Group I Introns and Homing Endonucleases in T-even-like Bacteriophages

Sandegren, Linus

January 2004

<p>Homing endonucleases are rare-cutting enzymes that cleave DNA at a site near their own location, preferentially in alleles lacking the homing endonuclease gene (HEG). By cleaving HEG-less alleles the homing endonuclease can mediate the transfer of its own gene to the cleaved site via a process called homing, involving double strand break repair. Via homing, HEGs are efficiently transferred into new genomes when horizontal exchange of DNA occurs between organisms.</p><p>Group I introns are intervening sequences that can catalyse their own excision from the unprocessed transcript without the need of any proteins. They are widespread, occurring both in eukaryotes and prokaryotes and in their viruses. Many group I introns encode a HEG within them that confers mobility also to the intron and mediates the combined transfer of the intron/HEG to intronless alleles via homing.</p><p>Bacteriophage T4 contains three such group I introns and at least 12 freestanding HEGs in its genome. The majority of phages besides T4 do not contain any introns, and freestanding HEGs are also scarcely represented among other phages.</p><p>In the first paper we looked into why group I introns are so rare in phages related to T4 in spite of the fact that they can spread between phages via homing. We have identified the first phage besides T4 that contains all three T-even introns and also shown that homing of at least one of the introns has occurred recently between some of the phages in Nature. We also show that intron homing can be highly efficient between related phages if two phages infect the same bacterium but that there also exists counteracting mechanisms that can restrict the spread of introns between phages. </p><p>In the second paper we have looked at how the presence of introns can affect gene expression in the phage. We find that the efficiency of splicing can be affected by variation of translation of the upstream exon for all three introns in T4. Furthermore, we find that splicing is also compromised upon infection of stationary-phase bacteria. This is the first time that the efficiency of self-splicing of group I introns has been coupled to environmental conditions and the potential effect of this on phage viability is discussed.</p><p>In the third paper we have characterised two novel freestanding homing endonucleases that in some T-even-like phages replace two of the putative HEGs in T4. We also present a new theory on why it is a selective advantage for freestanding, phage homing endonucleases to cleave both HEG-containing and HEG-less genomes.</p>

Bacteriophage

Self-splicing introns

Homing endonucleases

Molecular biology

Molekylärbiologi

Group I Introns and Homing Endonucleases in T-even-like Bacteriophages

Sandegren, Linus

January 2004

Homing endonucleases are rare-cutting enzymes that cleave DNA at a site near their own location, preferentially in alleles lacking the homing endonuclease gene (HEG). By cleaving HEG-less alleles the homing endonuclease can mediate the transfer of its own gene to the cleaved site via a process called homing, involving double strand break repair. Via homing, HEGs are efficiently transferred into new genomes when horizontal exchange of DNA occurs between organisms. Group I introns are intervening sequences that can catalyse their own excision from the unprocessed transcript without the need of any proteins. They are widespread, occurring both in eukaryotes and prokaryotes and in their viruses. Many group I introns encode a HEG within them that confers mobility also to the intron and mediates the combined transfer of the intron/HEG to intronless alleles via homing. Bacteriophage T4 contains three such group I introns and at least 12 freestanding HEGs in its genome. The majority of phages besides T4 do not contain any introns, and freestanding HEGs are also scarcely represented among other phages. In the first paper we looked into why group I introns are so rare in phages related to T4 in spite of the fact that they can spread between phages via homing. We have identified the first phage besides T4 that contains all three T-even introns and also shown that homing of at least one of the introns has occurred recently between some of the phages in Nature. We also show that intron homing can be highly efficient between related phages if two phages infect the same bacterium but that there also exists counteracting mechanisms that can restrict the spread of introns between phages. In the second paper we have looked at how the presence of introns can affect gene expression in the phage. We find that the efficiency of splicing can be affected by variation of translation of the upstream exon for all three introns in T4. Furthermore, we find that splicing is also compromised upon infection of stationary-phase bacteria. This is the first time that the efficiency of self-splicing of group I introns has been coupled to environmental conditions and the potential effect of this on phage viability is discussed. In the third paper we have characterised two novel freestanding homing endonucleases that in some T-even-like phages replace two of the putative HEGs in T4. We also present a new theory on why it is a selective advantage for freestanding, phage homing endonucleases to cleave both HEG-containing and HEG-less genomes.

Bacteriophage

Self-splicing introns

Homing endonucleases

Molecular biology

Molekylärbiologi

An evolutionary and biochemical characterization of a self-splicing group II intron and its encoded LAGLIDADG homing endonuclease in Leptographium truncatum

Mullineux, Sahra-Taylor

06 July 2010

Evolutionary relationships amongst strains of the fungal genus Leptographium and related taxa were inferred using the internal transcribed spacer (ITS) region of the nuclear ribosomal DNA repeat. To generate robust sequence alignments for phylogenetic analysis the relationship between DNA sequence variability and RNA structural conservation of ITS segments was examined. The results demonstrate that structural conservation of helical regions is facilitated by compensatory base changes, compensating insertions/deletions, and, possibly, RNA strand slippage. A high mol % G+C bias for ITS1 and ITS2 and structural constraints at the RNA level appear to limit the types of changes observed. Fifty strains of Leptographium were screened for the presence of introns within mitochondrial genes. Superimposing intron survey data onto the ITS-derived phylogenetic tree reveals that introns are absent from the small ribosomal RNA (rns) gene of all strains of L. procerum yet are found in all strains of L. lundbergii. Amongst members of L. wingfieldii, L. terebrantis, and L. truncatum intron distribution is stochastic and is not correlated to the evolutionary relationships amongst strains. A group II intron/LAGLIDADG homing endonuclease gene (HEG) composite element from the mt rns gene of L. truncatum strain CBS929.85 was characterized. Intron-catalyzed splicing was tested using ORF-less and ORF-containing precursor transcripts, and both versions of the intron readily self-splice under moderate temperature and ionic conditions (37 °C and 6 mM MgCl2). Cleavage activity of the intron-encoded protein (I-LtrII) was tested using an N-terminal His6-tagged and near native protein. The homing endonuclease cleaves double-stranded DNA 2 nucleotides upstream of the intron insertion site within the exon, generating 4 nucleotide 3’ OH overhangs. Intron splicing is not enhanced by the addition of I-LtrII and RNA-binding assays indicate that the His6-tagged protein does not bind to the intron. Phylogenetic relationships amongst the rns gene, intron, and amino acid sequences were inferred. An evolutionary model of the composite element is proposed in which the HEG invaded a group II intron and mobilized it. The mobile genetic element may be transmitted vertically amongst L. lundbergii strains and horizontally through lateral gene transfer amongst strains of L. wingfieldii, L. terebrantis, and L. truncatum.

group II

ribozymes

LAGLIDADG

homing

endonucleases

evolution

Leptographium

An evolutionary and biochemical characterization of a self-splicing group II intron and its encoded LAGLIDADG homing endonuclease in Leptographium truncatum

Mullineux, Sahra-Taylor

06 July 2010

Evolutionary relationships amongst strains of the fungal genus Leptographium and related taxa were inferred using the internal transcribed spacer (ITS) region of the nuclear ribosomal DNA repeat. To generate robust sequence alignments for phylogenetic analysis the relationship between DNA sequence variability and RNA structural conservation of ITS segments was examined. The results demonstrate that structural conservation of helical regions is facilitated by compensatory base changes, compensating insertions/deletions, and, possibly, RNA strand slippage. A high mol % G+C bias for ITS1 and ITS2 and structural constraints at the RNA level appear to limit the types of changes observed. Fifty strains of Leptographium were screened for the presence of introns within mitochondrial genes. Superimposing intron survey data onto the ITS-derived phylogenetic tree reveals that introns are absent from the small ribosomal RNA (rns) gene of all strains of L. procerum yet are found in all strains of L. lundbergii. Amongst members of L. wingfieldii, L. terebrantis, and L. truncatum intron distribution is stochastic and is not correlated to the evolutionary relationships amongst strains. A group II intron/LAGLIDADG homing endonuclease gene (HEG) composite element from the mt rns gene of L. truncatum strain CBS929.85 was characterized. Intron-catalyzed splicing was tested using ORF-less and ORF-containing precursor transcripts, and both versions of the intron readily self-splice under moderate temperature and ionic conditions (37 °C and 6 mM MgCl2). Cleavage activity of the intron-encoded protein (I-LtrII) was tested using an N-terminal His6-tagged and near native protein. The homing endonuclease cleaves double-stranded DNA 2 nucleotides upstream of the intron insertion site within the exon, generating 4 nucleotide 3’ OH overhangs. Intron splicing is not enhanced by the addition of I-LtrII and RNA-binding assays indicate that the His6-tagged protein does not bind to the intron. Phylogenetic relationships amongst the rns gene, intron, and amino acid sequences were inferred. An evolutionary model of the composite element is proposed in which the HEG invaded a group II intron and mobilized it. The mobile genetic element may be transmitted vertically amongst L. lundbergii strains and horizontally through lateral gene transfer amongst strains of L. wingfieldii, L. terebrantis, and L. truncatum.

group II

ribozymes

LAGLIDADG

homing

endonucleases

evolution

Leptographium

Gene editing in Aedes aegypti

Aryan, Azadeh

08 October 2013

Aedes aegypti (Ae. aegypti) is one of the most important vectors of dengue, chikungunya and yellow fever viruses. The use of chemical control strategies such as insecticides is associated with problems including the development of insecticide resistance, side effects on animal and human health, and environmental concerns. Because current methods have not proven sufficient to control these diseases, developing novel, genetics-based, control strategies to limit the transmission of disease is urgently needed. Increased knowledge about mosquito-pathogen relationships and the molecular biology of mosquitoes now makes it possible to generate transgenic mosquito strains that are unable to transmit various parasites or viruses. Ae. aegypti genetic experiments are enabled, and limited by, the catalog of promoter elements available to drive transgene expression. To find a promoter able to drive robust expression of firefly (FF) luciferase in Ae. aegypti embryos, an experiment was designed to compare Ae. aegypti endogenous and exogenous promoters. The PUb promoter was found to be extremely robust in expression of FF luciferase in different stages of embryonic development from 2-72 hours after injection. In subsequent experiments, transformation frequency was calculated using four different promoters (IE1, UbL40, hsp82 and PUb) to express the Mos1 transposase open reading frame in Mos1-mediated transgenesis. Germline transformation efficiency and size of transgenic cluster were not significantly different when using endogenous Ae. aegypti PUb or the commonly used exogenous Drosophila hsp82 promoter to express Mos1 transposase. This study also describes the development of new tools for gene editing in the Ae. aegypti mosquito genome and the use of these tools to design an efficient gene drive system in this mosquito. Homing endonucleases (HEs) are selfish elements which catalyze double-stranded DNA (dsDNA) breaks in a sequence-specific manner. The activities of four HEs (Y2-I-AniI, I-CreI, I-PpoI, and I-SceI) were investigated for their ability to catalyze the excision of genomic segments from the Ae. aegypti genome. All four enzymes were found to be active in Ae. aegypti; however, the activity of Y2-I-AniI was higher compared to the other three enzymes. Single-strand annealing (SSA) and non-homologous end-joining (NHEJ) pathways were identified as mechanisms to repair HE-induced dsDNA breaks. TALE nucleases (TALENs) are a group of artificial enzymes capable of generating site-specific DNA lesions. To examine the ability of TALENs for gene editing in Ae. aegypti, a pair of TALENs targeted to the kmo gene were expressed from a plasmid following embryonic injection. Twenty to forty percent of fertile G0 produced white-eyed progeny which resulted from disruption of the kmo gene. Most of these individuals produced more than 20% white-eyed progeny, with some producing up to 75%. A small deletion of one to seven bp occurred at the TALEN recognition site. These results show that TALEN and HEs are highly active in the Ae. aegypti germline and can be used for gene editing and gene drive strategies in Ae. aegypti. / Ph. D.

Aedes aegypti

PUb promoter

Homing endonucleases

TALEN

transgenic mosquito

Análise computacional da diversidade viral presente na comunidade microbiana do processo de compostagem do Zoológico de São Paulo / Computational analysis of the viral diversity in the Sao Paulo Zoo composting microbial community

Amgarten, Deyvid Emanuel

18 November 2016

O estudo da diversidade viral em amostras ambientais tem se tornado cada vez mais importante devido a funções-chave desempenhadas por esses organismos. Estudos recentes têm fornecido evidências de que vírus de bactérias (bacteriófagos) podem ser os principais determinantes em ciclos biogeoquímicos de grandes ecossistemas, além de atuarem no fluxo de genes entre comunidades ambientais e na plasticidade funcional das mesmas frente a estresses ambientais. Neste trabalho, propomos a investigação e caracterização da diversidade viral presente em amostras de compostagem através de abordagens não dependentes e dependentes de cultivo. Na primeira abordagem, coletamos amostras seriadas de uma unidade de compostagem do zoológico de São Paulo para realização de sequenciamento metagenômico. O conjunto de sequências gerado foi extensivamente minerado (data-mining) para a produção de resultados de diversidade e abundância de táxons virais ao longo do processo de compostagem. Adicionalmente, procedemos com a montagem e recuperação de sequências virais candidatas a genomas completos e/ou parciais de novos vírus ambientais. Os dois protocolos computacionais utilizados para a mineração de dados encontram-se definidos e automatizados, podendo ser aplicados em quaisquer conjuntos de dados de sequenciamento metagenômico ou metatranscritômico obtidos através da plataforma Illumina. A segunda abordagem correspondeu ao isolamento e caracterização de novos fagos de Pseudomonas obtidos de amostras de compostagem. Três novos fagos foram identificados e tiveram os seus genomas sequenciados. A caracterização genômica desses fagos revelou genomas com alto grau de novidade, insights sobre a evolução de Caudovirales e a presença de genes de tRNA, cuja função pode estar relacionada com um mecanismo dos fagos para contornar o viés traducional apresentado pela bactéria hospedeira. A caracterização experimental dos novos fagos isolados demonstrou grande potencial para lise e dissolução de biofilme da cepa Pseudomonas aeruginosa PA14, conhecida como agente causador de infecções hospitalares em pacientes imunodeprimidos. Em suma, os dados reunidos nesta dissertação caracterizam a diversidade presente no viroma da compostagem e contribuem para o entendimento dos perfis taxonômico, funcional e ecológico do processo. / The study of the viral diversity in environmental samples has become increasingly important due to key-roles that are performed by these organisms in our ecosystems. Recent publications provide evidence that viruses of bacteria (bacteriophages) may be key-players in biogeochemical cycles of large ecosystems, as oceans and forests. Besides, they may also be determinant in the genes flux among populations and in the plasticity of the communities face to environmental stresses. In this work, we propose the investigation and characterization of the viral diversity in composting samples through non-culturable and culturable-dependent approaches. In the first approach, we sampled a composting unit from the Sao Paulo Zoo Park in different time points and proceeded with metagenomic sequencing. The dataset generated was extensively mined to provide results of diversity and abundance of viral taxa through the composting process. Additionally, we proceeded with the assembly and retrieval of candidate sequences to partial or/and complete viral genomes. The two computational protocols were automatized as pipelines and can be applied to any metagenomic dataset of illumina reads. The second approach refers to the isolation and characterization of new Pseudomonas phages obtained from composting samples. Three new phages were identified and their genomes were sequenced. A detailed characterization of these genomes revealed high degree of novelty, insights about evolution of tailed-phages and the presence of tRNA genes, which may be related to a mechanism to bypass host translational bias. The experimental characterization of the new phages demonstrated great potential to lyse bacterial cells and to degrade Pseudomonas aeruginosa PA14 biofilms. In short, the data presented in this dissertation shed light to the composting virome diversity, as well as to the functional and ecological profiles of viruses in the composting environment.

Bioinformática

Bioinformatics

Compostagem

Composting

Diversidade

Diversity

Environmental viruses

Fagos

Homing-endonucleases

Homing-endonucleases

Metagenômica

Metagenomics

Phages

Pipeline

Pipeline

Virus

Vírus

Vírus ambientais

Análise computacional da diversidade viral presente na comunidade microbiana do processo de compostagem do Zoológico de São Paulo / Computational analysis of the viral diversity in the Sao Paulo Zoo composting microbial community

Deyvid Emanuel Amgarten

18 November 2016

O estudo da diversidade viral em amostras ambientais tem se tornado cada vez mais importante devido a funções-chave desempenhadas por esses organismos. Estudos recentes têm fornecido evidências de que vírus de bactérias (bacteriófagos) podem ser os principais determinantes em ciclos biogeoquímicos de grandes ecossistemas, além de atuarem no fluxo de genes entre comunidades ambientais e na plasticidade funcional das mesmas frente a estresses ambientais. Neste trabalho, propomos a investigação e caracterização da diversidade viral presente em amostras de compostagem através de abordagens não dependentes e dependentes de cultivo. Na primeira abordagem, coletamos amostras seriadas de uma unidade de compostagem do zoológico de São Paulo para realização de sequenciamento metagenômico. O conjunto de sequências gerado foi extensivamente minerado (data-mining) para a produção de resultados de diversidade e abundância de táxons virais ao longo do processo de compostagem. Adicionalmente, procedemos com a montagem e recuperação de sequências virais candidatas a genomas completos e/ou parciais de novos vírus ambientais. Os dois protocolos computacionais utilizados para a mineração de dados encontram-se definidos e automatizados, podendo ser aplicados em quaisquer conjuntos de dados de sequenciamento metagenômico ou metatranscritômico obtidos através da plataforma Illumina. A segunda abordagem correspondeu ao isolamento e caracterização de novos fagos de Pseudomonas obtidos de amostras de compostagem. Três novos fagos foram identificados e tiveram os seus genomas sequenciados. A caracterização genômica desses fagos revelou genomas com alto grau de novidade, insights sobre a evolução de Caudovirales e a presença de genes de tRNA, cuja função pode estar relacionada com um mecanismo dos fagos para contornar o viés traducional apresentado pela bactéria hospedeira. A caracterização experimental dos novos fagos isolados demonstrou grande potencial para lise e dissolução de biofilme da cepa Pseudomonas aeruginosa PA14, conhecida como agente causador de infecções hospitalares em pacientes imunodeprimidos. Em suma, os dados reunidos nesta dissertação caracterizam a diversidade presente no viroma da compostagem e contribuem para o entendimento dos perfis taxonômico, funcional e ecológico do processo. / The study of the viral diversity in environmental samples has become increasingly important due to key-roles that are performed by these organisms in our ecosystems. Recent publications provide evidence that viruses of bacteria (bacteriophages) may be key-players in biogeochemical cycles of large ecosystems, as oceans and forests. Besides, they may also be determinant in the genes flux among populations and in the plasticity of the communities face to environmental stresses. In this work, we propose the investigation and characterization of the viral diversity in composting samples through non-culturable and culturable-dependent approaches. In the first approach, we sampled a composting unit from the Sao Paulo Zoo Park in different time points and proceeded with metagenomic sequencing. The dataset generated was extensively mined to provide results of diversity and abundance of viral taxa through the composting process. Additionally, we proceeded with the assembly and retrieval of candidate sequences to partial or/and complete viral genomes. The two computational protocols were automatized as pipelines and can be applied to any metagenomic dataset of illumina reads. The second approach refers to the isolation and characterization of new Pseudomonas phages obtained from composting samples. Three new phages were identified and their genomes were sequenced. A detailed characterization of these genomes revealed high degree of novelty, insights about evolution of tailed-phages and the presence of tRNA genes, which may be related to a mechanism to bypass host translational bias. The experimental characterization of the new phages demonstrated great potential to lyse bacterial cells and to degrade Pseudomonas aeruginosa PA14 biofilms. In short, the data presented in this dissertation shed light to the composting virome diversity, as well as to the functional and ecological profiles of viruses in the composting environment.

Bioinformática

Compostagem

Diversidade

Fagos

Homing-endonucleases

Metagenômica

Pipeline

Vírus

Vírus ambientais

Bioinformatics

Composting

Diversity

Environmental viruses

Homing-endonucleases

Metagenomics

Phages

Pipeline

Virus

Exploring the rns gene landscape in ophiostomatoid fungi and related taxa: Molecular characterization of mobile genetic elements and biochemical characterization of intron-encoded homing endonucleases.

Abdel-Fattah, Mohamed Hafez

January 2012

The mitochondrial small-subunit ribosomal RNA (mt. SSU rRNA = rns) gene appears to be a reservoir for a number of group I and II introns along with the intron- encoded proteins (IEPs) such as homing endonucleases (HEases) and reverse transcriptases. The key objective for this thesis was to examine the rns gene among different groups of ophiostomatoid fungi for the presence of introns and IEPs. Overall the distribution of the introns does not appear to follow evolutionary lineages suggesting the possibility of rare horizontal gains and frequent loses. Some of the novel findings of this work were the discovery of a twintron complex inserted at position S1247 within the rns gene, here a group IIA1 intron invaded the ORF embedded within a group IC2 intron. Another new element was discovered within strains of Ophiostoma minus where a group II introns has inserted at the rns position S379; the mS379 intron represents the first mitochondrial group II intron that has an RT-ORF encoded outside Domain IV and it is the first intron reported to at position S379. The rns gene of O. minus WIN(M)371 was found to be interrupted with a group IC2 intron at position mS569 and a group IIB1 intron at position mS952 and they both encode double motif LAGLIDADG HEases referred as I-OmiI and I-OmiII respectively. These IEPs were examined in more detail to evaluate if these proteins represent functional HEases. To express I-OmiI and I-OmiII in Escherichia. coli, a codon-optimized versions of I-OmiI and I-OmiII sequences were synthesized based on differences between the fungal mitochondrial and bacterial genetic code. The optimized I-OmiI and I-OmiII sequences were cloned in the pET200/D TOPO expression vector system and transformed into E. coli BL21 (DE3). These two proteins were biochemically characterized and the results showed that: both I-OmiI and I-OmiII are functional HEases. Detailed data for I-OmiII showed that this endonuclease cleaves the target site two nucleotides upstream of the intron insertion site generating 4 nucleotide 3’overhangs.

Mitochondrial genome

Mobile introns

Homing endonucleases

mt. SSU rRNA gene

Twintron

reverse transcriptase

Exploring the rns gene landscape in ophiostomatoid fungi and related taxa: Molecular characterization of mobile genetic elements and biochemical characterization of intron-encoded homing endonucleases.

Abdel-Fattah, Mohamed Hafez

January 2012

The mitochondrial small-subunit ribosomal RNA (mt. SSU rRNA = rns) gene appears to be a reservoir for a number of group I and II introns along with the intron- encoded proteins (IEPs) such as homing endonucleases (HEases) and reverse transcriptases. The key objective for this thesis was to examine the rns gene among different groups of ophiostomatoid fungi for the presence of introns and IEPs. Overall the distribution of the introns does not appear to follow evolutionary lineages suggesting the possibility of rare horizontal gains and frequent loses. Some of the novel findings of this work were the discovery of a twintron complex inserted at position S1247 within the rns gene, here a group IIA1 intron invaded the ORF embedded within a group IC2 intron. Another new element was discovered within strains of Ophiostoma minus where a group II introns has inserted at the rns position S379; the mS379 intron represents the first mitochondrial group II intron that has an RT-ORF encoded outside Domain IV and it is the first intron reported to at position S379. The rns gene of O. minus WIN(M)371 was found to be interrupted with a group IC2 intron at position mS569 and a group IIB1 intron at position mS952 and they both encode double motif LAGLIDADG HEases referred as I-OmiI and I-OmiII respectively. These IEPs were examined in more detail to evaluate if these proteins represent functional HEases. To express I-OmiI and I-OmiII in Escherichia. coli, a codon-optimized versions of I-OmiI and I-OmiII sequences were synthesized based on differences between the fungal mitochondrial and bacterial genetic code. The optimized I-OmiI and I-OmiII sequences were cloned in the pET200/D TOPO expression vector system and transformed into E. coli BL21 (DE3). These two proteins were biochemically characterized and the results showed that: both I-OmiI and I-OmiII are functional HEases. Detailed data for I-OmiII showed that this endonuclease cleaves the target site two nucleotides upstream of the intron insertion site generating 4 nucleotide 3’overhangs.

Mitochondrial genome

Mobile introns

Homing endonucleases

mt. SSU rRNA gene

Twintron

reverse transcriptase

Investigation of Ribonuclease HI handle region dynamics using Solution-state nuclear magnetic resonance spectroscopy, Molecular Dynamic simulations and X-ray crystallography

Martin, James Arthur

January 2020

Ribonuclease HI (RNase HI), a ubiquitous, non-sequence-specific endonuclease, cleaves the RNA strand in RNA/DNA hybrids. The enzyme has roles in replication, genome maintenance, and is the C-terminal domain of retroviral multi-domain reverse transcriptase (RT) proteins. Murine Leukemia Virus (MLV) and Human Immunodeficiency Virus (HIV) are two such retroviruses and their RNase HI (RNHI) domains are necessary for viral replication, making it an attractive drug target. RNase HI has a “handle region”, an extended loop with a large cluster of positive residues, that is critical for substrate recognition. MLV-RNHI is active in isolation and contains a handle region, but, HIV-RNHI is inactive in isolation and does not contain a handle region. HIV-RT, however, has a region in its polymerase domain (positive charge cluster and aromatic cluster) that makes contact with the RNHI domain that may be serving as a “pseudo” handle region; additionally, insertion of a handle region into isolated HIVRNHI restores its activity. Overall, a breadth of information exists on this region’s dynamics, but important gaps remain unfilled; gaps that may potentially lead to creating effective drugs to treat the above-mentioned viruses. Solution-state nuclear magnetic resonance (NMR) spectroscopy combined with Molecular Dynamic (MD) simulations suggest a model in which the extended handle region domain of the mesophilic Escherichia coli RNHI (EcRNHI) populates "open" (substrate-bindingcompetent) and "closed" (substrate-binding incompetent) states, while the thermophilic Thermus thermophilus RNHI (TtRNHI) mainly populates the closed state at 300 K. In addition, an in silico designed mutant Val98Ala (V98A) EcRNHI was predicted to populate primarily the closed state. Understanding the structural features and internal motions that lead RNase HI to adopt these various conformers is of central importance to better understanding RNase HI’s role in retroviral infection. To formulate a comprehensive model on handle region dynamics, an integrative approach of NMR spectroscopy, X-ray crystallography, and MD simulations is employed. The sensitivity to internal conformational dynamics at multiple time scales of NMR spectroscopy, molecular range and resolution of X-ray crystallography, and structural interpretations of dynamic processes by MD simulations create a synergistic trio capable of tackling this issue. First, the in silico 2-state Kinetic model is validated through NMR observables that correlate with the respective conformers, thus serving as experimental analogs. The NMR parameters also correlate with the Michaelis constants (KM) for RNHI homologs and help to confirm the in silico predictions of V98A EcRNHI. This study shows the important role of the handle region in modulation of substrate recognition. It also illustrates the power of NMR spectroscopy in dissecting the conformational preferences underlying enzyme function. Next, a deeper dive is taken into handle region dynamics, specifically focusing on residue 88 and the impact its identity has on this region. Its sidechain interactions are shown to directly correlate with handle region conformations and helps to amend the originally proposed in silico 2-state Kinetic model. Lastly, looking at RNHI handle region dynamics through an evolutionary lens opens the door to uncovering novel mutations that have been previously overlooked or not identified. Through a phylogenetic analysis, researchers have reconstructed seven ancestral RNHI mutants and three of them have been expressed here. The sequence identity of these three ancestral mutants range from 60-87% to extant homologs and this is reflected by similar peak positions in their 15N HSQC spectra. Requisite experiments to assign the NMR backbone have been completed.

Biophysics

Biochemistry

HIV (Viruses)

Mouse leukemia viruses

RNA

Endonucleases

Nuclear magnetic resonance spectroscopy