Control of retroviral replication by host cellular factors /

Kaiser, Shari Marie.

January 2007

Thesis (Ph. D.)--University of Washington, 2007. / Vita. Includes bibliographical references (leaves 115-127).

Involvement of CDP/Cux in the Regulation of Histone H4 Gene Expression, Proliferation and Differentiation: a Dissertation

Luong, Mai X.

07 May 2003

Proliferation and differentiation are essential processes for the growth and development of higher eukaryotic organisms. Regulation of gene expression is essential for control of cell division and differentiation. Normal eukaryotic cells have a limited proliferative capacity, and ultimately undergo cellular senescence and apoptosis. Terminal differentiation of cells is associated with loss of proliferative capacity and acquisition of specialized functions. Proliferation and differentiation are processes required for the creation and maintenance of diverse tissues both during embryonic development and postnatal life. The cell cycle is the process by which cells reproduce, and requires duplication and segregation of hereditary material. Loss of cell cycle control leads to genetic instability and cancer. Expression of replication-dependent histone genes is tightly coupled to DNA synthesis, thus making histone genes a good model for studying cell cycle regulation. The HiNF-D complex interacts with all five classes (H1, H2A, H2B, H3 and H4) of histone genes in a cell cycle-dependent manner. The CCAAT displacement protein (CDP)/Cux and the tumor suppressor pRB are key components of the HiNF-D complex. However, the molecular interactions that enable CDP/Cux and pRB to form a complex and thus convey cell growth regulatory information onto histone gene promoters are poorly understood. Transient transfection assays show that CDP/Cux represses the histone H4 promoter and that the pRB large pocket domain functions with CDP/Cux as a co-repressor. Direct interaction between CDP/Cux C-terminus and the pRB pocket domain was observed in GST pull-down assays. Furthermore, co-immunoprecipitation assays and immunofluorescence microscopy established that CDP/Cux and pRB form complexes in vivo and associate in situ. pRB interaction and co-repression with CDP/Cux is independent of pRB phosphosphorylation sites, as revealed by GST pull-down assays and transient transfection assays using a series of pRB mutant proteins. Thus, several converging lines of evidence indicate that complexes between CDP/Cux and pRB repress cell cycle-regulated histone gene promoters. CDP/Cux is regulated by phosphorylation and acetylation at the C-terminus, which contains two repressor domains and interacts with histone deacetylase HDAC1. In vivo function of the CDP/Cux C-terminus in development and gene regulation was assessed in genetically targeted mice (Cutl1tm2Ejn, referred to as Cutl1ΔC). The mice express a mutant CDP/Cux protein with a deletion of the C-terminus including the homeodomain. Indirect immunofluorescence microscopy showed that the mutant protein exhibited significantly reduced nuclear localization in comparison to the wildtype protein. Consistent with these data, DNA binding activity of HiNF-D was lost in nuclear extracts derived from mouse embryonic fibroblasts (MEFs) or adult tissues of homozygous mutant (Cutl1 ΔC -/-) mice, indicating the functional loss of CDP/Cux in the nucleus. No significant difference in growth characteristics or total histone H4 mRNA levels was observed between wildtype and Cutl1 ΔC -/- MEFs in culture. However, the histone H4.1 (murine FO108) gene containing CDP/Cux binding sites have reduced expression levels in homozygous mutant MEFs. Stringent control of growth and differentiation appears to be compromised in vivo. Homozygous mutant mice exhibit stunted growth (20-50% weight reduction), a high postnatal death rate of 60-70%, sparse abnormal coat hair and severely reduced fertility. Hair follicle deformities and severely diminished fertility in Cutl1 ΔC -/- mice suggest that CDP/Cux is required for normal development of dermal tissues and reproductive functions. Together the data presented in this dissertation provide new insight into the in vivo functions of CDP/Cux in the regulation of histone gene expression, growth control and differentiation.

Gene Expression Regulation

Histones

Nuclear Proteins

Repressor Proteins

Amino Acids, Peptides, and Proteins

Cells

Genetic Phenomena

Tn1 Insertions in the 3' Untranslated Region of the ant Operon of Bacteriophage P22 Affect ant Gene Expression and Alter ant mRNA Stability: a Thesis

McMahan, Linda

01 September 1985

Insertion of transposable elements within an operon has been known not only to abolish expression of the gene interrupted by the insertion, but also to exert a strong polar effect on the expression of downstream genes in the same operon. In this dissertation, I have shown that insertions of the transposable ampicillin-resistance element Tn1, either in the polar or nonpolar orientation, in the 3' untranslated region of the bacteriophage P22 antirepressor (ant) operon reduce the rate of upstream ant gene expression; insertions of Tn1 in the nonpolar orientation reduce the rate of ant gene expression more significantly than those in the polar orientation. This effect appears to be due to reduced stability of ant mRNA. Tn1 deletion mutants of one of the nonpolar Tn1 insertion mutations have been isolated. Two classes of Tn1 deletions are obtained. Class I retains a 68 bp Tn1 sequence that shows a potential 14 bp stem and 37 bp loop conformation, while class II retains 147 bp Tn1 sequence that shows a potential 69 bp stem and 6 bp loop conformation. These two classes of Tn1 deletions do not delete any P22 sequences. Class I but not class II Tn1 deletion mutants restore the rate of ant gene expression and ant mRNA stability. Six different Ant+ revertants of the class II Tn1 deletion mutant simultaneously restore the rate of ant gene expression and ant mRNA stability. They all have deletions that remove all or part of the class II Tn1 sequence. In one case, the Tn1 sequence retained shows a potential 15 bp stem and 8 bp loop conformation, in the other cases, no secondary structure is predicted to form. The results of the Tn1 deletion mutants suggest that the stem-and-loop structures and the length of stems potentially formed by the Tn1 sequences in mRNA may affect its stability.

Operon

Gene Expression Regulation

Repressor Proteins

Viral Proteins

Academic Dissertations

Life Sciences

Medicine and Health Sciences

Human PC4 Prevents Mutagenesis and Killing by Oxidative DNA Damage: a Dissertation

Wang, Jen-Yeu

16 December 2004

Chapter II Abstract Human positive cofactor 4 (PC4) is a transcriptional coactivator with a highly conserved single-strand DNA (ssDNA) binding domain of unknown function. We identified PC4 as a suppressor of the oxidative mutator phenotype of the Escherichia coli fpg mutY mutant and demonstrate that this suppression requires its ssDNA binding activity. Saccharomyces cerevisiae mutants lacking their PC4 ortholog Sub1 are sensitive to hydrogen peroxide and exhibit spontaneous and peroxide-induced hypermutability. PC4 expression suppresses the peroxide sensitivity of the yeast sub1Δ mutant, suggesting that the human protein has a similar function. A role for yeast and human proteins in DNA repair is suggested by the demonstration that Sub1 acts in a peroxide resistance pathway involving Rad2 and by the physical interaction of PC4 with the human Rad2 homolog XPG. We show that XPG recruits PC4 to a bubble-containing DNA substrate with a resulting displacement of XPG and formation of a PC4-DNA complex. We discuss the possible requirement for PC4 in either global or transcription-coupled repair of oxidative DNA damage to mediate the release of XPG bound to its substrate. Chapter III Abstract Previously I established that (1) PC4 significantly suppresses oxidative mutagenesis via its single-strand DNA binding activity, (2) a partial suppression of H2O2-induced lethality was observed in a sub1Δ rad2Δ yeast double mutant compared to the sub1Δ mutant, and (3) PC4 interacts with XPG physically and functionally. These results led me to believe that suppression of oxidative mutagenesis and lethality by PC4 is partially due to its function in an XPG/Rad2-dependent pathway and through additional unidentified mechanism(s). In this chapter, I present studies aimed at investigating different DNA repair pathways in which PC4/Sub1 might participate. I address the possible roles of PC4/Sub1 in transcription-coupled repair (TCR) in terms of its binding specificity to oxidative DNA lesions and its ability to allow efficient resumption of transcription after oxidative DNA damaging treatment. To ask if PC4/Sub1 interacts with other DNA repair proteins to protect cells from oxidative DNA damage, I analyzed spontaneous mutation rates among a series of isogenic, haploid yeast mutant strains deficient of SUB1, base excision repair (BER) and/or nucleotide excision repair (NER) functions. I further analyzed genetic interactions between SUB1 and genes critical to various DNA damage avoidance/tolerance mechanisms, such as mismatch repair (MMR), homologous recombination (HR) and translesion synthesis (TLS).

Repressor Proteins

Trans-Activators

DNA Damage

Mutagenesis

Academic Dissertations

Life Sciences

Medicine and Health Sciences

The role of regulatory proteins at the FEPDGC-ENTS promoter region in escherichia coli a new model for the fur-DNA interaction /

Lavrrar, Jennifer L.

January 2002

Thesis (Ph. D.)--University of Missouri--Columbia, 2002. / Typescript. Vita. Includes bibliographical references (leaves 179-198). Also issued on the Internet.

Nrg1p and Rfg1p in Candida albicans yeast-to-hyphae transition

Lacroix, Céline.

January 2008

The ability of Candida albicans to change morphology plays several roles in its virulence and as a human commensal. The yeast-to-hyphae transition is tightly regulated by several sets of activating and repressing pathways. The DNA-binding proteins Rfg1p, Nrg1p and the global repressor Tup1p are part of the repressors found to regulate this morphogenesis. Knowledge of these repressors is based on extrapolations from homology to S. cerevisiae and from expression studies of mutants in inducing conditions, all of which are indirect means of determining a protein's function. We proposed a genome-wide location study of the Nrg1 and Rfg1 transcription factors to obtain direct data to identify their in vivo targets. Our results suggest different avenues for Nrg1p function and a regulation behaviour diverging from the previously suggested model: Nrg1p acts not only as a repressor but also as a transcription activator. Furthermore it regulates its target genes through binding in their coding regions instead binding to the expected regulatory elements on promoters.

Morphogenesis.

Hyphae -- metabolism.

Fungal Proteins.

Repressor Proteins.

Saccharomyces cerevisiae Proteins.

Insights into the molecular interactions of the neurogenic basic helix-loop-helix transcription factor, neuroD2, and the mechanism of regulation of a key target, RE-1 silencing transcription factor /

Ravanpay, Ali Cyrus,

January 2007

Thesis (Ph. D.)--University of Washington, 2007. / Vita. Includes bibliographical references (leaves 61-63).

Examining the role of MalG in the assembly and function of the maltose transport complex in Escherichia coli : implications for the study of integral membrane proteins /

Nelson, Bryn D.

January 1998

Thesis (Ph. D.)--University of Washington, 1998. / Vita. Includes bibliographical references (leaves [100]-113).

The bHLH/PAS transcription factor SIM1 is a novel obesity gene

Holder, Jimmy Lloyd, Jr.

January 2005

Thesis (Ph. D.) -- University of Texas Southwestern Medical Center at Dallas, 2005. / Vita. Bibliography: 123-135.

Identification of Novel Interacting Proteins of Histone Gene Regulator, HINF-P: a Dissertation

Miele, Angela

18 December 2006

Histone Nuclear Factor P (HiNF-P) is a known transcriptional regulator that is critical for the activation of replication dependent histone H4 genes during S phase. HiNF-P is a 65 kDa zinc finger protein that binds to its consensus binding sequence in the Cell Cycle Control Element (Site II) of the proximal promoter region of 11 of the 14 histone H4 genes. HiNF-P is a known co-factor of the global histone gene regulator and cyclinE/CDK2 substrate p220NPAT, however it was not known if this regulatory function reflected a physical interaction. In addition, other HiNF-P interacting proteins have yet to be identified. The work presented in this thesis identifies and characterizes HiNF-P interactions with various proteins within the cell, including p220NPAT. A yeast two-hybrid interaction screen identified candidate interacting proteins of HiNF-P and provided insight into novel cellular functions and transcriptional targets. A candidate yeast two-hybrid approach identified an interaction between HiNF-P and p220NPAT. This direct physical interaction links the cyclin E/CDK2 signaling pathway governing the G1/S phase transition with replication dependent histone gene transcription in S phase. An unbiased yeast two-hybrid screen for HiNF-P interacting proteins revealed an interactome library which suggests roles of HiNF-P in multiple cellular processes. This screen identified 67 candidate HiNF-P interacting proteins that are RNA processing factors, known and putative gene regulators, uncharacterized proteins, proliferation related proteins, as well as metabolic and signaling proteins. Identification of multiple RNA binding and processing factors, including the splicing cofactor, SRm300, links HiNF-P to mRNA processing. HiNF-P is potentially functioning in mRNA processing by interacting with these proteins directly and functioning in complex with them, or more likely, by recruiting these and other splicing factors to sites of transcription. We identified a number of known and putative gene regulators which are candidate HiNF-P interacting proteins. We isolated the atypical C2CH zinc finger protein, THAP7, a known transcriptional repressor. THAP7 interacts with HiNF-P by co-immunoprecipitation and co-immunofluorescence experiments. We show forced expression of THAP7 abrogates HiNF-P/p220 mediated activation of histone H4 gene transcription. THAP7 may represent a novel co-factor of HiNF-P and p220 mediated regulation of histone H4 genes. Identification of interacting proteins of HiNF-P that are involved in transcriptional regulation provides insight into other transcriptional targets of HiNF-P. HiNF-P is localized throughout the nucleus, presumably at multiple gene foci. These interacting proteins may represent novel co-factors of HiNF-P regulation of these other multiple target genes. HiNF-P has been identified as a regulator of cell cycle dependent histone genes, therefore we were interested in identifying other proliferation related proteins with which HiNF-P is interacting. We identified a number of proteins thought to be involved in cellular proliferation, including Ki-67 and an unknown protein XTP2. The functions of these proteins have not been identified. An interaction with HiNF-P might suggest a role for these proteins in histone gene regulation. In addition, Ki-67 has been implicated transcriptional control of ribosomal genes, although no role of HiNF-P in this function has been identified. HiNF-P is a known regulator of histone gene expression via a functional interaction with the global histone gene regulator and cyclin E/CDK2 substrate, p220. This thesis demonstrates HiNF-P directly interacts with the N-terminus of p220. This interaction requires multiple regions within the N-terminus including a LisH-like domain known to function in protein-protein interactions, a region (aa 121-145) known to be required for histone gene transactivation, and another uncharacterized region (209-318). In addition a phylogenically conserved region within the C-terminus of HiNF-P, the HiNF-P Specific Conserved Region (PSCR) is necessary for this interaction. Mutational analysis of these regions abrogates this interaction. HiNF-P and p220 co-localize at specific foci within the cell corresponding to Cajal bodies, which are known sites of histone gene clusters. This work shows that this interaction is necessary for histone gene transcriptional activation and HiNF-P dependent recruitment of p220 to histone H4 gene promoters. In addition HiNF-P as well as p220 interact with the Stem Loop Binding Protein (SLBP) and co-localize in situ. SLBP is a necessary factor for histone pre-mRNA processing events which also occur at Cajal bodies. These interactions provide evidence of the coupling of transcription and processing of histone genes and the involvement of common factors in both processes. This would allow for rapid production of abundant histone proteins which is needed during S phase. This thesis has identified multiple candidate interacting proteins of HiNF-P. These proteins establish HiNF-P as a protein involved in many cellular processes and mechanisms beyond transcriptional control of cell cycle dependent histone genes.

Repressor Proteins

Cell Cycle Proteins

Gene Expression Regulation

Histones

Nuclear Proteins

S Phase

Academic Dissertations

Life Sciences

Medicine and Health Sciences