Browsing by Author "Santangelo, Thomas J., advisor"
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Item Embargo DNA replication in the environmental extremes(Colorado State University. Libraries, 2024) Liman, Geraldy Lie Stefanus, author; Santangelo, Thomas J., advisor; Markus, Steven, committee member; Schauer, Grant, committee member; Sloan, Daniel, committee memberDNA replication is an essential biological process across all life on Earth. For the prokaryotic Archaea domain, which contains organisms that can thrive in inhospitable environments like hydrothermal vents or salt deposits in the Dead Sea, the cell machinery for these conserved processes have acclimated over the course of evolution to encourage survival. While the origin of replication (ori), a predetermined position within the genome where DNA replication starts, is conserved in all Domains, its significance is not equal between them. Surprisingly, the model hyperthermophilic archaeon, T. kodakarensis, replicates its genome without relying on origin-dependent replication (ODR), and instead, relies mostly on recombination-dependent replication (RDR). In fact, the ori in T. kodakarensis is dispensable from the organism without much phenotypic consequence. Although dispensable, ori persists after millions of years of evolution in this organism, suggesting some functional significance under certain conditions. Not to mention, archaeal replisomes are comprised of unique components that are distinct from the other two domains of life, though surprisingly more similar to those found in Eukarya. Central to all replisomes is the activity of the DNA polymerase (DNAP). Most archaeal organisms, except for the Creanarchaea, encode two main replicative DNAPs, the eukaryotic-like B-family DNAP (PolB) and the archaeal-specific D-family DNAP (PolD). In T. kodakarensis, PolD is the essential replicative DNAP while PolB is dispensable. This thesis aims to (1) characterize the activity and regulation of RadA, the main recombinase in Archaea, (2) characterize the exaptation of inteins to regulate DNA replication, (3) delineate the in vivo function(s) of PolB. Furthermore, I hope to further characterize DNA replication in the context of evolutionary biology and how it relates to the three Domains of life.Item Open Access Factor dependent archaeal transcription termination(Colorado State University. Libraries, 2017) Walker, Julie, author; Santangelo, Thomas J., advisor; Montgomery, Tai, committee member; Stargell, Laurie, committee member; Yao, Tingting, committee memberRNA polymerase activity is regulated by nascent RNA sequences, DNA template sequences and conserved transcription factors. Transcription factors regulate the activities of RNA polymerase (RNAP) at each stage of the transcription cycle: initiation, elongation, and termination. Many basal transcription factors with common ancestry are employed in eukaryotic and archaeal systems that directly bind to RNAP and influence intramolecular movements of RNAP and modulate DNA or RNA interactions. We describe and employ a flexible methodology to directly probe and quantify the binding of transcription factors to the archaeal RNAP in vivo. We demonstrate that binding of the conserved and essential archaeal transcription factor TFE to the archaeal RNAP is directed, in part, by interactions with the RpoE subunit of RNAP. As the surfaces involved are conserved in many eukaryotic and archaeal systems, the identified TFE-RNAP interactions are likely conserved in archaeal-eukaryal systems and represent an important point of contact that can influence the efficiency of transcription initiation. While many studies in archaea have focused on elucidating the mechanism of transcription initiation and elongation, studies on termination were slower to emerge. Transcription factors promoting initiation and elongation have been characterized in each Domain but transcription termination factors have only been identified in bacteria and eukarya. Here we characterize the first archaeal termination factor (termed Eta) capable of disrupting the transcription elongation complex, detail the rate of and requirements for Eta-mediated transcription termination and describe a role for Eta in transcription termination in vivo. Eta-mediated transcription termination is energy-dependent, requires upstream DNA sequences and disrupts transcription elongation complexes to release the nascent RNA to solution. Deletion of TK0566 (encoding Eta) is possible, but results in slow growth and renders cells sensitive to DNA damaging agents. Structure-function studies reveal that the N-terminal domain of Eta is not necessary for Eta-mediated termination in vitro, but Thermococcus kodakarensis cells lacking the N-terminal domain exhibit slow growth compared to parental strains. We report the first crystal structure of Eta that will undoubtedly lead to further structure-function analyses. The results obtained argue that the mechanisms employed by termination factors in archaea, eukarya, and bacteria to disrupt the transcription elongation complex may be conserved and that Eta stimulates release of stalled or arrested transcription elongation complexes.Item Open Access Factors and mechanisms of archaeal transcription termination and DNA repair(Colorado State University. Libraries, 2022) Marshall, Craig, author; Santangelo, Thomas J., advisor; Peersen, Olve, committee member; Wilusz, Carol, committee member; Yao, Tingting, committee memberRNA synthesis by RNA polymerase (RNAP) is an essential process and must be properly regulated both temporally and spatially to ensure cellular health in dynamic environments. Regulation of RNA synthesis in response to internal and environmental stimuli is typically achieved through interactions with RNAP at all stages of the transcription cycle- initiation, elongation, and termination. While studies of transcription initiation and elongation have identified multiple regulatory transcription factors and defined mechanisms, only a handful of protein factors able to terminate transcription have yet been described, and the general mechanism of transcription termination is still highly debated. We previously identified the first two factors capable of terminating transcription elongation complexes (TECs) in Archaea from the genetically tractable Thermococcus kodakarensis, and use both factors as models to explore the molecular mechanisms involved in collapse of the TEC. The Factor that terminates transcription in Archaea (FttA), a close homolog of the human CPSF subunit CPSF73, is completely conserved throughout Archaea, and appears to act analogously to the bacterial termination factor Rho, terminating transcription after the uncoupling of transcription and translation at the end of protein coding genes. We employed a novel genetic screen to verify the role of FttA in the polar repression of transcription, a phenomenon specific to regulation of genes contained within operons in prokaryotes. Eta, a euryarchaeal-specific superfamily 2 (SF2) helicase, appears to terminate transcription in a more specialized context, potentially terminating transcription of TECs arrested at sites of DNA damage while concurrently recruiting appropriate DNA repair enzymes, akin to the bacterial termination factor Mfd. A structure-function study of Eta employing select mutations derived from a crystallographic structure was conducted to elucidate the Eta-TEC contacts and various activities of Eta required for Eta-mediated termination. Further, many efforts were directed at establishing a role of Eta as an archaeal transcription-repair coupling factor (TRCF), and while this was not achieved, a state-of-the-art next-generation sequencing based approach to monitor nucleotide excision repair (NER) and the sub pathway transcription-coupled repair (TCR) genome-wide was developed and verified in E.coli. The work in this dissertation adds valuable insight to multiple fields of research. First, exploration into the mechanism of Eta-mediated transcription termination reveals a potential shared susceptibility of core RNAP subunits to transcription termination while elucidating activities of SF2 helicases- enzymes which are ubiquitously distributed in multiple essential cellular pathways. Second, our genetic screen identifies FttA as the archaeal polarity factor, shedding light on functions of an ancestral factor indispensable in mammalian transcription termination pathways. Establishment of the novel RADAR-seq/RNA-seq measurement of NER genome-wide will likely prove instrumental in future studies of archaeal DNA repair, and potentially presents a new paradigm in research of eukaryotic-like NER by use of Archaea as a advantageous model organism.Item Embargo The epitranscriptome in heat-loving Archaea enhances thermophily(Colorado State University. Libraries, 2023) Fluke, Kristin Alison, author; Santangelo, Thomas J., advisor; Wilusz, Carol, committee member; Sloan, Daniel, committee member; Abdo, Zaid, committee member>170 RNA modifications are known to decorate the transcriptome across all three Domains of life. The totality of RNA modifications in a cell is called the epitranscriptome. Modifications expand the form and function of RNA, often invoking new structures, activities, and interactions. The molecular consequences, fitness impacts, transcriptome-wide distribution, and genesis of the vast majority of modifications are largely unknown, but more > 100 human diseases are linked to mutations in the genes that encode RNA modifying enzymes. It is therefore critical to elucidate the generation and impact of RNA modifications on fitness and function. 5-methylcytidine (m5C) is one of the most abundant and conserved modifications across Domains and is generated through the post-transcriptional activities of several RNA m5C methyltransferases (R5CMTs). RNA modifications, especially m5C, have largely been studied in the context of abundant rRNA and tRNAs while research into the impact of mRNA modifications is lacking due to their low abundance in the cell. Archaeal model organisms have been shown to incorporate a higher abundance of select modifications compared to Eukarya, proving a new avenue to resolve fundamental questions regarding the phenotypic consequences of epitranscriptomic changes. In the model hyperthermophilic archaeon, Thermococcus kodakarensis, I comprehensively mapped m5C to the transcriptome. I identified at least five R5CMTs that site-specifically generate m5C and showed an unprecedented level of m5C incorporation that includes 10% of unique transcripts, mainly in mRNA. I demonstrated that R5CMTs target mRNAs for modification with both sequence and structural specificity. Cells lacking m5C exhibit a severe temperature dependent growth defect, indicating the m5C epitranscriptome is critical for cellular fitness under heat stress. The extensive m5C epitranscriptome coupled with the large collection of R5CMTs indicate that T. kodakarensis is the ideal model system to pursue fundamental questions regarding the epitranscriptome. Efforts to identify RNA methyltransferases that install m5C led to the discovery of a novel modification, N4,N4-dimethylcytidine (m42C) and the enzyme responsible for its in vivo and in vitro installation. I showed that m42C is robustly resistant to bisulfite-driven deamination, potentially indicating that all bisulfite-sequencing datasets may be falsely reporting m5C sites that are instead occupied by m42C. I mapped a single m42C residue to the ribosomal decoding center in the 16S rRNA and showed that cells lacking m42C exhibit a severe growth defect at higher temperatures. Structural studies of the enzyme that generates m42C, tentatively named m42C synthase, demonstrate it adopts a canonical class I Rossman fold at the C-terminal lobe and a unique N-terminal lobe. I showed that m42C synthase methylates assembled ribosomes and defined the catalytic amino acid residue. Taken together, I report a novel writer enzyme and show that both m5C and m42C promote hyperthermophilic growth. The dense and chemically diverse epitranscriptome argues that Thermococcus provides an excellent model system for further epitranscriptomic studies that probe the impact of both ubiquitous and rare modifications on core biological processes.