Crystal structure of the zinc-, cobalt-, and iron-containing adenylate kinase from Desulfovibrio gigas: a novel metal-containing adenylate kinase from Gram-negative bacteria

J Biol Inorg Chem (2011) 16:51–61 DOI 10.1007/s00775-010-0700-8

Estudo da expressão génica da Legionella pneumophila estirpe paris após co-cultura em Acanthamoeba castellanii

RESUMO: A Legionella é um bacilo Gram-negativo que replica dentro de protozoários como Acanthamoeba castellanii (A. castellanii) e no interior de macrófagos alveolares humanos, podendo resultar numa pneumonia grave. A Legionella em meio líquido tem um ciclo de vida bifásico, apresentando traços replicativos na fase exponencial e expressando factores transmissíveis na fase estacionária. Estudos recentes demonstraram que a Legionella precisa de assegurar um tempo preciso no seu ciclo de vida para efectuar com êxito a infecção das células hospedeiras. Muitos modelos de estudo foram desenvolvidos a fim de aumentar o conhecimento sobre o ciclo de vida intracelular e identificar os genes necessários para a modulação da célula hospedeira. Embora o conhecimento sobre a interacção bactéria-hospedeiro ainda seja limitado, parece que esta interacção gera um conjunto de características de virulência permitindo que a bactéria infecte células fagocíticas humanas e cause doença. O objectivo do presente projecto de investigação foi investigar e seleccionar genes críticos para a infecciosidade da Legionella pneumophila estirpe Paris (Lp Paris), desenhar e optimizar uma técnica de PCR em tempo real para o estudo da expressão génica e comparar o perfil de expressão da Lp Paris antes e depois da co-cultura em A. castellanii. Os resultados mostraram que oito dos 12 genes em estudo alteraram a sua expressão relativa após co-cultura em A. castellanii quando os ensaios foram realizados com culturas de Lp Paris na fase estacionária precoce (cinco foram induzidos e três reprimidos) Quando os ensaios foram realizados com culturas de Lp Paris na fase estacionária tardia 11 genes apresentaram repressão na sua expressão relativa. Analisando os resultados, concluímos que o perfil de expressão de Lp Paris foi modificado pela interacção com A. castellanii, no entanto essa mudança foi dependente da fase do seu ciclo de vida.-------ABSTRACT: Legionella is a pathogenic Gram-negative bacterium that replicates not only within aquatic protozoa like Acanthamoeba castellanii (A. castellanii), but also within human alveolar macrophages, which can result in a severe pneumonia. Legionella has a biphasic life cycle in broth, where exponential phase cultures display replicative traits and stationary bacteria express transmissive factors. Recent studies demonstrated that for successful infection of host cells, Legionella needs to ensure a precise timing of its life cycle. Many models of study were developed in order to learn about the intracellular life cycle and to identify the genes necessary for the host cell modulation. Although knowledge about the bacteria-host interaction is still limited, it appears that this interaction generate a pool of virulence traits, allowing the bacterium to infect human phagocytic cells and cause disease. The purpose of the present study was to investigate and select de critical genes for the infectivity of Legionella pneumophila strain Paris (Lp Paris), design and optimize a real time PCR technique for gene expression study and compare the expression profile of Lp Paris before and after co- culture of A. castellanii. The results show that eight of 12 genes in study changed its relative expression after coculture in A. castellanii when we performed the intracellular assays with early stationary phase Lp Paris cultures (five were induced and tree were repressed). When we performed the intracellular assays with late stationary phase Lp Paris cultures 11 genes showed a repressed relative expression. Analysing the results, we conclude that the expression profile of Lp Paris was modified by interaction with A. castellanii but this change was dependent of the timing of its life cycle.

Exopolysaccharide production by Enterobacter A47: optimization of cultivation conditions and study of polymer functional properties

Dissertação para obtenção do Grau de Mestre em Biotecnologia

Exploring the relationship between toxin and spore production in the human enteric pathogen Clostridium difficile

RESUMO: Clostridium difficile é presentemente a principal causa de doença gastrointestinal associada à utilização de antibióticos em adultos. C. difficile é uma bactéria Gram-positiva, obrigatoriamente anaeróbica, capaz de formar endósporos. Tem-se verificado um aumento dos casos de doença associada a C. difficile com sintomas mais severos, elevadas taxas de morbilidade, mortalidade e recorrência, em parte, devido à emergência de estirpes mais virulentas, mas também devido à má gestão do uso de antibióticos. C. difficile produz duas toxinas, TcdA e TcdB, que são os principais fatores de virulência e responsáveis pelos sintomas da doença. Estas são codificadas a partir do Locus de Patogenicidade (PaLoc) que codifica ainda para um regulador positivo, TcdR, uma holina, TcdE, e um regulador negativo, TcdC. Os esporos resistentes ao oxigénio são essenciais para a transmissão do organismo e recorrência da doença. A expressão dos genes do PaLoc ocorre em células vegetativas, no final da fase de crescimento exponencial, e em células em esporulação. Neste trabalho construímos dois mutantes de eliminação em fase dos genes tcdR e tcdE. Mostrámos que a auto-regulação do gene tcdR não é significativa. No entanto, tcdR é sempre necessário para a expressão dos genes presentes no PaLoc. Trabalho anterior mostrou que, com a exceção de tcdC, os demais genes do PaLoc são expressos no pré-esporo. Mostrámos aqui que TcdA é detectada à superfície do esporo maduro e que a eliminação do tcdE não influencia a acumulação de TcdA no meio de cultura ou em associação às células ou ao esporo. Estas observações têm consequências para o nosso entendimento do processo infecioso: sugeremque o esporo possa ser também um veículo para a entrega da toxina nos estágios iniciais da infecção, que TcdA possa ser libertada durante a germinação do esporo, e que o esporo possa utilizar o mesmo receptor reconhecido por TcdA para a ligação à mucosa do cólon.---------------------------ABSTRACT: Clostridium difficile is currently the major cause of antibiotic-associated gastrointestinal diseases in adults. This is a Gram-positive bacterium, endospore-forming and an obligate anaerobe that colonizes the gastrointestinal tract. Recent years have seen a rise in C. difficile associated disease (CDAD) cases, associated with more severe disease symptoms, higher rates of morbidity, mortality and recurrence, which were mostly caused due to the emergence of “hypervirulent” strains but also due to changing patterns of antibiotics use. C. difficile produces two potent toxins, TcdA and TcdB, which are the main virulence factors and the responsible for the disease symptoms. These are codified from a Pathogenicity Locus (PaLoc), composed also by the positive regulator, TcdR, the holin-like protein, TcdE, and a negative regulator, TcdC. Besides the toxins, the oxygen-resistant spores are also essential for transmission of the organism through diarrhea; moreover, spores can accumulate in the environment or in the host, which will cause disease recurrence. The expression of the PaLoc genes occurs in vegetative cells, at the end of the exponential growth phase, and in sporulating cells. In this work, we constructed two in-frame deletion mutants of tcdR and tcdE. We showed that the positive auto regulation of tcdR is not significant. However, tcdR is always necessary for the expression of the PaLoc genes. A previous work showed that, except tcdC, all the PaLoc genes are expressed in the forespore. Here, we detected TcdA at the spore surface. Furthermore, we showed that the in-frame deletion of tcdE does not affect the accumulation of TcdA in the culture medium or in association with cells or spores. This data was important for us to conclude about the infeccious process: it suggests that the spore may be the vehicle for the delivery of TcdA in early stages of infection, that TcdA may be released during spores germination and that this spore may use the same receptor recognized by TcdA to bind to the colonic mucosa.

Structural stability of adenylate kinase from the sulfate-reducing bacteria Desulfovibrio gigas

Biophysical Chemistry 110 (2004) 83–92

Massive shift in the pneumococcal nasopharyngeal flora after the 7-valent conjugate vaccine: epidemiological studies and testing pathogenic potential in animal models

Dissertation presented to obtain the PhD degree in Biology/Molecular Biology by Universidade Nova de Lisboa, Instituto de Tecnologia Química e Biológica

Bacterial inter-species communication mediated by the autoinducer-2 signal

Dissertation presented to obtain the Ph.D degree in Biology by Universidade Nova de Lisboa, Instituto de Tecnologia Química e Biológica, Instituto Gulbenkian de Ciência.

Structural investigation of the Bacillus subtilis morphogenic factor RodZ

A thesis to obtain a Master degree in Structural and Functional Biochemistry

Studies of the assembly of the Streptococcus pneumoniae capsular polysaccharide

Dissertation presented to obtain the Ph.D degree in Biology.

Dissecting the function of the SpoIIIJ and YqjG membrane protein insertases during bacterial spore development

Dissertation presented to obtain the Ph.D degree in Biology, Microbial Biology

Green synthesis of 2-Oxazoline-based polymers with antimicrobial activity using scCO2

Using a green methodology, 17 different poly(2-oxazolines) were synthesized starting from four different oxazoline monomers. The polymerization reactions were conducted in supercritical carbon dioxide under a cationic ring-opening polymerization (CROP) mechanism using boron trifluoride diethyl etherate as the catalyst. The obtained living polymers were then end-capped with different types of amines, in order to confer them antimicrobial activity. For comparison, four polyoxazolines were end-capped with water, and by their hydrolysis the linear poly(ethyleneimine) (LPEI) was also produced. After functionalization the obtained polymers were isolated, purified and characterized by standard techniques (FT-IR, NMR, MALDI-TOF and GPC). The synthesized poly(2-oxazolines) revealed an unusual intrinsic blue photoluminescence. High concentration of carbonyl groups in the polymer backbone is appointed as a key structural factor for the presence of fluorescence and enlarges polyoxazolines’ potential applications. Microbiological assays were also performed in order to evaluate their antimicrobial profile against gram-positive Staphylococcus aureus NCTC8325-4 and gram-negative Escherichia coli AB1157 strains, two well known and difficult to control pathogens. The minimum inhibitory concentrations (MIC)s and killing rates of three synthesized polymers against both strains were determined. The end-capping with N,N-dimethyldodecylamine of living poly(2- methyl-2-oxazoline) and poly(bisoxazoline) led to materials with higher MIC values but fast killing rates (less than 5 minutes to achieve 100% killing for both bacterial species) than LPEI, a polymer which had a lower MIC value, but took a longer time to kill both E.coli and S.aureus cells. LPEI achieved 100% killing after 45 minutes in contact with E. coli and after 4 hours in contact with S.aureus. Such huge differences in the biocidal behavior of the different polymers can possibly underlie different mechanisms of action. In the future, studies to elucidate the obtained data will be performed to better understand the killing mechanisms of the polymers through the use of microbial cell biology techniques.

Manipulation of host cell functions by Salmonella: the role of the bacterial effector protein SteA

Salmonella enterica serovars are Gram-negative facultative intracellular bacterial pathogens that infect a wide variety of animals. Salmonella infections are common in humans, causing usually typhoid fever and gastrointestinal diseases. Salmonella enterica serovar Typhimurium (S. Typhimurium), which is a leading cause of human gastroenteritis, has been extensively used to study the molecular pathogenesis of Salmonella, because of the availability of sophisticated genetic tools, and of suitable animal and tissue culture models mimicking different aspects of Salmonella infections.(...)