Structural and Biochemical Analysis of DNA Processing Protein A (DprA) from Helicobacter Pylori

Dwivedi, Gajendradhar R

January 2014

H. pylori has a panmictic population structure due to high genetic diversity. The homoplasy index for H. pylori is 0.85 (where 0 represents a completely clonal organism and 1.0 indicates a freely recombining organism) which is much higher than homoplasy index for E. coli (0.26) or naturally competent Neisseria meningitides (0.34). It undergoes both inter as well as intra strain transformation. Intergenomic recombination is subject to strain specific restriction in H. pylori. Hence, a high homoplasy index means that competence predominates over restriction in H. pylori. Annotation of the genomes of H. pylori strains 26695 and J99 show the presence of nearly two dozen R-M systems out of which 16 were postulated to be Type II for J99. H. pylori has been described to be an ideal model system for understanding the equilibrium between competing tension of genomic integrity and diversity (42). R-M systems allow some degree of sexual isolation in a population of competent cells by acting as a barrier to transformation. The mixed colonizing population of H. pylori has a polyploidy nature where each H. pylori strain adds to ‘ploidy’ of the colonizing population. Maintenance of polyploidy nature of mixed colonizing population in a selective niche of stomach needs a barrier to free gene flow. Restriction barrier maintains a polyploidy nature of H. pylori population which is considered as yet another form of genetic diversity helping in persistence of infection. Thus, according to the model proposed by Kang and Blaser, where H. pylori are considered as perfect gases like bacterial population, transformation and restriction both add to genetic diversity of the organism. Again, restriction barriers are not completely effective, which could be due to cellular regulation of restriction system. Thus, a perfect balance between restriction and transformation in turn regulates the gene flow to equilibrate competition and cooperation between various H. pylori strains in a mixed population. RecA, DprA and DprB have been shown to be involved in the presynaptic pathway for recombination substrates brought in through the Com system. Biochemical characterization of HpDprA, during this study revealed its ability to bind to ssDNA and dsDNA. Binding of HpDprA to both ssDNA as well as dsDNA results in large nucleoprotein complex that does not enter the native PAGE. However, DNA trapped in the wells could be released by the addition of excess of competitor DNA, illustrating that the complex are formed reversibly and do not represent dead-end reaction products. Transmission electron microscopy for SpDprA interaction with ssDNA established that a large nucleoprotein complex consisting of a network of several DNA molecules bridged by DprA is formed which is retained in the well. A large DNA-protein complex that sits in the well has also been observed with other DNA binding proteins like RecA. It has been observed for ssDNA binding protein (SSB) that they bind non-specifically to dsDNA under low salt condition (20 mM NaCl) in the absence of Mg2+. The non specific binding of SSB to dsDNA was prevented under high salt conditions (200 mM NaCl) or in the presence of Mg2+. HpDprA interaction with both ssDNA and dsDNA was stable under high salt condition (200 mM NaCl) and in the presence of Mg2+ indicating that these interactions are specific. The interaction of HpDprA with dsDNA is significant since dsDNA plays an important role in natural transformation of H. pylori. The pathway of transformation by dsDNA is highly facilitated (nearly 1000 fold) as compared to ssDNA. However, dsDNA is a preferred substrate for REases which are a barrier to horizontal gene transfer. This implies that the decision of ‘restriction’ or ‘facilitation for recombination’ of incoming DNA might be taken before the conversion of dsDNA into ssDNA. The incoming DNA has been shown to be in the double-stranded form in periplasm and in single-stranded form in cytoplasm. Hence, the temporal and spatial events surrounding endonuclease cleavage remain to be understood. Taken together, these results suggest a very important role of dsDNA in natural transformation in H. pylori. Hence, binding and protection of dsDNA by HpDprA is possibly of crucial importance in the success of natural transformation process of the organism. DprA is characterized by presence of a conserved DNA binding domain. The DNA binding domain adopts a Rossman fold like topology spanning most region of the protein. Rossman fold consists of alternating alpha helix and beta strands in the topological order of β-α-β-α-β. It generally binds to a dinucleotide in a pair as a single Rossman fold can bind to a mononucleotide only. All homologous DprA proteins characterized till date show that in addition of the prominent Rossman fold domain they consist one or more smaller domains. RpDprA consists two more domains other than the Rossman fold domain i.e., N- terminal SAM (sterile alpha motif) domain and a C-terminal DML-1 like domain. SpDprA consist of an N-terminal SAM domain other than Rossman fold domain. While the main function of Rossman fold is to bind DNA, the supplementary domains are highly variable in sequences and functions. For example, the SAM domain in S. pneumoniae plays a key role in shut-off of competence by directly interacting with ComE~P. HpDprA consist of an N-terminal Rossman fold domain and a C-terminal DML-1 like domain. Both these domains are found to be prominently α-helical in nature. Amino acid sequence analysis of the protein suggests that NTD is basic and CTD is acidic in nature. NTD is sufficient for binding with ssDNA and dsDNA, while CTD plays an important role in formation of higher order polymeric complex with DNA. For HpDprA and SpDprA, dimerization site was mapped in Rossman fold domain. Gel filtration data revealed an important observation that HpDprA can exist as a monomer (dominant species at lower concentration) as well as a dimer (dominant species at higher concentration) in solution. However, the exchange between these two forms is very fast resulting in a single peak of elution. Since, HpDprA binds to DNA in dimeric form, the dimer species will be favoured in presence of DNA. Hence, even at lower concentrations HpDprA will be mainly a dimer in presence of DNA. Interestingly, both domains of HpDprA i.e., NTD and CTD were able to form dimers but no higher oligomeric form. On the other hand, HpDprA was seen to form oligomeric forms higher than dimer in gluteraldehyde cross linking assay. The strength of CTD dimer was much lower that NTD dimer, therefore it could be proposed that there are two sites of interaction present in HpDprA - a primary interaction site (N-N interaction) and a secondary interaction site (C-C interaction). The N-N interaction is responsible for dimer formation but further oligomerization of HpDprA necessitates the interaction of two dimers using C-C interaction site. It was shown that NTD binds to ssDNA but forms lower molecular weight complex. SPR analysis of DprA and NTD – DNA interaction pointed out that deletion of CTD leads to faster dissociation of the protein from DNA. Concomitantly, reduction in binding affinity was observed for both ss and ds DNA upon deletion of CTD from full length protein. These results suggest that CTD does play an important role in interaction of full length HpDprA with DNA. Two possible roles of CTD were proposed by Wang et al (2014) group to explain their observation of formation of lower molecular weight complex in absence of CTD. (i) CTD possesses a second DNA binding site but much weaker than site present in NTD. (ii) CTD is not involved in DNA binding but mediates nucleoprotein complex formation through protein – protein interaction. EMSA and SPR analysis with purified CTD protein confirmed that there is no secondary DNA binding site present in CTD. As discussed above, it was observed that CTD can mediate interaction between two HpDprA through C-C interaction. Since the interaction is weaker it is lesser likely to be responsible for dimer formation but in trimer or higher oligomeric form of HpDprA, the presence of N-N interaction will facilitate and stabilize C-C interaction. These observations together bring forward an interesting model for HpDprA – DNA interaction. HpDprA forms dimer through N-N interaction (favourably in presence of DNA) and many HpDprA dimers bind to DNA owing to their high affinity and sequence independent nature of binding. These dimers interact with each other through C-C interaction resulting in higher molecular weight nucleoprotein complex. HpDprA - DNA complex formation is slower than NTD – DNA complex but the former one is more stable (Fig. 2). According to the above proposed model there are two binding events (DNA – protein and protein – protein) in case of HpDprA – DNA complex formation and hence it would take longer time than NTD-DNA complex formation which involves only one binding event. But the resulting higher order complex with HpDprA – DNA would be much more stable. NTD is able to offer equally efficient protection from nuclease to ssDNA and dsDNA (Fig. 7). This shows that NTD alone is sufficient to completely coat single molecule DNA. AFM images confirm the difference in binding pattern of HpDprA full length protein and NTD. As can be seen in Fig. 8F, NTD binds a DNA molecule by entirely occupying all the available space but forms nucleoprotein filaments isolated from each other. In contrast to full length HpDprA, which forms tightly packed, condensed, extensively cross linked polynucleoprotein complexes, NTD forms much thinner complexes with DNA. In the electron micrographs of SpDprA – DNA complex, extensive cross filament interaction was observed resulting in a dense molecular aggregate. Similar kinds of complexes with DNA were also observed for Bacillus subtilis DprA in atomic force microscope images. Thus, it could be proposed that HpDprA binds to a single DNA molecule (single strand or double strand) mainly as a dimer formed through N-N interaction. Such multiple individual nucleoprotein filaments come together and interact with each other through C- C interaction resulting in dense and intricate poly – nucleoprotein complex. HpDprA is proposed to undergo conformational changes from closed state to open state in presence of ssDNA. In agreement with this, structural transition (resulting in reduction of α-helicity of the protein) was observed in presence of ssDNA. Similar structural transitions were observed for dsDNA indicating possibly a common mode of interaction for both forms of DNA. Further, mutation of the residues shown to be involved in binding ssDNA from crystallographic data, resulted in decrease of binding affinity with dsDNA as well. The fold reduction in binding affinity of dsDNA was lower than that for ssDNA despite that it is obvious that the same positively charged pocket which is primarily involved in ssDNA interaction is also responsible (atleast partially) for binding with dsDNA. However, the residues crucial for interaction with these two forms of DNA may be different. Both DprA and R-M systems have been shown to have presynaptic role in natural transformation process. While DprA has a protective role, R-M systems have an inhibitory role for incoming DNA suggesting a functional interaction between them. Results of this study show that HpDprA interacts with dsDNA, inhibits Type II restriction enzymes from acting on it and at the same time stimulates the activity of MTases resulting in increased methylation of bound DNA. This observation is of significance from the view of genetic diversity as the only way a bacterial cell discriminates between self and nonself DNA is through the pattern of methylation. Binding of HpDprA to incoming DNA inhibits its access to restriction endonucleases but not to methyltransferases. As a result DNA will be methylated with the same pattern as that of the host cell. Hence, it no longer remains a substrate for restriction enzymes. HpDprA thus, effectively alleviates the restriction barrier. However, it remains to be understood as to how DNA in complex with HpDprA, while not accessible to REases or other cellular nucleases, is accessible to a MTase? A possible explanation could be that HpDprA interacts with MTase and recruits it on DNA. It has been shown that there is a overlap between DprA dimerization and RecA interaction interfaces and in presence of RecA, DprA-DprA homodimer is replaced with DprA-RecA heterodimer allowing RecA nucleation and polymerization on DNA followed by homology search and synapsis with the chromosome. A similar scenario can be thought for interaction of HpDprA with the MTase. R-M systems play an important role in protection of genomic DNA from bacteriophage DNA. Hence, downregulation of restriction barrier by HpDprA may not be desirable by host during the entire life cycle. Therefore, the expression of HpDprA, which is ComK dependent and that which takes place only when competence is achieved is noteworthy. In H. pylori, DNA damage induces genetic exchange via natural competence. Direct DNA damage leads to significant increase in intergenomic recombination. Taken together it can be proposed that when genetic competence is induced, R-M systems are down regulated to allow increased genetic exchange and thus, increasing adaptive capacity in a selective environment of stomach. There is an evolutionary arms race between bacterial genomes and invading DNA molecules. R-M systems and anti-restriction systems have co-evolved to maintain an evolutionary balance between prey and predator. Phages and plasmids employ anti-restriction strategies to avoid restriction barrier by a) DNA sequence alteration, b) transient occlusion of restriction sites and c) subversion of restriction-modification activities. DNA binding proteins have been shown to bind and occlude restriction sites. On the other hand, λ Ral protein alleviates restriction by stimulating the activity of Type IA MTases. The observations of MTase stimulation and site occlusion of restriction sites by HpDprA appears to be analogous to anti restriction strategies, otherwise employed by bacteriophages. Thus, DprA could be a unique bacterial anti-restriction protein used by H. pylori for downregulating its own R-M systems to maintain the balance between fidelity and diversity. In conclusion, HpDprA has unique ability to bind to dsDNA in addition ssDNA but displays higher affinity towards ssDNA. Binding of HpDprA to DNA results in a compact complex that is inert to the activity of nucleases. A novel site of oligomerization for HpDprA was observed which suggests the role of C-C interaction in inter-nucleoprotein filament interaction. It would be interesting to further study the effects of CTD deletion on the transformation efficiency of H. pylori, to understand these mechanisms better. It has been well demonstrated that R-M systems offer a barrier to incoming DNA, but our understanding of the regulation of R-M systems has been poor. While other factors like regulation of cellular concentration of restriction enzymes and conversion of dsDNA into ssDNA might play crucial roles in striking the perfect balance between genome diversity and integrity, one of the factors that regulate R-M systems could be DprA.

DNA Molecular Structures

Helicobacter pylori DprA

DNA Binding Proteins

DNA Processing Protein

Bacterial Pathogens

Gram-Negative Bacterium

Bacterial Transformation

DprA

HpDprA

H. pylori

Biochemistry

Generation of a stem cell driven in vitro culture of polarized cells to study gastric tissue homeostasis and response to infections

Wölffling, Sarah

07 September 2020

In der humanen Magenschleimhaut regulieren eine Vielzahl von Interaktionen zwischen verschiedenen Zellpopulationen die Verdauung und die Überwachung von Infektionen. Epithelzellen in der Schleimhaut differenzieren in spezialisierte Zelltypen, die schützenden Mukus, Magensäure, Verdauungsenzyme oder Hormone produzieren. Eine Infektion mit Helicobacter pylori kann die Gewebehomöostase fehlregulieren, was die Wahrscheinlichkeit erhöht, dass an der Infektionsstelle ein Magengeschwür, ein Adenokarzinom oder letztendlich Magenkrebs auftritt. In dieser Arbeit wird die Entwicklung eines neuartigen in vitro Kulturmodells für humane primäre Magenepithelzellen, die sogenannte Mukosoidkultur, gezeigt. Die Mukosoidkulturen sind repräsentativ für Epithelbarrieren und rekapitulieren die meisten Funktionen der menschlichen Magenschleimhaut in vivo, einschließlich der Schleimproduktion, und ermöglichen eine langfristige und stabile Kultivierung von Epithelzellen sowie Infektionsstudien mit H.pylori. Mukosoidkulturen aus Corpus wurden verwendet, um die Nischenfaktoren zu untersuchen, die die Differenzierung von Oberflächenepithelzellen, Hauptzellen und Parietalzellen fördern. EGF erwies sich zusammen mit BMP/Noggin als ein wichtiger Regulator bei der Differenzierung. Stromazellen sind Teil der Lamina propria der Magenschleimhaut. Über die Wechselwirkung mit dem Epithel unter homöostatischen Bedingungen und bei bakteriellen Infektionen mit H.pylori ist nur sehr wenig bekannt. Die Co-Kultur von humanen primären Stromazellen des Magens mit Epithelzellen unter Verwendung des Mukosoidkultur-Modells zeigte die aktive Signalübertragung zwischen beiden Zelltypen auf. Darüber hinaus wurden Mukosoidkulturen erfolgreich mit H.pylori infiziert. Die Ergebnisse zeigen, dass Stromazellen aktiv mit Cytokin- und Chemokinexpression auf eine epitheliale Infektion reagieren. Gleichzeitig erhöhten Stromazellen die NFκB-gesteuerte Entzündungsreaktion in Epithelzellen. / In the human gastric mucosa, multiple interactions between different cell populations regulate digestion and surveillance of infections. Epithelial cells in the mucosa differentiate into specialized cell types to produce protective mucins, gastric acid, digestive enzymes or hormones. Infection with Helicobacter pylori dysregulates the tissue homeostasis increasing the chance to develop a gastric ulcer, adenocarcinoma or ultimately gastric cancer at the site of infection. In this thesis, the development of a novel in vitro culture model for human primary gastric epithelial cells, called the mucosoid culture, is shown. The mucosoid cultures are representative of epithelial barriers and recapitulate most of the functions of the human gastric mucosa in vivo, including mucus production, and allow long-term and stable cultivation of epithelial cells as well as infection studies with H.pylori. Corpus derived mucosoids were used to investigate the niche factors that promote the differentiation of foveolar cells, chief cells, and parietal cells. EGF was found to be a major regulator in differentiation together with BMP/Noggin. Stromal cells are part of the lamina propria of the gastric mucosa. Very little is known about the interaction with the epithelium under homeostatic conditions and during bacterial infections with Helicobacter pylori. The co-culture of human primary gastric stromal cells with epithelial cells using the mucosoid culture model demonstrated the active signaling between both cell types. Furthermore, mucosoid cultures were successfully infected with H. pylori. The results revealed that stromal cells actively respond to epithelial infection with cytokine and chemokine expression. Concurrently stromal cells increased the NFκB-driven inflammatory response in epithelial cells.

Mukosoidkultur

Humane gastrische Primärzellen

Corpus Differenzierung

Stromazellen

Helicobacter pylori

Human gastric primary cells

mucosoid culture

corpus differentiation

stromal cells

Helicobacter pylori

570 Biologie

XH 7104

XH 7111

XH 7112

ddc:570

Prevalência de Helicobacter pylori e vírus Epstein-barr em crianças e adolescentes

OLIVEIRA, Kátia Soares de

13 March 2013

Submitted by Edisangela Bastos (edisangela@ufpa.br) on 2013-04-23T18:02:31Z No. of bitstreams: 2 license_rdf: 23898 bytes, checksum: e363e809996cf46ada20da1accfcd9c7 (MD5) Dissertacao_PrevalenciaHelicobacterPylori.pdf: 934699 bytes, checksum: b0ff88938ac2eac1e23b4faf11e82eb3 (MD5) / Approved for entry into archive by Ana Rosa Silva(arosa@ufpa.br) on 2013-04-24T14:45:38Z (GMT) No. of bitstreams: 2 license_rdf: 23898 bytes, checksum: e363e809996cf46ada20da1accfcd9c7 (MD5) Dissertacao_PrevalenciaHelicobacterPylori.pdf: 934699 bytes, checksum: b0ff88938ac2eac1e23b4faf11e82eb3 (MD5) / Made available in DSpace on 2013-04-24T14:45:38Z (GMT). No. of bitstreams: 2 license_rdf: 23898 bytes, checksum: e363e809996cf46ada20da1accfcd9c7 (MD5) Dissertacao_PrevalenciaHelicobacterPylori.pdf: 934699 bytes, checksum: b0ff88938ac2eac1e23b4faf11e82eb3 (MD5) Previous issue date: 2013 / Introdução: Infecções por Helicobacterpylori(HP) e vírusEpstein-Barr (VEB) são comuns no mundo todo, embora o HP seja o maior fator em doenças gastroduodenais, seu percentual de associação com VEB é incerto. Tanto o VEB quanto o HP são classificados como carcinógenos classe 1 pela Organização Mundial de Saúde, e uma substancial fração de indivíduos se tornam co-infectados na adultice. Esses dois patógenos podem potencializar sinergicamente para causar gastrite crônica perpetua. O objetivo deste trabalho foi verificar a prevalência de HP e do vírus Epstein-Barr em crianças e adolescentes. Material e Método: Estudo descritivo, do tipo transversal. Foram analisadas amostras de mucosa gástrica de 64 crianças e adolescentes através do Teste da Urease para diagnóstico do HP, da técnica de PCR para detecção da cepa cagA de H. pylori, da técnica de hibridização in situ para detecção do EBV e da análise patológica para determinação de características histopatológicas. Resultados: A prevalência de HP nas crianças e adolescentes em estudo foi de 53,1% enquanto a prevalência de VEB foi 3,1%. Entre os pacientes infectados por HP, a maioria (94,3%) apresentava gastrite a endoscopia digestiva alta, sendo gastrite enantemática a mais comumente encontrada. Na análise histopatológica, também a maioria (97,1%) dos pacientes apresentava algum grau de gastrite, com 80% classificados com gastrite crônica moderada. Cepas cagA positivas foram encontradas em 64,7% dos infectados com HP e entre estes todos tinham gastrite, com predomínio de gastrite crônica moderada (54%), no entanto não se observou correlação com significância estatística entre esses achados. Em adição, também não houve significância estatística para a associação entre infecção por HP e por VEB na população estudada, a baixa prevalência de VEB nesta análise sugere que esse vírus não é um agente etiológico das lesões da mucosa gástrica. No nosso conhecimento, este é o primeiro estudo que relaciona estes dois agentes infecciosos na mucosa gástrica de crianças e adolescentes do norte do Brasil. Conclusão: A maioria dos achados deste estudo se assemelha aos relatos da literatura, contudo evidenciou-se a necessidade de estudos com maior casuística, envolvendo a população pediátrica imunocompetente afim de melhor esclarecer se há ou não correlação entre a infecção por HP e VEB em nossa região. / Introduction: Infections by Helicobacter pylori (HP) and Epstein-Barr virus (EBV) are common worldwide, although HP is the highest factor in gastroduodenal diseases, its percentage of association with EBV is uncertain. Both EBV and HP are classified are class 1 carcinogens by the World Health Organization, and a substantial number of individuals become co-infected in adulthood. These two pathogens may have synergic potential to cause perpetual chronic gastritis. The purpose of this paper was to verify the prevalence of HP and Epstein-Barr virus in children and adolescents. Material and Methods: Transversal descriptive study. The gastric mucosa of 64 children and adolescents was analyzed through the Urease Test to diagnose HP and the PCR technique to detect H. pylori’s cagA strain, the in situ hybridization technique to detect EBV and the pathological analysis to determine the histopathological characteristics. Results: The prevalence of HP and EBV found by this study was 53.1% and 3.1, respectively. Most of the patients infected by HP (94.3%) presented gastritis in the upper gastrointestinal endoscopy, with enanthemathous gastritis being the most commonly found type. In the histopathological analysis, most patients (97.1%) presented some level of gastritis, 80% of which classified as moderate chronic gastritis. Positive cagA strains were found in 64.7% of the patients infected with HP and all of them had gastritis, with predominance of moderate chronic gastritis (54%); however, there was no statistically significant correlation between these findings. There was also no statistically significant association between infection by HP and EBV in the studied population. The low prevalence of EBV in this analysis suggests that this virus is not an etiological agent in gastric mucosa lesions. To our knowledge, this is the first study that relates these two infectious agents in the gastric mucosa of children and adolescents in northern Brazil. Conclusion: Most of the findings in this study are in line with the literature; however, it is necessary to conduct larger studies, involving aimmunocompetent pediatric population in order to determine whether there is a correlation between infection by HP and EBV in our region.

CNPQ::CIENCIAS BIOLOGICAS::MICROBIOLOGIA

Infecções por Helicobacter

Herpesvírus humano 4

Crianças

Adolescentes

Prevalência

Helicobacter pylori

Amazônia Brasileira

Efeito de bebidas alcoólicas no crescimento in vitro de Helicobacter pylori

Lopes, Maria Palma Mateus

January 2005

Tese de Mestrado em Nutrição Clínica apresentada à Faculdade de Ciências de Nutrição e Alimentação da Universidade do Porto / Resumo da dissertação: A infecção por Helicobacfer pylori (H. pylorg afecta 50 % da população mundial e está associada a gastrite crónica, a úlcera péptica e ao cancro gástrico. A aquisição da infecção por H. pylori e a sua erradicação espontãnea parece ser comum na infância. Na fase adulta, a infecção é mais persistente. Alguns autores defendem que o consumo de bebidas alcoólicas pode contribuir para a erradicação espontãnea de H. pylori, nos adultos. Esta hipótese é apoiada por vários estudos epidemiológicos e experimentais. No presente trabalho foi testada, in vifro, a actividade anti H. pylori de vinho tinto e branco, de diferentes tipos de cerveja (branca com e sem álcool, preta com álcool e preta com álcool enriquecida com xantohumol e iso-xantohumol), assim como do resveratrol e do xantohumol, compostos fenólicos presentes no vinho e na cerveja, respectivamente. Onze estirpes clínicas e uma estirpe de referência (CCUG 15818) de H. pylori foram inoculadas em agar Columbia suplementado com 10 % de sangue, ao qual foram adicionadas as várias bebidas e os compostos fenólicos, em diferentes concentrações, e incubadas em condições de microaerofilia, a 36+-1ºC durante 48 horas.

Nutrição--Dissertação de mestrado

Bebidas Alcoólicas

Helicobacter pylori

Adaptive Responses by Transcriptional Regulators to small molecules in Prokaryotes : Structural studies of two bacterial one-component signal transduction systems DntR and HpNikR

Dian, Cyril

January 2007

<p>Prokaryotes are continually exposed to variations in their environment. Survival in unstable milieu requires a wide range of transcriptional regulators (TRs) that respond to specific environmental and cellular signals by modulating gene expression and provide an appropriate physiological response to external stimuli. These adaptive responses to environmental signals are mostly mediated by TRs from one of two families: the single or the two component signal transduction systems (1CSTS; 2CSTS). In this thesis the structural analysis of two 1CSTS – DntR and NikR − are presented. One study was carried out to try to develop a bacterial biosensor for synthetic dinitrotulenes compounds, the other to characterise the Ni-sensing mechanism that contributes to the acid adaptation of the human pathogen<i> Helicobacter pylori.</i> DntR belongs to the LysR family and the crystal structures obtained have allowed the proposal a model of the interaction of DntR with salicylate inducer as well as giving insights into the signal propagation mechanism in LysR-type transcription factors (<b>paper I</b>). DntR mutant crystal structures combined with the modelling of DntR-2,4-dnt interactions led to the design of a DntR mutant that has a limited response to 2,4-dnt in a whole cell biosensor system (<b>paper 2</b>). Crystal structures of apo-NikR from <i>H. pylori </i>(HpNikR) and of Ni-bound intermediary states of the protein were obtained. The latter have helped in unravelling the Ni incorporation and selectivity mechanisms of NikRs and have shown a strong cooperativity between conformational changes in the Ni binding domain with movements of the DNA binding domain (<b>paper 3</b>). Biochemical studies and comparisons of the HpNikR crystal structures with those of NikR homologues strongly suggest that HpNikR has evolved different surface properties (<b>paper 4</b>) and a new mode of DNA binding. </p>

transcription regulator

bacterial biosensor

LysR family

Inducer-binding

nickel-sensing

NikR

signal transduction system

Helicobacter pylori

Biochemistry

Biokemi

Identification of bacterial pathogenic gene classes subject to diversifying selection

Sumir Panji

January 2009

<p>Availability of genome sequences for numerous bacterial species comprising of different bacterial strains allows elucidation of species and strain specific adaptations that facilitate their survival in widely fluctuating micro-environments and enhance their pathogenic potential. Different bacterial species use different strategies in their pathogenesis and the pathogenic potential of a bacterial species is dependent on its genomic complement of virulence factors. A bacterial virulence factor, within the context of this study, is defined as any endogenous protein product encoded by a gene that aids in the adhesion, invasion, colonization, persistence and pathogenesis of a bacterium within a host. Anecdotal evidence suggests that bacterial virulence genes are undergoing diversifying evolution to counteract the rapid adaptability of its host&rsquo / s immune defences. Genome sequences of pathogenic bacterial species and strains provide unique opportunities to study the action of diversifying selection operating on different classes of bacterial genes.</p>

Helicobacter pylori

Neisseria meningitidis

Vibrio Cholerae

Positive Selection

Virulence Gene

Nucleotide Diversity

Statistical Enrichment

Functional Annotation

Biological Processes

Metabolic Pathways.

Adaptive Responses by Transcriptional Regulators to small molecules in Prokaryotes : Structural studies of two bacterial one-component signal transduction systems DntR and HpNikR

Dian, Cyril

January 2007

Prokaryotes are continually exposed to variations in their environment. Survival in unstable milieu requires a wide range of transcriptional regulators (TRs) that respond to specific environmental and cellular signals by modulating gene expression and provide an appropriate physiological response to external stimuli. These adaptive responses to environmental signals are mostly mediated by TRs from one of two families: the single or the two component signal transduction systems (1CSTS; 2CSTS). In this thesis the structural analysis of two 1CSTS – DntR and NikR − are presented. One study was carried out to try to develop a bacterial biosensor for synthetic dinitrotulenes compounds, the other to characterise the Ni-sensing mechanism that contributes to the acid adaptation of the human pathogen Helicobacter pylori. DntR belongs to the LysR family and the crystal structures obtained have allowed the proposal a model of the interaction of DntR with salicylate inducer as well as giving insights into the signal propagation mechanism in LysR-type transcription factors (<b>paper I</b>). DntR mutant crystal structures combined with the modelling of DntR-2,4-dnt interactions led to the design of a DntR mutant that has a limited response to 2,4-dnt in a whole cell biosensor system (<b>paper 2</b>). Crystal structures of apo-NikR from H. pylori (HpNikR) and of Ni-bound intermediary states of the protein were obtained. The latter have helped in unravelling the Ni incorporation and selectivity mechanisms of NikRs and have shown a strong cooperativity between conformational changes in the Ni binding domain with movements of the DNA binding domain (<b>paper 3</b>). Biochemical studies and comparisons of the HpNikR crystal structures with those of NikR homologues strongly suggest that HpNikR has evolved different surface properties (<b>paper 4</b>) and a new mode of DNA binding.

transcription regulator

bacterial biosensor

LysR family

Inducer-binding

nickel-sensing

NikR

signal transduction system

Helicobacter pylori

Biochemistry

Biokemi

Modeling of transient protein-protein interactions: a structural study of the thioredoxin system

Obiero, Josiah Maina

25 February 2011

ABSTRACT Protein-protein interactions play a central role in most biological processes. One such biological process is the maintenance of a reducing environment inside the cell. To maintain an internal reducing environment, living cells have evolved two enzymatic systems (glutathione and thioredoxin (Trx) systems). The Trx system is composed of the enzyme TrxR and its substrate Trx. The two proteins constitute an important thiol-dependent redox system that catalyzes the reduction of many proteins that are responsible for a variety of cellular functions. The system relies on transient protein-protein interactions between Trx and TrxR for its function. Cross-reactivity of components of the Trx system between species has been shown to be medically relevant. For example, Helicobacter pylori Trx (HP Trx) is thought to mediate catalytic reduction of human immunoglobulins and thus facilitate immune evasion. It has also been proposed that Helicobacter pylori gains access to the impenetrable gastric mucous layer by using secreted HP Trx to reduce the disulfide bonds present in the cysteine-rich mucin regions that are responsible for cross-linking mucin monomers. Therefore, disruption of secreted HP Trx-host protein interaction may result in restoration of the viscoelastic and hydrophobic protective properties of mucus. Previous studies aimed at understanding the nature of cross-reactivity of Trx system components among various species have shown that Trxs have higher affinity for cognate TrxRs (same species), than for TrxRs from different species. However, the basis for this specificity is not known. A growing body of evidence suggests that most protein-protein interactions are mediated by a small number of protein-protein interface residues, referred to as hot spot residues or binding epitopes. Therefore, understanding the biochemical basis of the affinity of proteins for their partners usually begins by identifying the hot spot residues responsible for the protein complex interactions. In this study, the crystal structures of Deinococcus radiodurans thioredoxin reductase (DR TrxR) and Helicobacter pylori TrxR (HP TrxR) were determined at 1.9 Å and 2.4 Å respectively. Analysis of the Trx-binding sites of both structures suggests that the basis of affinity and specificity of Trx for TrxR is primarily due to the shape rather than the charge of the surface. In addition, the complex between Escherichia coli thioredoxin reductase (EC TrxR) and its substrate thioredoxin (EC Trx) was used to identify residues that are responsible for TrxR-Trx interface stability. Using computational alanine scanning mutagenesis and visual inspection of the EC TrxR-Trx interface, 22 EC TrxR side chains were shown to make contact across the TrxR-Trx interface. Although more than 20 EC TrxR side chains make contact across the TrxR-Trx interface, our results suggest that only 4 residues (F81, R130, F141, and F142) account for the majority of the EC TrxR-Trx interface stability. Individual replacement of equivalent DR TrxR residues (M84, K137, F148, F149) with alanine resulted in drastic changes in binding affinity, confirming that the four residues account for most of TrxR-Trx interface stability. These hot spot residues are surrounded by less important residues (hydrophobic and hydrophilic) that are also predicted to contribute to interface stability. F148 and F149 are invariant across bacterial TrxRs, however other residues that contact Trx are less conserved including M84 and K137. When M84 and K137 were changed to match equivalent E. coli TrxR residues (K137R, M84F); D. radiodurans TrxR substrate specificity was altered from its own Trx to that of E. coli Trx. The results suggest that a small subset of the TrxR-Trx interface residues are responsible for the majority of Trx binding affinity and specificity, a property that has been shown to general to protein-protein interfaces.

fluorescence spectroscopy

Deinococcus radiodurans

Helicobacter pylori

enzyme kinetics

site-directed mutagenesis

thioredoxin system

x-ray crystallography

Protein-protein interactions

Modeling of transient protein-protein interactions: a structural study of the thioredoxin system

Obiero, Josiah Maina

25 February 2011

ABSTRACT Protein-protein interactions play a central role in most biological processes. One such biological process is the maintenance of a reducing environment inside the cell. To maintain an internal reducing environment, living cells have evolved two enzymatic systems (glutathione and thioredoxin (Trx) systems). The Trx system is composed of the enzyme TrxR and its substrate Trx. The two proteins constitute an important thiol-dependent redox system that catalyzes the reduction of many proteins that are responsible for a variety of cellular functions. The system relies on transient protein-protein interactions between Trx and TrxR for its function. Cross-reactivity of components of the Trx system between species has been shown to be medically relevant. For example, Helicobacter pylori Trx (HP Trx) is thought to mediate catalytic reduction of human immunoglobulins and thus facilitate immune evasion. It has also been proposed that Helicobacter pylori gains access to the impenetrable gastric mucous layer by using secreted HP Trx to reduce the disulfide bonds present in the cysteine-rich mucin regions that are responsible for cross-linking mucin monomers. Therefore, disruption of secreted HP Trx-host protein interaction may result in restoration of the viscoelastic and hydrophobic protective properties of mucus. Previous studies aimed at understanding the nature of cross-reactivity of Trx system components among various species have shown that Trxs have higher affinity for cognate TrxRs (same species), than for TrxRs from different species. However, the basis for this specificity is not known. A growing body of evidence suggests that most protein-protein interactions are mediated by a small number of protein-protein interface residues, referred to as hot spot residues or binding epitopes. Therefore, understanding the biochemical basis of the affinity of proteins for their partners usually begins by identifying the hot spot residues responsible for the protein complex interactions. In this study, the crystal structures of Deinococcus radiodurans thioredoxin reductase (DR TrxR) and Helicobacter pylori TrxR (HP TrxR) were determined at 1.9 Å and 2.4 Å respectively. Analysis of the Trx-binding sites of both structures suggests that the basis of affinity and specificity of Trx for TrxR is primarily due to the shape rather than the charge of the surface. In addition, the complex between Escherichia coli thioredoxin reductase (EC TrxR) and its substrate thioredoxin (EC Trx) was used to identify residues that are responsible for TrxR-Trx interface stability. Using computational alanine scanning mutagenesis and visual inspection of the EC TrxR-Trx interface, 22 EC TrxR side chains were shown to make contact across the TrxR-Trx interface. Although more than 20 EC TrxR side chains make contact across the TrxR-Trx interface, our results suggest that only 4 residues (F81, R130, F141, and F142) account for the majority of the EC TrxR-Trx interface stability. Individual replacement of equivalent DR TrxR residues (M84, K137, F148, F149) with alanine resulted in drastic changes in binding affinity, confirming that the four residues account for most of TrxR-Trx interface stability. These hot spot residues are surrounded by less important residues (hydrophobic and hydrophilic) that are also predicted to contribute to interface stability. F148 and F149 are invariant across bacterial TrxRs, however other residues that contact Trx are less conserved including M84 and K137. When M84 and K137 were changed to match equivalent E. coli TrxR residues (K137R, M84F); D. radiodurans TrxR substrate specificity was altered from its own Trx to that of E. coli Trx. The results suggest that a small subset of the TrxR-Trx interface residues are responsible for the majority of Trx binding affinity and specificity, a property that has been shown to general to protein-protein interfaces.

fluorescence spectroscopy

Deinococcus radiodurans

Helicobacter pylori

enzyme kinetics

site-directed mutagenesis

thioredoxin system

x-ray crystallography

Protein-protein interactions

Identification of bacterial pathogenic gene classes subject to diversifying selection

Sumir Panji

January 2009

<p>Availability of genome sequences for numerous bacterial species comprising of different bacterial strains allows elucidation of species and strain specific adaptations that facilitate their survival in widely fluctuating micro-environments and enhance their pathogenic potential. Different bacterial species use different strategies in their pathogenesis and the pathogenic potential of a bacterial species is dependent on its genomic complement of virulence factors. A bacterial virulence factor, within the context of this study, is defined as any endogenous protein product encoded by a gene that aids in the adhesion, invasion, colonization, persistence and pathogenesis of a bacterium within a host. Anecdotal evidence suggests that bacterial virulence genes are undergoing diversifying evolution to counteract the rapid adaptability of its host&rsquo / s immune defences. Genome sequences of pathogenic bacterial species and strains provide unique opportunities to study the action of diversifying selection operating on different classes of bacterial genes.</p>

Helicobacter pylori

Neisseria meningitidis

Vibrio Cholerae

Positive Selection

Virulence Gene

Nucleotide Diversity

Statistical Enrichment

Functional Annotation

Biological Processes

Metabolic Pathways.