Regulação da adesão de Escherichia coli enteropatogênica (EPEC) por genes de resposta à limitação nutricional e estresse. / Regulation of enteropathogenic Escherichia coli (EPEC) adhesion by genes related to nutrional shortage and stress.

Ferreira, Gerson Moura

24 August 2009

Escherichia coli enteropatogênica (EPEC) é uma das principais causas de diarreia em crianças. Na carência de fosfato (Pi), um conjunto de genes conhecido como regulon PHO é induzido. Esse regulon é controlado pelo sistema Pst, que além de ser um transportador de Pi, reprime a expressão de PHO quando Pi é abundante, e pelo sistema de dois componentes PhoB/PhoR. A deleção de pst reduziu a adesão de EPEC à células epiteliais in vitro, pois diminuiu da expressão dos reguladores PerA/PerC, que por sua vez controlam a expressão de genes envolvidos na adesão. Este efeito foi exclusivo de pst e não devido a expressão constitutiva dos genes de PHO causada pela deleção de pst. A expressão da fímbria BFP, PerA e PerC também dependem da síntese de ppGpp, uma molécula de alarme envolvida na regulação de genes relacionados à carência nutricional. ppGpp regula positivamente a expressão de PerA e PerC. Entretanto, RpoS, o fator relacionado à resposta ao estresse, afetou negativamente o nível de adesão de EPEC e a expressão de BFP. / Enteropathogenic E. coli (EPEC) is one of the causes of diarrhea in children. Phosphate (Pi) shortage induces transcription of the genes known as the PHO regulon. These genes are controlled by the Pst system, that is also a high-affinity Pi transporter, and represses PHO expression under Pi-replete conditions. PHO is also controlled by the two-component system PhoB/PhoR. Deletion of the pst operon reduced the adhesion of EPEC to epithelial cells in vitro due to a decrease in the expression of the regulators PerA and PerC that in turn control the expression of genes related to adhesion. The constitutive expression of the PHO genes in the pst mutant was not the cause of adhesion inhibition. Expression of bfp and the regulators PerA and PerC was also dependent on ppGpp, an alarmone involved in the regulation of genes related to nutrient limitation. On the other hand, RpoS, the factor that controls the general stress response, negatively affected EPEC adhesion and bfpA expression.

Escherichia coli (pathogenicity)

Escherichia coli (patogenicidade)

Adesão

Adhesion

Bacterial genetics

Estresse

Gene regulation

Genética bacteriana

Genética microbiana

Host-parasite (Microbiology)

Microbial genetics

Microbiologia

Microbiology

Operon pst

ppGpp

ppGpp

pst operon

Regulação gênica

RpoS

RpoS

Stress

Ações das Hsp65r nativa e sua mutante K409A de Mycobacterium leprae durante o processo de envelhecimento. / The influence of Mycobacterium leprae rHsp65 wild type and its mutant K409A during the ageing process.

Estevam José Baldon

05 August 2010

As Hsp60 acham-se conservadas em todos os organismos, participando da estruturação de proteínas e em processos crônico-degenerativos. Foi avaliada a ação das Hsp65r WT e sua mutante K409A de M. leprae no envelhecimento. Análises do Tempo Médio de Sobrevida (TMS), titulação dos isótipos, ensaios de avidez e análises histopatológicas foram realizadas em camundongos das linhagens HIII e LIII inoculados intraperitonealmente aos 120 ou 270 dias de vida com 2.5µg/mL das Hsp65r. Verificou-se redução no TMS de fêmeas HIII, envelhecidas e adultas, inoculadas com WT. A inoculação da Hsp65r WT em fêmeas LIII envelhecidas resultou no aumento do TMS. A dosagem dos anticorpos não revelou alterações marcantes na produção dos isótipos, e a avidez de IgG foi menor nas fêmeas HIII envelhecidas inoculadas com WT. A análise histopatológica mostrou inflamação nos rins de fêmeas HIII velhas tratadas com Hsp65r WT. Os resultados indicaram a interferência da Hsp65r WT na imunidade durante o processo de senescência de fêmeas envelhecidas constitutivamente boas produtoras de anticorpos. / The Hsp60 are conserved in all organisms, involved in proteins folding and chronic-degenerative processes. We evaluated the action of M. leprae rHsp65 WT and its mutant K409A in aging. Analyses of mean survival time (MST), antibody titration, avidity assays and histopathological examinations were performed in mice from HIII and LIII lines intraperitoneally inoculated at 120 or 270 days of life with 2.5µg/mL of rHsp65. There was a decrease in MST in adult and aged HIII females mice inoculated with WT protein. WT rHsp65 treatment in aged LIII females resulted in the increase of MST. The antibodies titration showed no marked changes in the production of isotypes and IgG avidity was lower in aged HIII females inoculated with WT. Histopathology showed inflammation in the kidneys of old HIII females treated with WT rHsp65. The results indicated the interference of WT rHsp65 in immunity during the senescence of aged females from HIII line constitutively producing good antibodies.

Mycobacterium leprae

Anticorpos

Genética bacteriana

Hsp65r nativa e mutante K409A

Mimetismo molecular

Mutação genética

Processo de envelhecimento

Mycobacterium leprae

Ageing process

Antibody

Bacterial genetics

Genetic mutation

Molecular mimicry

Wild type rHsp65 and its mutant K409A

Regulação da adesão de Escherichia coli enteropatogênica (EPEC) por genes de resposta à limitação nutricional e estresse. / Regulation of enteropathogenic Escherichia coli (EPEC) adhesion by genes related to nutrional shortage and stress.

Gerson Moura Ferreira

24 August 2009

Escherichia coli enteropatogênica (EPEC) é uma das principais causas de diarreia em crianças. Na carência de fosfato (Pi), um conjunto de genes conhecido como regulon PHO é induzido. Esse regulon é controlado pelo sistema Pst, que além de ser um transportador de Pi, reprime a expressão de PHO quando Pi é abundante, e pelo sistema de dois componentes PhoB/PhoR. A deleção de pst reduziu a adesão de EPEC à células epiteliais in vitro, pois diminuiu da expressão dos reguladores PerA/PerC, que por sua vez controlam a expressão de genes envolvidos na adesão. Este efeito foi exclusivo de pst e não devido a expressão constitutiva dos genes de PHO causada pela deleção de pst. A expressão da fímbria BFP, PerA e PerC também dependem da síntese de ppGpp, uma molécula de alarme envolvida na regulação de genes relacionados à carência nutricional. ppGpp regula positivamente a expressão de PerA e PerC. Entretanto, RpoS, o fator relacionado à resposta ao estresse, afetou negativamente o nível de adesão de EPEC e a expressão de BFP. / Enteropathogenic E. coli (EPEC) is one of the causes of diarrhea in children. Phosphate (Pi) shortage induces transcription of the genes known as the PHO regulon. These genes are controlled by the Pst system, that is also a high-affinity Pi transporter, and represses PHO expression under Pi-replete conditions. PHO is also controlled by the two-component system PhoB/PhoR. Deletion of the pst operon reduced the adhesion of EPEC to epithelial cells in vitro due to a decrease in the expression of the regulators PerA and PerC that in turn control the expression of genes related to adhesion. The constitutive expression of the PHO genes in the pst mutant was not the cause of adhesion inhibition. Expression of bfp and the regulators PerA and PerC was also dependent on ppGpp, an alarmone involved in the regulation of genes related to nutrient limitation. On the other hand, RpoS, the factor that controls the general stress response, negatively affected EPEC adhesion and bfpA expression.

Escherichia coli (patogenicidade)

Adesão

Estresse

Genética bacteriana

Genética microbiana

Microbiologia

Operon pst

ppGpp

Regulação gênica

RpoS

Escherichia coli (pathogenicity)

Adhesion

Bacterial genetics

Gene regulation

Host-parasite (Microbiology)

Microbial genetics

Microbiology

ppGpp

pst operon

RpoS

Stress

Etude bioinformatique de l'évolution de la régulation transcriptionnelle chez les bactéries / Bioinformatic study of the evolution of the transcriptional regulation in bacteria

Janky, Rekin's

17 December 2007

L'objet de cette thèse de bioinformatique est de mieux comprendre l’ensemble des systèmes de régulation génique chez les bactéries. La disponibilité de centaines de génomes complets chez les bactéries ouvre la voie aux approches de génomique comparative et donc à l’étude de l’évolution des réseaux transcriptionnels bactériens. Dans un premier temps, nous avons implémenté et validé plusieurs méthodes de prédiction d’opérons sur base des génomes bactériens séquencés. Suite à cette étude, nous avons décidé d’utiliser un algorithme qui se base simplement sur un seuil sur la distance intergénique, à savoir la distance en paires de bases entre deux gènes adjacents. Notre évaluation sur base d’opérons annotés chez Escherichia coli et Bacillus subtilis nous permet de définir un seuil optimal de 55pb pour lequel nous obtenons respectivement 78 et 79% de précision. Deuxièmement, l’identification des motifs de régulation transcriptionnelle, tels les sites de liaison des facteurs de transcription, donne des indications de l’organisation de la régulation. Nous avons développé une méthode de recherche d’empreintes phylogénétiques qui consiste à découvrir des paires de mots espacés (dyades) statistiquement sur-représentées en amont de gènes orthologues bactériens. Notre méthode est particulièrement adaptée à la recherche de motifs chez les bactéries puisqu’elle profite d’une part des centaines de génomes bactériens séquencés et d’autre part les facteurs de transcription bactériens présentent des domaines Hélice-Tour-Hélice qui reconnaissent spécifiquement des dyades. Une évaluation systématique sur 368 gènes de E.coli a permis d’évaluer les performances de notre méthode et de tester l’influence de plus de 40 combinaisons de paramètres concernant le niveau taxonomique, l’inférence d’opérons, le filtrage des dyades spécifiques de E.coli, le choix des modèles de fond pour le calcul du score de significativité, et enfin un seuil sur ce score. L’analyse détaillée pour un cas d’étude, l’autorégulation du facteur de transcription LexA, a montré que notre approche permet d’étudier l’évolution des sites d’auto-régulation dans plusieurs branches taxonomiques des bactéries. Nous avons ensuite appliqué la détection d’empreintes phylogénétiques à chaque gène de E.coli, et utilisé les motifs détectés comme significatifs afin de prédire les gènes co-régulés. Au centre de cette dernière stratégie, est définie une matrice de scores de significativité pour chaque mot détecté par gène chez l’organisme de référence. Plusieurs métriques ont été définies pour la comparaison de paires de profils de scores de sorte que des paires de gènes ayant des motifs détectés significativement en commun peuvent être regroupées. Ainsi, l’ensemble des nos méthodes nous permet de reconstruire des réseaux de co-régulation uniquement à partir de séquences génomiques, et nous ouvre la voie à l’étude de l’organisation et de l’évolution de la régulation transcriptionnelle pour des génomes dont on ne connaît rien.<p><p>The purpose of my thesis is to study the evolution of regulation within bacterial genomes by using a cross-genomic comparative approach. Nowadays, numerous genomes have been sequenced facilitating in silico analysis in order to detect groups of functionally related genes and to predict the mechanism of their relative regulation. In this project, we combined prediction of operons and regulons in order to reconstruct the transcriptional regulatory network for a bacterial genome. We have implemented three methods in order to predict operons from a bacterial genome and evaluated them on hundreds of annotated operons of Escherichia coli and Bacillus subtilis. It turns out that a simple distance-based threshold method gives good results with about 80% of accuracy. The principle of this method is to classify pairs of adjacent genes as “within operon” or “transcription unit border”, respectively, by using a threshold on their intergenic distance: two adjacent genes are predicted to be within an operon if their intergenic distance is smaller than 55bp. In the second part of my thesis, I evaluated the performances of a phylogenetic footprinting approach based on the detection of over-represented spaced motifs. This method is particularly suitable for (but not restricted to) Bacteria, since such motifs are typically bound by factors containing a Helix-Turn-Helix domain. We evaluated footprint discovery in 368 E.coli K12 genes with annotated sites, under 40 different combinations of parameters (taxonomical level, background model, organism-specific filtering, operon inference, significance threshold). Motifs are assessed both at the level of correctness and significance. The footprint discovery method proposed here shows excellent results with E. coli and can readily be extended to predict cis-acting regulatory signals and propose testable hypotheses in bacterial genomes for which nothing is known about regulation. Moreover, the predictive power of the strategy, and its capability to track the evolutionary divergence of cis-regulatory motifs was illustrated with the example of LexA auto-regulation, for which our predictions are remarkably consistent with the binding sites characterized in different taxonomical groups. A next challenge was to identify groups of co-regulated genes (regulons), by regrouping genes with similar motifs, in order to address the challenging domain of the evolution of transcriptional regulatory networks. We tested different metrics to detect putative pairs of co-regulated genes. The comparison between predicted and annotated co-regulation networks shows a high positive predictive value, since a good fraction of the predicted associations correspond to annotated co-regulations, and a low sensitivity, which may be due to the consequence of highly connected transcription factors (global regulator). A regulon-per-regulon analysis indeed shows that the sensitivity is very weak for these transcription factors, but can be quite good for specific transcription factors. The originality of this global strategy is to be able to infer a potential network from the sole analysis of genome sequences, and without any prior knowledge about the regulation in the considered organism. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished

Sciences exactes et naturelles

Biologie

Structural bioinformatics

Bacterial genetics

Microbial metabolism -- Regulation

Microbial genomics

Bio-informatique structurale

Génétique bactérienne

Génomique microbienne

dyad-analysis

Evaluation

coregulation network

lexA

operon prediction

pattern-discovery

Bacteria

Phylogenetic footprinting

RSAT

Studies on the Evolution of Aromatic Beta-Glucoside Catabolic Systems under Different Stress Conditions in Escherichia coli

Zangoui Nejad Chahkootahi, Parisa

January 2014

The genetic systems involved in the utilisation of aromatic β-glucosides in E. coli consist of the bgl, asc, and chb operons and the locus bglA encoding phospho-β-glucosidase A. The bgl and asc operons are known as cryptic or silent systems since their expression is not sufficient for utilisation of these sugars in wild type strains of E. coli. Their transcriptional activation by different classes of mutations confers a Bgl+ phenotype to the mutant. The maintenance of cryptic genes without accumulating deleterious mutation in spite of being silent is an evolutionary puzzle. Several observations have suggested the possibility that these genes may be expressed under specific physiological conditions conferring a fitness advantage to the organism. The main aim of this study was to investigate the possible role of aromatic β-glucoside catabolic systems of E. coli in combating nutrient stress and microaerobic growth conditions. The results presented in Chapter 2 address the evolution of aromatic β-glucoside catabolic systems when exposed to a novel β-glucoside as the sole substrate. The results indicate that the bgl opeon, the primary system involved in the utilisation of the aromatic β-glucosides arbutin and salicin, is also involved in esculin utilisation. In the absence of bglB encoding the enzyme phospho-β-glucosidase B, activation of the silent asc operon enables esculin utilisation. The bglA gene encoding phospho-β-glucosidase A specific for arbutin, can undergo successive mutations to evolve the ability to hydrolyse esculin and salicin sequentially when bglB and ascB are absent. The Esc+ and Sal+ mutants retain their arbutin+ phenotype, indicating that the mutations enhance the promiscuity of the enzyme. Sequencing data indicate that the first step Esc+ mutant carries a four base insertion within the promoter of the bglA gene that results in enhanced transcription of bglA. RT-PCR studies confirm that both the steady-state levels as well as the half-life of the bglA mRNA are enhanced in the mutant. This is further corroborated by the observation that overexpression of wild type bglA in the parent strain using a multicopy plasmid confers an Esc+ phenotype. The second step Sal+ mutant carries a point mutation within bglA ORF, a thymine to guanine transversion at position 583 (T583G) of the bglA gene, resulting in an amino acid change from cysteine to glycine at position 195 (C195G) of the BglA ORF close to the active site. Presence of a plasmid carrying the T583G mutation, introduced by site-directed mutagenesis, results in a Sal+ phenotype, confirming the role of the transversion in conferring the Sal+ phenotype. Based on docking studies, the positioning of salicin into the substrate binding site of the mutant BglA enzyme is different compared to wild type BglA due to the loss of stearic hindrance for the binding of salicin when C195 is replaced by the smaller amino acid glycine in the mutant protein. These observations indicate that under conditions of nutrient deprivation, exposure to novel substrates can result in the evolution of new metabolic capabilities by the sequential modification of a pre-existing genetic system. In the case of one novel substrate, the mutation results in the overexpression of the hydrolytic enzyme, while in the case of the second substrate, a mutation close to its active site increases its substrate specificity. Results presented in Chapter 3 specifically deal with the involvement of the bgl operon under low levels of oxygen. Earlier observations have shown that there is a 22 fold enhancement in the expression of the bgl operon under anaerobic condition. The present results provide evidence that bgl expression has a physiological role under low levels of oxygen and in addition suggest a possible mechanism for the overexpression of the bgl operon that involves the ArcAB two component system known to mediate regulation under microaerobic and static conditions. Transcription studies using a lacZ reporter fused to the wild type bgl promoter show that there is enhanced transcription from the bgl promoter under microaerobic and static conditions in the presence of arcA encoding the response regulator compared to that in its absence. The positive effect of arcA on the expression of the bgl operon is dispensable in the absence of H-NS since presence or absence of arcA does not change the expression of the bgl operon in an hns-null background, implying that the involvement of ArcA is via antagonizing H-NS. Competition experiments indicate that there is growth advantage associated with the activated allele of the bgl operon under low levels of oxygen since Bgl+ strains carrying the activated allele of the bgl operon as well as strains expressing BglG constitutively can out-compete wild-type strains. Presence of the wild type arcA allele results in a strong growth advantage compared to its absence under static conditions but not aerobic condition. The bgl operon seems to be one of the possible downstream targets of ArcA under static condition since absence of the bgl operon results in a modest reduction of the growth advantage (GASP) phenotype conferred by arcA. The up-regulation of the bgl operon is likely to enable the cells to scavenge available nutrients from their niche more efficiently. These experiments also show that the GASP phenotype associated with BglG constitutive strains under static conditions involves downstream genes that are different from oppA known to be one of the downstream targets during aerobic growth. It is possible that under low level of oxygen, the bgl operon is regulating a different set of downstream genes involving a different mechanism. In summary, the results of this investigation show that the aromatic β-glucoside catabolic systems in E. coli play a role in the generation of new metabolic capabilities via mutations in pre-existing genetic systems as well as through changes in gene expression patterns. The mechanisms outlined in this study are likely to be of broader significance applicable to microbial evolution under stress in general.

Microorganisms - Evolution

Beta-Glucosides

Escherichia Coli - Bgl Operons

Bacteria - Evolution

Bacterial Genetics

β-glucosides

bgl Operon

asc Operon

chb Operon

bglA Gene

ArcA

gcvA

Bacteriology

Expressão do fator estimulador de colônia de granulócito humano recombinante (rhG-CSF) em Escherichia coli. / Expression of recombinant human colony stimulating factor (rhG-CSF) in Escherichia coli.

Fernanda Resende Gomes

22 June 2010

O Fator estimulador de colônias de granulócitos humano recombinante (rhG-CSF) produzido em Escherichia coli é uma proteína não glicosilada com 175 aminoácidos, de grande importância clínica para o tratamento de neutropenias. O presente trabalho propõe a construção de dois sistemas de expressão em E. coli, um sistema para obtenção do rhG-CSF no citoplasma e outro para secreção da proteína recombinante no meio de cultura utilizando a sequência sinal da L-asparaginase II. Os dois sistemas de expressão foram testados e comparados. A partir desses dados, passou-se para as etapas de obtenção do rhG-CSF com o sistema de expressão sem a sequência sinal. As etapas de renaturação e purificação foram eficientes obtendo-se uma proteína com adequado grau de pureza, integridade estrutural e atividade biológica. Essa proteína também foi utilizada com sucesso para a produção de anticorpos policlonais em camundongos. Com os resultados obtidos, a proteína rhG-CSF mostrou-se viável para estudos posteriores em bioreatores e produção em escala-piloto. / The recombinant human granulocyte colony stimulating factor (rhG-CSF) is a non-glycosylated protein with 175 amino acids. This factor plays an important role in hematopoietic cell proliferation and has been widely used for treating neutropenia. The purpose of this work is to construct two expression systems in E. coli; a system for obtaining rhG-CSF in the cytoplasm and the other for secretion of recombinant protein in the culture medium using the signal sequence of L-asparaginase II. The two expression systems were tested and compared. From these data, the next steps for obtaining the rhG-CSF were done with the expression system without the signal sequence. The refolding and purification steps were efficient, resulting in a protein with adequate purity, structural integrity and biological activity. This protein has also been successfully used for the production of polyclonal antibodies in mice. With these results, the protein rhG-CSF was feasible for further studies in bioreactors and pilot scale production.

Escherichia coli

Corpos de Inclusão

Expressão heteróloga

Fatores biológicos

Genética bacteriana

Granulócitos (Humano)

Granulócitos citoplasmáticos

rhG-CSF

Escherichia coli

Bacterial genetics

Biological factors

Granulocytes (Human)

Granulocytes cytoplasmic

Heterolog expression

Inclusion body

rhG-CSF

Genomic Island Discovery through Enrichment of Statistical Modeling with Biological Information

Jani, Mehul

08 1900

Horizontal gene transfer enables acquisition and dissemination of novel traits including antibiotic resistance and virulence among bacteria. Frequently such traits are gained through the acquisition of clusters of functionally related genes, often referred to as genomic islands (GIs). Quantifying horizontal flow of GIs and assessing their contributions to the emergence and evolution of novel metabolic traits in bacterial organisms are central to understanding the evolution of bacteria in general and the evolution of pathogenicity and antibiotic resistance in particular, a focus of this dissertation study. Methods for GI detection have also evolved with advances in sequencing and bioinformatics, however, comprehensive assessment of these methods has been lacking. This motivated us to assess the performance of current methods for identifying islands on broad datasets of well-characterized bacterial genomes and synthetic genomes, and leverage this information to develop a novel approach that circumvents the limitations of the current state-of-the-art in GI detection. The main findings from our assessment studies were 1) the methods have complementary strengths, 2) a gene-clustering method utilizing codon usage bias as the discriminant criterion, namely, JS-CB, is most efficient in localizing genomic islands, specifically the well-studied SCCmec resistance island in methicillin resistant Staphylococcus aureus (MRSA) genomes, and 3) in general, the bottom up, gene by gene analysis methods, are inherently limited in their ability to decipher large structures such as GIs as single entities within bacterial genomes. We adapted a top-down approach based on recursive segmentation and agglomerative clustering and developed a GI prediction tool, GEMINI, which combined compositional features with segment context information to localize GIs in the Liverpool epidemic strain of Pseudomonas aeruginosa. Application of GEMINI to the genome of P. aeruginosa LESB58 demonstrated its ability to delineate experimentally verified GIs in the LESB58 genome. GEMINI identified several novel islands including pathogenicity islands and revealed the mosaic structure of several LESB58 harbored GIs. A new GI identification approach, CAFE, with broad applicability was developed. CAFE incorporates biological information encoded in a genome within the statistical framework of segmentation and clustering to more robustly localize GIs in the genome. CAFE identifies genomic islands lacking markers by virtue of their association with genomic islands with markers originating from the same source. This is made possible by performing marker enrichment and phyletic pattern analyses within the integrated framework of recursive segmentation and clustering. CAFE compared favorably with frequently used methods for genomic island detection on synthetic test datasets and on a test-set of known islands from 15 well-characterized bacterial species. These tools can be readily adapted for cataloging GIs in just sequenced, yet uncharacterized genomes.

Evolution

Genomic island

antibiotic resistance

pathogen

virulence

MRSA

Pseudomonas aeruginosa

Staphylococcus aureus

genome segmentation

clustering

Biology, Bioinformatics

Biology, Microbiology

Biology, General

Genetic transformation.

Bacterial genetics.

Pseudomonas aeruginosa.

Staphylococcus aureus.

Drug resistance in microorganisms.