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

Methylobacterium spp.: Emerging Opportunistic Premise Plumbing Pathogens

Szwetkowski, Kyle John

15 May 2017

Opportunistic premise plumbing pathogens (OPPPs) are responsible for many infections linked to drinking water. The annual cost of disease caused by these waterborne pathogens is $850 million. Key characteristics of these opportunistic waterborne pathogens include: disinfectant- resistant, biofilm formation, thermal-tolerance, desiccation-resistant, growth in amoebae and growth in low oxygen conditions. Methylobacterium spp. have been recognized as an emerging OPPP, so the purpose of this study was to investigate these waterborne bacteria in more detail to determine whether they have all characteristics of OPPPs. Seven Methylobacterium spp. strains were studied to measure growth in laboratory broth medium and drinking water, measure hydrophobicity on surfaces found in household plumbing, measure adherence and biofilm formation to surfaces found in household plumbing and measure susceptibility to hot water heater temperatures. Methylobacterium spp. were found to aggregate in lab broth medium and drinking water, hydrophobic on different surfaces in household plumbing, adhere readily and form biofilm on different surfaces and thermal-tolerant to water heater temperatures. These results support and identify Methylobacterium spp. as opportunistic premise plumbing pathogens. / Master of Science

Methylobacterium spp.

opportunistic premise plumbing pathogens

hydrophobicity

adherence

biofilm formation

thermal-tolerance

Étude sur le biofilm et les mécanismes de résistance à la bacitracine chez Clostridium perfringens

Charlebois, Audrey

01 1900

Clostridium perfringens est ubiquitaire dans l’environnement. Ce microorganisme peut être retrouvé dans la flore normale du tractus gastro-intestinal des mammifères et peut également causer une variété d’infections intestinales. Le phénotype de résistance à la bacitracine a déjà été rapporté chez C. perfringens mais les gènes associés n’ont pas été caractérisés. Dans cette étude, 24 des 99 isolats de C. perfringens aviaires testés ont démontré une résistance à la bacitracine. Les analyses ont révélé la présence d’un transporteur ABC ainsi que d’une undécaprénol kinase surproduite. Ces deux mécanismes semblent être codés par l’opéron bcrABDR. En amont et en aval des gènes bcr, un élément IS1216-like a été identifié, celui-ci pouvant jouer un rôle dans la dissémination de la résistance à la bacitracine. Des analyses d’hybridation sur ADN ont révélé que les gènes bcrABDR étaient localisés sur le chromosome. De plus, il a été démontré que les gènes bcr étaient exprimés en présence de bacitracine. Plusieurs études ont associé la tolérance aux antibiotiques et aux désinfectants à la formation de biofilm. Dans la littérature, peu d’informations sont disponibles sur le biofilm de C. perfringens. La majorité des isolats testés dans cette étude ont démontré la formation d’un biofilm. L’analyse de la matrice a démontré que celle-ci contenait des protéines, de l’ADN extracellulaire ainsi que des polysaccharides liés en bêta-1,4. Une meilleure survie des cellules en biofilm a été observée suite à une exposition à de fortes concentrations d’antibiotiques. Une exposition à de faibles doses de certains antibiotiques semblait diminuer le biofilm formé alors que pour d’autres, le biofilm semblait augmenter. Dans la présente étude, la susceptibilité des biofilms de C. perfringens à la désinfection a été également analysée. Les résultats ont démontré que la formation de biofilm protégeait les cellules de l’action du monopersulfate de potassium, des ammoniums quaternaires, du peroxyde d’hydrogène et du glutéraldéhyde. Toutefois, l’hypochlorite de sodium a été démontré comme étant efficace contre le biofilm de C. perfringens. Il a été démontré que les biofilms mixtes de C. perfringens cultivés en présence de Staphylococcus aureus ou d’Escherichia coli étaient plus résistants à la désinfection en comparaison aux biofilms simples de S. aureus ou d’E. coli. Toutefois, le biofilm simple de C. perfringens était plus résistant à la désinfection que les biofilms mixtes. Finalement, les profils de transcription entre les populations planctoniques et en biofilm ont été analysés par séquençage d’ARN. L’analyse transcriptomique du biofilm a identifié 238 gènes différentiellement exprimés entre les deux conditions. Les gènes négativement régulés sont impliqués dans la virulence, la production d’énergie, le métabolisme des sucres ainsi que dans la biosynthèse des acides gras et des acides aminés alors que les gènes induits sont impliqués dans la réponse au stress et au stress oxydatif, dans la biosynthèse d’acides gras et de phospholipides ainsi que dans la virulence. Cette étude décrit pour la première fois la découverte des gènes associés à la résistance à la bacitracine chez C. perfringens. Elle rapporte également de nouvelles données sur la matrice du biofilm, la tolérance aux antibiotiques et aux désinfectants ainsi que sur le transcriptome du biofilm de C. perfringens. / Clostridium perfringens is ubiquitous in the environment. This microorganism can be found in the intestinal tract of mammals as normal flora and can also cause many gastrointestinal infections. Phenotypic bacitracin resistance has been reported in the literature for C. perfringens but the genes responsible for this resistance have not yet been characterized. In this study, twenty-four of the 99 poultry isolates tested showed bacitracin resistance. Analysis revealed putative genes encoding for both an ABC transporter and an overproduced undecaprenol kinase. These two mechanisms were shown to be both encoded by the putative bcrABDR operon. An IS1216-like element was found upstream and downstream from the bcr cluster, which may play a role in the dissemination of this resistance determinant. DNA hybridization analyses revealed that the bacitracin resistance genes bcrABDR were located on the chromosome. Moreover, this gene cluster has been showed to be expressed under bacitracin stress. Many studies have associated tolerance to antibiotics and disinfectants to biofilm. In the literature, very little is known on the biofilm formation by C. perfringens. Most of the C. perfringens isolates tested in this study were able to form biofilms. Matrix composition analysis revealed the presence of proteins, extracellular DNA and beta-1,4 linked polysaccharides. Biofilm could also protect C. perfringens bacterial cells from an exposition to high concentrations of antibiotics. Exposition to low doses of antibiotics tended to lead to a diminution of the biofilm formed but for few isolates, the biofilm formation was increased. In the present study, susceptibilities of C. perfringens biofilms to disinfectants were also analysed. Results showed that biofilms can protect the bacterial cells from the action of potassium monopersulfate, quaternary ammonium chlorides, hydrogen peroxide and gluteraldehyde solutions. However, sodium hypochlorite solution was shown to be effective on C. perfringens biofilms. Our investigation of dual-species biofilms of C. perfringens with the addition of Staphylococcus aureus or Escherichia coli demonstrated that these dual-species biofilms were more tolerant to disinfection with sodium hypochlorite than the mono-species biofilms of S. aureus or E. coli. However, further disinfection studies using sodium hypochlorite suggest that the mono-species biofilms formed by C. perfringens is more tolerant to this disinfectant than the dual-species biofilms of C. perfringens with S. aureus or E. coli. Finally, the differential gene expression patterns between planktonic populations and biofilms of C. perfringens were investigated by RNA sequencing. The transcriptomic analysis identified 238 genes that were significantly differentially expressed between both conditions. Genes that were down-regulated in biofilm cells, relative to planktonic cells, included those involved in virulence, energy production, carbohydrate metabolism, fatty acids and amino acids biosynthesis. On the other hand, genes up-regulated in biofilm cells were involved in oxidative and stress responses, fatty acids and phospholipids biosynthesis and few genes were involved in virulence. This study reports on the discovery of genes associated to bacitracin resistance of C. perfringens. Our work brings also new data on matrix cohesion of the biofilm, tolerance to antibiotics and disinfectants, and on the transcriptome of the biofilm of C. perfringens.

Clostridium perfringens

Résistance à la bacitracine

Transcriptome

Formation de biofilm

Bacitracin resistance

Biofilm formation

Influência do tipo de substrato na dinâmica de formação do biofilme em matrizes de espuma de poliuretano / Influence of the substrate on the biofilm formation onto polyurethane foam matrices

Ribeiro, Rogers

23 March 2001

Este projeto estudou a influência do substrato na dinâmica do processo de formação do biofilme em espuma de poliuretano, em reatores anaeróbios horizontais de leito fixo diferenciais, alimentados com extrato de carne, glicose, amido, lipídeos e esgoto sanitário sintético. O estudo constitui em acompanhar a colonização das matrizes de espuma, ao longo do tempo, em relação a quantidade de biomassa aculumada, polímero extracelular produzido e características morfológicas das células presentes nos suportes retirados dos reatores diferenciais. O uso dessas técnicas permitiu o melhor entendimento do processo de aderência, além da verificação da composição morfológica e a estrutura do biofilme aderido ao suporte, possibilitando correlacionar a ocorrência de determinadas morfologias com cada etapa da colonização observada. A influência do substrato na dinâmica de aderência foi verificada devido aos diferentes padrões de colonização encontrados. Foi observada uma grande variabilidade morfológica em relação ao substrato utilizado. Todavia, uma grande ocorrência de organismos semelhantes a Methanosaeta sp foi verificada em todos os ciclos, principalmente em relação a Methanosarcina sp. O fenômeno de excreção de polímeros pareceu ser de fundamental importância no processo de colonização de matrizes de poliuretano, estando vinculado provavelmente à fixação das células aos suportes. A produção de polímeros, na etapa de aderência inicial, apresentou comportamento diferenciado para cada substrato utilizado. De acordo com os modelos propostos e as análises de microscopia eletrônica de varredura, verificou-se que os polímeros extracelulares podem estar ligados ao entupimento de reatores de leito fixo, permanecendo no interior dos suportes e nos interstícios do leito, causando problemas operacionais. As rápidas partidas observadas em trabalhos utilizando reatores de leito fixo e espuma de poliuretano como suporte podem estar vinculadas à rápida aderência dos organismos em todos os ciclos estudados. / This work focused on the influence of the type of substrate on the process of biofilm formation onto polyurethane foam matrices, in differential horizontal anaerobic immobilized sludge reactors, fed with meat extract (protein), glucose, starch, lipid and synthetic domestic wastewater. It consisted of accompanying the colonization of foam matrices with time, regarding to biomass amount, extracellular polymers produced and the morphological characteristics of the cells present on the supports packed in the differential reactors. These techniques permitted a better understanding of the adhesion process, besides a verification of the morphological composition and the structure of the biofilm attached to the support, making possible a correlation of the particular morphologies occurrences with each colonization step. The influence of the substrate was verified due to the different colonization patterns found. It was observed considerable morphological variety depending on the substrate utilized. However, the presence of Methanosaeta sp.- like organisms was often verified in all cycles, specially Methanosarcina sp. The excretion of polymers seemed to be crucial in the colonization process of the polyurethane matrices, being probably related to the cell fixation on the support. The polymeric production, in the inital adhesion step, showed a particular behavior for each substrate employed. According to the proposed models and the scanning electronic microscopy analysis, it was verified that the extracellular polymers can be related to the clogging of the fixed-bed reactors, as it keeps into the supports and the bed interstices, causing operational problems. The fast start-ups observed in works using fixed-bed reactors and polyurethane foam as support can be related to the fast cell adhesion during all cycles studied.

Anaerobic biofilm formation

Biomassa imobilizada

Espuma de poliuretano

Extracellular polymers

Formação de biofilme anaeróbio

Immobilized biomass

Polímeros extracelulares

Polyurethane foam

The aquatic microbial food web and occurence of predation-resistant and potentially pathogenic bacteria, such as Francisella tularensis

Thelaus, Johanna

January 2008

All natural aquatic systems harbour a vast variety of microorganisms. In the aquatic microbial food web, the larger microorganisms (i.e. protozoa) feed on the smaller microorganisms (i.e. bacteria and phytoplankton). An increase in nutrient availability results in changes of the microbial food web structure, like altered community composition and blooms of toxic phytoplankton. In this thesis work I hypothesised that nutrient-rich aquatic environments, with strong protozoan predation, favour the occurrence of predation-resistant bacteria like F. tularensis, and that the microbial food web may provide a reservoir for the bacterium between outbreaks. By using a size-structured ecosystem food web model it was shown that the protozoan predation pressure on bacteria, defined as protozoan predation per bacterial biomass, increases with increasing nutrient availability in aquatic systems (estimated chlorophyll a 0.2 to 112 μg L-1). This dynamics was caused by increasing growth-rate of a relatively constant number of bacterial cells, maintaining the growth of an increasing number of protozoan cells. The results were supported by meta-analysis of field studies. Thus my results suggest that protozoa control the bacterial community by predation in nutrient-rich environments. In a field study in a natural productivity gradient (chlorophyll a 1.4 to 31 μg L-1) it was shown that intense selection pressure from protozoan predators, favours predation-resistant forms of bacteria. Thus, the abundance of predation-resistant bacteria increases with increasing nutrient availability in lakes. Furthermore, I could demonstrate that the bacterium Francisella tularensis, the causative agent of tularemia, was present in eutrophic aquatic systems in an emerging tularemia area. Isolated strains of the bacterium were found to be resistant to protozoan predation. In a microcosm study, using natural lake water, high nutrient availability in combination with high abundance of a small colourless flagellate predator favoured the occurrence of F. tularensis holarctica. In laboratory experiments F. tularensis strains were able to form biofilm at temperatures between 30-37°C, but not below 30°C. In conclusion, I have shown that the protozoan predation pressure on bacteria increases with increasing nutrient availability in aquatic systems. Predation-resistant forms of bacteria, such as F. tularensis are favoured in nutrient-rich environments. The complexity of the microbial food web and nutrient-richness of the water, influence the transmission of the pathogenic F. tularensis holarctica. However, over long periods of time, the bacterium survives in lake water but may lose its virulence. The temperature-regulated biofilm formation by F. tularensis may play a role in colonization of vectors or for colonization of hosts, rather than for survival in aquatic environments.

bacteria

protozoa

ecology

predation

nutrient-availability

microbial food web

model

predation-resistance

Francisella

reservoir

biofilm formation

Freshwater ecology

Limnisk ekologi

Influência do tipo de substrato na dinâmica de formação do biofilme em matrizes de espuma de poliuretano / Influence of the substrate on the biofilm formation onto polyurethane foam matrices

Rogers Ribeiro

23 March 2001

Este projeto estudou a influência do substrato na dinâmica do processo de formação do biofilme em espuma de poliuretano, em reatores anaeróbios horizontais de leito fixo diferenciais, alimentados com extrato de carne, glicose, amido, lipídeos e esgoto sanitário sintético. O estudo constitui em acompanhar a colonização das matrizes de espuma, ao longo do tempo, em relação a quantidade de biomassa aculumada, polímero extracelular produzido e características morfológicas das células presentes nos suportes retirados dos reatores diferenciais. O uso dessas técnicas permitiu o melhor entendimento do processo de aderência, além da verificação da composição morfológica e a estrutura do biofilme aderido ao suporte, possibilitando correlacionar a ocorrência de determinadas morfologias com cada etapa da colonização observada. A influência do substrato na dinâmica de aderência foi verificada devido aos diferentes padrões de colonização encontrados. Foi observada uma grande variabilidade morfológica em relação ao substrato utilizado. Todavia, uma grande ocorrência de organismos semelhantes a Methanosaeta sp foi verificada em todos os ciclos, principalmente em relação a Methanosarcina sp. O fenômeno de excreção de polímeros pareceu ser de fundamental importância no processo de colonização de matrizes de poliuretano, estando vinculado provavelmente à fixação das células aos suportes. A produção de polímeros, na etapa de aderência inicial, apresentou comportamento diferenciado para cada substrato utilizado. De acordo com os modelos propostos e as análises de microscopia eletrônica de varredura, verificou-se que os polímeros extracelulares podem estar ligados ao entupimento de reatores de leito fixo, permanecendo no interior dos suportes e nos interstícios do leito, causando problemas operacionais. As rápidas partidas observadas em trabalhos utilizando reatores de leito fixo e espuma de poliuretano como suporte podem estar vinculadas à rápida aderência dos organismos em todos os ciclos estudados. / This work focused on the influence of the type of substrate on the process of biofilm formation onto polyurethane foam matrices, in differential horizontal anaerobic immobilized sludge reactors, fed with meat extract (protein), glucose, starch, lipid and synthetic domestic wastewater. It consisted of accompanying the colonization of foam matrices with time, regarding to biomass amount, extracellular polymers produced and the morphological characteristics of the cells present on the supports packed in the differential reactors. These techniques permitted a better understanding of the adhesion process, besides a verification of the morphological composition and the structure of the biofilm attached to the support, making possible a correlation of the particular morphologies occurrences with each colonization step. The influence of the substrate was verified due to the different colonization patterns found. It was observed considerable morphological variety depending on the substrate utilized. However, the presence of Methanosaeta sp.- like organisms was often verified in all cycles, specially Methanosarcina sp. The excretion of polymers seemed to be crucial in the colonization process of the polyurethane matrices, being probably related to the cell fixation on the support. The polymeric production, in the inital adhesion step, showed a particular behavior for each substrate employed. According to the proposed models and the scanning electronic microscopy analysis, it was verified that the extracellular polymers can be related to the clogging of the fixed-bed reactors, as it keeps into the supports and the bed interstices, causing operational problems. The fast start-ups observed in works using fixed-bed reactors and polyurethane foam as support can be related to the fast cell adhesion during all cycles studied.

Biomassa imobilizada

Espuma de poliuretano

Formação de biofilme anaeróbio

Polímeros extracelulares

Anaerobic biofilm formation

Extracellular polymers

Immobilized biomass

Polyurethane foam

Microalgal Adhesion to Model Substrates / A Quantitative in vivo Study on the Biological Mechanisms and Surface Forces

Kreis, Christian Titus

16 November 2017

No description available.

571.4

Bioadhesion

Biofilm formation

Chlamydomonas

Microalgae

Biotechnology

Flagellar functionality

Force spectroscopy

Micropipettes

Quantitative single cell adhesion study

Biologie (PPN619462639)

Implication des gènes curli dans un phénotype distinct d'autoagrégation et de formation de biofilm chez certaines souches Escherichia coli O157: H7

Rodriguez Olivera, Yaindrys

12 1900

Les bactéries pathogènes Escherichia coli entérohémorrhagiques (EHEC) O157:H7 causent des toxi-infections sévères chez l’humain. Les biofilms des EHEC rendent difficile leur contrôle dans les environnements favorisant leur persistance. Certaines souches O157:H7 dont celle de référence Sakai, possèdent une capacité accrue à s'autoagréger et former des biofilms. L’étude a visé à identifier les gènes impliqués dans l’autoagrégation et la formation de biofilm chez la souche Sakai, et vérifier l’association des facteurs identifiés avec d’autres EHEC O157:H7 du même phénotype. Avec une banque de mutants Tn10 de la souche Sakai, des mutants non-autoagglutinants et non-formateurs de biofilms des gènes csgB et csgG furent sélectionnés et caractérisés. Ces mutants formaient significativement moins de biofilms et d´autoagrégats que Sakai, et ne produisaient plus curli. La complémentation des mutants restaurait le phénotype sauvage. De plus, des gènes responsables de la biogenèse de curli csgA, csgB et csgG étaient significativement surexprimés chez Sakai, comparativement avec la souche EDL933 non-autoagglutinant, qui forme moins de biofilm. Parmi les souches d’E. coli 0157:H7 on distingue deux groupes d’isolats: Sakai-like et EDL933-like selon leur production de curli, et leur capacité à former des autoagrégats et biofilms. Nos résultats suggèrent qu’une surproduction de fibres de curli dans un sous-ensemble de souches O157:H7 pourrait être responsable de leur phénotype particulier d'autoagrégation et de formation de biofilms forts. Le projet permet de mieux cerner le mécanisme de formation de biofilm dans EHEC et renforce l’hypothèse que le curli est une cible intéressante pour contrer la persistance des EHEC en environnements naturels et industriels. / Enterohemorrhagic E. coli (EHEC) O157:H7 is an important foodborne pathogen that causes severe toxi-infections in humans. These bacteria have a higher capacity to form biofilm, impeding the control of the contamination in different environments and allowing their persistence. Some E. coli O157:H7 strains, including the Sakai reference strain, display a distinctive ability to autoaggregate and form strong biofilms. The aim of this work was to identify the genes involved in autoaggregation and biofilm formation in Sakai strain, and to verify the association between identified factors and the same phenotype in other EHEC O157: H7. We found that csgA, csgB and csgG curli genes were significantly overexpressed in strain Sakai compared to strain EDL933, a low biofilm-former and non-autoaglutinating strain. Sakai csgB and csgG Tn10 mutants formed significantly less biofilm and autoaggregation than the wild-type strain, and lost the curli-producing phenotype. Complementation restored the strong autoaggregation and biofilm formation phenotype, and the curliated morphotype of Sakai. In addition, E. coli O157: H7 isolates tested for curli formation, Sakai-like strains were curli-producing, whereas EDL933-like strains were non-curliated. These results suggest that overproduction of extracellular curli fibers in a subset of E. coli O157: H7 strains may be responsible for their particular phenotype of autoaggregation and strong biofilm formation. The project provides a better understanding of the mechanism of biofilm formation in EHEC, as well as reinforcing the hypothesis that curli fibers are an attractive target to counter the persistence of these bacteria in natural and industrial environments.

Escherichia coli O157:H7

EHEC

autoagrégation

biofilms

curli

autoaggregation

biofilm formation

curli fibers

Modulation der Candida albicans Biofilmbildung und Expression von Pathogenitätsfaktoren durch Lactobacillus spp.

Dreßel, Tilmann

19 June 2014

Lactobacillus- Spezies, die zur Gattung der Milchsäurebakterien gehören, haben bereits hemmende Eigenschaften gegen Candida albicans gezeigt. Dieser dimorphe Hefepilz ist einer der bedeutendsten Erreger von Pilzinfektionen beim Menschen und einer der häufigsten Verursacher Katheter- assoziierter Infektionen. Eine bedeutende Rolle bei der Pathogenität von C. albicans spielt die Biofilmbildung, die sowohl die körpereigene Abwehr als auch die antimykotische Therapie einer invasiven Infektion erheblich erschwert. Zu den Virulenzfaktoren zählt eine Vielzahl von Genen, darunter auch die sekretorischen Aspartylproteasen (SAPs), die zur Infektion sowohl in vitro als auch in vivo beitragen. In der vorliegenden Arbeit wurde der Einfluss verschiedener Lactobacillus- Stämme auf die Biofilmbildung des invasiv pathogenen C. albicans SC 5314 und des in der Pathogenität abgeschwächten Stammes ATCC 10231 untersucht, sowohl phänotypisch als auch hinsichtlich der metabolischen Aktivität durch den semi- quantitativen XTT- Reduktions- Assay. Zudem erfolgten Expressionsanalysen ausgewählter Gene von C. albicans, deren Zusammenhang mit der Biofilmbildung und Pathogenität bekannt ist. Dabei konnte gezeigt werden, dass L. johnsonii DSM 10533 die metabolische Aktivität beider C. albicans- Stämme erheblich verringern kann (um bis zu 80%) und auch einen phänotypisch drastisch reduzierten Biofilm verursacht. In Anwesenheit dieses Stammes kam es zu stark verringerter Aktivität der beobachteten SAP- Gene vor allem des invasiven Stammes C. albicans SC 5314. Andere Pathogenitäts- assoziierte Gene wie Als 3 und Hwp 1 wurden dagegen eher hochreguliert. L. rhamnosus DSM 20021 und ein klinisches Isolat verursachten ebenfalls eine Verringerung der metabolischen Aktivität, sorgten phänotypisch aber eher für vermehrte Hyphenbildung des Pilzes. Ersterer verursachte eine deutlich reduzierte Aktivität von Hwp 1 und Ume 6 bei C. albicans ATCC 10231. L. reuteri DSM 20016 zeigte keinen signifikanten Einfluss auf Biofilmbildung, Aktivität und Genexpression der beobachteten C. albicans- Stämme. Diese Ergebnisse zeigen deutlich, dass unterschiedliche Lactobacillus- Stämme sich in ihrem Einfluss auf C. albicans erheblich unterscheiden. Auch die Reaktion verschiedener C. albicans- Stämme auf Lactobacillus- Spezies ist sehr verschieden. In dieser Arbeit zeigte L. johnsonii DSM 10533 ein deutliches Potential, C. albicans in der Biofilmbildung und Expression von Pathogenitätsfaktoren zu hemmen. Dieser Stamm erscheint damit für weiterführende Untersuchungen hinsichtlich probiotischen Potentials geeignet. Die Ergebnisse einer Lactobacillus Spezies können nicht generell auf andere Lactobacillus Spezies übertragen werden. Ob sich innerhalb einer Spezies alle Stämme gleichermaßen verhalten, bedarf ebenfalls der Überprüfung. Die Ergebnisse dieser Arbeit werfen auch die Frage auf, ob Lactobacillus Spezies sogar die Pathogenität von C. albicans erhöhen können.

info:eu-repo/classification/ddc/610

ddc:610

Studies on the Effects of Carbon Nanomaterials and Efflux Pump Inhibitors on Biofilm Formation and Lipid Biosynthesis in Mycobacterium smegmatis

Rashmika Gunda (17555157)

07 December 2023

<p dir="ltr">Tuberculosis remains a global health challenge, ranking as the second leading cause of mortality worldwide in 2022. The resilience of <i>Mycobacterium tuberculosis</i>, the causative agent of tuberculosis, is enhanced by the high expression of efflux pumps that confer antibiotic tolerance and the formation of biofilms that confer resistance to antibiotics. Carbon nanomaterials (CNMs) exhibit a broad-spectrum of antibacterial efficacy, making them promising candidates for combating drug-resistant bacterial strains. The effects of the novel carbon allotropes called fullertubes (C₉₀) on any living cell have not been studied. In our study, we employed <i>Mycobacterium smegmatis</i> as a model organism for <i>M. tuberculosis</i> and exposed it to fullertubes and fullerenes. We explored the impact of these CNMs on efflux activity and biofilm formation through biochemical assays like ethidium bromide transport assay and crystal violet assay. We also investigated their impact on lipid biosynthesis associated with log-phase growth and biofilm formation using metabolic radiolabeling studies. We also investigated the effects of the efflux pump inhibitors (EPIs) piperine, berberine, 1-(1-naphthylmethyl)-piperazine and thioridazine on efflux activity, biofilm formation, and lipid biosynthesis associated with log-phase growth and biofilm formation in <i>M. smegmatis.</i> We utilized metabolic radiolabeling methods using ¹⁴C-palmitic acid and ¹⁴C-acetic acid which are precursors of lipid biosynthesis and analyzed the lipids by silica-thin layer chromatography and autoradiography. Our studies revealed that CNMs do not influence efflux activity. However, efflux pump inhibitors effectively block efflux activity in <i>M. smegmatis</i>. Biofilm formation was decreased by CNMs and EPIs. In biofilm cells, fullertubes increased the incorporation of radiolabeled ¹⁴C-palmitic acid into glycopeptidolipids on the cell surface as well as inside the cell. Piperine and berberine affected the incorporation of the radiolabels into lipids such as trehalose monomycolate, phosphatidylethanolamine and cardiolipin in planktonic and biofilm cells. Our study provides insights into the diverse effects of CNMs and efflux pump inhibitors on <i>M. smegmatis</i>.</p>

Analytical biochemistry

Infectious agents

Fullerenes C 60

Fullertubes C 90

Efflux pump inhibitor

Mycobacterium smegmatis cell envelope

Biofilm formation