Regulation de transcription plastidique par des facteurs sigma et ARNs anti-sense chez Arabidopsis Thaliana.

Mustafa, Malik Ghulam

15 December 2010

Les chloroplastes, responsables de la photosynthèse chez les organismes autotrophes, possèdent un génome plastidial codant de 100 à 130 gènes dont environ 80 pour des protéines principalement impliquées dans la photosynthèse, la transcription et la traduction. L'expression de ces gènes, coordonnée entre le plaste et le noyau, implique deux types d'ARN polymérases, la NEP (Nucleus Encoded RNA Polymerase) et la PEP (plastid Encoded RNA Polymerase) laquelle s‟associe à l‟un des 6 facteurs sigma (SIG), codés dans le noyau pour la reconnaissance spécifique de promoteurs de transcription. Nous avons tout d‟abord analysé le rôle de ces facteurs sigma dans la régulation transcriptionnelle des deux opérons codant des sous-unités de l‟ATP synthase, atpI/H/F/A et atpB/E, en précisant le rôle particulier de SIG3 dans la reconnaissance spécifique du promoteur (-418) de l‟atpH. Nous avons identifié les promoteurs des transcrits polycistronique et ceux situés en amont des gènes atpH et atpE, et avons montré (1) que les gènes des deux opérons sont co-régulés par SIG3 et SIG2 sauf atpI régulé par SIG2 seul et (2), que SIG3 jouerait un rôle essentiel dans la surexpression monocistronique d‟atpH par la reconnaissance d‟un promoteur (-418) en amont de atpH. L‟analyse systématique des transcrits plastidiaux accumulés en fonction de l‟éclairement des plantes nous a permis de corréler cette surexpression à un éclairement élevé (1300 μE) de plantes matures. SIG3 reconnaît aussi spécifiquement le promoteur de psbN, gène localisé sur le brin opposé de l‟opéron psbB/T/H/petB/petD, produisant un ARN anti-sens de psbT et de la région intergénique psbT/psbH. Nos résultats montrent que l‟anti-sens de psbT couvre la région codante, le 5'UTR et la quasi-totalité 3' UTR du transcrit sens psbT, pouvant ainsi réguler la production de PSBT en interférant dans la traduction par la formation d‟un duplex ARN. L‟anti-sens pourrait aussi intervenir dans le processing dans la région 5‟ UTR de psbH.

Arabidopsis thaliana

Chloroplast

transcription

facteur sigma

sigma3

ARNs anti sense

operon ATP

Genomic data mining for the computational prediction of small non-coding RNA genes

Tran, Thao Thanh Thi

20 January 2009

The objective of this research is to develop a novel computational prediction algorithm for non-coding RNA (ncRNA) genes using features computable for any genomic sequence without the need for comparative analysis. Existing comparative-based methods require the knowledge of closely related organisms in order to search for sequence and structural similarities. This approach imposes constraints on the type of ncRNAs, the organism, and the regions where the ncRNAs can be found. We have developed a novel approach for ncRNA gene prediction without the limitations of current comparative-based methods. Our work has established a ncRNA database required for subsequent feature and genomic analysis. Furthermore, we have identified significant features from folding-, structural-, and ensemble-based statistics for use in ncRNA prediction. We have also examined higher-order gene structures, namely operons, to discover potential insights into how ncRNAs are transcribed. Being able to automatically identify ncRNAs on a genome-wide scale is immensely powerful for incorporating it into a pipeline for large-scale genome annotation. This work will contribute to a more comprehensive annotation of ncRNA genes in microbial genomes to meet the demands of functional and regulatory genomic studies.

Bioinformatics

Non-coding RNA genes

Operon prediction

Neural networks

Computational biology

Non-coding RNA

Data mining

Genomics Data processing

Genomes Data processing

Evolution Of New Metabolic Functions By Mutations In Pre-Existing Genes : The chb Operon Of Escherichia Coli As A Paradigm

Kachroo, Aashiq Hussain

02 1900

Escherichia coli has the ability to respond to stress such as starvation in a very efficient manner. Under conditions of starvation wherein a novel substrate is provided as a sole nutritional source, Spontaneous mutants arise in a population of E.Coli that are able to utilize this novel carbon Many generic systems, upon mutational activation, have been shown to allow E.coli to Grow on novel substrates. . Wildtype E.coli is not able to utilize cellobiose, a disaccharide of glucose, as a carbon source. However after prolonged incubation with cellobiose as a sole carbon source, spontaneous Cel+ mutants can be isolated. The Cel+ derivatives have mutations in the chb operon involved in the utilization of N-N-diacetylchitobiose, a disaccharide of N-acetyl glucosamine. The chb operon of E.coli is comprised of six ORFs (chbBCARFG) with a ~200bp regulatory region (chbOP); chbBCA encode the IIB, IIC and IIA domains of the PTS-dependent permease respectively, chbR encodes for a dual function activator/repressor, chbF encodes the phopho-chitobiase and chbG codes for a protein of unknown function. It has been shown that the three proteins ChbR, CAP and NagC regulate the expression of the chb operon. ChbR along with CAP activates the chb operon in the presence of chitobiose. In the absence of the inducer, ChbR, along with NagC, represses the chb operon. Activation of the chb operon allowing utilization of cellobiose was earlier shown to occur either via insertion of IS1, IS2 or IS5 into the regulatory region (chbOP) upstream of the transcription start site or by base substitutions in chbR. Comparison of the chb operon sequence obtained from various Cel+ mutants with E.coli K12 genome sequence showed many differences. These differences were clustered in both the permease (chbBCA) as well as the enzyme (chbF) of the chb operon, suggesting that mutations are needed in all the ORFs of this operon in order to alter the specificity of E.coli towards utilization of cellobiose. The main objective of this thesis is to elucidate the mechanism of mutational activation of the chb operon of E.coli to allow utilization of cellobiose. These studies have shown that two classes of mutations, those that abrogate repression by NagC and those that alter the regulation by ChbR, together are necessary and sufficient to confer a Cel+ phenotype to E.coli. These studies also show that the wildtype permease and phospho-â -glucosidase are able to recognize and cleave cellobiose. Initial experiments were designed to study the role of independent mutational events of either insertion within the regulatory region or loss-of-function of chbR in conferring E.coli a Cel+ phenotype. The single mutational event of either the insertion within the regulatory region chbOP that disrupts the strong NagC binding site (mimicking an IS element) or knockout of chbR did not confer on E.c oli a Cel+ phenotype. However the presence of the artificial insertion within chbOP accelerated the process of obtaining Cel+ mutants suggesting a positive role for insertion elements. The apparent inability of the chbR knockout strain to mutate to Cel+ suggested that chbR is essential for acquisition of a Cel+ phenotype. Reporter gene assays showed that the presence of an insertion within chbOP enhances the promoter activity marginally. The role of chbR as a repressor was further ascertained by increased promoter activity seen from wildtype chbOP-lacZ fusion in a chbR knockout strain. A marginal enhancement in promoter activity in the presence of cellobiose in a strain carrying a wildtype chbR as compared to chbR knockout strain suggested an additional positive role of chbR. The inability of cellobiose to produce an inducing signal necessary for activation by wildtype ChbR protein suggested that gain-of-function mutations within chbR locus might play a crucial role in acquisition of cellobiose utilization phenotype by E.coli. The chbR clones obtained from various Cel+ mutants could activate transcription from the chb promoter at a higher level in the presence of cellobiose. However this activation was seen only in a strain carrying disruptions of the chromosomal nagC and chbR loci. These transformants also showed a Cel+ phenotype on the MacConkey cellobiose medium suggesting that the wildtype permease and enzyme upon induction could recognise, transport and cleave cellobiose, respectively. This was confirmed by cloning the wildtype genes encoding the permease and phospho-â -glucosidase under a heterologous promoter (Plac). The wildtype E.coli strain transformed with a plasmid carrying the genes could utilize cellobiose efficiently. Large scale isolation of Cel+ mutants was undertaken. Variation in the ability of cellobiose utilization was observed among the different mutants. Several Cel+ mutants retained the ability to utilize chitobiose. Cel+ mutants lacking insertions within chbOP contained a loss-of-function mutation at the nagC locus. The sequencing of the chbR locus from Cel+ mutant strains showed a single basepair change at the DNA level translating into a single amino acid change when compared to the Cel- counterpart. Nucleotide sequence of chbR obtained from two Cel+ natural isolates of E.coli also showed a single base mutation. The chbR clones from the two mutants, when transformed into a strain carrying disruptions at the chromosomal nagC and chbR loci, conferred it a Cel+ phenotype. Initial characterization of one of the mutant ChbR (N238S) was carried out. Reporter assays in a strain containing a wildtype copy of chbR at the genomic locus and a disruption of nagC showed that the wildtype ChbR is dominant over the mutant ChbR (N238S). The biochemical investigations of the wildtype and mutant ChbR (N238S) were undertaken. Wildtype ChbR showed non-specific binding to chbOP that could not be competed out by excess cold DNA. DNaseI protection assays confirmed that wildtype ChbR formed a relatively nonspecific complex with chbOP as compared to mutant ChbR (N238S). Finally DNaseI footprinting experiments showed that mutant ChbR (N238S) binds the specific direct repeat within chbOP better than the wildtype protein. These results indicated that mutant ChbR (N238S) has lost its ability to repress transcription by its inability to bind chbOP non-specifically. In addition, the mutant ChbR (N238S) has acquired the ability to activate transcription in the presence of cellobiose. This could be partly mediated via enhanced binding of the mutant ChbR (N238S) to the specific DNA binding site within chbOP in contrast to its wildtype counterpart. To conclude, this work has shown that acquisitive evolution of E.coli towards utilization of cellobiose in laboratory conditions alters the regulation of the chb operon and allows it to acquire new metabolic capability for utilizing cellobiose under selective pressure.

Metabolic Functions

Mutation Genetics

Escherichia Coli

Cellobiose-positivie Mutants

Chitobiose (Chb) Operon

Gene-Regulation

ChbR N238S

Genetics

Modelling Approaches to Molecular Systems Biology / Systembiologisk modellering på molekylär nivå

Fange, David

January 2010

Implementation and analysis of mathematical models can serve as a powerful tool in understanding how intracellular processes in bacteria affect the bacterial phenotype. In this thesis I have implemented and analysed models of a number of different parts of the bacterium E. coli in order to understand these types of connections. I have also developed new tools for analysis of stochastic reaction-diffusion models. Resistance mutations in the E. coli ribosomes make the bacteria less susceptible to treatment with the antibiotic drug erythromycin compared to bacteria carrying wildtype ribosomes. The effect is dependent on efficient drug efflux pumps. In the absence of pumps for erythromycin, there is no difference in growth between wildtype and drug target resistant bacteria. I present a model explaining this unexpected phenotype, and also give the conditions for its occurrence. Stochastic fluctuations in gene expression in bacteria, such as E. coli, result in stochastic fluctuations in biosynthesis pathways. I have characterised the effect of stochastic fluctuations in the parallel biosynthesis pathways of amino acids. I show how the average protein synthesis rate decreases with an increasing number of fluctuating amino acid production pathways. I further show how the cell can remedy this problem by using sensitive feedback control of transcription, and by optimising its expression levels of amino acid biosynthetic enzymes. The pole-to-pole oscillations of the Min-proteins in E. coli are required for accurate mid-cell division. The phenotype of the Min-oscillations is altered in three different mutants: filamentous cells, round cells and cells with changed membrane lipid composition. I have shown that the wildtype and mutant phenotypes can be explained using a stochastic reaction-diffusion model. In E. coli, the transcription elongation rate on the ribosmal RNA operon increases with increasing transcription initiation rate. In addition, the polymerase density varies along the ribosomal RNA operons. I present a DNA sequence dependent model that explains the transcription elongation rate speed-up, and also the density variation along the ribosomal operons. Both phenomena are explained by the RNA polymerase backtracking on the DNA. / Felaktigt tryckt som Digital Comprehensive Summaries of Uppsala Dissertations from the Faculty of Science and Technology 715

stochastic reaction-diffuion kinetics

antibiotic drugs

efflux pumps

amino acid biosynthesis

Min-system

rRNA operon

transcription

Molecular biology

Molekylärbiologi

Caractérisation des ARN régulateurs chez Streptococcus agalactiae / Characterization of regulatory RNAs in Streptococcus agalactiae

Zorgani, Mohamed Amine

07 December 2016

Streptococcus agalactiae, appelé aussi Group B Streptococcus (GBS), est une bactérie commensale du tractus digestif et génital de diverses espèces animales dont l’espèce humaine. Elle représente la première cause d’infections néonatales et est aussi un pathogène émergent chez l’adulte immunodéprimé. L’objectif de ma thèse est la caractérisation fonctionnelle et mécanistique des ARNrég. J’ai étudié plus particulièrement l’ARNrég CetR (pour «cell-envelope-targeting RNA»). Il module la résistance au peptide antimicrobiens (PAM) et la virulence à travers la régulation post-transcriptionnelle de l’ARNm dltD codant une protéine de biosynthèse de l'acide D-alanyl-lipotéichoïque. La délétion de cetR induit des changements dans la morphologie cellulaire, une diminution de la formation du biofilm et de la résistance aux PAM. Une zone d’interaction, CetRdltD, de 27 nucléotides a été prédite in silico. Des mutations compensatoires chez GBS montrent que CetR interagit directement avec l’ARNm dltD et que la perturbation de la zone d’appariement est suffisante pour observer les phénotypes associés à CetR. La quantification des niveaux d’ARNm et de la protéine DltD nous a permis de montrer que CetR active la traduction de dltD et que la perturbation du duplex CetR-dltD induit une diminution spectaculaire de la protéine DltD. De plus, en utilisant un modèle murin d’infection et en quantifiant la survie des bactéries dans les macrophages, nous avons montré que CetR et DltD sont cruciaux pour la virulence de GBS. Enfin, une approche protéomique globale nous a permis de montrer que CetR joue un rôle important dans l’expression des protéines dites « moonlighting » et de certains facteurs de virulence potentiels. Cet ARNrég peut jouer un rôle important dans la capacité de S. agalactiae à s'établir dans son biotope et à exprimer ses facteurs de virulence. Enfin, les résultats de ces recherches sont des prérequis au développement de stratégies permettant de réduire le risque des infections néonatales dues à S. agalactiae. / The opportunistic pathogen group B Streptococcus (GBS) is the leading cause of neonatal infections. The aim of this work is the characterization of a 680 nt-long regulatory RNA, CetR (cell-envelope-targeting RNA). It modulates antimicrobial peptides (AMPs) resistance and virulence through posttranscriptional regulation of dltD mRNA which encodes a D-alanyl-lipoteichoic acid biosynthesis protein. Deletion of cetR leads to cell morphology changes, reduced biofilm formation and AMPs resistance. A 27 nt-long CetR-dltD interacting region is predicted in silico. Compensatory base pair exchanges in GBS demonstrate that CetR interacts directly with dltD mRNA and that disruption of this RNA pairing is sufficient to observe the CetR-associated phenotypes. By quantifying both mRNA and protein, we demonstrate that CetR enhances dltD translation and disruption of the CetR/dltD mRNA interaction results in a dramatic decrease in DltD protein. Moreover, using an infection murine model and quantifying bacterial survival in macrophages, we observe that both CetR and DltD are crucial for GBS virulence. Finally, we highlight CetR pleiotropic role in the expression of several moonlighting proteins and potential virulence factors. This regulatory RNA may play an important role in the ability of GBS to settle in its biotope and express its virulence factors.

ARN régulateurs

Streptococcus agalactiae

Opéron dlt

Virulence

Protéome global

Regulatory RNA

Streptococcus agalactiae

Dlt operon

Virulence

Global proteome

Molecular Determinants of Mutant Phenotypes in the CcdAB Toxin -Antitoxin System

Guptha, Kritika

January 2017

A major challenge in biology is to understand and predict the effect of mutations on protein structure, stability and function. Chapter 1 provides a general introduction on protein sequence-structure relationships and use of the CcdAB toxin-antitoxin system as a model to study molecular determinants of mutant phenotypes. In Chapter 2, we describe the use of saturation mutagenesis combined with deep sequencing to determine phenotypes for 1664 single-site mutants of the E. coli cytotoxin, CcdB. We examined multiple expression levels, effects of multiple chaperones and proteases and employed extensive in vitro characterization to understand how mutations affect these phenotypes. While general substitution preferences are known, eg polar residues preferred at exposed positions and non-polar ones at buried positions, we show that depth from the surface is important and that there are distinctly different energetic penalties for each specific polar, charged and aromatic amino acid introduced at buried positions. We also show that over-expression of ATP independent chaperones can rescue mutant phenotypes. Other studies have primarily looked at effects of ATP dependent chaperone expression on phenotype, where it is not possible to say whether mutational effects on folding kinetics or thermodynamic stability are the primary determinant of altered phenotypes, since there is energy input with these chaperones. The data suggest that mutational effects on folding rather than stability determine the in vivo phenotype of CcdB mutants. This has important implications for efforts to predict phenotypic effects of mutations and in protein design. While looking at the mutational landscape of a given gene from an evolutionary perspective, it is important to establish the genotype-phenotype relationships under physiologically relevant conditions. At the molecular level, the relationship between gene sequence and fitness has implications for understanding both evolutionary processes and functional constraints on the encoded proteins. Chapter 3 describes a methodology to test the fitness of individual CcdB mutants in E.coli over several generations by monitoring the rate of plasmid loss. We also propose a methodology for high throughput analysis of a pool of CcdB mutants using deep sequencing to quantitate the relative population of each mutant in a population of E.coli cells, grown for several generations and build the fitness landscape. While the F-plasmid based CcdAB system is known to be involved in plasmid maintenance through post-segregational killing, recent identification of ccdAB homologs on the chromosome, including in pathogenic strains of E.coli and other bacteria, has led to speculations on their functional role on the chromosome. In Chapter 4, we show that both the native ccd operon of the E.coli O157 strain as well as the ccd operon from the F- plasmid when inserted on the E.coli chromosome lead to protection from cell death under multiple antibiotic stress conditions through formation of persisters. Both the ccdF and ccdO157 operons may share common mechanisms for activation under stress conditions and also display weak cross activation. The chromosomal toxin shows weaker activity as compared to the plasmidic counterpart and is therefore less efficient in causing cell death. This has important implications in generation of potential therapeutics that target these TA systems. Chapter 5 describes the use of site-saturation mutagenesis coupled with deep sequencing to infer mutational sensitivity for the intrinsically disordered antitoxin, CcdA. The data allows us to make comparisons between overall as well as residue specific mutational sensitivity patterns with that of globular proteins, like CcdB (described in Chapter 2) and study toxin- antitoxin interaction and regulation through saturation suppressor mutagenesis. Interestingly, we found several examples of synonymous point mutations in CcdA that lead to loss of its activity. In Chapter 6 we attempt to explore the molecular bases for some of these synonymous mutations. In most cases the mutated codon has a similar overall codon preference to the WT one. Initial findings suggest a change in mRNA structure leading to change in CcdB: CcdA ratio, thereby causing cell death. These observations have important implications, because TA systems are ubiquitous, highly regulated and are known to be involved in multiple functions including drug tolerance. However a role for RNA structure in their regulation has not been shown previously. Appendix–I lists the mutational sensitivity scores for the CcdB mutants. Phenotypes for CcdA mutants obtained through deep sequencing have been tabulated in Appendix-II. Overall, we provide extensive datasets for mutational sensitivities of a globular (CcdB) and an intrinsically disordered protein (CcdA). Exploration of the molecular determinants of these mutant phenotypes not only provides interesting insights into CcdAB operon function but is also useful in understanding various aspects of protein stability, folding and activity as well as regulation of gene expression in bacteria.

CcdAB Toxin-Antitoxin System

CcdB Toxin-Antitoxin System

Mutant Phenotypes

CcdB

Globular Protein

CcdAB Operon

Molecular Biophysics

Leukotoxin gene and activity in animal and human strains of Fusobacterium species

Tadepalli, Sambasivarao

January 1900

Doctor of Philosophy / Department of Diagnostic Medicine/Pathobiology / Tiruvoor G. Nagaraja / George C. Stewart / Fusobacterium necrophorum, a gram negative anaerobe and an opportunistic pathogen, causes necrotic infections in humans and animals. Two subspecies of F. necrophorum, subsp. necrophorum and subsp. funduliforme are described. Leukotoxin (Lkt), a secreted protein encoded by a tricistronic operon (lktBAC), is the major virulence factor of F. necrophorum. The concentration of Lkt produced by subsp. necrophorum is higher than that of subsp. funduliforme. Quantitative-PCR was used to determine the relative expression of lktA by the two subspecies of bovine origin. The mRNA transcript of lktA was detectable in early-log phase of growth in subsp. necrophorum, whereas in subsp. funduliforme, the lktA transcript was detected only in the mid-log phase. Q-PCR analysis revealed that subsp. necrophorum had 20-fold more lktA transcript than subsp. funduliforme. The amount of lktA transcript declined by late-log phase in both subspecies; but lktA mRNA levels in subsp. necrophorum was 8-fold higher than in subsp. funduliforme. Leukotoxin protein stability assays showed the Lkt to be stable in both subspecies despite the decrease in the concentration of the protein during late-log phase. The subspecies identity of human F. necrophorum strains and whether they possess lktA and leukotoxin activity are not known. Human clinical isolates (n = 4) of F. necrophorum were identified as subsp. funduliforme based on 16S rRNA sequence and absence of hemagglutinin gene. Four human strains had the lkt promoter, lktB, and lktC similar to that of subsp. funduliforme. One strain had full length lktA, while other three strains exhibited considerable heterogeneity. All four strains secreted Lkt that was toxic to human leukocytes. Fusobacterium equinum, formerly F. necrophorum, is a newly recognized species. It is associated with infections of the respiratory tract in horses. Little is known about the virulence factors of F. equinum. Southern hybridization revealed that F. equinum strains had lktA gene with greater similarities to F. necrophorum subsp. necrophorum. The toxicity of culture supernatants of isolates to equine leukocytes was variable. Our data indicate that F. equinum isolates possess lktA gene and exhibit leukotoxin activity. The importance of leukotoxin as a virulence factor in human and equine fusobacterial infections needs to be investigated.

Fusobacterium necrophorum

lktA

Human strains

leukotoxin operon

Fusobacterium equinum

differential expression

Biology, Microbiology (0410)

Biology, Veterinary Science (0778)

Elucidating the Roles of Lon Protease and its Substrate, MarA, in Response to salicylate and other Compounds in Escherichia coli

Bhaskarla, Chetana

January 2016

Cytosolic protein degradation is crucial for cellular homeostasis as it orchestrates protein turnover by destruction of misfolded, unstable and abnormal proteins. This process has two main stages: (i) an ATP-dependent stage mediated by unfoldases and proteases, and (ii) an ATP-independent stage mediated by various peptidases. The ATP dependent proteases recognise target proteins and cleave them into smaller peptides. These enzymes comprise the ATPase-family-associated-with-various-cellular-activities domain that is important for unfolding target proteins. Subsequently, unfolded proteins enter a barrel-shaped proteolytic chamber, an architecture conserved throughout prokaryotes, archea and eukaryotes, where the peptide bond is hydrolysed in an ATP-independent manner. The smaller peptides released are broken down by ATP-independent peptidases into free amino acids recycled into the cellular pool. In prokaryotes, major cellular protein degradation functions are performed by Clp and Lon proteases. Earlier studies in our laboratory have shown the role of an ATP-independent peptidase, AminopeptidaseN, in sodium salicylate (NaSal) induced growth inhibition. NaSal belongs to the family of Non-Steroidal Anti-Inflammatory Drugs and its acetyl ester, Aspirin, is a very widely used analgesic. It is produced by plants as a defence response and is known to cause different effects, including xenobiotic stress i. e. stress mediated by compounds which are not naturally produced or expected to be present in the organism in bacteria. In bacteria, salicylate modulates outer membrane proteins, virulence factors, and reduces motility. In addition, NaSal is able induce “phenotypic antibiotic resistance” by binding to MarR and de-repressing the mar operon. NaSal promotes the dissociation of MarR from the promoter site leading to transcription of MarA, a transcription factor that induces several genes that encode the AcrAB-TolC pump which effluxes multiple antibiotics from the cell. The present study investigates the possible roles of ATP-dependent proteases, Lon and Clp, during growth reduction of E. coli induced with high (2-3 mM) amounts of NaSal. The growth of the Lon mutant (lon), but not clpP, was found to be greatly reduced with high doses of NaSal in the media. Our hypothesis was that the lack of Lon led to the accumulation of high amounts of substrate proteins, which led to its greater sensitivity with high doses of NaSal. To identify the substrate protein/s and to better understand the mechanism of action, single and double mutants (with lon) of E. coli lacking several prominent Lon substrates, i.e. MarA, RcsA, StpA, SulA and UmuD, were generated and screened for rescue of growth with 2-3 mM NaSal. MarA, a transcription factor, was identified to be important during NaSal-induced growth reduction. It modulates outer membrane proteins and induces the AcrAB-TolC pump that increases the efflux of antibiotics from the cell. Also, RT-PCR analysis revealed that the levels of marA and its targets, acrA and acrB, were higher in the lon strain suggesting that the MarA protein levels were stabilised the cell in the absence of Lon. Further studies using approriate strains demonstrated that one of the effectors of MarA, i.e. the AcrAB-TolC efflux pump, was not involved in the NaSal-induced growth inhibition of lon. Therefore, in presence of higher doses of NaSal, MarA is upregulated due to de-repression of the operon. The levels of MarA are regulated by Lon via degradation but in the absence of Lon, MarA levels are stabilised and lead to upregulation of MarA and its target genes like AcrAB-TolC. This study identifies higher amounts of MarA to be responsible for NaSal-induced growth inhibition of lon. Subsequently, experiments were conducted to demonstrate the role of MarA and its targets in antibiotic resistance with low dose (0.5 mM) NaSal that does not affect growth. This low dose of NaSal was able to upregulate marA and its target genes, acrA, acrB and tolC. Quantification of antibiotic resistance further revealed an induction in resistance by 0.5 mM NaSal in a MarA- and AcrB-dependent fashion. Studies using atomic force microscopy demonstrated that ciprofloxacin-induced cell elongation was lower in lon due to higher levels of MarA. Therefore, low dose of NaSal is capable of upregulating MarA and inducing antibiotic resistance but does not affect cell growth. This part of the study addresses the roles of Lon protease, its substrate MarA and MarA-induced targets, e.g. AcrB, during NaSal-mediated growth reduction and antibiotic resistance. The factors contributing to antibiotic resistance in bacteria are an important area of study for the global public health care system. Antibiotic resistance can be acquired by transmittance of genetic material, accumulation of antibiotic resistant mutations in the target molecule or can be induced by certain compounds present in the environment like NaSal. For rapid identification of compounds that may behave in a similar fashion as NaSal, a 96-well plate based screen was developed utilising the growth inhibition feature of the lon strain. The compounds were selected on the basis of their structural (phenolic compounds) and functional (Non-Steroidal Anti Inflammatory Drugs or NSAIDs) similarity to NaSal. Through this screen, four compounds were identified that lowered the growth of lon more than that of wild type strain and may be important in inducing phenotypic antibiotic resistance: Acetaminophen (anti-pyretic), Ibuprofen (NSAID), and two phenolic uncouplers, Carbonyl cyanide m-chlorophenyl hydrazone (CCCP) and 2,4-dinitrophenol (2,4-DNP). Notably, another compound Phenylbutazone (NSAID), which is used to lower inflammation in animals, did not reduce the growth of E. coli. RNA expression analysis revealed that these four compounds, but not phenylbutazone, induced the expression of marA and its target gene involved in antibiotic efflux, acrB. Furthermore, dose dependent and comparative studies with Nasal demonstrated differential effects of these four compounds in inducing antibiotic resistance with respect to ciprofloxacin, tetracycline and nalidixic acid. The two uncouplers were much more effective in inducing antibiotic resistance at lower doses than the NSAIDs. As NSAIDs are clinically important compounds, the study suggests that it would be desirable to screen them for induction of antibiotic resistance. The approach elucidated in this study has the potential to identify additional compounds present in the environment that may contribute to antibiotic resistance in bacteria. Overall, this study delineates the roles of Lon protease and its substrate, MarA, during NaSal-mediated responses, involving antibiotic resistance and/or growth reduction in E. coli. In addition, four other compounds were identified that could induce phenotypic antibiotic resistance in E. coli in a MarA-dependent manner. These observations may have implications in the adaptation of bacteria under different environmental conditions.

Escherichia coli

Salicylate Compounds

Lon Protease

Crystolic Protein Degradation

Caseinolytic Proteases

Clp Protease

MarA

marRAB Operon

Sodium Salicylate (NaSal)

Biochemistry

Produção e caracterização de mutantes do operon gum de Xylella fastidiosa. / Production and characterization of gum operon mutants of Xylella fastidiosa cvc strain.

Souza, Leonardo Cesar de Almeida

07 February 2003

A Xylella fastidiosa é uma bactéria gram.negativa, fastidiosa, que vive limitada ao xilema de plantas causando várias doenças de importância econômica como a doença de Pierce em videiras nos Estados Unidos e a Clorose Variegada dos Citros (CVC) no Brasil. A CVC tem afetado severamente a citricultura do estado de São Paulo pondo em risco milhares de empregos e milhões de dólares em geração de divisas. O sequenciamento do genoma de X. fastidiosa revelou genes envolvidos em possíveis mecanismos de patogenicidade dessa bactéria, entre eles um operon possivelmente envolvido na produção de um exopolissacarídeo extracelular denominado goma fastidiana. Supõe.se que esse exopolissacarídeo seja o responsável pela manutenção dos biofilmes bacterianos que causam a oclusão dos vasos xilemáticos levando ao surgimento dos sintomas da CVC. Para estudar esse operon, denominado operon gum, foram construídos vetores para a inativação dos genes gumB, gumD e gumF por duas estratégias: mutagênese por inserção.deleção e mutagênese por troca alélica. A mutagênese por inserção.deleção envolve a integração via recombinação homóloga com uma permuta.de um plasmídeo contendo uma cópia truncada do gene alvo. A mutagênese por troca alélica, por sua vez, envolve duas permutas e se caracteriza pela troca do gene alvo selvagem por uma cópia interrompida por um marcador de seleção. Nenhum mutante gum foi obtido usando.se a estratégia de troca alélica, todavia, mutantes para os genes gumB e gumF foram obtidos com sucesso pela estratégia de mutagênese por inserção.deleção. Nenhum mutante para o gene gumD foi obtido, sugerindo que essa mutação possa ser letal para a célula. A análise de células e colônias desses mutantes crescidos em meio sólido ou em suspensão não mostrou diferenças morfológicas em relação a linhagem selvagem. A inativação dos genes gumB e gumF não influenciou a capacidade de X. fastidiosa se aderir a vidro. Com o uso do gene repórter CAT, que codifica para a enzima clorafenicol acetil transferase a qual confere à bactéria resistência ao antibiótico clorafenicol foi possível verificar que a glicose não influencia na expressão desse operon ao nível de transcrição. Com o uso desse gene reporter, também foi possível identificar uma região transcrita a partir de um promotor não caracterizado, localizada na fita antisenso do operon gum. A comparação do perfil cromatográfico de proteínas solúveis totais dos mutantes e da linhagem selvagem mostrou diferenças significativas nesses pefis, indicando um efeito pleiotrópico dessas mutações. O estudo da função dos genes gumB e gumF na patogenicidade de X. fastidiosa foi impossibilitado por se ter verificado recentemente que a linhagem usada na construção dos mutantes não coloniza a planta eficientemente para a indução de sintomas em citros e tabaco em condições experimentais após inoculação mecânica. / Xylella fastidiosa is a fastidious, xylem restricted, gram.negative bacteria, that causes several economically important diseases as Pierce's disease of grapevine in USA and the Citrus Variegated Chlorosis (CVC) in Brasil. CVC affects severely the São Paulo State citriculture jeopardizing thousands of jobs and millions of dollars of incomes. The genome sequence of X. fastidiosa has revealed several genes possibly involved in the pathogenicity mechanisms of this bacterium, among them, an operon containing nine genes possibly involved in the synthesis of an exopolisaccharide named fastidian gum. This gum is possibly involved in the bacterial biofilm maintenance that causes the xylem occlusion leading to CVC symptoms development. To study this operon, named gum operon, vectors were constructed to inactivate the gumB, gumD and gumF genes by two strategies, insertion.duplication mutagenesis and allelic exchange mutagenesis. The insertion.duplication mutagenesis involves the integration a whole plasmid containing a truncated copy of the target gene by homologous recombination with one crossing over. The allelic exchange mutagenesis involves homologous recombination with two crossing overs that substitutes the wild.type copy of the target gene by a truncated copy interrupted by a selectable marker gene. No gum mutant was obtained using the allelic exchange strategy; however gumB and gumF mutants were obtained by insertion-duplication mutagenesis strategy. GumD mutant was not obtained, suggesting that the mutation in this gene is lethal to the cell. Analysis of cells and colonies of these mutants growing in solid media and in suspension hasn't reveal any morphological difference to the wild.type strain. The disruption of the gumB and gumF genes does not influenced the adhesion capacity of X. fastidiosa to the glass, used as a substrate. Using the reporter gene CAT, wich codes for cloramphenicol acetil transferase enzime confering resistance to cloramphenicol, we verified that glucose has no influence in the expression of this operon at the transcription level. Using this reporter gene, we also identified a transcribed region directed by a non characterized promoter, localized in the antisense strand of the gum operon. A comparison between the soluble protein profile of the mutants and the wild.type strain, obtained by liquid chromatography, showed significative differences, indicating a pleiotropic effect of these mutations. The study of the function of the gumB and gumF genes in the pathogenicity of X. fastidiosa was not concluded because we verified recently that the strainm, used to generate the mutants, do not colonize the plants efficiently to induce symptoms in citrus and tobacco plants after mechanical inoculation.

bactéria fitopatogênica

citrus variegated chlorosis

clorose variegada dos citros

genética microbiana

genoma-sequência

genome-sequences

microbial genetics

mutação

mutation

operon gum

plant pathogenic bacteria

Studies On The Expression Of The bgl Operon Of Escherichia Coli In Stationary Phase

Madan, Ranjna

10 1900

The bgl operon of Escherichia coli, involved in the uptake and utilization of aromatic β-glucosides salicin and arbutin, is maintained in a silent state in the wild type organism by the presence of structural elements in the regulatory region. This operon can be activated by mutations that disrupt these negative elements. The fact that the silent bgl operon is retained without accumulating deleterious mutations seems paradoxical from an evolutionary view point. Although this operon appears to be silent, specific physiological conditions might be able to induce its expression and/or the operon might be carrying out function(s) apart from the utilization of aromatic β-glucosides. The experiments described in this thesis were carried out to test these possibilities. In cultures exposed to prolonged stationary phase, majority of the bacterial population dies and a few mutants that have the ability to scavenge the nutrients released by the dying cell mass survive. Bgl+ mutants were found to be enriched in twenty-eight-day-old Luria Broth grown cultures of E. coli that are wild type for bgl but carry the rpoS819 allele. Out of the five Bgl+ mutants that were isolated, four carried a mutation in the hns locus while one of them, ZK819-97, had an activating mutation linked to the bgl operon. Further analysis of ZK819-97 by DNA sequencing revealed the existence of a single C to T transition at the CAP binding site in the regulatory region. ZK819-97 was chosen for further analysis. Competition assays were carried out in which Bgl+ strain, ZK819-97 (Strr), and the parental Bgl- strain, ZK820 (Nalr), were grown independently for twenty-four hours in Luria Broth and then mixed in 1:1,000 (v/v) ratio reciprocally, without addition of fresh nutrients. ZK819-97, when present in minority, was found to increase in number and take over the parental strain, ZK820, i.e. ZK819-97 showed a Growth Advantage in Stationary Phase phenotype. To determine whether the GASP phenotype of ZK819-97 is associated with the bgl locus, the bgl allele from this strain was transferred by P1 transduction to its parental strain, ZK819. The resulting strain, ZK819-97T (Bgl+, Tetr), when competed with the parental strain, ZK819 Tn5 (Bgl-, Kanr), also showed a GASP phenotype when present in minority in the mixed cultures. To reconfirm this further, the bgl locus was deleted from ZK819-97T. The resulting strain, ZK819-97Δbgl, showed a loss of the GASP phenotype. When the bglB locus was disrupted in ZK819-97T, the resulting strain, ZK819-97ΔB, also failed to show a GASP phenotype, indicating that the phospho-β-glucosidase B activity is essential for this phenotype. The strain, ZK819-IS1, carrying an activating IS1 insertion within the bgl regulatory region also showed a GASP phenotype, confirming that this phenotype of the Bgl+ strain is independent of the nature of the activating mutation. All the above mentioned strains used in the competition assays carry a mutant allele of rpoS, rpoS819. Introduction of the wild type rpoS allele in these strains resulted in the loss of the GASP phenotype of the Bgl+ strain, suggesting that the two mutations work in a concerted manner. The Bgl+ strain was found to show the GASP phenotype only when present in minority of 1:1,000 or 1:10,000 in the mixed cultures and showed a slight disadvantage at higher ratios, indicating that the GASP phenotype of the Bgl+ strain is a frequency dependent phenomenon. In competition assays carried out between 24-hour-old cultures of Bgl+ and Bgl- strains resuspended in five-day-old spent medium prepared from a wild type E. coli strain, Bgl+ strain did not show any extra or early GASP phenotype. In addition, a reporter strain, which has a lacZ transcriptional fusion with the activated bgl promoter, was resuspended in spent medium prepared from a five-day-old culture of wild type strain of E. coli and bgl promoter activity was measured by β-galactosidase assay. The bgl promoter did not show any induction in this medium. These experiments suggest the absence of any β-glucoside like molecules in the spent medium within the sensitivity of these assays. A reporter strain that has a lacZ transcriptional fusion to the wild type bgl promoter was used to measure the expression level of this promoter during exponential and stationary phase of growth in LB. Expression of the wild type as well as various activated promoters of bgl was found to be enhanced in stationary phase. To investigate a possible role of the rpoS encoded stationary phase specific sigma factor, RpoS (σs), and another stationary phase factor, Crl, known to be important for the regulation of many genes of the σs regulon, the bgl promoter activity measurements were carried out in the presence or the absence of RpoS and/or Crl. RpoS along with Crl was found to negatively regulate the expression of wild type as well as activated promoters of bgl, both in exponential and stationary phase. In the absence of the negative regulation by RpoS and Crl, the increase in the bgl promoter activity was more pronounced as compared to that in its presence. rpoS and crl mutations are common in nature and it has been suggested that crl deletion gives a growth advantage to the strain in stationary phase. To test this possibility crl deletion was created in wild type as well as in attenuated rpoS allele background. The strain carrying the crl deletion was found to have a growth advantage in stationary phase over the wild type strain in the presence of wild type rpoS allele, while it shows a slight disadvantage in combination with mutant rpoS. Over expression of LeuO or BglJ is known to activate the bgl operon. To study a possible role of these factors in the regulation of the bgl expression in stationary phase, the bgl promoter activity was measured in strains that were deleted for leuO and/or bglJ, in the absence or presence of crl. These studies indicated that BglJ had a moderate effect on the bgl promoter activity in stationary phase in the absence of Crl but not in its presence. LeuO did not have a significant effect on the bgl promoter activity in either condition. Thus under the conditions tested, the physiological increase in the levels of LeuO and BglJ in stationary phase was insufficient to regulate the bgl expression. Preliminary results show that the bgl operon might be involved in the regulation of oppA, an oligopeptide transporter subunit, in stationary phase. Implications of these findings are discussed. The studies reported in this thesis highlight the involvement of the bgl operon of E. coli in stationary phase. This could be mediated by genetic as well as physiological mechanisms. This study also underscores the importance of observing organisms closer to their natural context and the need to reconsider the concept of ‘cryptic genes’.

Chromosomes

Escherechia Coli

Bacterial Gene Expression

bgl Operon

Bacterial Genomes

Cryptic Genes

Bacterial Evolution

Bacterial Growth

BglG-BglF

E. coli - Stationary Phase

Biochemical Genetics