Cytopathology and Release of an RNA Virus From a Strain of Trichomonas Vaginalis

Champney, W. Scott, Curtis, Sherill K., Samuels, Robert

01 January 1995

A strain of Trichomonas vaginalis infected with a double-stranded RNA virus showed pronounced cytopathology in the form of giant syncytia generated by the recruitment of single cells. The giant cells ultimately lysed, releasing virus into the culture medium. In the infected cells, clusters of electron-dense particles resembling viral structures were found in the cytoplasm. In addition, distinctive inclusions composed of similar particles were present in the nuclei of some cells. Double-stranded viral RNA of 5.5 kbp was demonstrated in both cytoplasmic and nuclear fractions from these cells. Viral particles collected from the cell-free culture supernatant were of the same shape and size as the RNA virus isolated from a strain of T. vaginalis described previously (Wang and Wang, Journal of Biological Chemistry, 260: 3697-3702, 1985; Wang and Wang, Proceedings of the National Academy of Sciences of the U.S.A. 83: 7956-7986) which does not show this cytopathology.

cytopathology

double-stranded RNA virus

flagellate

protozoan virus

Trichomonas vaginalis

Biomedical Sciences

RNase L Amplifies Interferon Signaling by Inducing Protein Kinase R-Mediated Antiviral Stress Granules

Manivannan, Praveen

January 2020

No description available.

Biology

Virology

PKR

RNase L

Rig-I

double-stranded RNA

interferon

stress granules

Endogenous double-stranded RNA as a trigger for inflammation in health and disease

Dorrity, Tyler Johnathon

January 2024

Double-stranded RNA (dsRNA) is a key molecule that initiates the immune response to viral infection, but increasingly endogenous (self) dsRNA has been found to be central to the pathology of diverse non-infectious diseases, from neurodegenerative disease to autoimmunity to cancers. Therefore, it is critical to understand the mechanisms that regulate endogenous dsRNA and the pattern recognition receptors that sense dsRNA. In this dissertation, I address three main questions pertaining to this. First, why is the brain so prone to dsRNA-mediated non-infectious disease, especially considering that dsRNA sensors are expressed in almost all tissues. Using stem cell differentiation, gene expression manipulation, and microscopy, I determined that neurons are a special cell type that express high levels of endogenous dsRNA. This high dsRNA burden in neurons is driven by global lengthening of 3`untranslated regions (3`UTRs) and induces tonic inflammation. Second, I examined the mechanism through which the dsRNA regulator ADAR1 controls endogenous dsRNA levels. I employed heavy use of tissue culture and visualization of dsRNA by confocal microscopy to determine that both the dsRNA-binding and dsRNA-editing activities of ADAR1 are required to suppress global endogenous dsRNA levels. Third, after identifying the existence of transcript isoforms of the key dsRNA sensor PKR, I explored their regulatory potential on the PKR protein itself. By genetically altering human cells, I identify that 3`UTR isoforms of PKR regulate transcript localization, translation efficiency, and PKR protein activatability. Overall, the studies described herein demonstrate novel regulatory roles of endogenous dsRNA and underscore the importance of dsRNA in neurological disease.

Immunology

Neurosciences

Double-stranded RNA

Nervous system--Diseases

Inflammation

Brain--Diseases

Neurons

Targeted DNA integration in human cells without double-strand breaks using CRISPR-associated transposases

King, Rebeca Teresa

January 2023

The world of precision medicine was revolutionized by the discovery of CRISPR-Cas systems. In particular, the capabilities of the programmable nuclease Cas9 and its derivatives have unlocked a world in which applied genome engineering to cure human disease is a reality being pursued in patient clinical trials. Gene editing via the induction of programmable, site-specific double strand breaks (DSBs) has been revolutionary for the precision medicine field. However, there are many safety concerns centered on the induction of DSBs causing potential undesirable on- and off-target consequences, particularly for in vivo CRISPR applications. To circumvent these warranted concerns, many groups have attempted to repurpose recombinases or engineer new fusion systems to perform programmable genome engineering without the induction of DSBs. This dissertation will first highlight the development of recombinases for programmable DNA insertions over the course of decades, including efforts to evolve novel DNA recognition sequences, efforts to tether recombinases to programmable DNA-binding proteins, and the recent discovery of naturally occurring RNA-guided DNA transposition systems. This dissertation will then highlight the development of CRISPR-associated transposases (CASTs) as DSB-independent programmable mammalian gene editing tools capable of integrating large DNA cargos, as well as the future directions that may further enhance CAST activity in human cells. The works in this dissertation detail the initial efforts to engineer and optimize a new class of genome manipulation tools that were previously absent from the gene editing toolkit.

Genetics

Biochemistry

Personalized medicine

CRISPR (Genetics)

DNA-binding proteins

Nucleases

Double-stranded RNA

Homology-Directed Repair of One- and Two-Ended DNA Double-Strand Breaks

Kimble, Michael Taylor

January 2023

DNA double-strand breaks (DSBs) are one of the most dangerous lesions cells encounter, given that DSBs can lead to genomic instability and cell death if not repaired properly. Cells have two primary pathways to repair DSBs: Homologous recombination (HR) and nonhomologous end-joining (NHEJ). HR is the high-fidelity branch of the DSB repair pathway since it employs a process of homology search and synthesis from a homologous template. The homology search is carried out by ssDNA that is generated on either side of the DSB by end resection. End resection occurs via a two-step mechanism involving resection initiation, followed by long-range resection. Previous work has revealed that long-range resection is dispensable for some cases of HR; however, it is currently unclear why the requirement for long-range resection is context- dependent. Furthermore, it is not completely clear how the mechanisms of HR, including requirements for long-range resection, apply to single-ended DSBs (seDSBs) arising during replication. Therefore, we defined the role of long-range resection in two-ended DSB repair in different chromosomal contexts. We also established a Cas9 nickase (Cas9n) system to study seDSB repair and defined genetic requirements for repair. To study the requirement for long-range resection in HR, we employed inter- and intrachromosomal genetic recombination assays in haploid yeast. We found that long-range resection is required for interchromosomal HR, but not for intrachromosomal HR. This difference is linked to the observation that the DNA damage checkpoint, which is deficient in the absence of long-range resection, is activated in interchromosomal HR, but not intrachromosomal HR. The DNA damage checkpoint has also previously been implicated in promoting chromosome mobility. Therefore, we reason that the requirement for long-range resection in interchromosomal repair is due to a need to activate the DNA damage checkpoint and chromosome mobility, specifically during slower repair events. To study seDSB repair, we implemented Cas9n, which creates nicks that can cause replication fork collapse. We demonstrated that expression of Cas9n with an efficient gRNA can induce replication fork collapse and that repair of these seDSBs breaks is dependent on the HR machinery. A genome-wide screen using Cas9n revealed a requirement for replication-coupled nucleosome assembly (RCNA) in repair of seDSBs, specifically in replication origin-deplete regions of the genome. Consistent with the model of seDSB repair, we found that Cas9n-induced seDSBs preferentially undergo sister chromatid recombination. This preference was altered in the absence of Mre11, which we hypothesize is due to a role of MRX in sister chromatid tethering. Altogether, the results presented in this thesis offer a different perspective on the role of long-range resection in two-ended DSB repair and establish a Cas9n-based system to better study single-ended DSB repair.

Genetics

Double-stranded RNA

DNA repair

Genomes

DNA damage

Yeast--Genetics

Genetic recombination

Structural and functional studies of the bacterial RECA protein

Rajan, Rakhi

24 August 2007

No description available.

Biophysics, General

Homologous recombination

RecA

double stranded DNA break

x-ray crystallography

LuxS

Structural Analysis of DdrB from Deinococcus radiodurans: Insight into the Mechanism of Protein Mediated Single-Stranded DNA Annealing

Sugiman-Marangos, Seiji N.

13 September 2014

<p>Bacteria of the genus <em>Deinococcus</em> are perhaps the most resilient life forms ever discovered, demonstrating extreme resistance to ionizing radiation, ultraviolet radiation, desiccation, and a variety of mutagenic chemical agents. The most studied member of this genus, <em>D. radiodurans</em>, has been observed to rapidly reassemble its genome following severe fragmentation by hundreds of γ-radiation induced double-strand DNA breaks. Amongst the numerous factors contributing to DNA repair, a single-stranded annealing protein, DdrB, is believed to play an important role during the initial phases of recovery. The work described in this thesis represents the first structural characterization of DdrB, revealing a novel fold for single-stranded DNA binding. Together with biochemical data delineating the DNA-binding interface, two crystal structures of the DdrB/ssDNA complex were also solved, providing a comprehensive illustration of this interaction. Quaternary assemblies observed in these crystal structures also informed on the potential contribution of higher-order nucleoprotein complexes to the function of DdrB in single-stranded annealing. Most significantly, a face-to-face assembly of DdrB/ssDNA complexes provided insight into the mechanism by which DdrB mediates annealing of DNA, which may represent a common mechanism shared by other single-stranded annealing proteins.<strong></strong></p> / Doctor of Philosophy (PhD)

DdrB

Deinococcus radiodurans

single-stranded DNA annealing

structural biology

Structural Biology

Structural Biology

Étude de l’activité de Staufen1 dans la régulation traductionnelle de certains ARNm

Dugré-Brisson, Samuel

12 1900

Le transport et la traduction localisée des ARN messagers sont observés chez plusieurs organismes et sont requis pour de multiples phénomènes tels la mémoire, la division cellulaire asymétrique et l’établissement des axes durant le développement. Staufen, une protéine liant l’ARN double-brin, a été identifié dans un premier temps chez la mouche à fruits Drosophila melanogaster. Il a été montré, chez cet organisme, que Staufen est requis pour la localisation des messagers bicoid et oskar aux pôles antérieur et postérieur de l’ovocyte, respectivement. Également, Staufen est requis afin que la répression traductionnelle du messager oskar soit levée une fois qu’il est bien localisé. Chez les mammifères, Stau1 est une protéine ubiquiste qui est présente dans des complexes prenant la forme de granules dans les dendrites des neurones. Également, Stau1 peut interagir de façon indépendante de l’ARN avec le ribosome et cofractionner tant avec la sous-unité 40S qu’avec la sous-unité 60S du ribosome dans un gradient de saccharose. L’implication de Stau1 dans un mécanisme permettant la dérépression traductionnelle de certains ARNm chez les mammifères était donc une voie d’investigation intéressante. Nous avons donc décidé de vérifier si Stau1 mammifère avait la capacité de stimuler la traduction d’un ARNm cellulaire via un mécanisme régulé. Au moment où cette thèse a été entreprise, aucun ARNm cellulaire lié par Stau1 n’avait été identifié chez les mammifères. Des structures d’ARN double-brin ont donc été employées afin de réprimer la traduction d’un ARNm rapporteur. C’est ainsi que nous avons montré que Stau1 peut stimuler la traduction d’un ARNm lorsqu’il lie celui-ci dans sa région 5’ non-traduite. Par la suite, en employant des micropuces d’ADN, nous avons identifié des messagers cellulaires dont la distribution dans les polysomes lourds est modifiée par Stau1. En effet, un groupe de messagers est enrichi dans les polysomes lourds suite à une surexpression de Stau1, ce qui suggère que Stau1 stimule la traduction de cette population d’ARNm. Afin d’identifier un mécanisme potentiel de régulation de l’activité traductionnelle de Stau1, nous nous sommes intéressés à la capacité d’auto-association de cette protéine. Nous avons montré que Stau1, tout comme plusieurs protéines liant l’ARN double-brin, est en mesure de s’associer à lui-même, et ce, d’une façon indépendante de l’ARN. Nous avons identifié les déterminants impliqués mettant ainsi au jour un nouveau mécanisme pouvant influencer les activités cellulaires de Stau1. Les résultats présentés dans cette thèse suggèrent donc que Stau1 est en mesure de stimuler la traduction d’une sous-population précise d’ARN messagers au sein de la cellule permettant ainsi de jeter un regard nouveau sur l’implication de cette protéine dans divers phénomènes au sein de l’organisme. / Transport and local translation of RNA are found in several organisms and are required for multiple phenomena such as memory, asymmetric cell division and establishment of the axis during development. Staufen, a double-stranded RNA binding protein, was first identified in Drosophila melanogaster. In the fruitfly, it was shown that Staufen is required for the proper localization of the bicoid and oskar transcripts to the anterior and posterior ends of the oocyte, respectively. It was also found that Staufen is important for the translational derepression of oskar once it is adequately localized. In mammals, Stau1 is a ubiquitous protein found in granules in the dendrites of neurons. Also, Stau1 can bind the ribosome in a RNA-independent manner and cofractionates with both ribosomal subunits in a sucrose gradient. The implication of Stau1 in a mechanism allowing translational derepression of certain RNAs in mammals was therefore an interesting path to explore. Accordingly, we decided to verify if mammalian Stau1 had the capacity to stimulate the translation of cellular RNAs through a regulated mechanism. When this thesis was initiated, no cellular RNA target of Stau1 had been identified in mammals. Therefore, double-stranded RNA structures were used to repress the translation of a reporter mRNA. With this model, we showed that Stau1 can stimulate the translation of a transcript when it is bound to its 5’ UTR. With the use of DNA microarrays, we identified cellular mRNAs which distribution in heavy polysomes was altered by Stau1. When Stau1 is overexpressed, this group of mRNAs is enriched heavy polysomes, suggesting a translational stimulation of this population by Stau1. To identify a regulatory mechanism that could influence Stau1’s translational activity, we studied the self-association capacity of this protein. We showed that Stau1, like several double-stranded RNA binding proteins, can self-associate in a RNA-independent manner. We have identified the determinants required for this interaction that as the potential to be important for the regulation of the cellular activities of Stau1. The results presented in this thesis suggest that Stau1 can stimulate the translation of a specific subset of mRNAs in the cell, letting us look at Stau1’s implication in different processes from a new point of view.

Stau1

ARN messager

Traduction

ARN double-brin

Auto-association

Domaine de liaison à l'ARN double-brin

Messenger RNA

Translation

Double-stranded RNA

Self-Association

Double-stranded RNA binding domain

Étude de l’activité de Staufen1 dans la régulation traductionnelle de certains ARNm

Dugré-Brisson, Samuel

12 1900

Le transport et la traduction localisée des ARN messagers sont observés chez plusieurs organismes et sont requis pour de multiples phénomènes tels la mémoire, la division cellulaire asymétrique et l’établissement des axes durant le développement. Staufen, une protéine liant l’ARN double-brin, a été identifié dans un premier temps chez la mouche à fruits Drosophila melanogaster. Il a été montré, chez cet organisme, que Staufen est requis pour la localisation des messagers bicoid et oskar aux pôles antérieur et postérieur de l’ovocyte, respectivement. Également, Staufen est requis afin que la répression traductionnelle du messager oskar soit levée une fois qu’il est bien localisé. Chez les mammifères, Stau1 est une protéine ubiquiste qui est présente dans des complexes prenant la forme de granules dans les dendrites des neurones. Également, Stau1 peut interagir de façon indépendante de l’ARN avec le ribosome et cofractionner tant avec la sous-unité 40S qu’avec la sous-unité 60S du ribosome dans un gradient de saccharose. L’implication de Stau1 dans un mécanisme permettant la dérépression traductionnelle de certains ARNm chez les mammifères était donc une voie d’investigation intéressante. Nous avons donc décidé de vérifier si Stau1 mammifère avait la capacité de stimuler la traduction d’un ARNm cellulaire via un mécanisme régulé. Au moment où cette thèse a été entreprise, aucun ARNm cellulaire lié par Stau1 n’avait été identifié chez les mammifères. Des structures d’ARN double-brin ont donc été employées afin de réprimer la traduction d’un ARNm rapporteur. C’est ainsi que nous avons montré que Stau1 peut stimuler la traduction d’un ARNm lorsqu’il lie celui-ci dans sa région 5’ non-traduite. Par la suite, en employant des micropuces d’ADN, nous avons identifié des messagers cellulaires dont la distribution dans les polysomes lourds est modifiée par Stau1. En effet, un groupe de messagers est enrichi dans les polysomes lourds suite à une surexpression de Stau1, ce qui suggère que Stau1 stimule la traduction de cette population d’ARNm. Afin d’identifier un mécanisme potentiel de régulation de l’activité traductionnelle de Stau1, nous nous sommes intéressés à la capacité d’auto-association de cette protéine. Nous avons montré que Stau1, tout comme plusieurs protéines liant l’ARN double-brin, est en mesure de s’associer à lui-même, et ce, d’une façon indépendante de l’ARN. Nous avons identifié les déterminants impliqués mettant ainsi au jour un nouveau mécanisme pouvant influencer les activités cellulaires de Stau1. Les résultats présentés dans cette thèse suggèrent donc que Stau1 est en mesure de stimuler la traduction d’une sous-population précise d’ARN messagers au sein de la cellule permettant ainsi de jeter un regard nouveau sur l’implication de cette protéine dans divers phénomènes au sein de l’organisme. / Transport and local translation of RNA are found in several organisms and are required for multiple phenomena such as memory, asymmetric cell division and establishment of the axis during development. Staufen, a double-stranded RNA binding protein, was first identified in Drosophila melanogaster. In the fruitfly, it was shown that Staufen is required for the proper localization of the bicoid and oskar transcripts to the anterior and posterior ends of the oocyte, respectively. It was also found that Staufen is important for the translational derepression of oskar once it is adequately localized. In mammals, Stau1 is a ubiquitous protein found in granules in the dendrites of neurons. Also, Stau1 can bind the ribosome in a RNA-independent manner and cofractionates with both ribosomal subunits in a sucrose gradient. The implication of Stau1 in a mechanism allowing translational derepression of certain RNAs in mammals was therefore an interesting path to explore. Accordingly, we decided to verify if mammalian Stau1 had the capacity to stimulate the translation of cellular RNAs through a regulated mechanism. When this thesis was initiated, no cellular RNA target of Stau1 had been identified in mammals. Therefore, double-stranded RNA structures were used to repress the translation of a reporter mRNA. With this model, we showed that Stau1 can stimulate the translation of a transcript when it is bound to its 5’ UTR. With the use of DNA microarrays, we identified cellular mRNAs which distribution in heavy polysomes was altered by Stau1. When Stau1 is overexpressed, this group of mRNAs is enriched heavy polysomes, suggesting a translational stimulation of this population by Stau1. To identify a regulatory mechanism that could influence Stau1’s translational activity, we studied the self-association capacity of this protein. We showed that Stau1, like several double-stranded RNA binding proteins, can self-associate in a RNA-independent manner. We have identified the determinants required for this interaction that as the potential to be important for the regulation of the cellular activities of Stau1. The results presented in this thesis suggest that Stau1 can stimulate the translation of a specific subset of mRNAs in the cell, letting us look at Stau1’s implication in different processes from a new point of view.

Stau1

ARN messager

Traduction

ARN double-brin

Auto-association

Domaine de liaison à l'ARN double-brin

Messenger RNA

Translation

Double-stranded RNA

Self-Association

Double-stranded RNA binding domain

Chromatin Regulators and DNA Repair: A Dissertation

Bennett, Gwendolyn M.

19 December 2014

DNA double-strand break (DSB) repair is essential for maintenance of genome stability. However, the compaction of the eukaryotic genome into chromatin creates an inherent barrier to any DNA-mediated event, such as during DNA repair. This demands that there be mechanisms to modify the chromatin structure and thus access DNA. Recent work has implicated a host of chromatin regulators in the DNA damage response and several functional roles have been defined. Yet the mechanisms that control their recruitment to DNA lesions, and their relationship with concurrent histone modifications, remain unclear. We find that efficient DSB recruitment of many yeast chromatin regulators is cell-cycle dependent. Furthering this, we find recruitment of the INO80, SWR-C, NuA4, SWI/SNF, and RSC enzymes is inhibited by the non-homologous end joining machinery, and that their recruitment is controlled by early steps of homologous recombination. Strikingly, we find no significant role for H2A.X phosphorylation (γH2AX) in the recruitment of chromatin regulators, but rather that their recruitment coincides with reduced levels of γH2AX. We go on to determine the chromatin remodeling enzyme Fun30 functions in histone dynamics surround a DSB, but does not significantly affect γH2AX dynamics. Additionally, we describe a conserved functional interaction among the chromatin remodeling enzyme, SWI/SNF, the NuA4 and Gcn5 histone acetyltransferases, and phosphorylation of histone H2A.X. Specifically, we find that the NuA4 and Gcn5 enzymes are both required for the robust recruitment of SWI/SNF to a DSB, which in turn promotes the phosphorylation of H2A.X.

Chromatin

Chromatin Assembly and Disassembly

DNA

Double-Stranded DNA Breaks

DNA Repair

Non-Histone Chromosomal Proteins

Histones

Dissertations, UMMS

DNA Breaks, Double-Stranded

Chromosomal Proteins, Non-Histone

Cellular and Molecular Physiology

Genetics and Genomics