Functional characterization of a bacteriophage-encoded inhibitor of Staphylococcus aureus transcription

Montero Diez, Cristina

18 October 2013

Functional characterization of a bacteriophage-encoded inhibitor of Staphylococcus aureus transcription

Microbiology

Anti-sigma

Bacteriophage

Transcription

Účast alternativních sigma faktorů RNA polymerasy při regulaci exprese genů Corynebacterium glutamicum / The role of alternative sigma factors of RNA polymerase in regulation of gene expression in Corynebacterium glutamicum

Šilar, Radoslav

January 2016

Abstract Regulation of transcription by extracytoplasmic-function (ECF) sigma factors of RNA polymerase is an efficient way of cell adaptation to diverse environmental stresses. Amino acid-producing gram-positive bacterium Corynebacterium glutamicum codes for seven sigma factors: the primary sigma factor SigA, the primary-like sigma factor SigB and five ECF stress- responsive sigma factors (SigC, SigD, SigE, SigH and SigM). The sigH gene encoding SigH sigma factor is located in a gene cluster together with the rshA gene, encoding the anti-sigma factor of SigH. Anti-sigma factors bind to their cognate sigma factors and inhibit their transcriptional activity. Under the stress conditions the binding is released allowing the sigma factors to bind to the RNAP core enzyme. In this thesis, regulation of expression of genes encoding the most important ECF sigma factor SigH and its anti-sigma factor RshA as well as genes belonging to the SigH-regulon were mainly studied. The transcriptional analysis of the sigH-rshA operon revealed four housekeeping promoters of the sigH gene and one SigH-dependent promoter of the rshA gene. For testing the role of the complex SigH-RshA in gene expression, the C. glutamicum ΔrshA strain was used for genome-wide transcription profiling with DNA Microarrays technique under...

Mechanism Of Interaction Of Escherichia Coli σ70 With Anti-Sigma Factors

Sharma, Umender K

07 1900

In bacteria, the RNA polymerase (RNAP) consists of the following subunits: α2, β, β’, ω and σ. The core RNAP (α2ββ’ω) possesses the polymerising activity and it associates with one of the sigma factors to initiate transcription from a promoter region on the DNA template. All bacteria carry an essential housekeeping sigma factor and a number of extra cytoplasmic function (ECF) sigma factors. During alternate physiological states, a major part of transcriptional regulation is carried out by sigma factors, which act as transcriptional switches, thus, making it possible for bacteria to adapt to varied environmental signals by transcribing the necessary set of genes. Bacteriophages utilise various mechanisms for subverting the bacterial biochemical machinery for their advantage. One such example in E. coli is AsiA protein encoded by an early gene of T4 bacteriophage. Because of its property of binding to σ70, AsiA can inhibit transcription from E. coli promoters bearing –10 and –35 DNA sequences leading to inhibition of growth. σ70 of E. coli is also regulated by a stationary phase specific protein, Rsd, whose major function seems to be helping the cell in switching the transcription in favour of stationary phase genes. In this study we have investigated the mechanism of interaction of T4 AsiA and E. coli Rsd to σ70 of E. coli and also tried to determine the basis of differential inhibition of E. coli growth by AsiA and Rsd. In chapter one we have reviewed the published literature on regulation of transcription in bacteria. Some of the well known mechanisms of regulating gene expression are: DNA supercoiling, two component signal transduction system (TCS), regulation by alarmone ppGpp and 6S RNA, and sigma-antisigma interactions. Most bacteria carry a number of sigma factors and each of them is dedicated to transcribing genes in response to environmental signals. Intracellular levels of sigma factors and their binding affinity to core RNAP are deciding factors for initiating transcription from specific subsets of genes. In addition, sigma factor activity is also controlled by specific proteins, which bind to sigma factors (anti-sigma factors) under certain environmental conditions. A number of anti-sigma factors have been isolated from a variety of bacteria and the mechanisms of action of binding to cognate sigma factors have been worked out by using genetic, biochemical and structural tools. In chapter two, using yeast two hybrid assay (YTH), we have identified the regions of σ70 which interact with AsiA, and it was observed that amino acid residues from 547-603, encompassing region 4.1 and 4.2 are involved in binding to σ70. Interestingly, we found that truncated σ70 fragments lacking the N-terminal regions, apparently bound to AsiA with higher affinity compared to full length σ70. As AsiA expression, because of its transcription inhibitory activity, is inhibitory to E.coli growth, co-expression of the truncated C-terminal σ70 fragments (e.g. residues 493-613, σ70C121), which bind to σ70 with high affinity, could relieve growth inhibition. The complex of GST:AsiA-σ70C121 could be purified from E. coli cells. GST:AsiA purified from E .coli cells was found to be associated with RNAP subunits. Since further studies on this interaction required GST:AsiA preparation devoid of RNAP subunits, we decided to express this protein in S. cerevisiae. Bioinformatics analysis indicated the absence of a σ70 homologue in S.cerevisiae. As expected, GST:AsiA purified from the yeast was found to be free from any RNAP like proteins. The protein purified from yeast was used for in-vitro binding experiments. Our YTH analysis had indicated that deletion a part of region 4.1 or 4.2 of σ70 leads to loss of binding to AsiA. However, the published NMR structure of AsiA in complex with peptides corresponding to region 4 of σ70, showed that either region 4.1 or 4.2 alone can bind to AsiA indicating at the possible existence of two binding sites for AsiA. In order to confirm the physiological significance of this finding, we studied the interaction of truncated σ70 fragments lacking either region 4.1 or 4.2 with AsiA in-vivo in E. coli and in-vitro by affinity pull down assays. It was observed that σ70 fragments lacking either region 4.1 (σ70∆4.1) or 4.2 (σ70∆4.2), did not neutralize the GST:AsiA toxicity, indicating lack of interaction. The affinity purified GST:AsiA from these E. coli cells did not have σ70∆4.1 or σ70∆4.2 associated with it. Similar results were obtained from pull down assays in-vitro, where we found that σ70∆4.1 or σ70∆4.2 do not show any observable interaction with AsiA. This clearly established that the minimum region of σ70 required for physiologically relevant interaction with AsiA consists of both the regions 4.1 and 4.2. Chapter 3 of this thesis has been devoted to this aspect of AsiA-σ70 interaction. Having defined the minimum region of σ70 interacting with AsiA, we sought to identify the regions and amino acid residues of AsiA, which are critical for interaction with σ70. The approach for identification of mutants and their characterisation has been discussed in chapter 4. For this purpose, we made systematic deletions in the N and C-terminal regions of the protein and also isolated random mutants of AsiA, which lack binding to σ70 and thus are non-inhibitory to E. coli growth. It was found that deletion of 5 amino acids from N-terminus and 17 amino acids from C-terminus did not alter the inhibitory activity of AsiA. In contrast, deletion of N-terminal 10 amino residues led to complete loss of activity, while in the C-terminus, a gradual loss of activity was observed when amino acid residues beyond 17 amino acids were deleted. A 34 amino acids C-terminal deletion mutant was found to be completely inactive. E10K mutant was found to be inactive, but changes of E to other amino acids such as S, Y, L, A and Q were tolerated, indicating that negative charge at E10 is not a crucial element for interaction with σ70. Inactive mutants could be overexpressed in E. coli and showed reduced binding in YTH assay and were also poor inhibitors of in-vivo transcription in E. coli. We concluded that the primary σ70 binding site of AsiA is present in the N-terminus, yet C-terminal 64-73 amino acid residues are required for effective binding in-vivo. These studies also correlate the inhibitory potential of AsiA with its σ70 binding proficiency. In chapter 5, we have made a comparative analysis of mechanism of interaction of AsiA and Rsd to E. coli RNAP. Overexpression of Rsd was found to be less inhibitory to E. coli cell growth than that of AsiA. The affinity purified GST-AsiA from E. coli was found to have all the RNAP subunits associated with it, whereas, only σ70 was found to be associated with similarly purified GST:Rsd, pointing towards differences in binding to RNAP. In affinity pull down assays, in-vitro, it was found that both AsiA and Rsd do not show any observable binding to core RNAP. Binding of AsiA to σ70 in holo RNAP led to the formation of a ternary complex, whereas no ternary complex was observed when Rsd was made to interact with holo RNAP. Analysis of protein-protein interaction by YTH showed that region 4.1 and 4.2 are critical for binding of both AsiA and Rsd to σ70. However, in the case of Rsd, the surface of interaction is not limited to this region only and other regions of σ70 make significant contribution to this binding. Possibly, the interaction of Rsd with the core binding regions of σ70 prevents its association with core RNAP. Kinetic analysis of binding by surface plasmon resonance (SPR) showed that binding affinities (Kd) of AsiA and Rsd to σ70 are in similar range. Therefore, we concluded that the ability of AsiA to trap the holo RNAP is, probably, responsible for higher inhibitory activity of this protein compared to that of Rsd. Thus, T4 AsiA and E. coli Rsd, which share regions of interaction on σ70, have evolved differences in their mechanism of binding to RNAP such that T4 AsiA, by trapping the holo RNAP subverts the complete bacterial transcription machinery to transcribe its own genes. Rsd, on the other hand, has evolved to interact primarily with σ70, which favours the utilisation of core RNAP by other sigma factors.

Cytoplasmic Factor

Escherichia coli Cytoplasmic Factor

Transciption Regulation

Bacterial RNA Polymerase (RNAP)

Gene Expression

Bacterial Mutants

Bacteriophages - Genes

Bacteriophage T4

T4 AsiA

Anti-Sigma Factors

Escherichia coli σ70

Sigma(70)

Sigma 70

Rsd

Biochemical Genetics

Understanding the Regulatory Steps that Govern the Activation of Mycobacterium Tuberculosis σK

Shukla, Jinal K

January 2013

A distinctive feature of host-pathogen interactions in the case of Mycobacterium tuberculosis is the asymptomatic latent phase of infection. The ability of the bacillus to survive for extended periods of time in the host suggests an adaptive mechanism in M. tuberculosis that can cope with a variety of environmental stresses and other host stimuli. Extensive genomic studies and analysis of knock-out phenotypes revealed elaborate cellular machinery in M. tuberculosis that ensures a rapid cellular response to host stimuli. Prominent amongst these are two-component systems and σ factors that exclusively govern transcription re-engineering in response to environmental stimuli. M. tuberculosis σK is a σ factor that was demonstrated to control the expression of secreted antigenic proteins. The study reported in this thesis was geared to understand the molecular basis for σK activity as well as to explore conditions that would regulate σK activity. Transcription in bacteria is driven by the RNA polymerase enzyme that can associate with multiple σ factors. σ factors confer promoter specificity and thus directly control the expression of genes. The association of different σ factors with the RNA polymerase is essential for the temporal and conditional re-engineering of the expression profile. Environment induced changes in expression rely on a subset of σ factors. This class of σ factors (also referred to as Class IV or Extra-cytoplasmic function (ECF) σ factors) is regulated by a variety of mechanisms. The regulation of an ECF σ factor activity at the transcriptional, translational or posttranslational steps ensures fidelity in the cellular concentration of free, active ECF σ factors. In general, ECF σ factors associate with an inhibitory protein referred to as an anti-σ factor. The release of a free, active σ factor from a σ /anti-σ complex is thus a mechanism that can potentially control the cellular levels of an active σ factor in the cell. M. tuberculosis σK is associated with a membrane bound anti-σK (also referred to as RskA) (Said-Salim et al., Molecular Microbiology 62: 1251-1263: 2006). The extracellular stimulus that is recognized by RskA remains unclear. However, recent studies have suggested the possibility of a regulated proteolytic cascade that can selectively degrade RskA and other membrane associated anti-σ factors. The goal of the study was to understand this regulatory mechanism with a specific focus on the M. tuberculosis σK/RskA complex. The structure of the cytosolic σK/RskA complex and the associated biochemical and biophysical characteristics revealed several features of this /anti-σ complex that were hitherto unclear. In particular, these studies revealed a redox sensitive regulatory mechanism in addition to a regulated proteolytic cascade. These features and an analysis of the M. tuberculosis σK/RskA complex vis-à-vis the other characterized σ/anti σfactor complexes are presented in this thesis. This thesis is organized as follows- Chapter 1 provides an overview of prokaryotic transcription. A brief description of the physiology of M. tuberculosis is presented along with a summary of characterized factors that contribute to the pathogenecity and virulence of this bacillus. The pertinent mechanistic issues of σ/anti-σ factor interactions are placed in the context of environment mediated changes in M. tuberculosis transcription. A summary of studies in this area provides a background of the research leading to this thesis. Chapters 2 and 3 of this thesis describe the structural and mechanistic studies on the σK/RskA complex. The crystal structure of the σK/RskA complex revealed a disulfide bond in domain 4 (σK4). σK4 interacts with the -35 element of the promoter DNA. The disulfide forming cysteines were seen to be conserved in more than 70% of σK homologs, across both gram-positive and gram-negative bacteria. The conservation of the disulfide-forming cysteines led us to further characterize the role of this disulfide in σK/RskA interactions. These were examined by several biochemical and biophysical experiments. The redox potential of these disulfide bond forming cysteine residues were consistent with the proposed role of a sensor. The crystal structure and biochemical studies thus suggest that M. tuberculosis σK is activated under reducing conditions. Chapter 4 of this thesis describes the progress made thus far in the structural and biochemical characterization of an intra-membrane protease, M. tuberculosis Rip1 (Rv2869c). This protein is an essential component of the proteolytic cascade that selectively cleaves RskA. The proteolytic steps that govern the selective degradation of an anti-σ factor were first characterized in the case of E. coli σE (Li, X. et al. Proc. Natl. Acad. Sci. USA, 106:14837-14842, 2009). This cascade is triggered by the concerted action of a secreted protease (also referred to as a site-1 protease) and a trans-membrane protease (also referred to as a site-2 protease). M. tuberculosis Rip1 was demonstrated to be bona-fide site 2 protease that acts on three anti-σ factors viz., RskA, RslA and RsmA (Sklar et al., Molecular Microbiology 77:605-617; 2010). To further characterize the role of Rip1 in the proteolytic cascade, this intra-membrane protease was cloned, expressed and purified for structural, biochemical and biophysical analysis. The preliminary data on this membrane protein is described in this chapter. The conclusions from the studies reported in this thesis and the scope for future work in this area is described in Chapter 5. Put together, the σK/RskA complex revealed facets of σ/anti-σ factor interactions that were hitherto unrecognized. The most prominent amongst these is the finding that an ECF σfactor can respond to multiple environmental stimuli. Furthermore, as seen in the case of the σK/RskA complex, the σ factor can itself serve as a receptor for redox stimuli. Although speculative, a hypothesis that needs further study is whether these features of the σK/RskA complex contribute to the variable efficacy of the M. bovis BCG vaccine. In this context it is worth noting that σK governs the expression of the prominent secreted antigens- MPT70 and MPT83. The studies reported in this thesis thus suggest several avenues for future research to understand mycobacterial diversity, immunogenicity and features of host-pathogen interactions. The appendix section is divided into two subparts- Appendix 1 of the thesis is a review on peptidase V. This is a chapter in The Handbook of Proteolytic enzymes (Elsevier Press, ISBN:9780123822192). Appendix 2 of the thesis includes technical details and an extended materials and methods section.

Mycobacterium Tuberculosis

Mycobacterim Tuberculosis σK Activation

σK Factors

Anti σK Factor RsKA

Mycobacterium Tuberculosis σK Factor

Site-2 Protease (Rip1)

Disulfide Forming Cysteines σK

σK/RsKA Complex

Extra-cytoplasmic Function σ Factor

σ/anti-σ Factor Protein Complexes

Mycobacterium tuberculosis SigK

Bacteriology