Structural and Functional Studies of Sensor Kinase RetS from Pseudomonas aeruginosa and Peptidoglycan Hydrolase SleB from Bacillus anthracis

Jing, Xing

11 June 2013

Part I: Signaling Role of the Sensor Kinase RetS in Biofilm formation Regulation of Pseudomonas aeruginosa-<br />The opportunistic human pathogen Pseudomonas aeruginosa causes both acute and chronic infections in predisposed individuals. Acute infections require a functional Type Three Secretion System (TTSS), which mediates the translocation of select cytotoxins into host cells. Chronic infections, the leading cause of death among cystic fibrosis patients, are characterized by drug-resistant biofilms formation. To regulate gene expression, Pseudomonas aeruginosa utilizes two-component regulatory systems (TCS). Specifically, we focus on the TCS signaling kinase RetS, which is a critical repressor of biofilm formation. The signaling mechanism of RetS is unusual. According to recent findings and one hypothesis, RetS employs a novel signaling mechanism involving direct binding to the signaling kinase GacS, thereby repressing the GacS-induced biofilm formation. RetS is believed to be regulated by the interaction of its periplasmic sensory domain (RetSperi) with an unknown ligand. As such, RetSperi is a potential drug target. We hypothesized that ligand-binding shifts the equilibrium between the formation of a RetS homo-dimer and the RetS-GacS complex by tuning the homo-dimerization of the RetSperi. While the molecular signal that regulates RetS is unknown, our structural studies of the sensory domain suggest that this ligand is a carbohydrate-based moiety. Unchanged biofilm-EPS production phenotype of RetSperi ligand binding site mutants indicates that the natural ligand is not from Pseudomonas aeruginosa.<br />Additional experiments unambiguously determined that the sensory domain forms a stable homodimer. Adding to the complexity of the system, we have identified<br />two possible dimer interfaces in our in vitro assays. However, inconsistent with the current model, elimination of RetSperi results in a slightly increased biofilm EPS production phenotype. Therefore, with the previous demonstration that RetS is able to dephosphorylate GacS, we propose an alternative hypothesis: the RetS kinase domain serves as a phosphatase for phosphorylated GacS; this phosphatase activity is tuned by signaling sensing on RetSperi. Finally, to provide an important piece of information for understanding the molecular basis of RetS-GacS signaling, we have developed a crystallization-based structure determination strategy in order to reveal the precise RetS-GacS interaction pattern.<br /><br />PartII: The catalytic domain of the germination-specific lytic transglycosylase SleB from Bacillus anthracis displays a unique active site topology-<br />germination-specific lytic enzymes (GSLEs) that degrade the unique cortex peptidoglycan to permit resumption of metabolic activity and outgrowth. We report the first crystal structure of the catalytic domain of a GSLE, SleB. The structure revealed a transglycosylase fold with unique active site topology and permitted identification of the catalytic glutamate residue. Moreover, the structure provided insights into the molecular basis for the specificity of the enzyme for muramic-"?lactam-containing cortex peptidoglycan. The protein also contains a metal-binding site that is positioned directly at the entrance of the substrate-binding cleft. / Ph. D.

Pseudomonas aeruginosa

biofilm formation

EPS

two-component systems

RetS

periplasmic sensory domain

GacS

dimer

phosphata

Antibody discovery and engineering using the anchored periplasmic expression (APEx) Escherichia coli display system with flow cytometric selection

Van Blarcom, Thomas John

05 February 2010

The development of recombinant proteins for therapeutic applications has revolutionized the pharmaceutical industry. In particular, monoclonal antibodies are the safest class of all therapeutic molecules and account for the majority of recombinant proteins currently undergoing clinical trials. A variety of technologies exist to engineer antibodies with a desired binding specificity and affinity, both of which are a prerequisite for therapeutic applications. This dissertation describes the implementation of a novel combinatorial library screening technology for the discovery and engineering of antibodies with unique binding properties. Combinatorial library screening technologies are used for the in vitro isolation of antibodies from large ensembles of proteins (libraries) typically produced by microorganisms using molecular biology techniques. Our lab has developed a powerful antibody discovery technology that relies on E. coli display by anchored periplasmic expression, otherwise known as APEx. First, I compared the effects of using combinatorial libraries comprising either smaller, monovalent single-chain antibody fragments (scFv), or the much larger, bifunctional full-length IgG antibodies. These technologies were used to isolate a small panel of antigen specific antibodies from the same library of antibody variable domains amplified from a mouse immunized with the Protective Antigen (PA) component from Bacillus anthracis, the causative agent of anthrax. Overall, IgG display resulted in the isolation of a broader panel of variable domain sequences. Most of these variable domains exhibited substantially reduced affinity when expressed as scFvs, which is consistent with the finding that none of these could be isolated from the equivalent scFv library. These results indicate that the antibody format used during in vitro selection affects which antibody variable domains will be discovered. Second, I developed several modifications of the APEx methodology to allow for more efficient recovery of antibodies with desired properties. Specifically, the system was reengineered to simultaneously account for antibody binding and expression levels in order to isolate the highest affinity antibodies with favorable expression characteristics. Third, the new approach, coupled with optimized fluorescence activated cell sorting (FACS) settings, was used to increase the affinity of an antibody by 35-fold resulting in a K[subscript D] of 100 pM. It was demonstrated that genetic transfer of this high affinity antibody specific for the V antigen of Yersinia pestis, the etiologic agent of the plague, conferred increased protection against intranasal challenge with a 363 LD₅₀ of Y. pestis in mice. / text

Recombinant proteins

Monoclonal antibodies

Anchored periplasmic expression

APEx

Escherichia Coli

High affinity antibodies

Structural Studies of Binding Proteins: Investigations of Flexibility, Specificity and Stability

Magnusson, Ulrika

January 2003

<p>Binding proteins are present both in gram-negative and gram-positive bacteria. They are the recognition components of the ABC transport systems that transport different nutrients into the cell, and are in some cases also involved in chemotaxis. In gram-negative bacteria, they are present in the periplasm between the inner and the porous outer membrane. Here, these highly specific proteins can bind to a certain ligand such as ions, sugars and amino acids. The protein-ligand complex can then interact with permeases bound to the inner membrane that transport the nutrient into the cell. Gram-positive bacteria lack an outer membrane and the binding protein must therefore be anchored to the cell membrane.</p><p>In this thesis different aspects of three members of the super-family of the periplasmic binding proteins have been studied. In the case of the allose-binding protein (ALBP) from <i>E. coli</i> we focused on the movement of the protein when ligand is bound and released. This protein was also compared with the ribose-binding protein (RBP) which belongs to the same structural cluster and from which both open and closed structures are available. The leucine-binding protein (LBP) from <i>E. coli</i> was studied with regards to the structural basis of its specificity for different ligands as well as its conformational changes. The leucine-isoleucine-valine protein has 80% sequence identity with LBP but still exhibits a different preference for ligands. The structure of the maltose-binding protein (MBP) was obtained from a gram-positive thermoacidophile, <i>A. acidocaldarius. </i>Here, our goal was to study acid-stability of proteins. Since little is known about this and structures of the mesophilic counterpart in <i>E. coli</i> are available, as well as structures from two hyperthermophiles, we had an opportunity to study differences in their structural properties that could explain their differing stabilities.</p>

Molecular biology

Periplasmic binding protein

X-ray crystallography

conformational change

acidophile

protein specificity

protein structure

Molekylärbiologi

Molecular biology

Molekylärbiologi

Structural Studies of Binding Proteins: Investigations of Flexibility, Specificity and Stability

Magnusson, Ulrika

January 2003

Binding proteins are present both in gram-negative and gram-positive bacteria. They are the recognition components of the ABC transport systems that transport different nutrients into the cell, and are in some cases also involved in chemotaxis. In gram-negative bacteria, they are present in the periplasm between the inner and the porous outer membrane. Here, these highly specific proteins can bind to a certain ligand such as ions, sugars and amino acids. The protein-ligand complex can then interact with permeases bound to the inner membrane that transport the nutrient into the cell. Gram-positive bacteria lack an outer membrane and the binding protein must therefore be anchored to the cell membrane. In this thesis different aspects of three members of the super-family of the periplasmic binding proteins have been studied. In the case of the allose-binding protein (ALBP) from E. coli we focused on the movement of the protein when ligand is bound and released. This protein was also compared with the ribose-binding protein (RBP) which belongs to the same structural cluster and from which both open and closed structures are available. The leucine-binding protein (LBP) from E. coli was studied with regards to the structural basis of its specificity for different ligands as well as its conformational changes. The leucine-isoleucine-valine protein has 80% sequence identity with LBP but still exhibits a different preference for ligands. The structure of the maltose-binding protein (MBP) was obtained from a gram-positive thermoacidophile, A. acidocaldarius. Here, our goal was to study acid-stability of proteins. Since little is known about this and structures of the mesophilic counterpart in E. coli are available, as well as structures from two hyperthermophiles, we had an opportunity to study differences in their structural properties that could explain their differing stabilities.

Molecular biology

Periplasmic binding protein

X-ray crystallography

conformational change

acidophile

protein specificity

protein structure

Molekylärbiologi

Molecular biology

Molekylärbiologi

Roles of Secreted Virulence Factors in Pathogenicity of Haemophilus Influenzae: A Dissertation

Rosadini, Charles V.

12 May 2011

Haemophilus influenzae is a pathogenic Gram-negative bacterium that colonizes the upper respiratory tract of humans and can cause otitis media, upper and lower respiratory infections, and meningitis. Factors important for H. influenzae to colonize humans and cause disease are not fully understood. Different bacterial pathogens are armed with virulence mechanisms unique to their specific strategies for interacting with their hosts. Many of the proteins mediating these interactions are secreted and contain disulfide bonds required for function or stability. I postulated that identifying the set of secreted proteins in H. influenzae that require periplasmic disulfide bonds would provide better understanding of this bacterium's pathogenic mechanisms. In this thesis, the periplasmic disulfide bond oxidoreductase protein, DsbA, was found to be essential for colonization and virulence of H. influenzae. Mutants of dsbA were also found to be sensitive to the bactericidal effects of serum. However, the DsbA-dependent proteins important for pathogenesis of this organism have not been previously identified. To find them, putative targets of the periplasmic disulfide bond pathway were identified and examined for factors which might be important for mediating critical virulence aspects. By doing so, novel virulence factors were discovered including those important for heme and zinc acquisition, as well as resistance to complement. Overall, the work presented here provides insight into requirements for H. influenzae to survive within various host environments.

Haemophilus influenzae

Periplasmic Binding Proteins

Protein Disulfide-Isomerases

Virulence Factors

Amino Acids, Peptides, and Proteins

Bacteria

Biological Factors

Microbiology

Respiratory System

Impact of glucose uptake rate on recombinant protein production in Escherichia coli

Bäcklund, Emma

January 2011

Escherichia coli (E. coli) is an attractive host for production of recombinant proteins, since it generally provides a rapid and economical means to achieve high product quantities. In this thesis, the impact of the glucose uptake rate on the production of recombinant proteins was studied, aiming at improving and optimising production of recombinant proteins in E. coli. E. coli can be cultivated to high cell densities in bioreactors by applying the fed-batch technique, which offers a means to control the glucose uptake rate. One objective of this study was to find a method for control of the glucose uptake rate in small-scale cultivation, such as microtitre plates and shake flasks. Strains with mutations in the phosphotransferase system (PTS) where used for this purpose. The mutants had lower uptake rates of glucose, resulting in lower growth rates and lower accumulation of acetic acid in comparison to the wild type. By using the mutants in batch cultivations, the formation of acetic acid to levels detrimental to cell growth could be avoided, and ten times higher cell density was reached. Thus, the use of the mutant strains represent a novel, simple alternative to fed-batch cultures.   The PTS mutants were applied for production of integral membrane proteins in order to investigate if the reduced glucose uptake rate of the mutants was beneficial for their production. The mutants were able to produce three out of five integral membrane proteins that were not possible to produce by the wild-type strain. The expression level of one selected membrane protein was increased when using the mutants and the expression level appeared to be a function of strain, glucose uptake rate and acetic acid accumulation. For production purposes, it is not uncommon that the recombinant proteins are secreted to the E. coli periplasm. However, one drawback with secretion is the undesired leakage of periplasmic products to the medium. The leakage of the product to the medium was studied as a function of the feed rate of glucose in fed-batch cultivations and they were found to correlate. It was also shown that the amount of outer membrane proteins was affected by the feed rate of glucose and by secretion of a recombinant product to the periplasm. The cell surface is another compartment where recombinant proteins can be expressed. Surface display of proteins is a potentially attractive production strategy since it offers a simple purification scheme and possibilities for on-cell protein characterisation, and may in some cases also be the only viable option. The AIDA-autotransporter was applied for surface display of the Z domain of staphylococcal protein A under control of the aidA promoter. Z was expressed in an active form and was accessible to the medium. Expression was favoured by growth in minimal medium and it seemed likely that expression was higher at higher feed rates of glucose during fed-batch cultivation. A repetitive batch process was developed, where relatively high cell densities were achieved whilst maintaining a high expression level of Z. / QC 20110608

AIDA-autotransporter

Escherichia coli

fed-batch

glucose uptake rate

integral membrane proteins

outer membrane proteins

periplasmic retention

phosphotransferase system

recombinant proteins

specific growth rate

surface expression

Biology

Biologi

Thermodynamic Characterization Of Wild Type And Mutants Of The E.coli Periplasmic Binding Proteins LBP, LIVBP, MBP And RBP

Prajapati, Ravindra Singh

12 1900

Native states of globular proteins typically show stabilization in the range of 5 to 15 kcal/mol with respect to their unfolded states. There has been a considerable progress in the area of protein stability and folding in recent years, but increasing protein stability through rationally designed mutations has remained a challenging task. Current ability to predict protein structure from the amino acid sequence is also limited due to the lack of quantitative understanding of various factors that defines the single lowest energy fold or native state. The most important factors, which are considered primarily responsible for the structure and stability of the biological active form of proteins, are hydrophobic interactions, hydrogen bonding and electrostatic interactions such as salt bridges as well as packing interactions. Several studies have been carried out to decipher the importance of each these factors in protein stability and structure via rationally designed mutant proteins. The limited success of previous studies emphasizes the need for comprehensive studies on various aspect of protein stability. An integrated approach involving thermodynamic and structural analysis of a protein is very useful in understanding this particular phenomenon. This approach is very useful in relating the thermodynamic stability with the structure of a protein. A survey of the current literature on thermodynamic stability of protein indicates that the majority of the model proteins which have been used for understanding the determinants of protein stability are small, monomeric, single domain globular proteins like RNase A, Lysozyme and Myoglobin. On the other hand large proteins often show complex unfolding transition profiles that are rarely reversible. The major part of this thesis is focused on studying potential stabilizing/destabilizing interactions in small and large globular proteins. These interactions have been identified and characterized by exploring the effects of various rationally designed mutations on protein stability. Spectroscopic, molecular biological and calorimetric techniques were employed to understand the relationships between protein sequence, structure and stability. The experimental systems used are Leucine binding proteins, Leucine isoleucine valine binding protein (LIVBP), Maltose binding protein (MBP), Ribose binding protein (RBP) and Thioredoxin (Trx). The last section of the thesis discusses thermodynamic properties of molten globule states of the periplasmic protein LBP, LIVBP, MBP and RBP. The amino acid Pro is unique among all the twenty naturally occurring amino acids. In the case of proline, the Cδ of the side chain is covalently linked with the main chain nitrogen atom in a five membered ring. Therefore, Pro lacks amide hydrogen and it is not able to form a main chain hydrogen bond with a carbonyl oxygen. Hence Pro is typically not found in the hydrogen bonded, interior region of α-helix. There have been several studies which showed that introduction of the Pro residue into the interior of an α-helix is destabilizing. Although, it is not common to find Pro residue in the interiors of an α-helix, it has been reported that it occurs with appreciable frequency (14%). The thermodynamic effects of replacements of Pro residue in helix interiors of MBP were investigated in Chapter 2 of this thesis. Unlike many other small proteins, MBP contains 21 Pro residues distributed throughout the structure. It contains three residues in the interiors of α-helices, at positions 48, 133 and 159. These Pro residues were replaced with an alanine and serine amino acids using site directed mutagenesis. Stabilities of all the mutant and wild type proteins have been studied via isothermal chemical denaturation at pH 7.4 and thermal denaturation as a function of pH ranging from pH 6.5 to 10.4. It has been observed that replacement of a proline residue in the middle of an α-helix does not always stabilize a protein. It can be stabilizing if the carbonyl oxygen of residue (i-3) or (i-4) is well positioned to form a hydrogen bond with the ith (mutated) residue and the position of mutation is not buried or conserved in the protein. Partially exposed position have the ability to form main chain hydrogen bonds and Ala seems to be a better choice to substitute Pro than Ser. Unlike other amino acids, the pyrolidine ring of Pro residue imposes rigid constraints on the rotation about the N---Cα bond in the peptide backbone. This causes conformational restriction of the φ dihedral angle of Pro to -63±15º in polypeptides. Therefore, introduction of a rigid Pro residue into an appropriate position in a protein sequence is expected to decrease the conformational entropy of the denatured state and consequently lead to protein stabilization. In Chapter 3 of this thesis, the thermodynamic effects of Pro introduction on protein stability has been investigated in LIVBP, MBP, RBP and Trx. Thirteen single and two double mutants have been generated in the above four proteins. Three of the MBP mutants were characterized by X-ray crystallography to confirm that no structural changes had occurred upon mutation. In the remaining cases, CD spectroscopy was used to show the absence of structural changes. Stability of all the mutant and wild type proteins was studied via isothermal chemical denaturation at neutral pH and thermal denaturation as a function of pH. The mutants did not show enhanced stability with respect to chemical denaturation at room temperature. However, six of the thirteen single mutants showed a small but significant increase in the free energy of thermal unfolding in the range of 0.3-2.4 kcal/mol, two mutants showed no change and five were destabilized. In five of the six cases, the stabilization was because of a reduced entropy of unfolding. Two double mutants were constructed. In both cases, the effects of the single mutations on the free energy of thermal unfolding were non-additive. In addition to the hydrogen bond, hydrophobic and electrostatic interactions, other interactions like cation-π and aromatic-aromatic interactions etc. are also considered to make important contributions to protein stability. The relevance of cation-π interaction in biological systems has been recognized in recent years. It has been reported that positively charged amino acids (Lys, Arg and His) are often located within 6 Å of the ring centroids of aromatic amino acids (Phe, Tyr and Trp). The importance of cation-π interaction in protein stability has been suggested by previous theoretical and experimental studies. We have attempted to determine the magnitude of cation-π interactions of Lys with aromatic amino acids in four different proteins (LIVBP, MBP, RBP and Trx) in Chapter 4 of the thesis. Cation-π pairs have been identified by using the program CaPTURE. We have found thirteen cation-π pairs in five different proteins (PDB ID’s 2liv, 1omp, 1anf, 1urp and 2trx). Five cation-π pairs were selected for the study. In each pair, Lys was replaced with Gln and Met. In a separate series of experiments, the aromatic amino acid in each cation-π pair was replaced by Leu. Stabilities of wild type (WT) and mutant proteins were characterized by similar methods, to those discussed in previous chapters. Gln and Aromatic → Leu mutants were consistently less stable than the corresponding Met mutants reflecting the non-isosteric nature of these substitutions. The strength of the cation-π interaction was assessed by the value of the change in the free energy of unfolding (ΔΔG0=ΔG0 (Met) - ΔG0(WT)). This ranged from +1.1 to –1.9 kcal/mol (average value – 0.4 kcal/mol) at 298 K and +0.7 to –2.6 kcal/mol (average value –1.1 kcal/mol) at the Tm of each WT. It therefore appears that the strength of cation-π interactions increases with temperature. In addition, the experimentally measured values are appreciably smaller in magnitude than the calculated values with an average difference |ΔG0expt -ΔG0calc|avg of 2.9 kcal/mol. At room temperature, the data indicate that cation-π interactions are at best weakly stabilizing and in some cases are clearly destabilizing. However at elevated temperatures, close to typical Tm’s, cation-π interactions are generally stabilizing. In Chapter 5, we have attempted to characterize molten globule states for the periplasmic proteins LBP, LIVBP, MBP and RBP. It was observed that all these proteins form molten globule states at acidic pH (3 - 3.4). All these molten globule states showed cooperative thermal transitions and bound with their ligand comparable to (LBP and LIVBP) or with lower (MBP and RBP) affinity than the corresponding native states. Trp, ANS fluorescence and near-UV CD spectra for ligand bound and free forms of molten globule states were found to be very similar. This shows that molten globule states of these proteins have the ability to bind to their corresponding ligand without conversion to the native state. All four molten globule states showed destabilization relative to the native state. ΔCp values indicate that these molten globule states contain approximately 29-67% of tertiary structure relative to the native state. All four proteins lack prosthetic groups and disulfide bonds. Therefore, it is likely that molten globule states of these proteins are stabilized via hydrophobic and hydrogen bonding interactions.

Proteins

Escherechia Coli

Leucine Binding Protein

Maltose Binding Protein

Ribose Binding Protein

Leucine Valine Binding Protein

Protein Folding

Protein Stability

Periplasmic Binding Protein

Thioredoxin (Trx)

Biochemistry

Clonagem, expressão heteróloga e caracterização parcial da trealase periplasmática de Xanthomonas citri subsp. citri e do seu envolvimento com a fitopatogenicidade

Alexandrino, André Vessoni

03 March 2015

Submitted by Livia Mello (liviacmello@yahoo.com.br) on 2016-09-22T12:11:52Z No. of bitstreams: 1 DissAVA.pdf: 2653238 bytes, checksum: 6ed4edf2962eb1273324c54a2e900fa6 (MD5) / Approved for entry into archive by Marina Freitas (marinapf@ufscar.br) on 2016-10-10T14:38:43Z (GMT) No. of bitstreams: 1 DissAVA.pdf: 2653238 bytes, checksum: 6ed4edf2962eb1273324c54a2e900fa6 (MD5) / Approved for entry into archive by Marina Freitas (marinapf@ufscar.br) on 2016-10-10T14:38:51Z (GMT) No. of bitstreams: 1 DissAVA.pdf: 2653238 bytes, checksum: 6ed4edf2962eb1273324c54a2e900fa6 (MD5) / Made available in DSpace on 2016-10-10T14:38:59Z (GMT). No. of bitstreams: 1 DissAVA.pdf: 2653238 bytes, checksum: 6ed4edf2962eb1273324c54a2e900fa6 (MD5) Previous issue date: 2015-03-03 / Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) / Citrus canker imposes damages to citriculture by causing drop in productivity and fruit quality and the absence of effective control and cure. Thus, the economic potential of citrus is limited in part by this disease mainly caused by the bacterium Xanthomonas citri subsp. citri (XAC) that presents the greatest virulence and broad spectrum of citrus hosts, compared to bacteria Xanthomonas fuscans subsp. aurantifolii types B (XauB) and C (XauC). In a proteomic analysis previously performed by our research group, periplasmic trehalase was identified as a protein which expression differed between XAC e XauC in an in vitro induction of pathogenicity. Trehalase is an enzyme that catalyzes hydrolysis reaction of trehalose, a disaccharide composed of two glucose units, which role in the plant-pathogen interaction is poorly understood. One of the objectives of the study was to obtain this enzyme in purified form using an IPTG-inducible heterologous expression system in E. coli, for purposes of partial characterization of its structure and activity. The recombinant XAC periplasmic trehalase is a monomer bearing wide pH stability and showed Michaelian kinetics. The Michaelis-Menten constant (Km) for trehalose was 0,124 ± 0,015 mM and Vmax 17,319 ± 0,035 μMol glucose.min-1.mg protein-1 . Circular dichroism spectroscopy indicated the following composition of secondary structures: 42.7% α-helices and 13% β-sheets. A gene knockout method based on double homologous recombination between the genomic DNA and suicide vector pNPTS138 has made possible to obtain a strain deleted in the gene encoding the periplasmic trehalase (XACΔ0604), which enabled to evaluate the relationship between this gene and the XAC pathogenicity in Citrus aurantifolia. Infiltrated leaves with XACΔ0604 showed drenching and necrosis of plant tissue and intense brownish pustules compared with wild XAC, suggesting greater virulence of the mutant strain. The periplasmic trehalase activity was compared in XAC and XauC cell extracts from two culture mediums, non-pathogenicity-inducing (CN) and pathogenicity-inducing (XAM-M). Interestingly, XauC has showed higher enzyme activity compared to XAC in XAM-M. Thus, the noticeable higher XACΔ0604 pathogenicity and the greater activity of XauC periplasmic trehalase compared to XAC are indicatives that trehalose may promote pathogenicity. / O cancro cítrico impõe prejuízos ao setor citricultor por ocasionar queda na produtividade e qualidade dos frutos e pela ausência de medidas eficazes de controle e cura. Assim, o potencial econômico dos citros é limitado, em parte, por essa doença causada principalmente pela bactéria Xanthomonas citri subsp. citri (XAC), que apresenta maior virulência e largo espectro de hospedeiros cítricos, comparativamente às bactérias Xanthomonas fuscans subsp. aurantifolii tipos B (XauB) e C (XauC). Em um trabalho de análise proteômica anteriormente realizado por nosso grupo de pesquisa, a trealase periplasmática foi identificada como uma proteína cuja expressão foi diferencial entre XAC e XauC, em condição de indução da patogenicidade in vitro. A trealase é uma enzima que catalisa a reação de hidrólise da trealose, um dissacarídeo formado por duas unidades de glicose, cujo papel na interação planta-patógeno é ainda pouco compreendido. Um dos objetivos do trabalho foi obter esta enzima purificada, utilizando um sistema de expressão heteróloga induzível por IPTG (isopropil-β-D-tiogalactosídeo) em E. coli, para fins de caracterização parcial da sua estrutura e atividade. A trealase periplasmática de XAC de origem heteróloga apresentou-se como um monômero relativamente estável em relação ao pH, e de cinética Michaeliana,. A constante de Michaelis-Menten (Km) da enzima para a trealose foi de 0,124 ± 0,015 mM e a Vmáx 17,319 ± 0,035 μMol de glicose.min-1.mg de proteína-1. Análise de dicroísmo circular resultou na seguinte composição de estruturas secundárias: 42,7 % de α-hélices e 13 % de folhas-β. Uma metodologia de nocaute gênico baseada na dupla recombinação homóloga entre o DNA genômico e o vetor suicida pNPTS138 viabilizou a obtenção de uma linhagem mutante deletada no gene que codifica a trealase periplasmática (XAC∆0604), o que possibilitou avaliar a relação entre tal gene e a patogenicidade de XAC em Citrus aurantifolia. Folhas infiltradas com a suspensão de XAC∆0604 apresentaram maior encharcamento e necrose do tecido vegetal, além de intensas pústulas acastanhadas quando comparadas com as folhas infiltradas com XAC selvagem, sugerindo maior virulência da linhagem mutante. A atividade da trealase periplasmática foi comparada em extratos celulares brutos provenientes de cultivos de XAC e XauC em dois meios de cultura, não-indutor de patogenicidade (CN) e indutor de patogenicidade (XAM- M). A bactéria XauC apresentou maior atividade enzimática de trealase em relação à XAC em XAM-M. Sendo assim, a acentuada patogenicidade de XAC∆0604 em relação à linhagem selvagem XAC e a maior atividade da trealase periplasmática de XauC em relação à XAC reforçam os recentes trabalhos que indicam a trealose como promotora da patogenicidade em fitopatógenos.

Cancro cítrico

Xanthomonas citri subsp. citri

Expressão heteróloga

Trealase periplasmática

Trealose

Citrus canker

Heterologous expression

Periplasmic trehalase

Trehalose

Pathogenicity

Gene knockout

CIENCIAS BIOLOGICAS::GENETICA

Growth rate control of periplasmic product retention in Escherichia coli

Bäcklund, Emma

January 2008

The recombinant product is secreted to the periplasm in many processes where E. coli is used as host. One drawback with secretion is the undesired leakage of the periplasmic products to the medium. The aim of this work was to find strategies to influence the periplasmic retention of recombinant products. We have focused on the role of the specific growth rate, a parameter that is usually controlled in industrial bioprocesses. The hypothesis was that the stability of the outer membrane in E. coli is gained from a certain combination of specific phospholipids and fatty acids on one side and the amount and specificity of the outer membrane proteins on the other side, and that the specific growth rate influences this structure and therefore can be used to control the periplasmic retention. We found that is possible to control the periplasmic retention by the growth rate. The leakage of the product increased as the growth rate increased. It was however also found that a higher growth rate resulted in increased productivity. This resulted in equal amounts of product inside the cells regardless of growth rate. We also showed that the growth rate influenced the outer membrane composition with respect to OmpF and LamB while OmpA was largely unaffected. The total amount of outer membrane proteins decreased as the growth rate increased. There were further reductions in outer membrane protein accumulation when the recombinant product was secreted to the periplasm. The lowered amount of outer membrane proteins may have contributed to the reduced ability for the cell to retain the product in the periplasm. The traditional way to control the growth rate is through a feed of substrate in a fed-batch process. In this work we used strains with a set of mutations in the phosphotransferase system (PTS) with a reduced uptake rate of glucose to investigate if these strains could be used for growth rate control in batch cultivations without the use of fed-batch control equipment. The hypothesis was that the lowering of the growth rate on cell level would result in the establishment of fed-batch similar conditions. This study showed that it is possible to control the growth rate in batch cultivations by using mutant strains with a decreased level of substrate uptake rate. The mutants also produced equivalent amounts of acetic acid as the wild type did in fed-batch cultivation with the same growth rate. The oxygen consumption rates were also comparable. A higher cell density was reached with one of the mutants than with the wild type in batch cultivations. It is possible to control the growth rate by the use of the mutants in small-scale batch cultivations without fed-batch control equipment. / QC 20101108

Escherichia coli

fed-batch

outer membrane proteins

recombinant proteins

specific growth rate

periplasmic retention

phosphotransferase system

high cell density cultivation

acetate formation

Industrial Biotechnology

Industriell bioteknik

Rôle du système ZraPSR dans le stress de l’enveloppe et la résistance aux antimicrobiens chez la bactérie Escherichia coli / Role of the ZraPSR system in envelope stress and antimicrobial resistance in Escherichia coli

Rome, Kevin Josué

18 December 2017

Les bactéries ont réussi à coloniser toutes les niches écologiques de la planète. Le passage d’un environnement à un autre s’accompagne de la fluctuation de nombreux paramètres environnementaux aboutissant à un stress cellulaire. Directement en contact avec le milieu environnant, l’enveloppe bactérienne est la première barrière contre ces stress extracellulaires. Toute rupture de son intégrité aura des conséquences délétères pour la cellule. Parmi les mécanismes permettant aux bactéries de détecter les changements de conditions environnementales, il existe des systèmes spécifiques appelés ESR (Envelope Stress Response). Ces systèmes maintiennent l’intégrité membranaire en réparant les dommages de l’enveloppe. Ce travail de thèse s’inscrit dans l’étude des mécanismes intrinsèques de résistance chez les bactéries, par la caractérisation d’un nouvel ESR d’E. coli : le système ZraPSR (Zinc Resistance Associated Protein Sensor Regulator). ZraPSR est un système à deux composants, composé d’un senseur ZraS, d’un régulateur transcriptionnel ZraR et d’une protéine périplasmique accessoire ZraP. La cascade ZraS-R est activée par des concentrations élevées en Zn et Pb. Ce travail a montré que ZraP établit un rétrocontrôle négatif sur la cascade de signalisation ZraSR par un mécanisme nécessitant sa métallation. Malgré une induction en présence de métaux, nous avons montré que le système ZraPSR ne possède aucun rôle dans l’homéostasie métallique. A contrario, en réponse à des signaux de stress, ZraSR va contribuer à la résistance intrinsèque à certains antimicrobiens. De plus, l’étude du régulon de ZraR a permis de commencer à entrevoir les mécanismes sous-jacents de réponse aux stress antimicrobiens médiée par ZraPSR. Cette réponse intègre des signaux de l’état physiologique de la cellule par l’intermédiaire de régulateurs globaux du métabolisme aboutissant à une réponse optimale. Le système ZraPSR semble donc être un nouveau mécanisme de résistance-croisée aux stress environnementaux. / Bacteria succeed in colonizing all the ecological niches on earth. Transition from one environment to another comes along with the fluctuation in numerous environmental parameters wich induce cellular stress. Directly in contact with the surrounding environment, the bacterial envelope is the first barrier against these extracellular stresses. Any break of its integrity will have deleterious consequences for the cell. Among mechanisms allowing bacteria to detect environmental changes, specific systems called ESR (Envelope Stress Response) have been studied. Such systems maintain membrane integrity by repairing envelope damages. This work takes part in the study of the intrinsic mechanisms of antimicrobial resistance in bacteria, by the characterization of a new ESR of E. coli: the ZraSR (Zinc Resistance Associated Protein Sensor Regulator) system. ZraPSR is a two-component system consisting of a ZraS sensor, a ZraR transcriptional regulator and a ZraP accessory periplasmic protein. The ZraS-R cascade is activated by high concentrations of Zn and Pb. In this study, we showed that ZraP establishes a negative feedback on the ZraSR pathway by a mechanism requiring its metallation. Despite the observed induction in the presence of metals, we showed that the ZraPSR system is not required for metal homeostasis. Whereas, in response to stress signals, ZraSR contribute to intrinsic resistance to certain antimicrobials. Futhermore, the study of the ZraR regulon allowed us to begin glimpsing the underlying mechanisms of antimicrobial stress response mediated by ZraPSR. This response incorporates signals from the physiological state of the cell through global regulators of the metabolism leading to an optimal response. The ZraPSR system seems to be a new cross-resistance mechanism to environmental stresses.

Microbiologie

Escherichia coli

Résistance intrinsèque

Résistance croisée

ESR antimicrobien

Protéine chaperonne périplasmique

Métabolisme central

Microbiology

Escherichia coli

Intrinsic resistance

Cross resistance

ESR anitmicrobial

Periplasmic chaperone protein

Central metabolism

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