Topoisomerases from Mycobacteria : Insights into the Mechanism, Regulation and Global Modulatory Functions

Ahmed, Wareed

January 2014

The eubacterial genome is maintained in a negatively supercoiled state which facilitates its compaction and storage in a small cellular space. Genome supercoiling can potentially influence various DNA transaction processes such as DNA replication, transcription, recombination, chromosome segregation and gene expression. Alterations in the genome supercoiling have global impact on the gene expression and cell growth. Inside the cell, the genome supercoiling is maintained judiciously by DNA topoisomerases to optimize DNA transaction processes. These enzymes solve the problems associated with the DNA topology by cutting and rejoining the DNA. Due to their essential cellular functions and global regulatory roles, DNA topoisomerases are fascinating candidates for the study of the effect of topology perturbation on a global scale. Genus Mycobacterium includes a large number of species including the well-studied Mycobacterium smegmatis (Msm) as well as various pathogens–Mycobacterium leprae, Mycobacterium abscessus and Mycobacterium tuberculosis (Mtb), the last one being the causative agent of the deadly disease Tuberculosis (TB), which claims millions of lives worldwide annually. The organism combats various stresses and alterations in its environment during the pathogenesis and virulence. During such adaptation, various metabolic pathways and transcriptional networks are reconfigured. Considering their global regulatory role, DNA topoisomerases and genome supercoiling may have an influence on the mycobacterial survival and adaptation. Biochemical studies from our laboratory have revealed several distinctive characteristics of mycobacterial DNA gyrase and topoisomerase I. DNA gyrase has been shown to be a strong decatenase apart from its characteristic supercoiling activity. Similarly, the mycobacterial topoisomerase I exhibits several distinct features such as the ability to bind both single- as well as double-stranded DNA, site specific DNA binding and absence of Zn2+ fingers required for DNA relaxation activity in other Type I enzymes. Although, efforts have been made to understand the biochemistry and mechanism of mycobacterial topoisomerases, in vivo significance and regulatory roles remain to be explored. The present study is aimed at understanding the mechanism, in vivo functions, regulation and genome wide distribution of mycobacterial topoisomerases. Chapter 1 of the thesis provides introduction on DNA topology, genome supercoiling and DNA topoisomerases. The importance of genome supercoiling and its regulatory roles has been discussed. Further, the regulation of topoisomerase activity and the role in the virulence gene regulation is described. Finally, a brief overview of Mtb genome, disease epidemiology, and pathogenesis is presented along with the description of the work on mycobacterial topoisomerases. In Chapter 2, the studies are directed to understand the DNA relaxation mechanism of mycobacterial Type IA topoisomerase which lack Zn2+ fingers. The N-terminal domain (NTD) of the Type IA topoisomerases harbor DNA cleavage and religation activities, but the carboxyl terminal domain (CTD) is highly diverse. Most of these enzymes contain a varied number of Zn2+ finger motifs in the CTD. The Zn2+ finger motifs were found to be essential in Escherichia coli TopoI but dispensable in the Thermotoga maritima enzyme. Although, the CTD of mycobacterial TopoI lacks Zn2+ fingers, it is indispensable for the DNA relaxation activity of the enzyme. The divergent CTD harbors three stretches of basic amino acids needed for the strand passage step of the reaction as demonstrated by a new assay. It is elucidated that the basic amino acids constitute an independent DNA-binding site apart from the NTD and assist the simultaneous binding of two molecules of DNA to the enzyme, as required during the strand passage step of the catalysis. It is hypothesized that the loss of Zn2+ fingers from the mycobacterial TopoI could be associated with Zn2+ export and homeostasis. In Chapter 3, the studies have been carried out to understand the regulation of mycobacterial TopoI. Identification of Transcription Start Site (TSS) suggested the presence of multiple promoters which were found to be sensitive to genome supercoiling. The promoter activity was found to be specific to mycobacteria as the promoter(s) did not show activity in E. coli. Analysis of the putative promoter elements suggested the non-optimal spacing of the putative -35 and -10 promoter elements indicating the involvement of supercoiling for the optimal alignment during the transcription. Moreover, upon genome relaxation, the occupancy of RNA polymerase was decreased on the promoter region of topoI gene implicating the role of DNA topology in the Supercoiling Sensitive Transcription (SST) of TopoI gene from mycobacteria. The involvement of intrinsic promoter elements in such regulation has been proposed. In Chapter 4, the importance of TopoI for the Mtb growth and survival has been validated. Mtb contains only one Type IA topoisomerase (Rv3646c), a sole DNA relaxase in the cell, and hence a candidate drug target. To validate the essentiality of Mtb topoisomerase I for bacterial growth and survival, conditionally regulated strain of topoI in Mtb was generated. The conditional knockdown mutant exhibited delayed growth on agar plate and in liquid culture the growth was drastically impaired when TopoI expression was suppressed. Additionally, novobiocin and isoniazid showed enhanced inhibitory potential against the conditional mutant. Analysis of the nucleoid revealed its altered architecture upon TopoI depletion. These studies establish the essentiality of TopoI for the Mtb growth and open up new avenues for targeting the enzyme. In Chapter 5, the influence of perturbation of TopoI activity on the Msm growth and physiology has been studied. Notably, Msm contains an additional DNA relaxation enzyme– an atypical Type II topoisomerase TopoNM. The TopoI depleted strain exhibited slow growth and drastic change in phenotypic characters. Moreover, the genome architecture was disturbed upon depletion of TopoI. Further, the proteomic and transcript analysis indicated the altered expression of the genes involved in central metabolic pathways and core DNA transaction processes in the mutant. The study suggests the importance of TopoI in the maintenance of cellular phenotype and growth characteristics of fast growing mycobacteria having additional topoisomerases. In Chapter 6, the ChIP-Seq method is used to decipher the genome wide distribution of the DNA gyrase, topoisomerase I (TopoI) and RNA polymerase (RNAP). Analysis of the ChIP-Seq data revealed the genome wide distribution of topoisomerases along with RNAP. Importantly, the signals of topoisomerases and RNAP was found to be co-localized on the genome suggesting their functional association in the twin supercoiled domain model, originally proposed by J. C. Wang. Closer inspection of the occupancy profile of topoisomerases and RNAP on transcription units (TUs) revealed their co-existence validating the topoisomerases occupancy within the twin supercoiled domains. On the genomic scale, the distribution of topoisomerases was found to be more at the ori domains compared to the ter domain which appeared to be an attribute of higher torsional stress at ori. The reappearance of gyrase binding at the ter domain (and the lack of it in the ter domain of E. coli) suggests a role for Mtb gyrase in the decatenation of the daughter chromosomes at the end of replication. The eubacterial genome is maintained in a negatively supercoiled state which facilitates its compaction and storage in a small cellular space. Genome supercoiling can potentially influence various DNA transaction processes such as DNA replication, transcription, recombination, chromosome segregation and gene expression. Alterations in the genome supercoiling have global impact on the gene expression and cell growth. Inside the cell, the genome supercoiling is maintained judiciously by DNA topoisomerases to optimize DNA transaction processes. These enzymes solve the problems associated with the DNA topology by cutting and rejoining the DNA. Due to their essential cellular functions and global regulatory roles, DNA topoisomerases are fascinating candidates for the study of the effect of topology perturbation on a global scale. Genus Mycobacterium includes a large number of species including the well-studied Mycobacterium smegmatis (Msm) as well as various pathogens–Mycobacterium leprae, Mycobacterium abscessus and Mycobacterium tuberculosis (Mtb), the last one being the causative agent of the deadly disease Tuberculosis (TB), which claims millions of lives worldwide annually. The organism combats various stresses and alterations in its environment during the pathogenesis and virulence. During such adaptation, various metabolic pathways and transcriptional networks are reconfigured. Considering their global regulatory role, DNA topoisomerases and genome supercoiling may have an influence on the mycobacterial survival and adaptation. Biochemical studies from our laboratory have revealed several distinctive characteristics of mycobacterial DNA gyrase and topoisomerase I. DNA gyrase has been shown to be a strong decatenase apart from its characteristic supercoiling activity. Similarly, the mycobacterial topoisomerase I exhibits several distinct features such as the ability to bind both single- as well as double-stranded DNA, site specific DNA binding and absence of Zn2+ fingers required for DNA relaxation activity in other Type I enzymes. Although, efforts have been made to understand the biochemistry and mechanism of mycobacterial topoisomerases, in vivo significance and regulatory roles remain to be explored. The present study is aimed at understanding the mechanism, in vivo functions, regulation and genome wide distribution of mycobacterial topoisomerases. Chapter 1 of the thesis provides introduction on DNA topology, genome supercoiling and DNA topoisomerases. The importance of genome supercoiling and its regulatory roles has been discussed. Further, the regulation of topoisomerase activity and the role in the virulence gene regulation is described. Finally, a brief overview of Mtb genome, disease epidemiology, and pathogenesis is presented along with the description of the work on mycobacterial topoisomerases. In Chapter 2, the studies are directed to understand the DNA relaxation mechanism of mycobacterial Type IA topoisomerase which lack Zn2+ fingers. The N-terminal domain (NTD) of the Type IA topoisomerases harbor DNA cleavage and religation activities, but the carboxyl terminal domain (CTD) is highly diverse. Most of these enzymes contain a varied number of Zn2+ finger motifs in the CTD. The Zn2+ finger motifs were found to be essential in Escherichia coli TopoI but dispensable in the Thermotoga maritima enzyme. Although, the CTD of mycobacterial TopoI lacks Zn2+ fingers, it is indispensable for the DNA relaxation activity of the enzyme. The divergent CTD harbors three stretches of basic amino acids needed for the strand passage step of the reaction as demonstrated by a new assay. It is elucidated that the basic amino acids constitute an independent DNA-binding site apart from the NTD and assist the simultaneous binding of two molecules of DNA to the enzyme, as required during the strand passage step of the catalysis. It is hypothesized that the loss of Zn2+ fingers from the mycobacterial TopoI could be associated with Zn2+ export and homeostasis. In Chapter 3, the studies have been carried out to understand the regulation of mycobacterial TopoI. Identification of Transcription Start Site (TSS) suggested the presence of multiple promoters which were found to be sensitive to genome supercoiling. The promoter activity was found to be specific to mycobacteria as the promoter(s) did not show activity in E. coli. Analysis of the putative promoter elements suggested the non-optimal spacing of the putative -35 and -10 promoter elements indicating the involvement of supercoiling for the optimal alignment during the transcription. Moreover, upon genome relaxation, the occupancy of RNA polymerase was decreased on the promoter region of topoI gene implicating the role of DNA topology in the Supercoiling Sensitive Transcription (SST) of TopoI gene from mycobacteria. The involvement of intrinsic promoter elements in such regulation has been proposed. In Chapter 4, the importance of TopoI for the Mtb growth and survival has been validated. Mtb contains only one Type IA topoisomerase (Rv3646c), a sole DNA relaxase in the cell, and hence a candidate drug target. To validate the essentiality of Mtb topoisomerase I for bacterial growth and survival, conditionally regulated strain of topoI in Mtb was generated. The conditional knockdown mutant exhibited delayed growth on agar plate and in liquid culture the growth was drastically impaired when TopoI expression was suppressed. Additionally, novobiocin and isoniazid showed enhanced inhibitory potential against the conditional mutant. Analysis of the nucleoid revealed its altered architecture upon TopoI depletion. These studies establish the essentiality of TopoI for the Mtb growth and open up new avenues for targeting the enzyme. In Chapter 5, the influence of perturbation of TopoI activity on the Msm growth and physiology has been studied. Notably, Msm contains an additional DNA relaxation enzyme– an atypical Type II topoisomerase TopoNM. The TopoI depleted strain exhibited slow growth and drastic change in phenotypic characters. Moreover, the genome architecture was disturbed upon depletion of TopoI. Further, the proteomic and transcript analysis indicated the altered expression of the genes involved in central metabolic pathways and core DNA transaction processes in the mutant. The study suggests the importance of TopoI in the maintenance of cellular phenotype and growth characteristics of fast growing mycobacteria having additional topoisomerases. In Chapter 6, the ChIP-Seq method is used to decipher the genome wide distribution of the DNA gyrase, topoisomerase I (TopoI) and RNA polymerase (RNAP). Analysis of the ChIP-Seq data revealed the genome wide distribution of topoisomerases along with RNAP. Importantly, the signals of topoisomerases and RNAP was found to be co-localized on the genome suggesting their functional association in the twin supercoiled domain model, originally proposed by J. C. Wang. Closer inspection of the occupancy profile of topoisomerases and RNAP on transcription units (TUs) revealed their co-existence validating the topoisomerases occupancy within the twin supercoiled domains. On the genomic scale, the distribution of topoisomerases was found to be more at the ori domains compared to the ter domain which appeared to be an attribute of higher torsional stress at ori. The reappearance of gyrase binding at the ter domain (and the lack of it in the ter domain of E. coli) suggests a role for Mtb gyrase in the decatenation of the daughter chromosomes at the end of replication.

Mycobacteria

Mycobacterial Topoisomerases

Mycobacterial Gyrase

DNA Supercoiling

DNA Topology

DNA Topoisomerase I

Mycobacterial Gene Regulation

Virulent Gene Expression

Mycobacterium Tuberculosis Topoisomerase

Mycobacterium Smegmatis Topoisomerase I

Bacterial Growth

RNA Polymerases

Bacterial DNA Topoisomerases

Topoisomerase I

Mycobacterial Topoisomerase I

Microbiology

Roles of Cellular RNA-Dependent RNA Polymerases in Endogenous Small RNA Pathways in Caenorhabditis elegans: A Dissertation

Vasale, Jessica J.

14 June 2010

The RNA interference (RNAi) pathway in Caenorhabditis elegans is a two-step, small RNA-mediated silencing pathway. Unlike in other organisms, Dicer processing of double-stranded RNA into small interfering (si) RNAs is not sufficient in worms to induce gene silencing. The activity of cellular RNA-dependent RNA polymerase (RdRP) is necessary to synthesize a secondary pool of siRNAs, which interact with a unique class of Argonaute proteins to form the functional effector complexes that mediate silencing. The aims of this thesis were to: 1) characterize the role of RdRP family members in endogenous small RNA biogenesis; 2) identify the Argonaute proteins that interact with RdRP-dependent small RNAs; and 3) investigate the biological function of RdRP-dependent small RNA pathways in C. elegans. In this thesis, I describe genetic, deep sequencing, and molecular studies, which identify 22G-RNAs as the most abundant class of endogenous small RNA in C. elegans. The 22G-RNAs resemble RdRP-dependent secondary siRNAs produced during exogenous RNAi, in that they possess a triphosphorylated 5’ guanine residue and exhibit a remarkable strand bias at target loci. Indeed, I show that 22G-RNAs are dependent on the activity of the RdRPs RRF-1 and EGO-1 and function in multiple distinct endogenous small RNA pathways. Interestingly, I have found that RRF-1 and EGO-1 function redundantly in the germline to generate 22G-RNAs that are dependent on and interact with members of an expanded family of worm-specific Argonaute (WAGO) proteins. The WAGO/22G-RNA pathway appears to be a transcriptome surveillance pathway that silences coding genes, pseudogenes, transposons, and non-annotated, or cryptic, transcripts. In contrast, I have found that EGO-1 alone is required for the biogenesis of a distinct class of 22G-RNAs that interact with the Argonaute CSR-1. Surprisingly, the CSR-1/22G-RNA pathway does not appear to silence its targets transcripts. Instead, the CSR-1/22G-RNA pathway is essential for the proper assembly of holocentric kinetochores and chromosome segregation. Lastly, I show that a third endogenous small RNA pathway, the ERI pathway, is a two-step silencing pathway that requires the sequential activity of distinct RdRPs and Argonautes. In the first step of this pathway, the RdRP, RRF- 3, is required for the biogenesis of 26G-RNAs that associate with the Argonaute, ERGO-1. In the second step, RRF-1 and EGO-1 generate 22G-RNAs that associate with the WAGO Argonautes. This work demonstrates how several C. elegans small RNAs pathways utilize RdRPs to generate abundant populations of small RNAs. These distinct categories of small RNAs function together with specific Argonaute proteins to affect gene expression, to play essential roles in development, and in the maintenance of genome and transcriptome integrity.

RNA Interference

RNA

Small Interfering

Caenorhabditis elegans Proteins

DNA-Directed RNA Polymerases

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Genetic Phenomena

Molecular Biology

Molecular Genetics

Mechanisms of recruitment of the CTD phosphatase Rtr1 to RNA polymerase II

Berna, Michael J., Sr.

19 October 2012

Indiana University-Purdue University Indianapolis (IUPUI) / The C-terminal domain (CTD) of the RNA polymerase II (RNAPII) subunit Rpb1 must exist in a hypophosphorylated state prior to forming a competent transcription initiation complex. However, during transcription, specific kinases and phosphatases act on the RNAPII CTD to regulate its phosphorylation state, which serves to recruit sequence-specific and general transcription factors at the appropriate stage of transcription. A key phosphatase involved in this process, Rtr1 (Regulator of Transcription 1), was shown to regulate a key step important for transcription elongation and termination. Although the role that Rtr1 plays in regulating RNAPII transcription has been described, the mechanism involved in the recruitment of Rtr1 to RNAPII during transcription has not been elucidated in yeast. Consequently, the present work utilized both affinity purification schemes in Saccharomyces cerevisiae and mass spectrometry to identify key Rtr1-interacting proteins and post-translational modifications that potentially play a role in recruiting Rtr1 to RNAPII. In addition to RNAPII subunits, which were the most consistently enriched Rtr1-interacting proteins, seven proteins were identified that are potentially involved in Rtr1 recruitment. These included PAF complex subunits (Cdc73, Ctr9, Leo1), the heat shock protein Hsc82, the GTPase Npa3, the ATPase Rpt6, and Spn1. Indirect evidence was also uncovered that implicates that the CTDK-I complex, a kinase involved in RNAPII CTD phosphorylation, is important in facilitating interactions between Rtr1, RNAPII, and select transcription factors. Additionally, a putative phosphorylation site was identified on Ser217 of Rtr1 that may also play a role in its recruitment to RNAPII during transcription.

Transcription factors

Genetic transcription -- Regulation

Molecular biology

RNA

Mass spectrometry

Phosphatases

RNA-protein interactions

RNA polymerases

Protein kinases

Proteins -- Analysis

Proteomics

The role of the Borrelia oxidative stress regulator protein in virulence gene expression of the Lyme disease spirochete

Khoo, Joleyn Yean Chern

25 February 2014

Indiana University-Purdue University Indianapolis (IUPUI) / The Lyme disease agent, Borrelia burgdorferi, has a complex system that allows it to thrive in the harsh and distinct environments of its tick vector and mammalian host. Although it has been known for some time that the Borrelia oxidative stress regulator protein (BosR) plays a necessary role in mammalian infectivity and functions as a transcriptional regulator of alternative sigma factor RpoS, very little is known about its mechanism of action, other than the suggestion that BosR activates rpoS transcription by binding to certain upstream regions of the gene. In our studies, we performed protein degradation assays and luciferase reporter assays for further understanding of BosR function. Our preliminary findings suggest that BosR is post-transcriptionally regulated by an unknown protease and may not need to bind to any rpoS upstream regions in order to activate transcription. We also describe the construction of luciferase reporter systems that will shed light on BosR’s mechanism of action. We postulate the provocative possibility that unlike its homologs Fur and PerR in other bacterial systems, BosR may not utilize a DNA-binding mechanism in order to fulfill its role as a transcriptional regulator to modulate virulence gene expression.

Lyme disease -- Research -- Analysis

Borrelia burgdorferi -- Research

Genetic regulation

Gene expression -- Technique

Genetic transcription -- Regulation

Protease inhibitors

Virulence (Microbiology)

RNA polymerases

Polymerase chain reaction

Ticks as carriers of disease

Microbial genetics -- Technique

Polyacrylamide gel electrophoresis

The role of the CTD phosphatase Rrt1 and post-translational modifications in regulation of RNA polymerase II

Cox, Mary L.

07 July 2014

Indiana University-Purdue University Indianapolis (IUPUI) / RNA polymerase II (RNAPII) is regulated by multiple modifications to the C-terminal domain (CTD) of the largest subunit, Rpb1. This study has focused on the relationship between hyperphosphorylation of the CTD and RNAPII turnover and proteolytic degradation as well as post-translational modifications of the globular core of RNAPII. Following tandem affinity purification, western blot analysis showed that MG132 treated RTR1 ERG6 deletion yeast cells have accumulation of total RNAPII and in particular, the hyperphosphorylated form of the protein complex. In addition, proteomic studies using MuDPIT have revealed increased interaction between proteins of the ubiquitin-proteasome degradation system in the mutant MG132 treated yeast cells as well as potential ubiquitin and phosphorylation sites in RNAPII subunits, Rpb6 and Rpb1, respectively. A novel Rpb1 phosphorylation site, T1471-P, is located in the linker region between the CTD and globular domain of Rpb1 and will be the focus of future studies to determine biological significance of this post-translational modification.

Transcription

RNA polymerase II

CTD phosphatase

Rtr1

MuDPIT

AP-MS

Cellular signal transduction

RNA -- Research

RNA polymerases

Genetic transcription -- Regulation

Transcription factors -- Research

Phosphatases -- Research

Proteins -- Analysis

Proteomics

Ubiquitin

Phosphorylation

Yeast -- Physiology