In vitro Detection of AutoInducer-2 by Small Molecule Fluorophores

McMullen, Justin G.

14 July 2009

No description available.

Biochemistry

AutoInducer-2

Quorum Sensing

Fluorophore

bacterial cell-to-cell communication

Lux-S

Amino Acid Residues in LuxR Critical for its Mechanism of Transcriptional Activation during Quorum Sensing

Trott, Amy Elizabeth

21 July 2000

<I>Vibrio fischeri</I>, a symbiotic bioluminescent bacterium, serves as one of the best understood model systems for a mechanism of cell-density dependent bacterial gene regulation known as quorum sensing. During quorum sensing in <I>V. fischeri</I>, an acylated homoserine chemical signal (autoinducer) is synthesized by the bacteria and used to sense their own species in a given environment. As the autoinducer levels rise, complexes form between the autoinducer and the N-terminal domain of a regulatory protein, LuxR. In response to autoinducer binding, LuxR is believed to undergo a conformational change that allows the C-terminal domain to activate transcription of the luminescence or <I>lux</I> operon. To further understand the mechanism of LuxR-dependent transcriptional activation of the <I>lux</I> operon, PCR-based site-directed mutagenesis procedures have been used to generate alanine-substitution mutants in the C-terminal forty-one amino acid residues of LuxR, a region that has been hypothesized to play a critical role in the activation process. An <I>in vivo</I> luminescence assay was first used to test the effects of the mutations on LuxR-dependent activation of the <I>lux</I> operon in recombinant <I>Escherichia coli</I>. Luciferase levels present in cell extracts obtained from these strains were also quantified and found to correlate with the luminescence results. Eight strains encoding altered forms of LuxR exhibited a "dark" phenotype with luminescence output less than 50% and luciferase levels less than 50% of the wildtype control strain. Western immunoblotting analysis with cell extracts from the luminescence and luciferase assays verified that the altered forms of LuxR were expressed at levels approximately equal to wildtype. Therefor, Low luminescence and luciferase levels could be the result of a mutation that either affects the ability of LuxR to recognize and bind its DNA target (the <I>lux</I> box) or to establish associations with RNA polymerase (RNAP) at the <I>lux</I> operon promoter necessary for transcriptional initiation. A third <I>in vivo </I>assay was used to test the ability of the altered forms of LuxR to bind to the <I>lux</I> box (DNA binding assay/repression). All of the LuxR variants exhibiting the "dark" phenotype in the luminescence and luciferase assay were also found to be unable to bind to the <I>lux</I> box in the<I> </I>DNA binding assay. Therefore, it can be concluded that the alanine substitutions made at these positions affect the ability of LuxR to bind to the <I>lux</I> box in the presence and absence of RNA polymerase. Another class of mutants exhibited wildtype phenotypes in the luminescence and luciferase assays but were unable to bind to the <I>lux</I> box in the DNA binding assay. The alanine substitutions made at these amino acid residues may be making contacts with RNAP that are important for maintaining the stability of the DNA binding region of LuxR. Alanine substitutions made at these positions have a defect in DNA binding at the promoter of the <I>lux</I> operon only in the absence of RNAP. None of the alanine substitutions made in the C-terminal forty-one amino acids of LuxR were found to affect activation of transcription of the <I>lux</I> operon without also affecting DNA binding. Taken together, these results support the conclusion that the C-terminal forty-one amino acids of LuxR are important for DNA recognition and binding of the <I>lux</I> box rather than positive control of the process of transcription initiation. / Master of Science

DNA binding

transcriptional activation

luminescence

autoinducer

lux operon

lux box

LuxR

Vibrio fischeri

luciferase

Autoinducer 2-based quorum sensing response of Escherichia coli to sub-therapeutic tetracycline exposure

Lu, Lingeng

30 October 2006

Autoinducer 2 (AI-2) is a quorum sensing signal employed by bacteria to coordinate their response to environmental stresses. The objective of this study was to determine the relationship between presence of AI-2 molecules, exposure to sub-therapeutic tetracycline, the expression of genes associated with the conjugal transfer of antibiotic resistance plasmids, and the conjugal transfer of these plasmids in Escherichia coli. The studies showed that AI-2 activity increased in Tets E. coli in the presence of tetracycline (2 µg/mL) under both batch and continuous culture conditions. The presence of AI-2 molecules induced tetracycline tolerance development in Tets E. coli. The studies showed that the survival rates of Tets E. coli exposed to AI-2 molecules were significantly higher compared to the cells not exposed to AI-2 molecules or cells that were exposed to only LB (Lauria-Bertani) broth. Molecular analyses using real-time PCR indicate that the expression of at least one conjugation-associated gene (trbC) is increased 9-fold in cells exposed to AI-2 molecules in the presence of sub-therapeutic tetracycline compared to its negative controls. The transconjugation frequency of the plasmid RP4 carrying the tet(A) gene increased between 10-100 fold in the presence of AI-2 molecules. In companion studies, AI-2-like activity was detected in fish, tomatoes, cantaloupes, carrots and milk samples. Interestingly, ground beef and poultry meat contained substances that appear to inhibit AI-2 activity. Collectively, these results highlight the potential importance of bacterial quorum sensing signals such as AI-2 in the response of bacterial cells to environmental stimuli and the possible role of quorum sensing signals in the quality and safety of foods.

quorum sensing

Autoinducer

tetracycline resistance

sub-therapeutic

transconjugation

RP4

tet(A)

Escherichia coli

food

airborne quorum sensing

microflora

Real-time PCR

Development and application of liquid chromatography-tandem mass spectrometry methods to the understanding of metabolism and cell-cell signaling in several biological systems

Gooding, Jessica Renee

01 December 2011

Liquid chromatography tandem mass spectrometry has become a powerful tool for investigating biological systems. Herein we describe the development of both isotope dilution mass spectrometry methods and targeted metabolomics methods for the study of metabolic and cell-cell signaling applications. A putative yeast enzyme was characterized by discovery metabolite profiling, kinetic flux profiling, transcriptomics and structural biology. These experiments demonstrated that the enzyme shb17 was a sedoheptulose bisphosphatase that provides a thermodynamically dedicated step towards riboneogenesis, leading to the redefinition of the canonical pentose phosphate pathway. An extension of metabolic profiling and kinetic flux profiling methods was developed for a set of symbiotic marine microorganisms. Carbon flux from the most abundant photosynthetic organism, Prochlorococcus, to a symbiotic Alteromonas was observed in liquid coculture. These methods enable a more biologically relevant assay for marine species and will lead to a better understanding of carbon flux in the oceans. Energy taxis refers to the active migration of bacteria in response to electron transport system related signals. The second messenger cyclic-di-GMP provides a link between the metabolic signals and motility. Quantitation of c-di-GMP helped characterize the nature of this regulation. Autoinducer-2 is a small sugar produced by a large variety of bacteria that is proposed to be a universal quorum sensing signal. The quorum sensing function of autoinducer-2 is disputed because it is produced by an enzyme of the activated methyl cycle, leading to an alternate hypothesis that it is simply a metabolic byproduct. Herein a method for the detection of autoinducer-2 is developed to enable studies of its signaling role and biosynthetic regulation. These studies demonstrated that autoinducer-2 does not function as a signal in all species. Further, metabolic experiments indicated that the metabolic impact of LuxS dysfunction was small and could be mitigated by recycling oxidized glutathione. Together, these data indicate that neither hypothesis is adequate. Evidence is provided that autoinducer-2 suppresses the immune system, by the interruption of cytokine signaling, implying that autoinducer play a protective role during host colonization.

Metabolomics

Quorum Sensing

Autoinducer-2

riboneogenesis

cytokine

pentose phosphate pathway

Analytical Chemistry

Biochemistry

Immunology of Infectious Disease

Microbial Physiology

Systems Biology

Studium vzájemných interakcí patogennich kvasinek rodu Candida a bakterie Pseudomonas aeruginosa v průběhu kokultivací / The study of mutual interaction between pathogenic yeasts of the genus Candida and bacterium Pseudomonas aeruginosa during cocultivation

Mynářová, Lenka

January 2013

The genus Candida includes several opportunistically pathogenic species which are common causative agents of the yeast infections in humans. Although current medical research is focused mostly on cancer, AIDS or Alzheimer disease, the problem of systemic candidiases cannot be neglected. These infections represent a real threat to the immunocompromissed patients, they are connected with a high mortality rate and expensive medication with poor prognosis. Pseudomonas aeruginosa could be an inspiration in a way of how to eliminate the pathogenic yeasts. The bacterium can inhibit growth of the most common yeast species of the genus Candida, C. albicans. This effect is based on production of toxic substances by the bacterium and on interaction of the bacterium with the C. albicans cell wall, which leads to the lysis of the yeast cells and which is not fully understood. Nevertheless, coexistence of these microorganisms is also possible and their relationship is affected by various factors. Knowledge of these inter- microbial interactions was obtained from studies of diseases and pathologies, during which C. albicans + P. aeruginosa coinfections occur. In this thesis I studied mechanisms of interaction between pathogenic yeast C. albicans and bacterium P. aeruginosa by a) C. albicans gene expression...

Le Quorum Sensing chez la bactérie marine Shewanella woodyi : Rôle dans l'émission de luminescence et dans la formation du biofilm / Quorum sensing in the marine bacterium Shewanella woodyi : Role in luminescence emission and biofilm formation

Hayek, Mahmoud

17 May 2018

Le « quorum sensing » (QS) est un moyen de communication bactérienne impliquant des petites molécules appelées auto-inducteurs qui au-delà d’un certain seuil de concentration induisent une synchronisation de l’expression génétique au sein de la communauté bactérienne. Ce mécanisme est impliqué dans plusieurs processus bactériens tels que la luminescence, la formation du biofilm, ce qui en fait une cible privilégiée pour l’inhibition du biofilm bactérien nuisible aux activités humaines. Plusieurs systèmes QS ont été identifiés ; les plus étudiés sont le système AHL (acyl homoserine lactone) et le système AI2 (auto inducteur 2). L’objectif principal de cette thèse est de caractériser le(s) système(s) QS de Shewanella woodyi, une bactérie marine luminescente capable de coloniser rapidement une surface et de former un biofilm. L’utilisation de biosenseurs de référence et des expériences de LC-MS ont montré que S. woodyi synthétise la C8-HSL et l’AI2. La mutation des gènes impliqués dans la synthèse ou la détection des HSL abolit la luminescence mais n’affecte pas la formation du biofilm. De plus, le système AI2 ne semble pas impliqué dans la luminescence et la formation de biofilm de S. woodyi. L’absence d’un récepteur d’AI2 suggère que cette molécule n’a pas un rôle régulateur et qu’elle ne serait qu’un produit secondaire du métabolisme cellulaire. Ce travail a donc permis de caractériser les 2 principaux systèmes QS de S. woodyi et pourrait permettre d’en faire un nouveau biosenseur marin. / Quorum sensing (QS) is a bacterial communication system involving small molecules called autoinducers which above a threshold concentration, induce the synchronization of genes expression within the bacterial community. This mechanism is involved in several bacterial processes such as luminescence and biofilm formation, making it a preferred target for the inhibition of bacterial biofilm harmful to human activities. Several QS systems have been identified; the most studied ones are the AHL system (acylhomoserine lactone) and the AI2 system (autoinducer 2). The main objective of this thesis is to characterize the QS system (s) of Shewanella woodyi, a luminescent marine bacterium able to rapidly colonize a surface and form a biofilm. The use of reference biosensors and LC-MS experiments have shown that S. woodyi synthesizes C8-HSL and AI2. The mutation of the genes involved in the synthesis or detection of HSL abolishes luminescence but does not affect the biofilm formation. Moreover, the AI2 system does not appear to be involved in the luminescence and biofilm formation of S. woodyi. The absence of an AI2 receptor suggests that this molecule does not have a regulatory role and that it is only a secondary product of cellular metabolism. This work has allowed the characterization of the 2 main QS systems of S. woodyi, which could make this strain a new marine biosensor.

Shewanella woodyi

AHL Acyl homoserine lactone

AI2 Auto inducteur 2

Bactérie biosenseur

Shewanella woodyi

AHL Acylhomoserine lactone

AI2 autoinducer 2

Biosensor bacteria

Molekulare Analyse des Biotin-regulatorischen Netzwerks Sinorhizobium meliloti durch Proteomanalyse, Expressionsstudien und Mutagenesen / Molecular Analysis of the Biotin-regulatory Network in Sinorhizobium meliloti by Proteome-Analysis, Expressional Studies und Mutagenesis

Heinz, Elke

30 October 2002

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Sinorhizoium meliloti

Biotin

2D-Gelelektrophorese

pcm

surE

Acyl-HSL

Autoinduktor

Proteomics

Sinorhizoium meliloti

Biotin

2D-gelelectrophoresis

pcm

surE

acyl-HSL

autoinducer

proteomics

42.3

WU 000: Mikrobiologie

Quorum Sensing Signals Produced by Heterotrophic Bacteria in Black Band Disease (BBD) of Corals and Their Potential Role in BBD Pathogenesis

Bhedi, Chinmayee D.

30 June 2017

Black band disease (BBD) of corals is a temperature dependent, highly virulent, polymicrobial disease affecting reef-building corals globally. The microbial consortium of BBD is primarily comprised of functional physiological groups that include photosynthetic cyanobacteria, sulfate reducers, sulfide oxidizers and a vast repertoire of heterotrophic bacteria. Quorum sensing (QS), the cell-density dependent communication phenomenon in bacteria, is known to induce expression of genes for a variety of virulence factors in diseases worldwide. Microbes capable of QS release signals such as acyl homoserine lactones (AHLs) and autoinducer-2 (AI-2), which coordinate microbial interaction. The focus of the present study was to investigate the presence and potential role of QS in BBD pathogenicity, utilizing culture dependent and independent methodologies. Isolates across coral health states including BBD, were screened for production of QS signals, and AHL and AI-2 production capabilities were analyzed via LC-MS/MS. The effect of temperature on AHLs was also examined. Additionally, antimicrobial production capabilities of isolates were tested. BBD metagenomes were utilized to screen for sequences related to QS, antimicrobial synthesis, and antimicrobial resistance genes. BBD isolates represented a significantly higher proportion of isolates capable of producing QS signals in comparison to healthy coral isolates. Several AHLs produced by coral derived bacterial cultures were identified, and three AHLs, specifically 3OHC4, 3OHC5 and 3OHC6, showed a significant increase in production at an elevated temperature of 30 °C, which correlates with increased BBD incidence on reefs with increasing water temperature. Most of the BBD cultured isolates were identified as vibrios. Several sequences related to QS, antimicrobial synthesis and resistance genes were detected in the BBD metagenomes. Based on the findings of this study, a model for potential microbial interactions amongst BBD heterotrophs, centered around QS, is proposed. Taken together, the findings from this study provide a clearer understanding of the potential role of QS in BBD, and serve as the basis for further studies aimed at elucidating the pathogenesis of an intricate coral disease.

black band disease

corals

quorum sensing

acyl homoserine lactones

metagenomics

temperature

coral disease

secondary metabolites

autoinducer-2

antimicrobial production

Bacteriology

Biology

Biotechnology

Marine Biology

Microbial Physiology

Microbiology

Pathogenic Microbiology