Investigation of the Regulation of the Lysine Decarboxylase LdcI Activity by the Alarmone ppGpp and MoxR Family AAA+ ATPase RavA

Zhao, Boyu

27 November 2012

The lysine-dependent acid stress response system in Escherichia coli protects the cells under moderately acidic conditions. It consists of LdcI, the inducible lysine decarboxylase and CadB, the lysine-cadaverine antiporter. LdcI interacts with both ppGpp, the signalling molecule in the stringent response, and RavA, a MoxR-family AAA+ protein induced in the stationary phase. Experiments in vitro have shown that ppGpp inhibits the activity of LdcI and that the interaction between LdcI and RavA antagonizes the inhibition. In this work, it was demonstrated, by using a media shift assay, that the antagonistic regulation of RavA and ppGpp of LdcI activity also takes place in vivo, thereby linking acid resistance to the stringnent response. As part of this study, components of the lysine decarboxylase pathway and the ravA-viaA operon were endogenously tagged with fluorescent proteins. These strains are useful tools to study the localization behaviour of these proteins under different stress conditions.

LdcI

ppGpp

0487

Investigation of the Regulation of the Lysine Decarboxylase LdcI Activity by the Alarmone ppGpp and MoxR Family AAA+ ATPase RavA

Zhao, Boyu

27 November 2012

The lysine-dependent acid stress response system in Escherichia coli protects the cells under moderately acidic conditions. It consists of LdcI, the inducible lysine decarboxylase and CadB, the lysine-cadaverine antiporter. LdcI interacts with both ppGpp, the signalling molecule in the stringent response, and RavA, a MoxR-family AAA+ protein induced in the stationary phase. Experiments in vitro have shown that ppGpp inhibits the activity of LdcI and that the interaction between LdcI and RavA antagonizes the inhibition. In this work, it was demonstrated, by using a media shift assay, that the antagonistic regulation of RavA and ppGpp of LdcI activity also takes place in vivo, thereby linking acid resistance to the stringnent response. As part of this study, components of the lysine decarboxylase pathway and the ravA-viaA operon were endogenously tagged with fluorescent proteins. These strains are useful tools to study the localization behaviour of these proteins under different stress conditions.

LdcI

ppGpp

0487

Investigation on Periplasmic Bacterial Sensing through Generation of a ppGpp Biosensor

Robinson, Andrew, Robinson, Andrew

06 April 2022

Guanosine tetraphosphate (ppGpp) is a bacterial signaling molecule involved in activating the stringent response, a cellular reaction to environmental stress that downregulates cell division and metabolism processes to conserve nutrients. The stringent response is implicated in some instances of antibiotic resistance, so broadening the current understanding of ppGpp signaling is useful. This experiment seeks to generate a ppGpp biosensor that will bind ppGpp and emit fluorescent light in its presence which will allow for improved research into the pathways and functions of the signaling molecule. To generate a novel ppGpp biosensor, I converted a biosensor previously used to detect cyclic di-GMP (a different signaling molecule) to contain a binding site transformed to now bind specifically with ppGpp. The genetic sequence for the cyclic di-GMP binding site was replaced with the ppGpp hydrolase domain which has a specific affinity for ppGpp; however, hydrolase activity would provide unwanted breakdown of the ppGpp, so it is mutated further to neutralize hydrolase activity. The desired outcome of this experiment results in a biosensor with an active site that has a specific and sufficient binding affinity for the ppGpp molecule. This sensor is designed to have the active site (ppGpp binding site) flanked by two fluorescent proteins that will interact more closely and transfer fluorescent light. When the first fluorescent protein is activated and the second fluorescent protein is in close proximity, emitted light can be transferred to the second. Binding of ppGpp will cause a conformational shift in the biosensor’s structure, causing the two fluorescent proteins to move further apart. This results in them losing the ability to transfer the fluorescent energy between fluorescent proteins. Using a fluorescent microscope or fluorescent plate reader, I will be able to determine the level of transferred fluorescent energy, and in turn measure the amount of ppGpp in the sample. Having generated the biosensor, I must now determine the ppGpp detection level, intensity of change in fluorescent transfer upon ppGpp binding, and the binding affinity for other nucleotides that might give me an incorrect signal. Using this, we can determine how ppGpp levels are regulated in bacteria under conditions of stress.

biosensor

ppGpp

bacterial sensing

Biosensors

Examining mechanisms of virulence gene regulation and the early host interactions in Francisella tularenisis

Faron, Matthew Leon

01 December 2014

Francisella tularensis is a facultative intracellular pathogen and is the etiological agent of tularemia. One key aspect to the success of Francisella as a pathogen is ability of the organism to establish infection with a low inoculum, as few as 10 colony forming units (cfu). Essential to this process is the Francisella pathogenicity island (FPI). Several studies have been performed to understand how the FPI is regulated; however, the working model is not complete, as the signals important for regulation are unknown. Additionally, the mechanisms of the proteins MigR, TrmE, and CphA, which are important for activation of the FPI, are unknown. I initiated the study of this regulatory system by measuring the ability of various cellular stresses to activate an iglA-lacZ reporter. I identified that amino acid starvation and growth in basic pH activated expression of the reporter in both LVS and Schu S4. By combining these two stresses I was able to induce iglA-lacZ reporter expression in an additive manner. As it was previously demonstrated that ppGpp is important for stabilization of the regulatory complex that transcribes FPI genes, I demonstrated by TLC that both amino acid starvation and basic pH effected iglA-lacZ expression by increasing ppGpp. Due to the importance of ppGpp in FPI expression and because MigR, TrmE, and CphA each appear to be involved in a metabolic process: fatty acid metabolism (migR) t-RNA modification (trmE) and amino acid storage (cphA), I had hypothesized that the effect on these mutations were due to decreased levels of the small alarmone ppGpp. I compared ppGpp accumulation of LVS mutants in migR, trmE, and cphA to the parent strain and observed that loss of these genes resulted in reduced ppGpp. To better understand the importance of ppGpp synthesis in F. tularensis pathogenesis, I compared the phenotypes of these strains in primary human macrophages and two immortalized epithelial cell lines. These experiments demonstrated that although each of these strains had reduced ppGpp, there were cell line specific growth phenotypes. Mice infected with these strains survived suggesting tight regulation of the FPI is required for virulence. When similar mutations were characterized in the Schu S4 background these mutations retained their regulatory role; however, mutation of migR did not significantly decrease virulence in mice. As my data demonstrated that there are different challenges that Francisella must overcome to successfully replicate within cells, I developed an in vitro model to study the interactions of F. tularensis with human alveolar type II cells (AT-II). Interestingly, Schu S4 internalizes and replicates in these recently immortalized human AT-II cells whereas, LVS internalizes, but replicates poorly within these cells. Finally, to better understand the role of AT-II cells in vivo, I performed Transmission Electron Microscopy (TEM) of infected mice. These data confirmed that Schu S4 infected both alveolar macrophages and AT-II cells. Together, this work contributes to the understanding of how Francisella adapts to various environments by modulating virulence gene expression and highlights differences between virulent Schu S4 and LVS, which may partially contribute to virulence differences observed between strains.

Alveoli

FPI

Francisella

ppGpp

regulation

Tularensis

Genetics

Investigation on Bacterial Signaling through Generation of a ppGpp Biosensor

Robinson, Andrew

01 May 2022

Guanosine tetraphosphate (ppGpp) is a bacterial signaling molecule involved in activating the stringent response, a cellular reaction to environmental stress that downregulates cell division and metabolism processes to conserve nutrients. The stringent response is implicated in some instances of antibiotic persistence, so broadening the current understanding of ppGpp signaling is useful. This thesis seeks to generate a ppGpp biosensor that will bind ppGpp and emit fluorescent light in its presence, which will allow for improved research into the pathways and functions of the signaling molecule. To generate a novel ppGpp biosensor, I converted a biosensor previously used to detect cyclic di-GMP (a different signaling molecule) to contain a binding site transformed to now bind specifically with ppGpp. The genetic sequence for the cyclic di-GMP binding site was replaced with the ppGpp hydrolase domain which has a specific affinity for ppGpp; however, hydrolase activity would provide unwanted breakdown of the ppGpp, so it is mutated further to neutralize hydrolase activity. The desired outcome of this thesis results in a biosensor with a binding site that has a specific and sufficient binding affinity for the ppGpp molecule. Using this, we can determine how ppGpp levels are regulated in bacteria under conditions of stress, and how this signaling molecule is related to the survival of bacteria in response to antibiotic treatment.

ppGpp

biosensor

second messenger

antibiotic persistence

Bacteria

Functional Characterization of Exopolyphosphatase/ Guanosine Pentaphosphate Phosphohydrolase (PPX/GPPA) Enzymes of Campylobacter jejuni

Kumar, Anand

17 July 2012

No description available.

Veterinary Services

ppGpp

PPX

poly-P

Identification of factors regulating guanosine tetraphosphate (ppGpp) biosynthesis in Arabidopsis thaliana / L'identification des facteurs qui modulent la biosynthèse de ppGpp chez Arabidopsis thaliana

Ke, Hang

30 September 2016

La ppGpp et la pppGpp, qui sont synthétisées/hydrolysées par les RelA/Spot homologs (RSH), jouent un rôle centrale dans l’adaptation des bactéries contre la privation des nutriments et les stress environnementaux. Les enzymes RSH et ppGpp ont été découverts dans le chloroplaste. Il a été récemment démontré que ppGpp joue un rôle comme répresseur globale de l’expression de gènes chloroplastiques. Certains stresses environnementaux et hormones induisent l’accumulation de ppGpp chez les plantes, cependant le mécanisme moléculaire n’est pas encore connu. Ici nous nous sommes intéressés à découvrir les facteurs qui interagissent avec les RSH, et qui donc sont susceptible de réguler le métabolisme du ppGpp. En utilisant un crible double-hybridation de levure nous avons identifiées des proteines qui interagissent avec les RSH y compris l’acyl carrier protein (ACP) et des GTPases associées au ribosome. ACP et RSH1 semblent être indispensables pour l’accumulation de ppGpp induite par la carence de la biosynthèse des acides gras, tandis que le ppGpp et un GTPase associé au ribosome contribuent à la résistance contre le heat-shock. Nous avons aussi effectué du co-immunoprécipitation spectrométrie de masse avec RSH1. Plusieurs protéines ont été identifiées y compris des protéines associées au nucléoid et des protéines liées à la signalisation chloroplastique, indiquant que RSH1 pourrait etre impliqué dans la machinerie de transcription chloroplastique. Nos résultats montrent que chez les plantes le ppGpp joue un rôle non seulement comme chez les bacteriés mais aussi participe à de nombreux processus biologiques qui sont spécifiques aux plantes. / Guanosine tetra-phosphate and penta-phosphate (ppGpp and pppGpp), which are synthesized/hydrolyzed by RelA/Spot homolog (RSH) enzymes, play a central role in the adaptation of bacteria to nutrient limitation or other stresses. Both RSH enzymes and ppGpp are present in the chloroplasts of plants. Recent studies have shown that ppGpp acts as a global repressor of chloroplast gene expression. Certain environmental stresses and hormones induce ppGpp accumulation in chloroplasts, however the molecular mechanisms underlying the activation of ppGpp signalling in response to such stimuli is essentially unknown. We searched for factors that interact with RSH enzymes and so could play a role in activating ppGpp signalling. Using a targeted yeast two hybrid screen several proteins were identified that interact with RSH enzymes including acyl carrier protein (ACP) and ribosome associated GTPases. ACP and RSH1 appear to be required for ppGpp induction in response to fatty acid biosynthesis depletion, while ppGpp and an RSH-interacting GTPase contribute to the resistance of plants to heat shock. We also performed non-targeted co-immunoprecipitation mass spectrometry (CoIP-MS) of RSH1. New RSH interaction candidates were identified, including plastid nucleoid associated proteins and chloroplast signalling proteins, suggesting that RSH1 may be associated with the plastid transcription machinery. Our results give new insights into ppGpp signalling, and show that some elements are conserved between plants and bacteria, while others are implicated in plant-specific biological processes.

PpGpp

RelA-SpoT Homologues

Chloroplaste

Arabidopsis thaliana

PpGpp

RelA-SpoT Homologs

Chloroplast

Arabidopsis thaliana

581

Manipulation des voies de signalisation de l'énergie pour améliorer la production des biocarburants chez les organismes photosynthétiques / Manipulating energy signaling to improve biofuel production in photosynthetic eukaryotes

Harchouni, Seddik

19 December 2018

Les triacylglycérol (TAG) est un métabolite hautement énergétique qui peut être facilement converti en biodiesel. Les TAG peuvent être produits à partir de plantes et de microalgues. L'étude des voies de signalisation de l'énergie peut offrir de nouvelles stratégies pour améliorer l'accumulation de biomasse et de TAG sans compromettre la croissance. Dans cette thèse, j'ai étudié le rôle de deux voies principales de signalisation énergétique: la voie du de guanosine ppGpp (guanosine penta(tétra) phosphate) dans le chloroplaste et la voie de TOR (Target of rapamycin) dans le cytosol. J'ai choisi de travailler sur la mousse Physcomitrella patens, un modèle d'eucaryote photosynthétique en raison de sa position évolutive entre les algues et les plantes vasculaires. Pour étudier le rôle du ppGpp, nous avons créé des lignées transgéniques exprimant de manière inductible une ppGpp synthase et sur-accumulant le ppGpp. J'ai trouvé que l'induction de SYN provoque une forte inhibition de la capacité photosynthétique en raison de l'inhibition de l'expression des protéines clés codées par les chloroplastes et aussi une réorganisation des membranes thylakoïdes. Pour l’étude de TOR nous avons traité la mousse avec des inhibiteurs de TOR et montré que cela provoque l’inhibition de la croissance de manière dose dépendante et l’accumulation de TAG. L’utilisation des marqueurs lipidiques a révélé la perte de petites vésicules associées à la croissance et l'accumulation de plus grandes structures de corps lipidiques. Des études supplémentaires permettront de développer des stratégies pour améliorer la production de biocarburants chez les organismes photosynthétiques. / Triacylglycerol (TAG) is a highly energetic metabolite that can be easily converted into biodiesel. TAG can be produced from both plants and microalgae. However, plants have low TAG yields in their dominant vegetative tissues. Microalgae can accumulate high amounts of TAG, but only under stress, leading to growth inhibition and limiting yield. The study and manipulation of stress and energy signaling pathways can offer new strategies to improve biomass and TAG accumulation without compromising growth. In this thesis, I studied the role of two major energy signaling pathways: the guanosine penta(tetra) phosphate (ppGpp) pathway in the chloroplast and the target of rapamycin (TOR) pathway in the cytosol. I chose to work on the moss Physcomitrella patens which is an interesting model of photosynthetic eukaryote because of its evolutionary position between algae and vascular plants. To study the role of ppGpp we created transgenic lines that inducibly express a ppGpp synthase and over-accumulate ppGpp. I found that ppGpp accumulation causes a strong inhibition of photosynthetic capacity due to the inhibition of the expression of key chloroplast encoded proteins, and also reorganization of the thylakoid membrane system into super grana. For the TOR pathway, we treated P. patens protonema with active site TOR inhibitors and showed that this cause growth inhibition in a dose dependent manner and is accompanied by TAG accumulation. The use of lipid dyes reveals a shift from small growth associated vesicles to a larger oil body structures after treatment. Further studies will allow the development of new strategies for improving biofuel production in photosynthetic organisms.

Physcomitrella

PpGpp

Tor

Azd8055

Lipid

Physcomitrella

PpGpp

Tor

Azd8055

Lipid

580

On the role of small regulatory molecules in the interplay between σ54- and σ70-dependent transcription

Holmfeldt, Linda

January 2009

Signal responsive transcriptional control in bacteria is mediated through both specific and global regulatory circuits to attune promoter output to prevailing conditions. Divergent transcription of a regulatory gene and a cognate promoter under its control provides an opportunity for interplay between transcription dependent on RNA polymerases utilizing various σ-factors, each of which programs the holoenzyme to recognize different classes of promoters. The work presented in this thesis analyses the consequences and mechanisms behind interplay between σ54- and σ70-dependent transcription within the dmp-system of Pseudomonas sp. CF600. The dmp-system confers the ability to grow at the expense of (methyl)phenols and is controlled by two promoters that drive non-overlapping divergent transcription from a common intergenic region: i) the σ54-Po promoter, which controls an operon encoding a suit of specialized catabolic enzymes, and ii) the σ70-Pr promoter, which controls production of the aromatic sensor DmpR - a mechano-activator whose transcription-promoting activity is obligatory for activity of the σ54-Po promoter. The σ54-Po promoter and its dependence on two non-classical transcriptional regulators - the alarmone ppGpp and its co-factor DksA that directly target RNA polymerase - are the focus of the first part of the thesis. These studies utilized ppGpp and DksA deficient strains, mutant RNA polymerases that bypass the need for ppGpp and DksA, reconstituted in vitro transcription systems, and a series of DmpR-regulated hybrid σ54-promoters with different affinities for σ54-RNA polymerase, together with analysis of protein levels of key transcriptional components. Collectively with previous work, these studies provide the experimental support for a robust but purely passive mechanism for ppGpp and DksA global regulation of σ54-transcription, which is likely to also be pertinent for transcription mediated via any alternative σ-factor (Papers I-III). The second part of the thesis focuses on additional roles of ppGpp and DksA through their direct and indirect effects on the activity of the σ70-Pr promoter. These studies unexpectedly revealed that the σ70-Pr promoter is regulated by a novel mechanism in which σ54-RNA polymerase occupancy and activity at the σ54-Po promoter stimulates σ70-Pr output. Evidence is presented that ppGpp and DksA, through DmpR levels, control a feed forward loop to reinforce silence of the σ54-Po promoter under high energy conditions with robust transcription from σ54-Po when the catabolic enzymes are needed. The interplay outlined above effectively places a σ70-dependent promoter under dual control of two forms of RNA polymerases, and also makes it subservient to regulatory signals that elicit activity of σ54-RNA polymerase. The possibility that such dual sensitivity may be a prevalent, but previously unappreciated, mechanism by which bacteria integrate diverse and/or conflicting signals to gain appropriate transcriptional control is discussed.

σ54

σ70

ppGpp

DksA

transcription regulation

Molecular biology

Molekylärbiologi

The Study of a Novel (p)ppGpp Synthase (YwaC) from Bacillus subtilis 168

Dalgleish, Heather

09 1900

Adaptation to any undesirable change in the environment helps to ensure the survival of many microorganisms. During nutrient starvation, bacteria undergo a stringent response characterized by the accumulation of the alarmone (p)ppGpp. This results in the repression of stable RNA species and a change in colony morphology. In Gram-negative bacteria such as Escherichia coli, RelA and SpoT synthesize and hydrolyze these nucleotides, respectively, under conditions of nutrient starvation. In Gram-positive bacteria, the bifunctional enzyme Rei is responsible for the accumulation of (p)ppGpp. These enzymes catalyze the transfer of a pyrophosphate moiety from ATP to the 3' end of either GTP or GDP. The overproduction of (p)ppGpp has many diverse consequences on bacterial physiology such as sporulation, virulence, long term persistence of pathogenic bacteria, cell morphology, antibiotic synthesis and fatty acid metabolism. In Bacillus subtilis a novel (p)ppGpp synthase, YwaC, is also involved in the accumulation of (p)ppGpp but does not associate with the ribosome. Transcriptional analysis of ywaC has implicated it with cell wall stress especially associated with lesions in the teichoic acid biosynthetic pathway. The work described here includes a steady state kinetic analysis of the reaction catalyzed by YwaC. Recombinant YwaC was over-expressed in E. coli and purified to homogeneity. Steady-state kinetic experiments were performed utilizing a high-performance liquid chromatography assay. This examination yielded Km values for GDP and GTP of 5 J.1M and 6 J.1M respectively, while the kcat was measured to be 0.13 min"1 and 0.11 min"1 respectively. As is common with other (p)ppGpp synthases, the low activity ofYwaC may be increased in the presence of the appropriate effector molecule. To explore the functional phenotype associated with ywaC a deletion strain was made by replacing the gene on the chromosome of B. subtilis with a spectinomycin resistance cassette. A variety of antibiotics were used to probe the ywaC deletion strain in an attempt to detect antibiotic sensitivity in comparison to wildtype cells. In addition, the morphology of the ywaC deletion strain was investigated using phase contrast confocal microscopy. Length and shape remained the same in a ywaC knockout. Growth profiles performed over a 24-hour period showed that the knockout strain grew similarly to wildtype B. subtilis. Thus, the phenotype analysis described herein failed to further elucidate the function of YwaC. Nevertheless, rigorous biochemical analysis described here have established the enzymatic role of (p)ppGpp synthesis for YwaC, but there remains much room for further investigation. / Thesis / Master of Science (MSc)

Novel (p)ppGpp

Synthase (YwaC)

Bacillus subtilis

bacteria