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1. Biochemical characterization of Mycobacterial RNA polymerases

   https://doi.org/10.1128/jb.00256-24  

   Cooper, Stephanie L; Requijo, Ryan M; Lucius, Aaron L; Schneider, David A (October 2024, Journal of Bacteriology)

   Champion, Patricia A (Ed.)

   ABSTRACT Tuberculosis is caused by the bacteriumMycobacterium tuberculosis(Mtb). While eukaryotic species employ several specialized RNA polymerases (Pols) to fulfill the RNA synthesis requirements of the cell, bacterial species use a single RNA polymerase (RNAP). To contribute to the foundational understanding of how Mtb and the related non-pathogenic mycobacterial species,Mycobacterium smegmatis(Msm), perform the essential function of RNA synthesis, we performed a series ofin vitrotranscription experiments to define the unique enzymatic properties of Mtb and Msm RNAPs. In this study, we characterize the mechanism of nucleotide addition used by these bacterial RNAPs with comparisons to previously characterized eukaryotic Pols I, II, and III. We show that Mtb RNAP and Msm RNAP demonstrate similar enzymatic properties and nucleotide addition kinetics to each other but diverge significantly from eukaryotic Pols. We also show that Mtb RNAP and Msm RNAP uniquely bind a nucleotide analog with significantly higher affinity than canonical nucleotides, in contrast to eukaryotic RNA polymerase II. This affinity for analogs may reveal a vulnerability for selective inhibition of the pathogenic bacterial enzyme.IMPORTANCETuberculosis, caused by the bacteriumMycobacterium tuberculosis(Mtb), remains a severe global health threat. The World Health Organization (WHO) has reported that tuberculosis is second only to COVID-19 as the most lethal infection worldwide, with more annual deaths than HIV and AIDS (WHO.int). The first-line treatment for tuberculosis, Rifampin (or Rifampicin), specifically targets the Mtb RNA polymerase. This drug has been used for decades, leading to increased numbers of multi-drug-resistant infections (Stephanie,et al). To effectively treat tuberculosis, there is an urgent need for new therapeutics that selectively target vulnerabilities of the bacteria and not the host. Characterization of the differences between Mtb enzymes and host enzymes is critical to inform these ongoing drug design efforts. 

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2. Engineering polymerases for applications in synthetic biology

   https://doi.org/10.1017/S0033583520000050  

   Nikoomanzar, Ali; Chim, Nicholas; Yik, Eric J.; Chaput, John C. (January 2020, Quarterly Reviews of Biophysics)

   Abstract DNA polymerases play a central role in biology by transferring genetic information from one generation to the next during cell division. Harnessing the power of these enzymes in the laboratory has fueled an increase in biomedical applications that involve the synthesis, amplification, and sequencing of DNA. However, the high substrate specificity exhibited by most naturally occurring DNA polymerases often precludes their use in practical applications that require modified substrates. Moving beyond natural genetic polymers requires sophisticated enzyme-engineering technologies that can be used to direct the evolution of engineered polymerases that function with tailor-made activities. Such efforts are expected to uniquely drive emerging applications in synthetic biology by enabling the synthesis, replication, and evolution of synthetic genetic polymers with new physicochemical properties. 

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3. Engineered signal-coupled inducible promoters: measuring the apparent RNA-polymerase resource budget

   https://doi.org/10.1093/nar/gkaa734  

   Davey, James A; Wilson, Corey J (September 2020, Nucleic Acids Research)

   Abstract Inducible promoters are a central regulatory component in synthetic biology, metabolic engineering, and protein production for laboratory and commercial uses. Many of these applications utilize two or more exogenous promoters, imposing a currently unquantifiable metabolic burden on the living system. Here, we engineered a collection of inducible promoters (regulated by LacI-based transcription factors) that maximize the free-state of endogenous RNA polymerase (RNAP). We leveraged this collection of inducible promotors to construct simple two-channel logical controls that enabled us to measure metabolic burden – as it relates to RNAP resource partitioning. The two-channel genetic circuits utilized sets of signal-coupled transcription factors that regulate cognate inducible promoters in a coordinated logical fashion. With this fundamental genetic architecture, we evaluated the performance of each inducible promoter as discrete operations, and as coupled systems to evaluate and quantify the effects of resource partitioning. Obtaining the ability to systematically and accurately measure the apparent RNA-polymerase resource budget will enable researchers to design more robust genetic circuits, with significantly higher fidelity. Moreover, this study presents a workflow that can be used to better understand how living systems adapt RNAP resources, via the complementary pairing of constitutive and regulated promoters that vary in strength. 

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4. Overexpression and isolation of RGVG and Y639F mutants of T7 RNA polymerase for in vitro transcription of modified RNA strands

   Allison Dittmer, Alex (March 2023, ACS spring 2023)

   Intrinsic properties of RNA to form Watson-Crick base pairing allows it to self-assemble into specific and programmable nano-sized complexes. However, the naturally occurring RNA strands are not stable, and they hydrolyze quickly in blood serum. This limits RNA application, for example, as a nanovehicle for targeted drug delivery. The replacement of the hydroxyl group at the 2’ position of the ribose to 2’-Fluoro (2’-F) or 2’-Methoxy (2’-Met) can drastically elevate the resistance of the RNA to nucleases and improve overall stability. However, to synthesize such modified RNAs, a mutated version of traditionally used T7 RNA polymerase is often required. The recombinant RNApol will not discriminate between regular riboNucleotideTriphosphates (rNTPs) vs modified-rNTPs and, hence, can be implemented to transcribe modified RNA strands. Herein, we describe overexpression and isolation of RGVG and Y639F RNA polymerases from E.Coli cells using metal-ion immobilized affinity chromatography. We demonstrated that in optimized conditions, these RNA polymerases can be used to obtain milligram quantities of 2’-F and 2’-Met RNA polymers possessing high levels of resistance to nuclease degradation in blood serum. 

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5. Novel Viral DNA Polymerases From Metagenomes Suggest Genomic Sources of Strand-Displacing Biochemical Phenotypes

   https://doi.org/10.3389/fmicb.2022.858366  

   Keown, Rachel A.; Dums, Jacob T.; Brumm, Phillip J.; MacDonald, Joyanne; Mead, David A.; Ferrell, Barbra D.; Moore, Ryan M.; Harrison, Amelia O.; Polson, Shawn W.; Wommack, K. Eric (April 2022, Frontiers in Microbiology)

   Viruses are the most abundant and diverse biological entities on the planet and constitute a significant proportion of Earth’s genetic diversity. Most of this diversity is not represented by isolated viral-host systems and has only been observed through sequencing of viral metagenomes (viromes) from environmental samples. Viromes provide snapshots of viral genetic potential, and a wealth of information on viral community ecology. These data also provide opportunities for exploring the biochemistry of novel viral enzymes. The in vitro biochemical characteristics of novel viral DNA polymerases were explored, testing hypothesized differences in polymerase biochemistry according to protein sequence phylogeny. Forty-eight viral DNA Polymerase I (PolA) proteins from estuarine viromes, hot spring metagenomes, and reference viruses, encompassing a broad representation of currently known diversity, were synthesized, expressed, and purified. Novel functionality was shown in multiple PolAs. Intriguingly, some of the estuarine viral polymerases demonstrated moderate to strong innate DNA strand displacement activity at high enzyme concentration. Strand-displacing polymerases have important technological applications where isothermal reactions are desirable. Bioinformatic investigation of genes neighboring these strand displacing polymerases found associations with SNF2 helicase-associated proteins. The specific function of SNF2 family enzymes is unknown for prokaryotes and viruses. In eukaryotes, SNF2 enzymes have chromatin remodeling functions but do not separate nucleic acid strands. This suggests the strand separation function may be fulfilled by the DNA polymerase for viruses carrying SNF2 helicase-associated proteins. Biochemical data elucidated from this study expands understanding of the biology and ecological behavior of unknown viruses. Moreover, given the numerous biotechnological applications of viral DNA polymerases, novel viral polymerases discovered within viromes may be a rich source of biological material for further in vitro DNA amplification advancements. 

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