Biochemical, Biophysical and Evolutionary Perspectives of Zinc Finger Proteins in Mycobacterium smegmatis

Ghosh, Subho

January 2017

Transcription is a major step in expression of genes of a given organism. Due to environmental constrains this step must be regulated in the favour of the sustenance and growth of the organism. Here comes the relevance of transcription factors, mostly proteins which regulate transcription. One such important group of transcription factors is the zinc finger proteins. It is well known that in eukaryotes the C2H2 zinc finger domain containing proteins are the largest group of transcription factors while in prokaryotes the largest group of transcription factors are represented by helix-turn-helix motif containing proteins. Till now only two C2H2 zinc finger domain proteins-Ros and Muc have been found in alpha proteobacteria which are also transcription factors. In eukaryotes the second largest group of zinc finger proteins have their zinc ion coordinated by four cysteine residues- the C4 zinc finger proteins. They make the nuclear hormone receptor superfamily of proteins. They have also been shown to act as transcription factors. But in eubacteria no such proteins have been described in details except an isolated report of crystal structure of a C-terminal zinc finger domain protein- Jann_2411 from Jannaschia sp. Though a lot of transcription factors have been described in mechanistic details in Escherichia coli and Bacillus subtilis, the list of well described mycobacterial transcription factors is short. Given this fact and the lack of any known zinc finger domain transcription factor in actinobacteria we wanted to see whether M. smegmatis genome also encode any homologue of Jann_2411 and if does whether they have ability to modulate transcription. To meet our aim we did BLASTP search against the genome of M. smegmatis using Jann_2411 as query. We found four C-terminal zinc finger domain proteins –Msmeg_0118. Msmeg_3613, Msmeg_3408 and Msmeg_1531, which we named as Mycobacterial single zinc finger protein (Mszfp) and numbered- Mszfp1, Mszfp2, Mszfp3 and Mszfp4, respectively. Mszfp1 and Mszfp2 were chosen for study as they were the top most hits. In this thesis:- Chapter1 introduces zinc finger proteins, transcription and several levels of control of transcription process in eubacteria. In chapter2 we characterised Mszfp1 biophysically and probed its secondary structure content and oligomeric state in the native and demetallated conditions. We have also shown that this conserved hypothetical protein is expressed throughout the growth phase of M. smegmatis, regulated by SigA and SigB. We have also showed that Mszfp1 is a DNA binding protein in the native state and the demetallated protein has altered DNA binding ability. It was noted that on over expression Mszfp1 affects colony morphology and biofilm forming ability, of M. smegmatis. In chapter3 the ability of Mszfp1 to bind to RNA polymerase of M. smegmatis has been explored. It was found that Mszfp1 can activate transcription by interacting with CTD/NTD of α subunit and domain 4 of σA like CRP on type II CRP activated promoter. In chapter4 similar to Mszfp1 the biophysical study of Mszfp2 has been carried out. It was found that Mszfp2 is also a predominantly alpha helical protein with oligomeric structure having DNA binding ability. Similar to Mszfp1 Mszfp2 on over expression changes the colony morphology. Chapter5 deals with the RNA polymerase binding ability of Mszfp2 and its ability to activate transcription by interacting with CTD/NTD of α subunit but not the σA. In chapter6 we have presented a glimpse of the possible biophysical properties of Mszfp3 and Mszfp4 and given a snapshot of distribution of homologues of Mszfps among other actinobacteria. We have also put forward a hypothesis about the origin of C4 and CCHC zinc finger domains. Chapter7 is the summary of the work embedded in the earlier chapters. In Appendix I is described the making of a bacteria (Bacillus licheniformis) driven heat engine. Appendix II describes an effort to study the visco-elastic properties of Mycobacterium smegmatis cells.

RNA Polymerase (RNAP)

Mszfp2

Mycobacteria

Mycobacterium Smegmatis

Zinc Finger Protein

Mszfp1

Molecular Biophysics

Mechanism Of Activation Of Bacteriophage Mu Late Genes By Transcription Activator Protein C

Swapna, Ganduri

12 1900

Initiation of transcription is a major step in the regulation of gene expression. A dominant theme in regulation of gene expression lies in understanding the mechanism involved in selective expression of the genes in response to external or internal stimuli. Gene regulatory proteins bind DNA at specific sites either cognate to the promoters they act upon or at a distance, thereby exerting their effect by turning on (activation) or turning off (repression) the genes. Response of these factors to the environmental signals is further achieved by the DNA binding affinity of the transcription factors that can be modulated by small ligands, concentrations of which may fluctuate in response to nutrient availability and stress. Bacteriophages achieve a high degree of efficiency in gene expression by evolving elegant strategies of transcriptional control. mom gene of enterobacteriophage Mu serves as an excellent model to understand this elaborate regulation of gene expression. The gene encodes a unique DNA modification function that confers an anti-restriction phenotype to the phage genome. Though dispensable for phage growth, it is fascinating in two respects (i) a novel modification; (ii) regulation follows a complex scheme without precedence in prokaryotes. mom is the last gene to be expressed during the phage lytic life cycle. Premature expression of the gene is deleterious to both host and phage and hence it is under a complex regulatory network. Dam methylase, a host encoded protein acts as a positive regulator of gene expression, an example where methylation has been shown to play a positive role in regulating tranascription. OxyR, another host encoded protein negatively regulates mom gene expression. Dam methylation prevents the binding OxyR to its site located in the mom regulatory region. The regulatory interplay also involves two phage encoded proteins. C, a middle gene product is essential for transcriptional switch from middle to late genes and Com, a late gene product, for enhancing translation of mom mRNA. Thus, C and Com serve as transcriptional and translational activators of mom gene expression. Pmom is a weak promoter with both -10 and -35 elements away from consensus and a sub-optimal 19 bp spacer element encompassing a stretch of 6T residues that act as negative elements. ‘T stretch’ is known to induce a kink in the DNA. The sub-optimal spacer region makes the promoter elements out of phase and RNAP by itself cannot bind at mom promoter. C protein exerts its effect in activation in a multistep mechanism. The protein binds DNA as a dimer overlapping the promoter and unwinds the DNA, realigning the promoter elements, thus recruiting the RNAP. In the next step, it enhances the promoter clearance by the enzyme, thus enhancing the rate of productive transcription. With this prevailing knowledge on C mediated mom gene expression, the present thesis work describes the experiments carried out to further understand the molecular mechanism of second step activation at Pmom. Genetic and biochemical analysis were carried out to identify the interacting surface of C protein on RNAP. Subsequently, studies have been extended to understand the C mediated transactivation at other late promoters- lys, I, P, which encode for the lysis and morphogenetic functions of the phage. Finally, Mg2+ coordinating residues in C protein were identified to decipher the ligand induced conformational changes in the activator protein required for its transactivator function. Chapter I, a general introduction to the thesis, deals with the detailed discussion on gene expression and its regulatory mechanisms. RNA polymerase (RNAP) being the central molecule of gene expression (transcription) its organization and assembly are discussed. With the availability of the high resolution crystal structures of bacterial RNAP, an in-depth review on RNAP structure in terms of its potential regulatory targets, conformational changes associated with the formation of a functional holoenzyme, and during its transition from initiation to elongation processes have been described. Regulation of transcription with an emphasis on activation mechanism, ligand mediated allosteric transitions in regulatory proteins and the polymerase-activator interactions are discussed citing a few examples. The chapter concludes by introducing bacteriophage Mu and mom gene and its regulation by C. The objectives of the thesis form the concluding section of the chapter. Activators are capable of resurrecting defective promoters in response to cellular demands. The unusual, multistep activation of mom promoter (Pmom) by C protein involves activator mediated promoter unwinding to recruit RNA Polymerase (RNAP) and subsequent enhanced promoter clearance of the enzyme. The first step of transactivation is an interaction independent step, while the later might involve a transient interaction between C and one of the subunits of RNAP. Previous studies pointed out β′ subunit to be the most probable interaction partner. Chapter II comprises the genetic and biochemical studies carried out to confirm this observation. Employing a genetic screen mutations in rpoC gene (encoding the β′ subunit of RNAP), were isolated which result in the defective RNAP. The mutant RNAPs were assayed for their C specific activity by in vivo transactivation assays. Such mutants have been purified and characterized to understand their effect at different steps of C mediated mom gene expression during transcription initiation. The mutant RNAP had normal transcription activity with typical σ70 promoters but exhibited reduced productive transcription and enhanced abortive initiation on C-dependent Pmom. Experiments carried out to probe the interaction between C and mutant RNAP revealed that the physical interaction per se is not disrupted between the two proteins. Post C-mediated recruitment of RNAP to the promoter, transient interactions between the two proteins appears to induce subtle conformational changes in RNAP leading to an enhanced promoter clearance. Transactiavtor protein C is essential for the expression of other late genes lys, I, P apart from mom during the phage life cycle. Although the mechanism of multistep activation at Pmom has been elucidated, little is known on the transactivation from lys, I and P promoters. Chapter III includes studies carried out to understand the process of activation at these promoters. Owing to the differences in their C-binding site and promoter architecture it was important to investigate the differential effect of C, if any at lys, I , P promoters compared to that at Pmom. Activators in prokaryotes are shown to stimulate different steps of transcription initiation pathway ranging from the polymerase binding to the promoters to the post recruitment steps of isomerization and promoter clearance. Effect of C at different steps of transcription initiation pathway was analysed. The results indicate that C is absolutely essential for transcription from lys, I and P promoters similar to mom. However, at these promoters C exerts its effect at the step of Isomerisation from closed complex to open complex formation. Thus, C acts at a single step here and the mode of activation is different from that observed at Pmom. C dimer binds DNA with high affinity and sequence specificity, to an interrupted palindromic sequence overlapping the -35 element of mom promoter. Mg2+ mediated conformational transitions in C protein are essential for its DNA binding and transactivation functions. Chapter IV deals with the identification of the Mg2+ coordinating residues in C protein. Primary sequence analyses lead to the identification of a putative metal coordinating motif (EXDXD) towards the N-terminus of the protein. These residues were subjected to site directed mutagenesis to infer their role in Mg2+ coordination, its associated allosteric transition required for specific interaction with DNA. Mutants showed an altered Mg2+ induced conformation, compromised DNA binding and reduced levels of transcription activation when compared to C protein. Though Mg2+ is widely used in various DNA transaction reactions, this study provides the first insights on the importance of metal-ion induced allosteric transitions in regulating transcription factor function.

Bacteriophages - Genes

Protein C

Gene Transcription

RNA Polymerase (RNAP)

Bacteriophage Mu

Biochemistry

Transcription Initiation and its Regulation in Mycobacterium Tuberculosis

Tare, Priyanka

January 2014

The ability to fine-tune gene-expression in the adverse conditions during pre and post infectious stages has contributed in no small measure to the success of Mycobacterium tuberculosis as the deadly pathogen. Multiple sigma factors, transcription regulators, and diverse two component systemshave facilitated tailoring the metabolic pathways to meet the challenges faced by the pathogen. Over the last decade, studies have been initiated to understand the various facets of transcription in mycobacteria. Although not as extensive as the work in other model systems, such as Escherichia coli and eukaryotes, it is evident from these initial studies that the machinery is conserved,yetmany aspects of transcription and its regulation seem to be different in mycobacteria.The work presented in the thesis deals with some of the steps in the process, primarily initiation in the context of the distinct physiology of M. tuberculosis. The detailed kinetic and equilibrium study of a few selected promoters of M. tuberculosis viz.PgyrB1, PgyrR, PrrnPCL1 and PmetU is described in Chapter 2.Different stages of transcription initiation that have been analyzed include promoter specific binding of RNAP, isomerization, abortive initiation and promoter clearance.The equilibrium binding and kinetic studies of various steps reveal distinct rate limiting events for each of the promoter, which also differed markedly in their characteristics from the respective promoters of Mycobacterium smegmatis. In addition, a novel aspect of the transcription initiation at the gyr promoter was unraveled. The marked differences in the transcription initiation pathway seen with rrn and gyr promoters of M. smegmatis and M. tuberculosis suggest that such species specific differences in the regulation of expression of the crucial housekeeping genes could be one of the key determinants contributing to the differences in growth rate and lifestyle of the two organisms. In Chapter 3, the mechanism of growth phase dependent control (GPDC) at a few of the M. tuberculosis promoters has been investigated. The experiments described in the chapter are carried out to demonstrate a different pattern of interaction between the promoters and sigma A (SigA) of M. tuberculosis to facilitate the iNTPs and pppGpp mediated regulation. Instead of cytosine and methionine, thymine at three nucleotides downstream to -10 element and leucine232 in SigA are found to be essential for iNTPs and pppGpp mediated response at the rrn and gyr promoters of the organism. The specificity of the interaction is substantiated by mutational replacements, either in the discriminator or in SigA, which abolish the nucleotide mediated regulation in vitro or in vivo. In chapter 4, the long standing hypothesis that deals with interdependence of the transcription elongation kinetics and the growth rates has been addressed. Previous studies suggest that the rate of synthesis of the key molecules in cells affects the growth kinetics. In order to validate, the kinetics of elongation of RNAPs from M. tuberculosis, M. smegmatis and E. coli whose growth rates vary from very slow to fast is measured. Surface Plasmon Resonance (SPR) is used to monitor the transcription in real time and kinetic equations are applied to calculate the elongation rates. Further, the effects of the composition of the template DNA on the elongation rates of RNAP from E. coli and M. smegmatis, whose genomes show difference in the GC content are explored. The results obtained from the analysis support the hypothesis and also reveal the effect of template composition on elongation rates of RNAP.

Mycobacterium Tuberculosis

Mycobacterial Transcription

Mycobacterium Tuberculosis Promoters

Mycobacterial RNA Polymerase (RNAP)

Mycobacterial Transcription Initiation

Mycobacterial Transciption Machinery

Transcription in Mycobacteria

Genetic Transcription

RNA Polymerase (RNAP)

Bacteriology

Mechanism Of mom Gene Transactivation By Transcription Factor C Of Phage MU

Chakraborty, Atanu

05 1900

Regulation of transcription initiation is the major determining event employed by the cell to control gene expression and subsequent cellular processes. The weak promoters, with low basal transcription activities, are activated by activators. Bacteriophage Mu mom gene, which encodes a unique DNA modification function, is detrimental to cell when expressed early or in large quantities. Mu has designed a complex, well-controlled and orchestrated regulatory network for mom expression to ensure its synthesis only in late lytic cycle. The phage encoded transcription activator protein C activates the gene by promoter unwinding of the DNA and thereby recruiting of RNAP to the promoter. C protein functions as a dimer for DNA binding and transcription activation. Mutagenesis and chemical crosslinking studies revealed that the leucine zipper motif, and not the coiled coil motif in the N terminal region, is responsible for C dimerization. The DNA binding domain of C is a HTH domain which is preceded by the leucine zipper motif. The C protein is one of the few examples in the bacterial proteins containing both leucine zipper and HTH domain. Most of the transcription activators either influence initial binding of RNAP or conversion of closed to open complex formation. Very few activators act at subsequent steps of promoter-polymerase interaction. Earlier studies showed high level of transcription from a mutant mom promoter, tin7. Addition of C further increased transcription from Ptin7 indicating that C may have a role beyond polymerase recruitment. Each steps of transcription initiation have been dissected using the Ptin7 and a positive control (pc) mutant of C, R105D. The results revealed multi-step transcription activation mechanism for C protein at Pmom. C recruits RNAP at Pmom and subsequently increases the productive RNAP-promoter complex and enhances promoter clearance. To further understand the C mediated transactivation mechanism, interaction between C and RNAP was assessed. C interacts with holo and core RNAP only in presence of DNA. Positive control mutants of C, F95A and R015D, were found to be compromised in RNAP interactions. These mutants were efficient in RNAP recruitment to Pmom but do not enhance promoter clearance. Trypsin cleavage protection experiment indicated that probably C protein interacts with b¢ subunit of RNAP. Interaction between C and RNAP appears to enhance the formation of productive RNAP-promoter complex leading to promoter clearance. The connection between activator-polymerase interaction and transcription activation is well documented where the recruitment of RNAP is influenced. In case of activators acting at post recruitment steps of initiation, the role of polymerase contact is poorly understood. Our study shows that activator-polymerase interaction can lead to increased promoter clearance at Pmom by overcoming abortive initiation.

Gene Expression

Gene Transcription

Bacteriophage MU

Transcription Activation

RNA Polymerase (RNAP)

C (Bacterial Protein)

Phage MU

DNA Binding

mom Promoter

C Protein

Cell Biology

Insights Into Transcription-Repair Coupling Factor From Mycobacterium Tuberculosis

Swayam Prabha, *

02 1900

Introduction Nucleotide excision repair (NER) is a highly conserved pathway involved in repair of a wide variety of structurally unrelated DNA lesions. One of the well characterized NER systems is from E. coli which involves UvrABC nucleases. NER consists of two related sub-pathways: global genomic repair (GGR), which removes lesions from the overall genome, and transcription coupled repair (TCR), which removes lesions from the transcribed strand of active genes. Bulky DNA lesions such as cyclobutane pyrimidine photodimers (CPD) induced by UV irradiation block RNA polymerase (RNAP) during transcription. In bacteria, a gene product of mfd called transcription repair coupling factor (TRCF) or Mfd is required for TCR. Bacterial Mfd interacts with the stalled RNAP, displaces it from the DNA and recruits NER proteins at the site of damage. Mfd, thus contributes to the faster repair of the transcribed strand compared to the non-transcribed strand for similar kind of lesions. Intracellular pathogens like M. tuberculosis are constantly exposed to a variety of stress conditions inside the host, mainly due to host defense systems and antibiotic treatments. It is therefore, extremely important for bacteria to have DNA damage repair and reversal mechanisms that can efficiently counteract these effects. However, very little is known about DNA repair systems in M. tuberculosis compared to other bacteria. Sequencing of M. tuberculosis genome revealed the presence of NER associated genes including a putative mfd. Additionally, due to the high GC content of genome as well as the DNA damage prone host environment, the transcription in M. tuberculosis may encounter the problems, which are not apparent in other bacteria. Therefore, the gene like mfd may play very important role in physiology of M. tuberculosis. In the present study, we describe the biochemical and functional characterization of Mfd from M. tuberculosis (MtbMfd) and discuss its unusual properties. Biochemical characterization of MtbMfd Genome analysis of M. tuberculosis as well as the sequence alignment studies revealed that MtbMfd is 1234 amino acids long multifunctional protein having various domains specialized for different functions. Cloning of Mtbmfd was carried out by reconstructing the full length gene from three PCR amplified fragments using genomic DNA as a template. Complementation study using Mtbmfd suggested that the gene of interest complements E. coli counterpart and increases survival of UV irradiated cells. To further characterize the function of Mtbmfd, a road block reporter assay was performed, which indicates that the MtbMfd interacts with stalled E. coli RNAP and displaces it from the site of transcription resulting in low reporter gene activity. The MtbMfd protein was expressed and purified by using various chromatographic techniques, and confirmed by mass spectrometry. In addition to full length protein, a number of truncated MtbMfd constructs were generated and purified to homogeneity. Mfd is a motor protein and requires ATP hydrolysis in order to translocate along DNA. The signature motifs of superfamily 2 helicases / ATPases are present at the C-terminal of Mfd along with translocase motif which is highly homologous to motif present in RecG helicase. To analyze the kinetics of ATP hydrolysis of MtbMfd and its truncated proteins, ATPase reactions were carried out using γ32P-ATP as a tracer. Wild-type MtbMfd exhibited ATPase activity, which was stimulated ~1.5 fold in presence of dsDNA. The mutant MtbMfd (D778A), which harbors mutation in one of the key residues of Walker B motif of the ATPase domain showed negligible ATPase activity indicating the importance of residue D778 for ATP hydrolysis. While the C-terminal domain (CTD) comprising amino acids 600 to 1234 showed elevated ATPase activity, the N-terminal domain (NTD) containing the first 500 amino acid residues was able to bind ATP but deficient in hydrolysis. Deletion of 184 amino acids from the C-terminal end of MtbMfd (MfdΔC) increased the ATPase activity by ~10-fold compared to full-length MtbMfd. The translocase activity of MtbMfd was measured by an oligonucleotide displacement assay and it was found that full length MtbMfd and CTD have a very weak translocase activity whereas, MfdΔC exhibited efficient translocation along DNA in ATP dependent manner. These results provide a direct correlation between translocase and ATPase activity of MtbMfd, and suggest possibly an auto-regulatory function for the extreme C-terminus of MtbMfd. Oligomeric status of MtbMfd was determined using various techniques including gel filtration chromatography and it was found that MtbMfd exists as monomer and hexamer in solution. The monomer showed increased ATPase activity and susceptibility to proteases compared to the hexameric form. MfdΔC, on the other hand, was predominantly monomer in solution implicating importance of the extreme C-terminal region in oligomerization of protein. Taken together, the biochemical evidence suggests that monomeric MtbMfd is an active form and oligomerization provides stability to the protein. One important finding of the present study is the binding of ATP to NTD of MtbMfd. All Mfd NTDs resemble UvrB and possesses the degenerate ATPase motifs. Indeed, on the basis of sequence and structural similarities, it has been suggested that Mfds have evolved from UvrB incorporating an additional translocase activity. UvrB has a cryptic ATPase activity while the NTD of Mfd may have lost the activity as it possesses degenerate Walker motifs. In contrast, NTD of MtbMfd binds ATP but is hydrolysis deficient. A closer comparison of the amino acid sequences in the Walker A motif reveal that conserved K 45 of UvrB has been replaced by R in case of NTD of MtbMfd. It has been shown previously that mutation of K 45 to A, D and R led to a loss of ATPase activity of UvrB. Thus, MtbMfd seems to be a natural mutant of UvrB. Since NTD harbors an intact UvrA interacting domain, when it is expressed it may sequester the cellular pool of UvrA leading to dominant negative phenotype. When UV survival assays were carried out, cells expressing NTD showed hyper-sensitivity to UV light – a typical characteristic of NER deficiency. In addition, in vitro NER assay clearly suggested that NTD sequesters pool of UvrA inside the cell and blocks both GGR and TCR which further affects the mutation frequency of bacterial cells. Influence of MtbMfd on elongation state of RNAP The movement of RNAP along the template during transcription elongation is not uniform and is interrupted due to various factors. To overcome transcription elongation interruptions, a number of proteins viz. Mfd, Gre and Nus act on RNAP and modify its activity. RNAP displacement and transcript release experiments showed that MtbMfd influenced the elongating RNAP by more than one way. MtbMfd displaced stalled RNAP, which was blocked by NTP starvation on T7A1 promoter based template in a concentration and time-dependent manner. RNAP displacement activity of MtbMfd was shown to depend on ATP or dATP hydrolysis. On the other hand nucleotides like ADP, GTP, CTP and ATPγS did not support the RNAP displacement activity. However, in presence of ATPγS, MtbMfd was able to bind stalled complex but unable to displace RNAP suggesting that ATP or dATP hydrolysis is important for MtbMfd function. On the other hand, MtbMfd did not affect initiating RNAP when σ factor was still bound suggesting that upstream DNA is necessary for Mfd function. To assay RNA or transcript release activity of MtbMfd after transcription complex disruption, immobilized transcription complex assay was carried out. Immobilized stalled complex was generated by UTP and CTP starvation on biotinylated T7A1 promoter based template which can be affixed to temporary pellet in presence of streptavidin beads. It was found that MtbMfd released RNA into a supernatant fraction in a concentration-dependent manner suggesting that MtbMfd releases transcript after ternary complex disruption. MtbMfd released transcript in an energy-dependent manner and both ATP and dATP supported the activity, which allows the complete separation of RNA release from RNA synthesis inside the cell. An ATPase mutant of MtbMfd (MfdD778A) failed to release transcript, which further supported that ATP hydrolysis is important for MtbMfd function. Since both Mfds and RNAPs are evolutionary conserved proteins, to analyze the effect of MtbMfd on other bacterial RNAPs, displacement and release assays were carried out. Stalled complexes were generated using EcoRNAP (E. coli), MsRNAP (M. smegmatis) and MtbRNAP (M. tuberculosis) on T7A1 promoter based template. It was observed that MtbMfd was able to displace all the three RNAPs from stalled elongation complex as well as released transcript with varying efficiency. MtbMfd showed optimal displacement and release activity in presence of mycobacterial RNAPs. Transcription elongation complexes adopt various conformations and exist as different isomerized states during elongation. In an active elongation complex the 3'-OH polymerizing end of transcript aligns with an active centre of the RNAP. However, one of the most common and intrinsic properties of RNAP is backtracking or reverse translocation, which leads to misalignment of 3'-OH polymerizing end from an active centre of the polymerase. It is of interest to know if backtracking affects MtbMfd function. It is likely that complexes blocked by lesions inside the cell might tend to backtrack, and different translocational isomers possibly have different sensitivities to MtbMfd action which may illuminate the overall mechanism of MtbMfd. Backtracking of RNAP was induced on +20 and +39 stalled complexes and the effect of MtbMfd was analyzed in presence of NTPs in the reaction. It was found that arrested or backtracked complexes were restored to the forward position by the activity of MtbMfd in presence of NTP resulting into productive elongation. These results suggest that arrested RNAP again resumes transcription if conditions are favorable; otherwise, MtbMfd further assists RNAP to dissociate which leads to release of transcript. Anti-backtracking activity of MtbMfd might have important function in cellular metabolism and it has been speculated that Mfd could play more general role during transcription apart from repair. To explore the role of MtbMfd as a transcription factor and effect of MtbMtb on transcription processes in the mycobacteria, a variety of T7A1 promoter based templates were generated. These templates were derived from genes of M. tuberculosis and E. coli having varying GC content (39-81 %). The rationale behind this experiment is that the high GC content of mycobacteria and the template derived from mycobacterial genes may pose as sequence dependent structural constraints and hence block the RNAP during transcription. By anti-backtracking activity of MtbMfd these paused complexes may get relieved, leading to efficient transcription by RNAP which may lead to the formation of more full length transcript. To analyze the effect of MtbMfd, purified templates of different GC content were incubated with RNAP and MtbMfd to carry out in vitro transcription. Although, in case of multiple rounds of transcription, multiple pauses were observed even in presence of MtbMfd. However, in presence MtbMfd around 1.5 - 2 fold increased full-length transcripts were observed suggesting that MtbMfd assisted RNAP during elongation to overcome sequence dependent pause. To avoid multiple pauses that are likely to occur due to the initiation of multiple round of transcription, and trailing effect of RNAP itself, single round of transcriptions were carried out in presence of heparin. Sequence specific pauses were observed with increasing GC percentage in template suggesting that indeed high GC content contributes to transcription pause. At the same time, MtbMfd in the reaction increased the amount of full length transcript by 1.5 - 2.0 fold probably by pushing paused RNAP forward to resume elongation. Taken together, this study investigates the biochemical properties of MtbMfd and its mechanism of action. In addition, it explores the importance of the coupling of transcription to repair in M. tuberculosis as well as the overall proof reading mechanism of transcription elongation in the GC rich genome of mycobacteria.

Mycobacterium tuberculosis

Mycobacterium tuberculosis Mfd

DNA Damage

RNA Polymerase (RNAP)

DNA Repair

Mycobacteria - Transcirption Elongation

M. tuberculosis

MtbMfd

Endogenous DNA

Biochemical Genetics

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

Structural and Functional Studies on the Mycobacterium tuberculosis σ factor σJ

Goutam, Kapil

January 2017

Regulation of transcription in prokaryotes is primarily governed at the transcription initiation step. This feature has been extensively characterized in model prokaryotes notably Escherichia coli and Bacillus subtilis. Transcription initiation was initially thought to be governed primarily by initiation factors that recruit the RNA polymerase (RNAP) enzyme to initiate expression of given gene. Recent studies reveal multiple mechanisms at play including additional protein factors that can modulate gene expression. Nonetheless, understanding transcription factors is key to rationalize the nuanced changes in prokaryotic gene expression in response to diverse environmental stimuli. This is particularly relevant in the case of the human pathogen, Mycobacterium tuberculosis, especially due to the ability of this bacterium to survive in the host, often for several decades prior to the onset of the disease. Transcription initiation factors, also called σ factors in prokaryotes, are diverse in size and sensory/regulatory mechanisms. Indeed, the number of alternate σ factors vary substantially from six in E. coli to more than 118 in Plesiocystis pacifica. The large number of alternative σ factors has been suggested to be correlated with the diversity of micro-environments experienced by a bacterial cell. Studies on several prokaryotic σ factors reveal common features in these proteins that was not evident earlier due to poor sequence conservation. A central theme that emerges from these studies is that a minimalistic architecture of two domains can recognize promoter DNA and recruit the RNAP enzyme to initiate transcription. Additional domains are required when certain promoter elements are missing or to enable a specific, context dependent regulatory mechanism. The work reported in this thesis was influenced by previous studies in this laboratory and elsewhere on M. tuberculosis σ factors. While these studies revealed multiple features of transcription initiation, several aspects of this mechanism, including some classes of σ factors remain to be examined. The focus of this study was to examine an under-explored sub-group of σ factors, classified as the ECF41 sub-group. This sub-group has an additional domain at the Carboxy-terminus that has been hypothesised to influence σ factor activity. Towards this goal, M. tuberculosis σJ was examined. Previous studies suggested a role for this σ factor in modulating the response to hydrogen peroxide stress. An intriguing feature based on sequence analysis was that neither did this extra-cytoplasmic function σ factor have an anti-σ factor that can respond to oxidative stress nor was it directly associated with a mechanism to sense oxidative stress. The specific goal of the research described here was to understand the structural and mechanistic features that govern σJ activity. This thesis is organized as follows- The first chapter provides a brief introduction to prokaryotic transcription and regulatory mechanisms that govern this process. This chapter also has the literature necessary to phrase the problem in characterizing this family of proteins with particular reference to the unique physiology of Mycobacterium tuberculosis. A summary of the previous work is provided in this chapter to place the current study in context of previous studies and highlight the lacunae in our understanding of the transcription mechanism in M. tuberculosis. Chapter two describes the structural characterization of M. tuberculosis σJ by single-crystal X-ray diffraction. The poor sequence similarity of σJ to known σ factors precluded efforts to obtain phase information by molecular replacement methods. Here we also describe the steps that were essential to obtain diffraction quality crystals and the subsequent steps to account for pseudo-merohedral twinning, an imperfection that could have potentially been a limitation for structure determination. The crystal structure of σJ provide an example of successful phase determination with data collected on near-perfectly twinned crystals using single-wavelength anomalous dispersion. Chapter three describes computational efforts to understand the regulatory mechanisms of M. tuberculosis σJ. Classical Molecular Dynamics (MD) simulations were performed to understand the role of a C-terminal SnoaL_2 domain in this transcription factor. The MD simulations suggest that the C-terminal SnoaL_2 domain limits inter-domain movements between σJ2 (the pribnow box binding domain) and σJ4 (the -35 promoter element binding domain) and confers a compact three domain organization to this protein. The biochemical and functional characterization of M. tuberculosis σJ is described in chapter four. This includes in vitro studies on σJ and cognate promoter DNA interactions performed using Surface Plasmon Resonance (SPR) and Electrophoretic Mobility Shift Assays (EMSA). The ex vivo reporter based experiments to examine the effect of SnoaL_2 domain on σJ activity are also described. Spectroscopic studies on σJ interactions with a small molecule limonene-1,2-epoxide suggested a potential novel role for the SnoaL_2 domain in σJ. Chapter five summarizes the work on M. tuberculosis σJ reported in this thesis. We note that this study opens up a new perspective to understand σ factors. In particular, M. tuberculosis σJ suggests that the domain organization is likely to be retained in ECF41 sub-group of σ factors. This study also hints at broader implications in the distinction between one-component systems and transcription factors. Bioinformatic analysis suggest that observations similar to that noted in M. tuberculosis σJ are likely to be more widespread across diverse phyla than currently acknowledged. This thesis has three annexures. Annexure-I summarizes experimental details of the work performed on the M. tuberculosis σ/anti-σ factor complex σH/RshA. Annexure-II summarizes experimental details and strategies that could not be incorporated in the main body of this thesis. Annexure-III describes a short project performed on a bi-domain protein tyrosine phosphatase PTP99A.

M. tuberculosis σH/RshA Complex

Mycobacterial Promoters

Mycobacterium Tuberculosis

M. tuberculosis σ factor σJ

Extra-Cytoplasmic Function

M. tuberculosis σJ

σ Factors

Protein Tyrosine Phosphatase PTP99A

RNA Polymerase (RNAP)

Molecular Biophysics

Probing Macromolecular Reactions At Reduced Dimensionality : Mapping Of Sequence Specific And Non-Specific Protein-Ligand lnteractions

Ganguly, Abantika

03 1900

During the past decade the effects of macromolecular crowding on reaction pathways is gaining in prominence. The stress is to move out of the realms of ideal solution studies and make conceptual modifications that consider non-ideality as a variable in our calculations. In recent years it has been shown that molecular crowding exerts significant effects on all in vivo processes, from DNA conformational changes, protein folding to DNA-protein interactions, enzyme pathways and signalling pathways. Both thermodynamic as well as kinetic parameters vary by orders of magnitude in uncrowded buffer system as compared to those in the crowded cellular milieu. Ignoring these differences will restrict our knowledge of biology to a “model system” with few practical understandings. The recent expansion of the genome database has stimulated a study on numerous previously unknown proteins. This has whetted our thirst to model the cellular determinants in a more comprehensive manner. Intracellular extract would have been the ideal solution to re-create the cellular environment. However, studies conducted in this solution will be contaminated by interference with other biologically active molecule and relevant statistical data cannot be extracted out from it. Recent advances in methodologies to mimic the cellular crowding include use of inert macromolecules to reduce the volume occupancy of target molecules and the use of immobilization techniques to increase the surface density of molecules in a small volumetric region. The use of crowding agents often results in non-specific interaction and side-reactions like aggregation of the target molecules with the crowding agents themselves. Immobilization of one of the interacting partners reduces the probability of aggregation and precipitation of bio-macromolecules by restricting their degrees of freedom. Covalent linkage of molecules on solid support is used extensively in research for creating a homogeneous surface of bound molecules which can be interrogated for their reactivity. However, when it comes to biomolecules, direct immobilization on solid support or use of organic linkers often results in denaturation. The use of bio-affinity immobilization techniques can help us overcome this problem. Since mild conditions are needed to regenerate such a surface, it finds universal applicability as bio-memory chips. This thesis focuses on our attempts to design a physiologically viable immobilization technique for following rotein-protein/protein-DNA interactions. The work explores the mechanism for biological interactions related to transcription process in E. coli. Chapter 1 deals with the literary survey of the importance and effects of molecular crowding on biological reactions. It gives a brief history of the efforts been made so far by experimentalists, to mimic macromolecular crowding and the methods applied. The chapter tries to project an all-round perspective of the pros and cons of different immobilization techniques as a means to achieve a high surface density of molecules and the advancements so far. Chapter 2 deals with the detailed technicality and applicability of the Langmuir-Blodgett method. It discusses the rationale behind our developing this technique as an alternate means of bio-affinity immobilization, under physiologically compatible conditions. It then goes on to describe our efforts to follow the sequence-specific and sequential assembly process of a functional RNA polymerase enzyme with one immobilized partner and also explore the role of omega subunit of RNAP in the reconstitution pathway. This chapter uses the assembly process of a multi-subunit enzyme to evaluate the efficiency of the LB system as a universal two-dimensional scaffold to follow sequence-specific protein-ligand interaction. Chapter 3 discusses the application of LB technique to quantitatively evaluate the kinetics and thermodynamics of promoter-RNA polymerase interaction under conditions of reduced dimensionality. Here, we follow the interaction of T7A1 phage promoter with Escherichia coli RNA polymerase using our Langmuir-Blodgett technique. The changes in mechanistic pathway and trapping of kinetic intermediates are discussed in detail due to the imposed restriction in the degrees of freedom of the system. The sensitivity of this detection method is compared vis-a-vis conventional immobilization methods like SPR. This chapter firmly establishes the universal application of LB technique as a means to emulate molecular crowding and as a sensitive assay for studying the effects of such crowding on vital biological reaction pathway. Chapter 4 describes the mechanistic pathway for the physical binding of MsDps1 protein with long dsDNA in order to physically protect DNA during oxidative stress. The chapter describes in detail the mechanism of physical sequestering of non-specific DNA strands and compaction of the genome under conditions where a kinetic bottleneck has been applied. The data obtained is compared with results obtained in the previous chapter for the sequence-specific DNA-protein interaction in order to understand the difference in recognition process between regulatory and structural proteins binding to DNA. Chapter 5 deals with the evaluation of the σ-competition model in E. coli for three different sigma factors (all belonging to the σ-70 family). Here again, we have evaluated the kinetic and thermodynamic parameters governing the binding of core RNAP with its different sigma factors (σ70, σ32and σ38) and performed a comparative study for the binding of each sigma factor to its core using two different non-homogeneous immobilization techniques. The data has been analyzed globally to resolve the discrepancies associated with establishing the relative affinity of the different sigma factors for the same core RNA polymerase under physiological conditions. Chapter 6 summarizes the work presented in this thesis. In the Appendix section we have followed the unzipping of promoter DNA sequence using Optical Tweezers in an attempt to follow the temporal fluctuations occurring in biological reactions in real time and at a single molecule level.

Molecular Crowding

Protein-Ligand Interactions

RNA Polymerase (RNAP)

DNA Binding Protein

Mimic Molecular Crowding

Mycobacterium DNA Binding Protein

Bio-Macromolecules

Protein-Protein Interactions

Protein-DNA Interactions

Macromolecular Crowding

RNA Polymerase Molecule

Biochemistry