetic approach to isolate EsaR* variants that are immune to the effects of AHL has been utilized. Error-prone PCR and site-directed mutagenesis were used to generate desired mutants, which were subsequently screened for their ability to repress transcription in the presence of AHL. Several individual amino acids playing a critical role in the AHL-insensitive phenotype have been identified and mapped onto a homology model of EsaR. A separate study attempted to localize the dimerization region and analyze the stability of the N-terminal domain of EsaR. Truncations of EsaR at amino acids 169 and 178, without and with the extended linker region respectively, were generated using PCR. Dimerization assays similar to those by Choi and Greenberg in 1991 were performed but proved to be unsuccessful. However, the N-terminal domain is stable as determined by western blotting, which may facilitate its future structural analysis. Together, these efforts have contributed to the molecular understanding of AHL-dependent derepression of EsaR. / Master of Science

Pantoea stewartii subsp. stewartii

repressor

EsaR

quorum sensing