Pituitary-specific transcription factor PIT-1 in Chinese grass carp: molecular cloning, functionalcharacterization, and regulation of its transcript expression at thepituitary level

Kwong, Ka-yee., 鄺嘉儀.

January 2004

published_or_final_version / abstract / toc / Zoology / Master / Master of Philosophy

Transcription factors.

Genetic transcription - Regulation.

Ctenopharyngodon idella - Genetics.

Transcriptional regulation in the EcoRI-F immunity region of the Bacillus subtilis phage [phi] 105

Chan, Yee-man., 陳綺雯.

January 2003

published_or_final_version / abstract / toc / Zoology / Master / Master of Philosophy

Genetic transcription - Regulation.

TATA-dependent repression of human immunodeficiency virus Type-1 transcription by the Adenovirus E1A 243R oncoprotein

Tsang, Shirley Xiaoman

01 1900

No description available.

HIV (Viruses)

Promoters (Genetics)

Genetic transcription Regulation

Gene expression

Adenoviruses

ROLE OF THE NEURONAL SPECIFIC TRANSCRIPTION COREGULATOR NPDC-1 IN RETINOID AND THYROID RECEPTOR SIGNALING IN HUMAN AND THE AXOLOTL AMBYSTOMA MEXICANUM

Theodosiou, Maria

01 January 2006

Section I: This section is an introduction to the field of nuclear receptors. A general overview of nuclear receptor-mediated transcriptional regulation is followed by a review of literature on retinoid and thyroid receptor-mediated signaling. Section II: An introduction to NPDC-1 (neural proliferation, differentiation, and control), its discovery and characterization with regards to developmental expression and cellular localization. In addition NPDC-1 has been found to associate with a number of cell cycle regulatory proteins. NPDC-1 is characterized as a regulator of nuclear receptor-mediated transcriptional regulation. NPDC-1 was also demonstrated to be regulated post-transcriptionally through the ubiquitin/proteosome degradation pathway. Section III: Axolotl NPDC-1 (aNPDC-1) was cloned from axolotl brain and analyzed for homology to NPDC-1 from higher vertebrates. The tissue distribution and developmental expression of axolotl NPDC-1 were also examined. Section IV: The axolotl homolog for RAR (aRAR) was isolated from axolotl brain. Axolotl NPDC-1 and aRAR were then examined in a series of assays for interactions. Axolotl NPDC-1 was found to repress transcription mediated by aRAR to a smaller extent than the repression observed in higher vertebrates. The DNA binding of aRAR-RXR was increased in the presence of aNPDC-1 and complex mobility was also observed. The domain of interaction between aNPDC-1, aRAR and hRXR was localized in the amino terminus of aNPDC-1. Axolotl NPDC-1 was also demonstrated to repress proliferation as measured by reduced [3H] thymidine incorporation. Section V: The axolotl homologs of TR and TR (aTR) genes were isolated and utilized in a series of experiments to demonstrate an interaction between aTRs and aNPDC-1. As observed for RE, aNPDC-1 increases the binding of aTR-RXR heterodimer to xDR4, but no change in the mobility of the complex was observed. Interaction between aNPDC-1, aTR and aTR was localized to the amino terminus of aNPDC-1. In contrast to previous observations for other nuclear receptors, aNPDC-1 was found to stimulate transcription mediated by axolotl TRs, suggesting a role for aNPDC-1 in axolotl metamorphosis. Section VI: A summary of data presented in the previous sections as well as a presentation of future directions and a proposed model for NPDC-1 actions in retinoid and thyroid-receptor mediated signaling in axolotl.

Dynamic Regulation of the Class II Transactivator by Posttranslational Modifications

Morgan, Julie E

11 August 2015

The class II Transactivator (CIITA) is the master regulator for Major Histocompatibility Class II (MHC II) molecules. CIITA is dynamically regulated by a series of Posttranslational Modifications (PTMs). CIITA is responsible for initiating transcription of MHC II genes, thus allowing peptides derived from extracellular antigens to be presented to CD4+ T cells. CIITA’s PTMs are necessary for regulation of CIITA’s location, activity, and stability. Our work identifies the kinase complex ERK1/2 as being responsible for phosphorylating the previously identified regulatory site, serine (S) 280 on CIITA. Phosphorylation by ERK1/2 of CIITA S280 leads to increased levels of CIITA mono-ubiquitination and overall increases in MHC II activity. We further identify a novel ubiquitin modification on CIITA, lysine (K) 63 linked ubiquitination poly ubiquitination. Our data shows novel crosstalk between K63 ubiquitination and ERK1/2 phosphorylation. K63 ubiquitinated CIITA is concentrated to the cytoplasm, and upon phosphorylation by ERK1/2, CIITA translocates to the nucleus, thus demonstrating that CIITA’s location and activity is regulated through PTM crosstalk. While ubiquitination has been shown to be a critical PTM in the regulation of CIITA, the enzyme(s) mediating this important modification remained to be elucidated. Previous reports implicating the histone acetyltransferase (HAT), pCAF as an ubiquitin E3 ligase were intriguing, as pCAF is also known to participate in the acetylation of both histones at the MHC II promoter and in acetylation of CIITA. We now identify novel roles for pCAF in the regulation of CIITA. We show pCAF acts as an E3 ligase, mediating mono, K63, and K48 linked ubiquitination of CIITA. We therefore demonstrate an additional substrate for the “dual acting” enzyme, pCAF. In sum, our observations identify enzymes involved in both the phosphorylation and ubiquitination of key residues of CIITA, which ultimately regulate CIITA activity. Together our observations contribute to knowledge of CIITA’s growing network of PTMs and their role in regulating the adaptive immune response, and will allow for development of novel therapies to target dysregulated CIITA activity during adaptive immune responses.

Posttranslational modifications

Ubiquitination

phosphorylation

CIITA

MHC II

transcription regulation

Proteomic Characterization of Hemogen in Erythropoiesis

Somasundaram, Brinda

31 October 2012

Hemogen (Hemgn) is reported as a tissue specific transcriptional regulator in testis as well as hematopoietic tissues. It is known that Hemgn positively regulates erythroid differentiation; however,the underlying molecular mechanism is not well understood. In the current study, using proteomic approach in combination with other molecular biology tools,we have attempted to decipher the role of Hemgn in differentiating Murine erythroblast leukemia (MEL) cells as a model system. Our study reveals that Hemgn predominantly interacts with transcriptional regulators, chromatin modifiers and histones. Furthermore, using Chromatin Immunoprecipitation and knockdown approach, we have demonstrated that Hemgn is recruited to the b-globin locus, which is known to be activated during erythroid differentiation. Based on the results,we speculate that Hemgn acts as a tissue specific histone chaperone that regulates transcription during erythroid differentiation.

Hemgn

Proteomic Characterization

erythropoiesis

transcription regulation

b-globin

Genomic Exploration of Transcriptional Regulation and Evolution in Vertebrates

Chan, Esther T. M.

16 March 2011

All cellular processes depend on the coordinate expression of genes and their interactions. Regulatory sequences encoded in the genome stipulate the necessary instructions interpreted by sequence-specific transcription factors (TFs) to control the spatial-temporal output of gene expression. Detection of cis-regulatory signals is challenging, owing to the lack of distinguishing features such as open reading frames and an overwhelming excess of spurious to functional TF binding site matching sequences embedded within the vast non-coding regions of vertebrate genomes. From an evolutionary standpoint, functional alterations in cis-regulatory architecture are thought to be important in diversifying morphology and physiology in the evolution of vertebrates, which share a similar body plan and complement of genes. Correspondingly, recent studies have highlighted the plasticity of cis-regulatory architecture organization over evolutionary time, finding associations with examples of both diverged and conserved patterns of gene expression. These observations underscore the gap in our collective knowledge with respect to the rules by which TFs recognize and bind their targets in vivo, as well as how this process evolves in vertebrates, and serve as a motivating basis for this thesis work. To begin, I probed the extent of conservation and divergence of sequence and expression profiles across tissues of diverse vertebrate species, identifying thousands of candidate genes with conserved expression by microarray analysis. However, corresponding conservation of non-exonic and potentially regulatory sequence was lacking, suggestive of binding site turnover over evolutionary time. Next, I analyzed the sequence specificity of a wide array of mouse and yeast TFs, finding great diversity and complexity in their binding preferences, with many factors recognizing multiple distinct motifs. Furthermore, comparative analysis of orthologous TFs suggest well conserved binding specificities. I also demonstrate the likely biological relevance of sequences highly preferred by these TFs by revealing distinctive signatures in their distribution and organization within putative regulatory regions in each genome. Lastly, I have begun to explore the organization of cis-regulatory sequences active in vertebrate tissues by high-throughput sequencing of open chromatin. Together, these data help illuminate the organization and evolution of vertebrate regulatory architectures, providing a useful toolkit for the testing of new models and hypotheses.

comparative genomics

transcription regulation

bioinformatics

vertebrates

evolution

0307

Cis-regulatory modules clustering from sequence similarity

Handfield, Louis-François.

January 2007

I present a method that regroups cis-regulatory modules by shared sequences motifs. The goal of this approach is to search for clusters of modules that may share some function, using only sequence similarity. The proposed similarity measure is based on a variable-order Markov model likelihood scoring of sequences. I also introduce an extension of the variable-order Markov model which could better perform the required task. Results. I show that my method may recover subsets of sequences sharing a pattern in a set of generated sequences. I found that the proposed approach is successful in finding groups of modules that shared a type of transcription factor binding site.

Nucleotide sequence -- Mathematics.

Transcription factors.

Genetic transcription -- Regulation.

Markov processes.

Model pro studium regulace transkripce granulocytarních genů MPO a MMP9 rozdílnými koncentracemi transkripčního faktoru PU.1 / Model for study of transcription regulation of granulocytic genes MPO and MMP9 by different levels of PU.1 transcription factor

Chramostová, Kamila

January 2018

9 Abstract Enhancers are distal cis - regulatory DNA sequences that regulate (enhance) transcription of the respective gene driven by its promoter. Enhancers are found in non-coding DNA upstream or downstream of the gene coding sequence, or in introns or coding regions that are located up to hundreds kb away from the gene. Superenhancers are newly discovered clusters of multiple enhancers that play a vital role in activating tissue-specific genes, determining cell identity and regulating differentiation. PU.1 is the transcription factor (TF) that is necessary for normal haematopoiesis, specifically for the development of myeloid and lymphoid blood lineages. Distinct levels of PU.1 induce differentiation of hematopoietic cells into different cell lineages whereby disruption of PU.1 levels leads to leukemogenesis. High PU.1 levels stimulate macrophage development, while intermediate levels stimulate the development of granulocytes. This diploma thesis seeks to contribute to addressing the interesting biological question of what are the regulatory mechanisms to ensure that granulocytic genes are activated only at the intermediate concentration of PU.1, whereas macrophage genes are activated only at its high levels. The aim of this diploma thesis was to create a series of reporter vectors carrying regulatory...

Proteomic Characterization of Hemogen in Erythropoiesis

Somasundaram, Brinda

January 2012

Hemogen (Hemgn) is reported as a tissue specific transcriptional regulator in testis as well as hematopoietic tissues. It is known that Hemgn positively regulates erythroid differentiation; however,the underlying molecular mechanism is not well understood. In the current study, using proteomic approach in combination with other molecular biology tools,we have attempted to decipher the role of Hemgn in differentiating Murine erythroblast leukemia (MEL) cells as a model system. Our study reveals that Hemgn predominantly interacts with transcriptional regulators, chromatin modifiers and histones. Furthermore, using Chromatin Immunoprecipitation and knockdown approach, we have demonstrated that Hemgn is recruited to the b-globin locus, which is known to be activated during erythroid differentiation. Based on the results,we speculate that Hemgn acts as a tissue specific histone chaperone that regulates transcription during erythroid differentiation.

Hemgn

Proteomic Characterization

erythropoiesis

transcription regulation

b-globin