ASSEMBLY AND DEGRADATION OF A TRIMERIC MEMBRANE PROTEIN ACRB

Chai, Qian

01 January 2016

Multidrug efflux pumps are membrane proteins that actively transport foreign objects out of cells. The active efflux of these pumps is a critical self-defense mechanism that enables the survival of bacteria under hostile environments. Efflux pump AcrB is a member of the Resistance-Nodulation-Division (RND) super family. In E. coli, it associates with periplasmic protein AcrA and outer membrane channel TolC to extrude a variety of noxious compounds out of cell from both the cytoplasm and the periplasm. My dissertation research focused on two aspects of this multidrug efflux pump: the oligomerization process during the biogenesis of AcrB and its degradation. Oligomerization is an important aspect of the structure and function for many proteins and has been the subject of many studies. However, most of such studies focused on soluble proteins. The oligomerization process of membrane proteins, including AcrB, is rarely explored. In chapter 2, the co-assembly of AcrB variants co-expressed in the same cell was used as a tool to investigate the assembly of AcrB trimers during its bio-production. By monitoring the portion of pure trimers containing only one type of subunit and hybrid trimers containing a mixture of the two kinds of subunits, it was found that the oligomerization of membrane proteins is not a random process as the formation of pure trimer is favored. In chapter 3, the GALLEX system was used to monitor AcrB oligomerization in cells under the native condition. Previously GALLEX has only been used to monitor the oligomerization of small transmembrane proteins. By constructing a series of fusion proteins with different linker length between LexA and AcrB, and optimizing inducer concentration, we finally developed a system that could be used to differentiate AcrB trimers of different oligomerization affinities. While chapters 2 and 3 focus on the trimerization of AcrB, a critical step of its biogenesis, chapters 4 and 5 focus on its life time and degradation. In chapter 4, the life time of AcrB was measured by incorporating non-natural amino acid azidohomoalanine (AHA) into protein translation. Using this method, it was determined that that the half-life of both AcrA and AcrB in E. coli were six days. The surprisingly long lifetime of these detoxification proteins might represent a strategy by the bacteria to conserve energy and maximize their competition niche for survival in a hostile environment. In chapter 5, the degradation process of ssra tagged AcrB was investigated. In-vivo degradation test showed that properly inserted AcrB can be digested after addition of ssra-tag to its C-terminus. It was found that cytoplasmic unfoldase-protease complex ClpXP and chaperone SspB are involved in the degradation. In vitro assay is still being optimized to quantitatively analyze the activity of ClpXP in the degradation of AcrB.

multidrug efflux pump

AcrB

oligomerization

dynamics

degradation

Biochemistry

Understanding multidrug resistance in Gram-negative bacteria -- A study of a drug efflux pump AcrB and a periplasmic chaperone SurA

Zhong, Meng

01 January 2013

Multiple drug resistance (MDR) has been a severe issue in treatment and recovery from infection.Gram-negative bacteria intrinsically exhibit higher drug tolerance than Gram-positive microbes. In this thesis, two proteins involved in Gram-negative bacterial MDR were studied, AcrB and SurA. Resistance-nodulation-cell division pump AcrAB-TolC is the major MDR efflux system in Gram-negative bacteria and efficiently extrudes a broad range of substances from the cells. To study subtle conformational changes of AcrB in vivo, a reporter platform was designed. Cysteine pairs were introduced into different regions in the periplasmic domain of the protein, and the extents of disulfide bond formation were examined. Using this platform, an inactive mutant, AcrB∆loop, was created that existed as a well-folded monomer in vivo. Next, random mutageneses were performed on a functionally compromised mutant, AcrBP223G, to identify residues that restored the function loss. The mechanism of function restoration was examined. SurA is a periplasmic molecular chaperone for outer membrane biogenesis. Deletion of SurA decreased outer membrane density and bacterial drug resistance. The dependence of SurA function on structural flexibility and stability was examined. In addition, the effect of molecular crowding on SurA interaction with its outer membrane protein substrates was examined.

Multidrug resistance

multidrug efflux pump

chaperone

AcrB

SurA

Biochemistry

STABILITY STUDIES OF MEMBRANE PROTEINS

Ye, Cui

01 January 2014

The World Health Organization has identified antimicrobial resistance as one of the top three threats to human health. Gram-negative bacteria such as Escherichia coli are intrinsically more resistant to antimicrobials. There are very few drugs either on the market or in the pharmaceutical pipeline targeting Gram-negative pathogens. Two mechanisms, the protection of the outer membrane and the active efflux by the multidrug transporters, play important roles in conferring multidrug resistance to Gram-negative bacteria. My work focuses on two main directions, each aligning with one of the known multidrug resistance mechanisms. The first direction of my research is in the area of the biogenesis of the bacterial outer membrane. The outer membrane serves as a permeability barrier in Gram-negative bacteria. Antibiotics cross the membrane barrier mainly via diffusion into the lipid bilayer or channels formed by outer membrane proteins. Therefore, bacterial drug resistance is closely correlated with the integrity of the outer membrane, which depends on the correct folding of the outer membrane proteins. The folding of the outer membrane proteins has been studied extensively in dilute buffer solution. However, the cell periplasm, where the folding actually occurs, is a crowded environment. In Chapter 2, effects of the macromolecular crowding on the folding mechanisms of two bacterial outer membrane proteins (OmpA and OmpT) were examined. Our results suggested that the periplasmic domain of OmpA improved the efficiency of the OmpA maturation under the crowding condition, while refolding of OmpT was barely affected by the crowding. The second direction of my research focuses on the major multidrug efflux transporter in Gram-negative bacteria, AcrB. AcrB is an obligate trimer, which exists and functions exclusively in a trimeric state. In Chapter 3, the unfolding of the AcrB trimer was investigated. Our results revealed that sodium dodecyl sulfate induced unfolding of the trimeric AcrB started with a local structural rearrangement. While the refolding of secondary structure in individual monomers could be achieved, the re-association of the trimer might be the limiting factor to obtain folded wild type AcrB. In Chapter 4, the correlation between the AcrB trimer stability and the transporter activity was studied. A non-linear correlation was observed, in which the threshold trimer stability was required to maintain the efflux activity. Finally, in Chapter 5, the stability of another inner membrane protein, AqpZ, was studied. AqpZ was remarkably stable. Several molecular engineering approaches were tested to improve the thermal stability of the protein.

Multidrug resistance

multidrug efflux pump

outer membrane proteins

protein stability

AcrB

Biochemistry

Molecular Biology

Structural Biology

INVESTIGATION OF THE TOXICITY AND EFFLUX OF POLYCHLORINATED BIPHENYLS AND HYDROXYLATED POLYCHLORINATED BIPHENYLS IN <em>ESCHERICHIA COLI</em>

Geng, Shen

01 January 2011

Polychlorinated biphenyls (PCBs) are persistent organic pollutants. Due to their properties, PCBs accumulate in the food-chain and post a threat to the health of human beings and wildlife. Hydroxylated PCBs (OH-PCBs) are oxidative metabolites of PCBs and are more hydrophilic than their parent PCBs. One of the best approaches to break down these contaminants is through bioremediation, which is an environmental friendly process that uses microorganisms to restore natural environment. Towards this goal, we have investigated the toxicity and accumulation of PCBs and OH-PCBs in a Gram-negative bacterium, Escherichia coli. We have also determined the role played by a primary multidrug efflux transporter AcrB on the accumulation of PCBs and OH-PCBs in bacterial cell. We found that one of the PCBs tested was toxic to E. coli, while different OH-PCBs have different levels of toxicity; the acrB knockout strain accumulated significantly more PCBs and OH-PCBs than the wild-type strain, suggesting that these compounds are substrates of the efflux pump; higher cytoplasmic concentrations of OH-PCBs were also observed in the acrB knockout strain using the biosensors. Based on these observations, we conclude that both PCBs and OH-PCBs are substrates of protein AcrB. Therefore the efflux activities of multidrug resistant pumps in Gram-negative bacteria should be considered while designing bioremediation approaches.

Polychlorinated biphenyls

hydroxylated polychlorinated biphenyls

E. coli

Multidrug Efflux Pump

Protein AcrB

Chemistry

ILLUMINATE THE PATHWAY OF MEMBRANE PROTEIN ASSOCIATION AND DEGRADATION

Wang, Zhaoshuai

01 January 2017

Escherichia coli transporter protein AcrB and its homologues are the inner membrane components of the Resistance-Nodulation-Division (RND) family efflux pumps in Gram-negative bacteria. It is well accepted that soluble proteins are only marginally stable, but such insight is missing for membrane proteins. The lack of stability data, including thermodynamic stability and oligomer association affinity is a result of intrinsic difficulties in working with membrane proteins. In addition, the degradation of soluble proteins in E. coli has been extensively studied whereas the degradation process of membrane proteins remains unclear. A focus of my thesis is the validation and development of methods used to measure the thermo- and oligomeric- stability of membrane proteins. I investigated the mechanism of a popular thermal-stability assay developed specifically for the study of membrane proteins uses a thiol-specific probe, 7-diethylamino-3-(4-maleimidophenyl)-4-methylcoumarin (CPM). I found that, contrary to current understanding, the presence of a sulfhydryl group was not a prerequisite for the CPM thermal stability assay. The observed fluorescence increase is likely caused by binding of the fluorophore to hydrophobic patches exposed upon protein unfolding. I then applied these methods in the study of three projects. In the first project, I investigated how suppressor mutations restore the function of AcrBP223G, in which the Pro223 to Gly mutation compromised the function of AcrB via disrupting AcrB trimerization. The results suggested that the function loss resulted from compromised AcrB trimerization could be restored through various mechanisms involving the compensation of trimer stability and substrate binding. In the second project, I created two AcrB fusion proteins, with C-terminal yellow fluorescence protein (YFP) and cyan fluorescence protein (CFP), respectively. YFP and CFP form a fluorescence resonance energy transfer (FRET) pair. Using this pair of fusion proteins, I studied AcrB assembly both in detergent micelles and in lipid bilayers. A positive cooperativity was observed in kinetic studies of association of AcrB trimer. Reconstitution experiment revealed that the association showed a higher FRET efficiency and faster association rate in liposome than in DDM. In the last project, I developed a fluorescence method to study the degradation of AcrB-ssrA by the ClpXP system. Comparing to the degradation of GFP-ssrA, degradation of AcrB-CFP-ssrA showed a lower maximum velocity and tighter binding to the enzymes with a positive cooperativity.

multidrug efflux pump

AcrB

FRET

oligomerization

degradation

ssrA

Biochemistry

Molecular Biology

Etude de l'assemblage du système d'efflux membranaire MexAB-OprM impliqué dans la résistance aux antibiotiques chez Pseudomonas aeruginosa : caractérisation combinée par Microbalance à cristal de quartz avec mesure de dissipation et cryo-tomographie électronique

Trépout, Sylvain

08 December 2008

Pseudomonas aeruginosa est une bactérie Gram-négative qui présente une grande résistance aux antibiotiques, lui permettant de sévir dans le milieu hospitalier en infectant plus particulièrement les patients immunodéprimés. Cette résistance est principalement due au système d’efflux membranaire MexAB-OprM, capable d’exporter les antibiotiques en dehors de la cellule. Cette pompe à efflux est composée de trois protéines, MexA, MexB et OprM, incorporées dans les membranes internes et externes de la paroi bactérienne. Les structures de MexA, OprM et AcrB -une protéine présente chez E. coli, homologue de MexB- ont été déterminées individuellement par cristallographie des rayons X. Cependant, la structure du complexe entier, regroupant les trois protéines en interaction, ainsi que le mécanisme de cette pompe font toujours défaut. Le renforcement de nos connaissances structurales et fonctionnelles est donc capital pour lutter plus efficacement contre ces bactéries, par de nouvelles stratégies médicamenteuses. Ce travail porte sur l’étude de la structure et de la stœchiométrie de l’assemblage des protéines OprM et MexA au sein d’une membrane lipidique. La caractérisation du complexe OprM/MexA a été réalisée à l’aide de nouvelles techniques de caractérisation physico-chimique des surfaces, telle que la Microbalance à Cristal de Quartz avec Mesure de Dissipation (QCM-D), et par des méthodes d’imagerie, telles que la Cryo-Microscopie Electronique en Transmission (CryoMET) et la Cryo-Tomographie Electronique (CryoTE). En QCM-D, les mesures d’interaction entre OprM et MexA ont été réalisées sur support solide en contrôlant l’orientation d’OprM placée dans un environnement lipidique. Après ajout de la protéine MexA, la formation de complexes OprM/MexA a été mise évidence. Pour comprendre l’organisation de ce complexe, nous avons procédé à une étude comparative de l’organisation des protéines OprM, MexA et du complexe OprM/MexA incorporés dans une membrane lipidique, par CryoMET. Trois types d’organisation, respectivement spécifiques d’OprM, de MexA et du complexe OprM/MexA, ont été mis en évidence. Une analyse structurale de ces trois différents assemblages, pris en sandwich entre deux membranes lipidiques, a été menée par CryoTE. La reconstitution de la protéine OprM conduit à la formation de protéoliposomes, dû à des interactions intervenant entre les protéines OprM au niveau de leurs hélices périplasmiques. La protéine MexA s’organise sous forme d’une structure annulaire de 13 nm de hauteur au sein des membranes lipidiques, et d’une structure plus complexe de 26 nm de hauteur, résultant de l’empilement tête-bêche de deux structures annulaires de 13 nm. Ce travail révèle les dimensions exactes de l’assemblage formé par MexA, et permet de localiser à proximité des membranes les domaines non résolus dans la structure cristallographique. La reconstitution du complexe OprM/MexA révèle une disposition régulière des deux protéines dans les membranes lipidiques. Au sein des complexes, les protéines OprM sont présentes sous forme de trimères. Dans la membrane opposée, à l’aplomb d’une molécule d’OprM, MexA ne forme pas une structure annulaire similaire à celle décrite précédemment, indiquant un état d’oligomérisation différent de celui observé dans les assemblages MexA. Les densités de MexA sont compatibles avec la présence de quelques molécules de MexA. Cependant des structures annulaires de MexA, positionnées à l’aplomb de trois trimères d’OprM sont visibles. Notre étude montre que MexA adopte des structures oligomériques spécifiques en fonction de ses interactions avec les membranes lipidiques ou avec son partenaire OprM. / The structure determination of membrane protein in lipid environment can be carried out using cryo electron microscopy combined with the recent development of data collection and image processing. We describe a protocol to study assemblies or stacks of membrane protein reconstitued into a lipid membrane using both cryo electron tomography and single particle analysis which is an alternative approach to electron crystallography for solving 3D structure. We show the organization of the successive layers of OprM molecules revealing the protein-protein interactions between OprM molecules of two successive lipid bilayers.

Microscopie Electronique

Tomographie Electronique

Pseudomonas aeruginosa

Reconstitution membranaire

Protéines membranaires

Membrane protein

Cryo electron tomography

Single particle analysis

Multidrug efflux pump