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351	Transcriptional regulation of neural crest-derived pharyngeal arch artery development Ivey, Kathryn Nicole. January 2004 (has links) (PDF) Thesis (Ph. D.) -- University of Texas Southwestern Medical Center at Dallas, 2003. / Vita. Bibliography: References located at the end of each chapter.
352	Regulation of expression of the HLA class II gene, DQB1 / Sukiennicki, Teresa Lyn. January 2000 (has links) Thesis (Ph. D.)--University of Washington, 2000. / Vita. Includes bibliographical references (leaves 106-140).
353	Critical roles for the transcription factor c-Myb in early B cell development / Greig, Kylie Tara. January 2009 (has links) Thesis (Ph.D.)--University of Melbourne, The Walter and Eliza Hall Institute of Medical Research, The Division of Immunology and the Division of Molecular Medicine, Dept. of Medical Biology, Faculty of Medicine and Dentistry, 2009. / Typescript. Includes bibliographical references (p. 133-165)
354	Analises estruturais e estudos das interações das proteinas INT6 e NY-REN-21 / Structural analysis and interaction studies of the INT6 and NY-REN-sa proteins Carneiro, Flavia Raquel Gonçalves 30 May 2006 (has links) Orientador: Nilson Ivo Tonin Zanchin / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-06T21:20:48Z (GMT). No. of bitstreams: 1 Carneiro_FlaviaRaquelGoncalves_D.pdf: 4565621 bytes, checksum: 26bdfc2a971d3837321625172c6745e8 (MD5) Previous issue date: 2006 / Resumo: O gene que codifica a proteína INT6 corresponde a um dos sítios de inserção do vírus de tumor de glândula mamária em camundongo (MMTV). Esta inserção pode levar à formação de proteínas truncadas sem a porção C-terminal e sem o domínio PCI, descrito como domínio de interação entre proteínas. Neste trabalho, realizamos 3 triagens para a identificação dos ligantes protéicos da proteína humana INT6 (hINT6) pelo método do duplo-híbrido de levedura. Embora interações específicas tenham sido identificadas, não foi possível a confirmação in vitro das novas interações isoladas. Para análises estruturais, usamos a proteína INT6 de Arabidopsis thaliana (AtINT6), visto que a proteína humana expressou em níveis muito baixos na fração solúvel do extrato de Escherichia coli. Análises de dicroísmo circular revelaram que a proteína AtINT6 é rica em estrutura do tipo a-hélice. A região que compreende os aminoácidos 172 a 415, incluindo o domínio PCI, foi identificada por proteólise parcial e espectrometria de massas como um domínio estrutural que após sua clonagem apresentou alto nível de expressão, solubilidade e estabilidade. Este trabalho envolveu também a caracterização da NY-REN-21, que foi isolada pelo duplo-híbrido para a identificação dos ligantes protéicos da proteína hINT6 e representa uma possível ortóloga para o fator de transcrição ZFP38 de camundongo. Ambas as proteínas apresentam um domínio de dimerização (SCAN), 7 domínios dedos de zinco tipo C2H2 na porção C-terminal e uma região central predita como desestruturada. A proteína NY-REN-21 se mostrou parcialmente desenovelada e sua estrutura secundária é afetada pela incubação com EDTA. Ensaios de proteólise limitada, dicroísmo circular e fluorescência confirmaram que sua região central é intrinsicamente desordenada, além de apresentar mobilidade anômala em gel de SDS-PAGE e representa uma fração flexível da proteína. Não foi possível a caracterização da região dos dedos de zinco, pois esta região se mostrou altamente instável. O domínio SCAN da NY-REN-21 é capaz de formar homodímeros e heterodímeros com a proteína SCAND1. Esta interação pode representar uma forma de regulação da atividade da proteína NY-REN-21 / Abstract: The INT6 gene was reported as a frequent genome integration site of Mouse Mammary Tumor Virus (MMTV). This integration may result in truncated forms of INT6 protein lacking its C-terminal region and the PCI domain. It has been reported that this domain is involved in protein-protein interaction. We performed 3 yeast two-hybrid screens in order to identify the human INT6 (hINT6) interaction partners. Although two previously described specific interactions were identified in these screens, it was not possible to confirm the new interactions by in vitro binding assays. The Arabidopis thalina INT6 ortholog (AtINT6) was used for structural analyses, since the hINT6 was insoluble following expression in Escherichia coli. AtINT6 showed CD spectra with high helical content. The region comprising amino acids 172 to 415 forms a compact protease resistant domain as determined by limited proteolysis and mass spectrometry analyses. This domain, comprising the PCI domain sequence, was cloned and expressed in E. coli and showed high solubility and stability. This recombinant protein has the potential to serve as a model protein for three-dimensional structure determination of the PCI domain. We also studied the NY-REN-21 protein, which was isolated as a potential hINT6 interaction partner and represents a putative ortholog of the mouse ZFP38 transcriptional factor. Both proteins are C2H2 type multifinger proteins, containing a conserved oligomerization domain (SCAN) in the N-terminal region and a predicted disordered central region. Our analyses showed that full-length NY-REN-21 is partially unfolded and its secondary structure content is affected by incubation with EDTA. The central region of NY-REN-21 shows an aberrant mobility on SDS-PAGE and is intrinsically unstructured as reveled by circular dichroism, fluorescence and limited proteolysis. The zinc finger region was not characterized because of its unstable nature. The recombinant SCAN domain of NY-REN-21 can form homodimers and heterodimers with the SCAND1 protein. This interaction may represent a novel regulatory mechanism of NY-REN-21 activity / Doutorado / Genetica Animal e Evolução / Doutor em Genetica e Biologia Molecular INT6 NY-REN-21 Técnicas do sistema de duplo-híbrido Dicroismo circular Transcrição genética Yeast two-hybrid system Circular dichroism Genetic transcription
355	Generation of cDNA chips from the black widow spider, latrodectus hesperus, for gene discovery and expression profiling using microarray technology, and molecular characterization of a novel silk glue protein Vasanthavada, Keshav 01 January 2005 (has links) eDNA microarray technology has generated a tremendous amount of interest among biologists because of its promise to monitor the entire genome on a single chip, thus enabling researchers to have a better picture of the interaction among thousands of genes simultaneously. In the current study, this technology was used to print over 3,000 unknown genes from various silk glands of the black widow spider to profile their expression patterns and to identify novel candidates. Spiders are remarkable creatures because of their ability to make different silks, each with a specific function. Some of these silks have amazing mechanical properties, comparable to those of the finest synthetic materials. Several silk genes have been cloned from various spiders over the last few years, and the contribution of each of those genes in silk production has been identified. However, the majority of cellular and biochemical processes involved in silk manufacture remain a mystery. In our research, we attempt to identify genes that might be involved in silk assembly, on a global scale and investigate more about those genes and their interplay with other key biological molecules involved in silk manufacture. Our study showed that silking spiders for a certain period of time resulted in down-regulation of two important silk genes, ECP-1 and ECP-2. Both these genes are key molecules implicated for their role in maintaining the egg case architecture in the black widow spider.,-and we believe that these genes are also directly or indirectly involved in the manufacture of dragline silk. Microarray analyses also enable the discovery of several other interesting molecules, two of which could be accessory proteins involved in silk formation. Furthermore, in a separate study we also characterized a novel silk glue protein with unique ensemble repeats. In conclusion, we believe that the findings of this study will indeed be significant to silk researchers and material scientists alike and it will enhance our knowledge in understanding the mystery behind silk production. RNA Synthesis Black widow spider DNA microarrays Genetic transcription Proteins Synthesis Gene expression Spiders Genetics Biology Life Sciences
356	Characterization of the large diameter fibers in egg case silk : identification of a core fibroin, TuSp1, and localization of fibroin-like molecules, ECPs, from the black widow spider, latrodectus hesperus McMullen, Erin 01 January 2008 (has links) Araneoid spiders use specialized sets of abdominal silk glands to produce up to seven different types of silks, each with diverse functional properties. At the time of these studies, fibroin eDNA sequences that encode egg case silk had not been reported in the literature. This study used conventional nucleic acid-nucleic acid screening of a eDNA library to isolate a novel gene, named tubuliform spidroin 1 , from the black widow spider Latrodectus hesperus. TuSp 1 was demonstrated to be selectively expressed in the tubuliform gland (the gland suspected for egg case silk production), and examination of the amino acid sequence revealed highly homogeneous repeats (184 amino acid ensemble repeats), a characteristic feature of fibroin sequences. Analyses of the ensemble repeats within the amino acid sequence of TuSp 1 revealed the lack of long stretches of polyalanine and glycine-alanine sub-repeats, which are commonly found in minor ampullate and major ampullate silks. Polyserine blocks and short polyalanine stretches were highly represented in the TuSp 1 amino acid sequence. Our data support the assertion that TuSp 1 represents the main constituent within egg case silk. This supposition is supported by the observation that the amino acid composition of raw egg case silk was strikingly similar to the amino acid composition predicted from the translated TuSp1 eDNA. Two additional constituents identified in black widow egg case, egg case protein 1 (ECP-1) and egg case protein 2 (ECP-2), were also partially characterized in this study. Using immunohistochemical approaches, we demonstrate that ECPs predominantly localize to the exterior of the large diameter fibers of egg cases. Additionally, these studies revealed smaller amounts of ECPs localized to the interior portion of the fibers. Collectively, these results support TuSp1 as the predominant fibroin within egg sacs as well as reveal a structural role for the ECPs, providing clues regarding the supramolecular structure of egg case fibers. Black widow spider Genetics Spider webs Silk Composition Genetic aspects Genetic transcription Proteins Analysis Biology Life Sciences
357	Evidence that aciniform silk and minor ampullate silk are major constituents of wrapping silk from the black widow Reza, Ryan C. 01 January 2008 (has links) Spider silk is one of the most remarkable materials produced in the natural world and its strength and extensibility are legendary. To date, the majority of studies have been performed on the following silks: dragline, capture spiral, and eggcase silk. The primary goal of this study was to characterize a lesser known silk type, called wrapping (swathing) silk, from Latrodectus hesperus. My research focused on elucidating the fibroins that make up the swathing silk. Perfonning MS/MS analyses on solubilized wrapping silk fibroins digested with trypsin, we demonstrate that a novel fibroin named AcSp !-like is present within wrapping silk. Consistent with this finding, SEM analyses reveal that wrapping silk is a composite material, containing at least three different diameter silk fibers. By using scanning electron micrographs, along with amino acid composition analyses and MS/MS analyses, we demonstrate wrapping material contains the fibroins AcSp1-like, MiSp1-like, MaSp1 and MaSp2. These are the first studies to reveal that minor, major and acinifonn silks are constituents of wrapping material. Black widow Spiders Genetics Spider webs Silk Composition Genetic aspects Genetic transcription Proteins Analysis Biology Genetics Genetics and Genomics Life Sciences
358	DECODING THE TRANSCRIPTIONAL LANDSCAPE OF TRIPLE-NEGATIVE BREAST CANCER USING NEXT GENERATION WHOLE TRANSCRIPTOME SEQUENCING Radovich, Milan 16 March 2012 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Triple-negative breast cancers (TNBCs) are negative for the expression of estrogen (ER), progesterone (PR), and HER-2 receptors. TNBC accounts for 15% of all breast cancers and results in disproportionally higher mortality compared to ER & HER2-positive tumours. Moreover, there is a paucity of therapies for this subtype of breast cancer resulting primarily from an inadequate understanding of the transcriptional differences that differentiate TNBC from normal breast. To this end, we embarked on a comprehensive examination of the transcriptomes of TNBCs and normal breast tissues using next-generation whole transcriptome sequencing (RNA-Seq). By comparing RNA-seq data from these tissues, we report the presence of differentially expressed coding and non-coding genes, novel transcribed regions, and mutations not previously reported in breast cancer. From these data we have identified two major themes. First, BRCA1 mutations are well known to be associated with development of TNBC. From these data we have identified many genes that work in concert with BRCA1 that are dysregulated suggesting a role of BRCA1 associated genes with sporadic TNBC. In addition, we observe a mutational profile in genes also associated with BRCA1 and DNA repair that lend more evidence to its role. Second, we demonstrate that using microdissected normal epithelium maybe an optimal comparator when searching for novel therapeutic targets for TNBC. Previous studies have used other controls such as reduction mammoplasties, adjacent normal tissue, or other breast cancer subtypes, which may be sub-optimal and have lead to identifying ineffective therapeutic targets. Our data suggests that the comparison of microdissected ductal epithelium to TNBC can identify potential therapeutic targets that may lead to be better clinical efficacy. In summation, with these data, we provide a detailed transcriptional landscape of TNBC and normal breast that we believe will lead to a better understanding of this complex disease. Breast Cancer Triple-Negative Breast Cancer Normal Breast Next Generation Sequencing RNA-Seq Breast -- Cancer BRCA genes Genetic transcription Transcriptome
359	UVSSA regulates transcription-coupled genome maintenance Liebau, Rowyn Church January 2024 (has links) DNA damage is a constant threat to our genomes which drives genome instability and contributes to cancer progression. DNA damage interferes with important DNA transactions such as transcription and replication. DNA lesions are removed by repair pathways that ensure genome stability during transcription and replication. Here, we identify and characterize distinct roles for the ultra violet stimulated scaffold protein A (UVSSA) in the maintenance of genome stability during transcription in human cells. First, we unravel a novel function for UVSSA in transcription-coupled repair of DNA interstrand crosslinks (ICLs), genotoxic adducts that covalently bind opposing strands of the DNA and block transcription and replication. UVSSA knockout cells are sensitive to ICL inducing drugs, and UVSSA is specifically required for transcription-coupled repair of ICLs in a fluorescence-based reporter assay. Based on analysis of the UVSSA protein interactome in crosslinker treated cells we propose a model for transcription-coupled ICL repair (TC-ICR) that is initiated by stalling of transcribing RNA polymerase II (Pol II) at an ICL. Stalled Pol II is first bound by CSA and CSB, followed by UVSSA which recruits TFIIH to initiate downstream lesion removal steps. Second, we establish that UVSSA counteracts MYC dependent transcription stress to promote genome stability in cells aberrantly expressing the cMYC oncogene. UVSSA knockdown sensitizes cells to MYC expression, resulting in synthetic sickness and increased doubling time. UVSSA knockdown impacts Pol II dynamics in MYC activated cells. We conclude that UVSSA is required for regulation of Pol II during MYC induced transcription to prevent transcription stress. Together, these studies expand our understanding of UVSSA’s role in genome stability during transcription and elucidates the poorly understood transcription-coupled ICL repair pathway. Molecular biology DNA damage DNA repair DNA replication Scaffold proteins Genomes Genetic transcription--Regulation Cancer--Genetic aspects
360	Regulation of Clustered Protocadherin Expression in the Murine Central and Peripheral Nervous Systems Nwakeze, Chiamaka January 2023 (has links) The combinatorial code of cPcdh isoforms creates a diversified cell-surface molecular signature for cell-cell recognition in neural networks. This genetic architecture, combined with a regulated expression pattern and trans-homophilic binding properties, provides insights into cell specialization and signaling. Anomalies in cPcdhs, which include genetic mutations, epigenetic modifications, structural variations, and altered gene expression profiles, are associated with several neurological, neuropsychiatric, and systemic conditions, highlighting the importance of cPcdh investigations. This study focuses on the transcriptional regulation of the Pcdhα gene cluster. Each neuron displays a specific Pcdhα alternate exon repertoire, necessitating an understanding of the transcriptional dynamics. Using the SK-N-SH human neuroblastoma cell line and methodologies such as cRNA-seq and Start-Seq, these dynamics are examined. The application of CRISPR-Cas9 gene editing and a dCas9-VPR gain-of-function assay in the HEK293T cell line reveals the role of as-lncRNA and its interaction with DNA methylation within the Pcdhα gene cluster. This study identifies the role of noncoding as-lncRNA in RNA transcription and provides information on CTCF binding and Pcdhα promoter activation. The research also examines the gastrointestinal domain, as cPcdhs are linked to various diseases. Shifting focus from the canonical realm of the CNS, the research embarks on a preliminary yet pivotal exploration of the gastrointestinal domain. As cPcdhs intersect with a plethora of diseases, an incisive understanding of their expression could yield revelations into tissue susceptibilities with potential disease ramifications. Employing a novel single-domain antibody technique coupled with immunohistochemistry, the endeavor casts a precise lens into the gastrointestinal expression dynamics of Pcdhα and Pcdhγ. These insights not only fortify the understanding of cPcdh within neural structures but also beckon a deeper inquiry into their multifaceted biological roles. Molecular biology Mice--Physiology Neuropsychology Central nervous system Nerves, Peripheral Neuroblastoma--Genetic aspects Genetic transcription--Regulation Gastrointestinal system--Diseases

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