Regulation of Cellular and HIV-1 Gene Expression by Positive Transcription Elongation Factor B: A Dissertation

O'Brien, Siobhan

26 October 2010

RNA polymerase II-mediated transcription of HIV-1 genes depends on positive transcription elongation factor b (P-TEFb), the complex of cyclin T1 and CDK9. Recent evidence suggests that regulation of transcription by P-TEFb involves chromatin binding and modifying factors. To determine how P-TEFb may connect chromatin remodeling to transcription, we investigated the relationship between P-TEFb and histone H1. We show that P-TEFb interacts with H1 and that H1 phosphorylation in cell culture correlates with P-TEFb activity. Importantly, P-TEFb also directs H1 phosphorylation during Tat transactivation and wild type HIV-1 infection. Our results also show that P-TEFb phosphorylates histone H1.1 at a specific C-terminal site. Expression of a mutant H1.1 that cannot be phosphorylated by P-TEFb disrupts Tat transactivation as well as transcription of the c-fos and hsp70 genes in HeLa cells. P-TEFb phosphorylation of H1 also plays a role in the expression of muscle differentiation marker genes in the skeletal myoblast cell line C2C12. Additionally, ChIP experiments demonstrate that H1 dissociates from the HIV-1 LTR in MAGI cells, stress-activated genes in HeLa cells, and muscle differentiation marker genes in C2C12 cells under active P-TEFb conditions. Our results overall suggest a new role for P-TEFb in both cellular and HIV-1 transcription through chromatin.

RNA Polymerase II

Transcription Factors

HIV-1

Amino Acids, Peptides, and Proteins

Genetics and Genomics

Viruses

A More Accessible Drosophila Genome to Study Fly CNS Development: A Dissertation

Chen, Hui-Min

16 March 2015

Understanding the complex mechanisms to assemble a functional brain demands sophisticated experimental designs. Drosophila melanogaster, a model organism equipped with powerful genetic tools and evolutionarily conserved developmental programs, is ideal for such mechanistic studies. Valuable insights were learned from research in Drosophila ventral nerve cord, such as spatial patterning, temporal coding, and lineage diversification. However, the blueprint of Drosophila cerebrum development remains largely unknown. Neural progenitor cells, called neuroblasts (NBs), serially and stereotypically produce neurons and glia in the Drosophila cerebrum. Neuroblasts inherit specific sets of early patterning genes, which likely determine their individual identities when neuroblasts delaminate from neuroectoderm. Unique neuroblasts may hence acquire the abilities to differentially interpret the temporal codes and deposit characteristic progeny lineages. We believe resolving this age-old speculation requires a tracing system that links patterning genes to neuroblasts and corresponding lineages, and further allows specific manipulations. Using modern transgenic systems, one can immortalize transient NB gene expressions into continual labeling of their offspring. Having a collection of knockin drivers that capture endogenous gene expression patterns would open the door for tracing specific NBs and their progenies based on the combinatorial expression of various early patterning genes. Anticipating the need for a high throughput gene targeting system, we created Golic+ (gene targeting during oogenesis with lethality inhibitor and CRISPR/Cas “plus”), which features efficient homologous recombination in cystoblasts and a lethality selection for easy targeting candidate recovery. Using Golic+, we successfully generated T2AGal4 knock-ins for 6 representative early patterning genes, including lab, unpg, hkb, vnd, ind, and msh. They faithfully recapitulated the expression patterns of the targeted genes. After preserving initial NB expressions by triggering irreversible genetic labeling, we revealed the lineages founded by the NBs expressing a particular early patterning gene. Identifying the neuroblasts and lineages that express a particular early patterning gene should elucidate the genetic origin of neuroblast diversity. We believe such an effort will lead to a deeper understanding of brain development and evolution.

Drosophila melanogaster

Cerebrum

Neural Stem Cells

Body Patterning

Gene Targeting

Cell Lineage

CRISPR-Cas Systems

Dissertations, UMMS

Developmental Biology

Developmental Neuroscience

Genetics and Genomics

Genomics

Approaches and Considerations Towards a Safe and Effective Adeno-Associated Virus Mediated Therapeutic Intervention for GM1-Gangliosidosis: A Dissertation

Weismann, Cara M.

05 August 2014

GM1 gangliosidosis is a lysosomal storage disorder caused by a deficiency in the catabolizing enzyme β-galactosidase (βgal). This leads to accumulation of GM1-ganglioside (GM1) in the lysosome inducing ER stress and cell death. GM1 gangliosidosis is primarily a disorder of the central nervous system (CNS) with peripheral organ involvement. In this work we report two major findings, 1) systemic treatment of GM1 gangliosidosis with an adenoassociated virus (AAV9) encoding mouse-βgal (mβgal) in a GM1 gangliosidosis mouse model (βGal-/-), and 2) an investigation into an intracranial injection of a therapeutic AAVrh8 encoding mβgal. Systemic treatment of GM1 gangliosidosis with AAV9 resulted in a moderate expression of enzyme in the CNS, reduction of GM1 storage, significant retention of motor function and a significant increase in lifespan. Interestingly, the therapeutic effect was more robust in females. Intracranial injections of AAVrh8 vector expressing high levels of βgal resulted in enzyme spread throughout the brain, significant retention of motor function and a significant increase in lifespan. Histological alterations were also found at the injection site in both βGal-/- and normal animals. We constructed a series of vectors with a range of decreasing enzyme expression levels to investigate the cause for the unanticipated result. Microarrays were performed on the injection site and we showed that a lower expressing AAVrh8-mβgal vector mitigated the negative response. Intracranial injection of this newly developed vector was shown to clear lysosomal storage throughout the CNS of βGal-/- mice. Taken together, these studies indicate that a combined systemic and fine-tuned intracranial approach may be the most effective in clearing lysosomal storage completely in the CNS while providing therapeutic benefit to the periphery.

Dependovirus

G(M1) Ganglioside

GM1 Gangliosidosis

Genetic Vectors

Lysosomal Storage Diseases

beta-Galactosidase

Dissertations, UMMS

Gangliosidosis, GM1

Genetics and Genomics

Nervous System Diseases

Neuroscience and Neurobiology

Therapeutics

The Recombination Enhancer Modulates the Conformation of Chr. III in Budding Yeast: A Dissertation

Belton, Jon-Matthew

09 December 2014

A hierarchy of different chromosome conformations plays a role in many biological systems. These conformations contribute to the regulation of gene expression, cellular development, chromosome transmission, and defects can lead to human disease. The highest functional level of this hierarchy is the partitioning of the genome into compartments of active and inactive chromatin domains (1’s -10’s Mb). These compartments are further partitioned into Topologically Associating Domains (TADs) that spatially cluster co-regulated genes (100’s kb – 1’s Mb). The final level that has been observed is long range loops formed between regulatory elements and promoters (10’s kb – 100’s Mb). At all of these levels, mechanisms that establish these conformations remain poorly understood. To gain new insights into processes that determine chromosome folding I used the mating type switching system in budding yeast to study the chromosome conformation at length scales analogous to looping interaction. I specifically examined the role in chromosome conformation in the mating type switching system. Budding yeast cells can have two sexes: MATa and MATα. The mating types are determined by allele-specific expression of the MAT locus on chromosome III. The MATa allele encodes for transcription factors responsible for the MATa mating type and the MATα allele encodes transcription factors responsible for the MATα mating type. Yeast cells can switch their mating type by a process that repairs a break at MAT using one of two silent loci, HML or HMR, as a donor to convert the allele at the MAT locus. When MATa cells switch they prefer to use HML, which contains the MATα allele, located at the end of the left arm. MATα cells prefer to use HMR, which contains the MATa allele, located on the end of the right arm of chromosome III. The sequences of the HM loci are not important for donor preference. Instead the cell chooses the donor on the left arm in MATa cells and chooses the donor on the right arm in MATα cells. This lack of sequence specificity has led to the hypothesis that the conformation of the chromosome may play a role in donor preference. I found that the conformation of chromosome III is, indeed, different between the two mating types. In MATa cells the chromosomes displays a more crumpled conformation in which the left arm of the chromosome interacts with a large region of the right arm which includes the centromere and the MAT locus. In MATα cells, on the other hand, the left arm of the chromosomes displays a more extend conformation. I found that the Recombination Enhancer (RE), which enhances recombination along the left arm of the chromosome in MATa cells, is responsible for these mating type-specific conformations. Deleting the RE affects the conformation of the chromosomes in both MATa and MATα cells. The left portion of the RE, which is essential for donor preference during the switching reaction in MATa cells, does not contribute to the conformation in MATa. This region does have a minor effect on the conformation in MATα cells. However, I found that the right portion of the RE is responsible for the conformation of chromosome III in both mating types prior to initiation of switching. This work demonstrates that chromosome conformation is determined by specific cis regulatory elements that drive cell-type specific chromosome conformation.

Chromosomes

Protein Conformation

Fungal Mating Type Genes

Saccharomycetales

Genetic Recombination

Dissertations, UMMS

Genes, Mating Type, Fungal

Recombination, Genetic

Genetics and Genomics

Genomics

Structural Biology

Genes Required for Wallerian Degeneration Also Govern Dendrite Degeneration: A Dissertation

Rooney, Timothy M.

03 April 2015

Neurons comprise the main information processing cells of the nervous system. To integrate and transmit information, neurons elaborate dendritic structures to receive input and axons to relay that information to other cells. Due to their intricate structures, dendrites and axons are susceptible to damage whether by physical means or via disease mechanisms. Studying responses to axon injury, called Wallerian degeneration, in the neuronal processes of Drosophila melanogaster has allowed the identification of genes that are required for injury responses. Screens in Drosophila have identified dsarm and highwire as two genes required for axon degeneration; when these genes are mutated axons fail to degenerate after injury, even when completely cut off from the neuronal cell body. We found that these genes are also required for dendrite degeneration after injury in vivo. Further, we reveal differences between axon and dendrite injury responses using in vivo timelapse recordings and GCaMP indicators of intracellular and mitochondrial calcium transients. These data provide insights into the neuronal responses to injury, and better define novel targets for the treatment of neurodegenerative diseases.

Wallerian degeneration

dendrite degeneration

nervous system

Dissertations, UMMS

Axons

Dendrites

Drosophila melanogaster

Neurites

Neurodegenerative Diseases

Neurons

Wallerian Degeneration

Genetics and Genomics

Molecular and Cellular Neuroscience

Neuroscience and Neurobiology

Investigation of RNA Binding Protein Pumilio as a Genetic Modifier of Mutant CHMP2B in Frontotemporal Dementia (FTD): A Masters Thesis

Du, Xing

14 August 2016

Frontotemporal dementia (FTD) is the second most common early-onset dementia. A rare mutation in CHMP2B gene was found to be associated with FTD linked to chromosome 3. Previous studies have shown that mutant CHMP2B could lead to impaired autophagy pathway and altered RNA metabolism. However, it is still unknown what genes mediate the crosstalk between different pathways affected by mutant CHMP2B. Genetic screens designed to identify genes interacting with mutant CHMP2B represents a key approach in solving the puzzle. Expression of mutant CHMP2B (CHMP2Bintron5) in Drosophila eyes leads to a neurodegenerative phenotype including melanin deposition and disrupted internal structure of ommatidia. The phenotype is easily quantified by estimating the percentage of black dots on the surface of the eyes. Using this established Drosophila model, I searched for genes encoding RNA binding proteins that genetically modify CHMP2Bintron5 toxicity. I found that partial loss of Pumilio, a translation repressor, mitigates CHMP2Bintron5 induced toxicity in the fly eyes. Western blot analysis showed that down regulation of Pumilio does not significantly decrease CHMP2Bintron5 protein level, indicating indirect regulation involved in suppression of the phenotype. The molecular targets regulated by Pumilio and the mechanism underlying CHMP2Bintron5 toxicity suppression by Pumilio down-regulation requires further investigation.

Frontotemporal Dementia

RNA-Binding Proteins

Theses, UMMS

Biochemistry

Genetics and Genomics

Medical Genetics

Molecular Biology

Nervous System Diseases

Plague and the Defeat of Mammalian Innate Immunity: Systematic Genetic Analysis of Yersinia pestis Virulence Factors: A Dissertation

Palace, Samantha G.

26 July 2016

Yersinia pestis, the causative agent of plague, specializes in causing dense bacteremia following intradermal deposition of a small number of bacteria by the bite of an infected flea. This robust invasiveness requires the ability to evade containment by the innate immune system. Of the various mechanisms employed by Y. pestis to subvert the innate immune response and to proliferate rapidly in mammalian tissue, only a few are well-characterized. Here, I present two complementary genetic analyses of Y. pestis adaptations to the mammalian environment. In the first, genome-wide fitness profiling for Y. pestis by Tn-seq demonstrates that the bacterium has adapted to overcome limitation of diverse nutrients during mammalian infection. In the second, a series of combinatorial targeted mutations disentangles apparent functional redundancy among the effectors of the Y. pestis type III secretion system, and we report that YpkA, YopT, and YopJ contribute to virulence in mice. We have also begun to investigate a novel relationship between Y. pestis and mammalian platelets, a highly abundant cell type in plasma. I present evidence that Y. pestis has evolved specific mechanisms to interfere with platelet activation, likely in order to evade immune responses and promote maintenance of bacteremia by undermining platelet thrombotic and innate immune functions. The principles guiding this work – systematic genetic analysis of complex systems, coupled with rational modification of in vitro assays to more closely mimic the in vivo environment – are a generalizable approach for increasing the efficiency of discovering new virulence determinants in bacterial pathogens.

Immune System

Innate Immunity

Plague

Platelet Activation

Virulence

Virulence Factors

Yersinia pestis

Dissertations, UMMS

Immunity, Innate

Bacterial Infections and Mycoses

Bacteriology

Genetics and Genomics

Immunity

Immunology of Infectious Disease

Pathogenic Microbiology

Functions of Argonaute Proteins in Self Versus Non-Self Recognition in the C. elegans Germline: A Dissertation

Seth, Meetu

18 August 2016

Organisms employ sophisticated mechanisms to silence foreign nucleic acid, such as viruses and transposons. Evidence exists for pathways that sense copy number, unpaired DNA, or aberrant RNA (e.g., dsRNA), but the mechanisms that distinguish “self” from “non-self” are not well understood. Our studies on transgene silencing in C. elegans have uncovered an RNA surveillance system in which the PIWI protein, PRG-1, uses a vast repertoire of piRNAs to recognize foreign transcripts and to initiate epigenetic silencing. Partial base pairing by piRNAs is sufficient to guide PRG-1 targeting. PRG-1 in turn recruits RdRP to synthesize perfectly matching antisense siRNAs (22G-RNAs) that are loaded onto worm-specific Argonaute (WAGO) proteins. WAGOs collaborate with chromatin factors to maintain epigenetic silencing (RNAe). Since mismatches are allowed during piRNA targeting, piRNAs could—in theory— target any transcript expressed in the germline, but germline genes are not subject to silencing by RNAe. Moreover, some foreign sequences are expressed and appear to be adopted as “self.” How are “self” transcripts distinguished from foreign transcripts? We have found that another Argonaute, CSR-1, and its siRNAs—also synthesized by RdRP—protect endogenous genes from silencing by RNAe. We refer to this pathway as RNA-mediated gene activation (RNAa). Reducing CSR-1 or PRG-1 or increasing piRNA targeting can shift the balance towards expression or silencing, indicating that PRG-1 and CSR-1 compete for control over their targets. Thus worms have evolved a remarkable nucleic acids immunity mechanism in which opposing Argonaute pathways generate and maintain epigenetic memories of self and non-self nucleotide sequences.

RNA Interference

Small Interfering RNA

Argonaute Proteins

Caenorhabditis elegans Proteins

Dissertations, UMMS

RNA, Small Interfering

Biochemistry

Developmental Biology

Genetics and Genomics

Molecular Biology

The Plasticity and Variation in Gene Expression during Development in C. elegans

Chan, Io Long

23 September 2019

Organisms modulate their response to changing environmental conditions through changes in gene expression, and extensive variations in gene expression are prevalent among individuals even within a population. This widespread plasticity and variability of gene expression is thought to play roles in adaptation and drive novel phenotypes in species. Understanding the mechanisms that contribute to such variations requires the analysis of interactions between the genome and its environment and sequence variations within the genome. This work consists of two projects investigating the plasticity and variation of gene expression during post-embryonic development in the nematode C. elegans. In the first study, I examined the response to changes in population density in developmentally arrested L1 larvae. I systematically characterized arrested L1 larvae from low to high densities using single-worm RNA-seq and uncovered that the density of resuspended L1 larvae regulates the expression of hundreds of mRNAs. Further analysis revealed that the physiological response to changes in density is rapid and signaled by a non-canonical daf-22 ascaroside independent pathway. In the second study, I investigated the evolution of gene expression within species using two genetically divergent C. elegans strains (N2 and CB4856). I carried out RNA-seq and allele-specific analysis across six different conditions and four developmental stages, and we examined gene expression divergence using the homozygous parent and F1 hybrid system. This work provides a new experimental model for studying the evolution of gene expression and a comprehensive view of gene expression variation during development in C. elegans.

c elegans

gene regulation

development

RNA-seq

evolution

metabolism

epigenetics

bleaching

synchronization

gene expression

Biology

Developmental Biology

Genetics and Genomics

Genomics

Molecular Genetics

Factors Influencing Primate Hair Microbiome Diversity

Kitrinos, Catherine

01 September 2021

Primate hair is both a substrate upon which essential social interactions occur and an important host-pathogen interface. As commensal microbes provide important immune functions for their hosts, understanding the microbial diversity in primate hair could provide insight into primate immunity and disease transmission. While studies of human hair and skin microbiomes show differences in microbial communities across body regions, little is known about the nonhuman primate hair microbiome. In this study, we collected hair samples (n=159) from 8 body regions across 12 nonhuman primate species housed at 3 US institutions to examine 1) the diversity and composition of the primate hair microbiome and 2) the factors predicting primate hair microbiome diversity and composition. If both environmental and evolutionary factors shape the microbiome, then we would expect significant differences in microbiome diversity across host body sites, host sex, host housing institutions, and host species. We found that the hair microbiomes of these captive primates contained high abundances of gut-, respiratory-, and environment-associated microbiota rather than skin-associated microbiota. We also found that host species identity is the strongest predictor of both hair microbiome diversity and composition, while sex and body region are strong predictors of taxonomic richness and microbiome composition, and institution is a moderate predictor for both diversity and composition. Our results suggest that hair microbial communities are affected by both evolutionary and environmental factors and vary both within and across primate species, and that there may be transmission of microbes across primate body regions. These findings have important implications for understanding the biology and conservation of both wild and captive primates.

microbiome

primatology

hair

evolution

microbiology

Animal Sciences

Biological and Physical Anthropology

Biology

Ecology and Evolutionary Biology

Environmental Studies

Genetics and Genomics

Immunology and Infectious Disease

Microbiology

Other Anthropology

Other Life Sciences