Global ETD Search

1	Organisation, expression and evolution of KruÌˆppel-type zinc finger genes in human chromosomal region 10p11.2-q11.2 Hearn, Thomas January 2000 (has links) No description available. 572.8 KRAB; Chromosome; Genome; Duplication
2	Characterisation of endogenous KRAB zinc finger proteins Crawford, Catherine January 2009 (has links) The Krüppel-associated box (KRAB) zinc finger protein (ZFP) genes comprise one of the largest gene families in the mammalian genome, encoding transcription factors with an N-terminal KRAB domain and C-terminal zinc fingers. The KRAB domain interacts with a co-repressor protein, KAP-1, which can recruit various factors causing transcriptional repression of genes to which KRAB ZFPs bind. Little is currently known about the gene targets of the ~400 human and mouse KRAB ZFPs. Many KRAB ZFPs interact with factors other than KAP-1. To identify proteins that may interact with one particular KRAB ZFP, Zfp647, I previously carried out a yeast two-hybrid screen using the full-length Zfp647 sequence and a mouse embryonic cDNA library. I have now tested the interactions from this screen for their specificity for Zfp647. I show that Zfp647 can interact with itself and at least 20 other KRAB ZFPs through their zinc finger domains, and have confirmed the Zfp647 self-interaction by in vitro co-immunoprecipitation. In my yeast two-hybrid screen, Zfp647 bound to KAP-1 as well as another related protein, ARD1/Trim23. Zfp647 also interacts with proteins that function in ubiquitylation. I have found evidence to suggest that Zfp647 may also interact with proteins encoding jumonji domains both by yeast two-hybrid assay and by co-immunoprecipitation from NIH/3T3 cell extracts. We have previously found that Zfp647 localises to non-heterochromatic nuclear foci in differentiated ES cells, which also contain KAP-1 and HP1, and which lie adjacent to PML nuclear bodies in a high proportion of cells. I have found that these foci are also visible in pMEFs, but not NIH/3T3 tissue culture cells. Immunofluorescence studies with antibodies against proteins from the yeast twohybrid screen have not shown any significant co-localisation with Zfp647. KAP-1 is sumoylated ex vivo, as are two human KRAB ZFPs. Because Zfp647 lies adjacent to PML nuclear bodies and can associate with proteins involved in posttranslational modification, I tested whether Zfp647 is also modified. I characterised a sheep _-Zfp647 antibody previously created in the lab and have shown that it detects Zfp647 by western blot, but not by immunofluorescence. I show that treatment of NIH/3T3 cells with NEM, which prevents the removal of protein modifications, leads to the appearance of higher molecular weight forms of Zfp647. Modification of Zfp647 is not dependent on KAP-1, which is known to function as a SUMO E3 ligase. Attempts to classify the modification as either ubiquitin, SUMO or NEDD8 have suggested that Zfp647 may be mono-ubquitylated. The larger modified forms of Zfp647 are present in both NIH/3T3 and ES cells. Interestingly, I found that the modification profile of the protein changes over the course of ES cell differentiation, during which time Zfp647 relocalises to punctate nuclear foci; thus Zfp647 modification may be involved in this process. 572.6
3	Identification de la sumoylation de ZNF74 et de l'interaction de cette protéine à multidoigt de zinc avec UBC9 et PIAS1 Abenhaim, Samantha January 2004 (has links) Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal. Syndrome de DiGeorge ZNF74 Multidoigt de zinc Motif KRAB Sumoylation UBC9 PIAS Répression transcriptionnelle Double hybride
4	Three Subfamilies of KRAB Zinc Finger Proteins : A Structural, Functional and Evolutionary Analysis Mark, Charlotta January 2003 (has links) <p>Krüppel-related zinc finger proteins constitute the largest single class of transcription factors within the human genome. Members of this protein family have the ability to either activate or repress transcription depending on the presence of specific activator or repressor domains within the protein. Approximately one third of the Krüppel-related zinc finger proteins contain an evolutionarily well-conserved repressor domain termed the KRAB domain. This domain acts as a potent repressor of transcription by interacting with the co-repressor protein, TIF1β. TIF1β then, in turn, recruits HP1 proteins, HDACs and probably other proteins involved in gene silencing. In order to identify novel KRAB-containing zinc finger proteins, one mouse monocytic cDNA library and two testis cDNA libraries were screened for novel members of this multigene family. Six novel KRAB-ZNF cDNAs, four mouse and two human, were isolated. The corresponding proteins were all shown to contain N-terminally located KRAB domains as well as varying numbers of C-terminally located zinc finger motifs. An extensive comparative sequence analysis of the KRAB domains of these proteins together with KRAB domains from a large number of previously identified KRAB-ZNF proteins resulted in a clear subdivision into three different subfamilies, A+B, A+b and A. Later, we also isolated a fourth KRAB box, which is present downstream of the KRAB A box in a few proteins of the KRAB A family. This module was named KRAB C. Potential functional differences between these different subfamilies were investigated. In line with previous observations, the KRAB A box was shown to repress transcription, an activity which was enhanced by the presence of the KRAB B box. However, addition of neither the KRAB b box nor the KRAB C box had any effect on repression. Moreover, all KRAB A motifs had the ability to bind TIF1β, and this binding was increased both by the presence of the KRAB B box and by the KRAB C box. The KRAB b box, however, did not seem to contribute to TIF1β-binding. One of the novel human cDNAs, HKr19, was found to be a member of the large ZNF91 family of KRAB zinc finger genes. Interestingly, the expression of HKr19 and a number of other closely related genes were restricted to lymphoid cells, indicating that these genes may be involved in regulating lineage commitment. The effect of HKr19 on cell viability was investigated by transfection into human embryonic kidney cells (HEK 293). The results indicated that HKr19, or its zinc finger domain in isolation, were toxic to these cells when expressed at high levels. The MZF6D protein, on the other hand, showed a testis-specific expression. <i>In situ</i> hybridization analysis located this expression to meiotic germ cells, suggesting a role for this protein in spermatogenesis. Further, the evolutionary perspectives of this large gene family were addressed, and its enormous expansion throughout evolution probably includes numerous duplication events. The results from two extensive sequence analyses give clues to how the repetitive nature of the ZNF motif has given rise to both internal duplications of single motifs as well as duplications of entire genes resulting in gene clusters.</p> Biology Krüppel zinc finger KRAB TIF1β transcriptional repression Biologi Biology Biologi
5	The ABC of KRAB zinc finger proteins Looman, Camilla January 2003 (has links) <p>All living organisms consist of cells and the identity of a cell is defined by the genes it expresses. To assure proper function, a cell receives continuous information on which genes to turn on and off. This information is, to a large extent, provided by transcription factors. Krüppel-related zinc finger proteins probably constitute the largest family of transcription factors in mammals and many of these proteins carry a potent repressor domain called Krüppel-associated box (KRAB). The human genome alone encodes more than 200 KRAB zinc finger proteins but still very little is known about their biological functions. </p><p>The Krüppel-related zinc finger genes appear to have been involved in a massive expansion throughout evolution. To unravel some of the secrets underlying this evolutionary success, we studied the molecular evolution of KRAB zinc finger genes. We show that the frequently occurring duplications of these genes are accompanied by a low sequence constraint in their zinc finger region. In addition, we show that the number of zinc finger motifs carried within these proteins is far from fixed. New zinc finger motifs are frequently added while others are inactivated or even discarded from the coding region. The structurally independent Krüppel zinc finger motif has, through these mechanisms, served as a highly adaptive building block for the generation of new transcriptional regulators. </p><p>The mouse, rat and human genomes carry four different variants of the KRAB domain – KRAB(AB), KRAB(Ab), KRAB(AC) and KRAB(A). This thesis presents the identification of a novel KRAB domain, KRAB C, as well as a functional analysis of the different KRAB domains. We conclude that all different KRAB domains share a common co-repressor, TIFβ, and effectively repress transcription. These functions are mainly mediated by the KRAB A box but are clearly influenced by the presence of a KRAB B, b or C box. Furthermore, we show that all KRAB zinc finger gene subfamilies originate from the KRAB(AB) zinc finger genes.</p><p>In addition, this thesis includes a structural and functional analysis of four novel mouse and human KRAB zinc finger genes; <i>MZF6D</i>, <i>HKr18</i>, <i>HKr19</i> and <i>HZF12</i>. Whereas <i>HKr18</i> and <i>HZF12</i> seem to be ubiquitously expressed, <i>MZF6D</i> and <i>HKr19</i> show a more restricted expression pattern. Northern blot and <i>in situ</i> hybridisation analyses of <i>MZF6D</i> showed that the expression of this gene is restricted to meiotic germ cells. <i>MZF6D</i> might thus be involved in the formation of male gametes. The expression of <i>HKr19</i>, on the other hand, seems to be restricted to lymphoid cells, indicating a possible role for this KRAB zinc finger gene in the regulation of lineage commitment.</p> Biology Krüppel zinc finger KRAB transcription repression evolution Biologi Biology Biologi
6	Three Subfamilies of KRAB Zinc Finger Proteins : A Structural, Functional and Evolutionary Analysis Mark, Charlotta January 2003 (has links) Krüppel-related zinc finger proteins constitute the largest single class of transcription factors within the human genome. Members of this protein family have the ability to either activate or repress transcription depending on the presence of specific activator or repressor domains within the protein. Approximately one third of the Krüppel-related zinc finger proteins contain an evolutionarily well-conserved repressor domain termed the KRAB domain. This domain acts as a potent repressor of transcription by interacting with the co-repressor protein, TIF1β. TIF1β then, in turn, recruits HP1 proteins, HDACs and probably other proteins involved in gene silencing. In order to identify novel KRAB-containing zinc finger proteins, one mouse monocytic cDNA library and two testis cDNA libraries were screened for novel members of this multigene family. Six novel KRAB-ZNF cDNAs, four mouse and two human, were isolated. The corresponding proteins were all shown to contain N-terminally located KRAB domains as well as varying numbers of C-terminally located zinc finger motifs. An extensive comparative sequence analysis of the KRAB domains of these proteins together with KRAB domains from a large number of previously identified KRAB-ZNF proteins resulted in a clear subdivision into three different subfamilies, A+B, A+b and A. Later, we also isolated a fourth KRAB box, which is present downstream of the KRAB A box in a few proteins of the KRAB A family. This module was named KRAB C. Potential functional differences between these different subfamilies were investigated. In line with previous observations, the KRAB A box was shown to repress transcription, an activity which was enhanced by the presence of the KRAB B box. However, addition of neither the KRAB b box nor the KRAB C box had any effect on repression. Moreover, all KRAB A motifs had the ability to bind TIF1β, and this binding was increased both by the presence of the KRAB B box and by the KRAB C box. The KRAB b box, however, did not seem to contribute to TIF1β-binding. One of the novel human cDNAs, HKr19, was found to be a member of the large ZNF91 family of KRAB zinc finger genes. Interestingly, the expression of HKr19 and a number of other closely related genes were restricted to lymphoid cells, indicating that these genes may be involved in regulating lineage commitment. The effect of HKr19 on cell viability was investigated by transfection into human embryonic kidney cells (HEK 293). The results indicated that HKr19, or its zinc finger domain in isolation, were toxic to these cells when expressed at high levels. The MZF6D protein, on the other hand, showed a testis-specific expression. In situ hybridization analysis located this expression to meiotic germ cells, suggesting a role for this protein in spermatogenesis. Further, the evolutionary perspectives of this large gene family were addressed, and its enormous expansion throughout evolution probably includes numerous duplication events. The results from two extensive sequence analyses give clues to how the repetitive nature of the ZNF motif has given rise to both internal duplications of single motifs as well as duplications of entire genes resulting in gene clusters. Biology Krüppel zinc finger KRAB TIF1β transcriptional repression Biologi Biology Biologi
7	The ABC of KRAB zinc finger proteins Looman, Camilla January 2003 (has links) All living organisms consist of cells and the identity of a cell is defined by the genes it expresses. To assure proper function, a cell receives continuous information on which genes to turn on and off. This information is, to a large extent, provided by transcription factors. Krüppel-related zinc finger proteins probably constitute the largest family of transcription factors in mammals and many of these proteins carry a potent repressor domain called Krüppel-associated box (KRAB). The human genome alone encodes more than 200 KRAB zinc finger proteins but still very little is known about their biological functions. The Krüppel-related zinc finger genes appear to have been involved in a massive expansion throughout evolution. To unravel some of the secrets underlying this evolutionary success, we studied the molecular evolution of KRAB zinc finger genes. We show that the frequently occurring duplications of these genes are accompanied by a low sequence constraint in their zinc finger region. In addition, we show that the number of zinc finger motifs carried within these proteins is far from fixed. New zinc finger motifs are frequently added while others are inactivated or even discarded from the coding region. The structurally independent Krüppel zinc finger motif has, through these mechanisms, served as a highly adaptive building block for the generation of new transcriptional regulators. The mouse, rat and human genomes carry four different variants of the KRAB domain – KRAB(AB), KRAB(Ab), KRAB(AC) and KRAB(A). This thesis presents the identification of a novel KRAB domain, KRAB C, as well as a functional analysis of the different KRAB domains. We conclude that all different KRAB domains share a common co-repressor, TIFβ, and effectively repress transcription. These functions are mainly mediated by the KRAB A box but are clearly influenced by the presence of a KRAB B, b or C box. Furthermore, we show that all KRAB zinc finger gene subfamilies originate from the KRAB(AB) zinc finger genes. In addition, this thesis includes a structural and functional analysis of four novel mouse and human KRAB zinc finger genes; MZF6D, HKr18, HKr19 and HZF12. Whereas HKr18 and HZF12 seem to be ubiquitously expressed, MZF6D and HKr19 show a more restricted expression pattern. Northern blot and in situ hybridisation analyses of MZF6D showed that the expression of this gene is restricted to meiotic germ cells. MZF6D might thus be involved in the formation of male gametes. The expression of HKr19, on the other hand, seems to be restricted to lymphoid cells, indicating a possible role for this KRAB zinc finger gene in the regulation of lineage commitment. Biology Krüppel zinc finger KRAB transcription repression evolution Biologi Biology Biologi
8	The SRY Gene and Reductionism in Molecular Biology: How to Move from the Benchtop to a Systems Approach Prokop, Jeremy W. 27 August 2013 (has links) No description available. Molecular Biology
9	Étude du promoteur de ZNF74 et des séquences d'ADN reconnues par ce répresseur transcriptionnel Bensmina, Imene January 2006 (has links) Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal. Syndrome DiGeorge Protéine KRAB multidoigt de zinc ZNF74 Liaison à l'ADN Éléments de réponse Sélection par South-Western Caractérisation du promoteur Autorégulation transcriptionnelle
10	Towards Understanding the Molecular Basis of Human Endoderm Development Using CRISPR-Effector and Single-Cell Technologies Genga, Ryan M. 12 February 2019 (has links) The definitive endoderm gives rise to several specialized organs, including the thymus. Improper development of the definite endoderm or its derivatives can lead to human disease; in the case of the thymus, immunodeficiency or autoimmune disorders. Human pluripotent stem cells (hPSCs) have emerged as a system to model human development, as study of their differentiation allows for elucidation of the molecular basis of cell fate decisions, under both healthy and impaired conditions. Here, we first developed a CRISPR-effector system to control endogenous gene expression in hPSCs, a novel approach to manipulating hPSC state. Next, the human-specific, loss-of-function phenotypes of candidate transcription factors driving hPSC-to-definitive endoderm differentiation were analyzed through combined CRISPR-perturbation and single-cell RNA-sequencing. This analysis revealed the importance of TGFβ mediators in human definitive endoderm differentiation as well as identified an unappreciated role for FOXA2 in human foregut development. Finally, as the differentiation of definitive endoderm to thymic epithelial progenitors (TEPs) is of particular interest, a single-cell transcriptomic atlas of murine thymus development was generated in anticipation of identifying factors driving later stages of TEP differentiation. Taken together, this dissertation establishes a CRISPR-effector system to interrogate gene and regulatory element function in hPSC differentiation strategies, details the role of specific transcription factors in human endoderm differentiation, and sets the groundwork for future investigations to characterize hPSC-derived TEPs and the factors driving their differentiation. dCas9-KRAB human pluripotent stem cells CRISPR single-cell RNA-sequencing thymus development endoderm CRISPR-effector Cell Biology Developmental Biology

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