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Characterisation of the zinc fingers of Erythroid Kruppel-Like FactorHallal, Samantha January 2008 (has links)
Doctor of Philosophy (PhD) / Gene expression is known to be regulated at the level of transcription. Recently, however, there has been a growing realisation of the importance of gene regulation at the post-transcriptional level, namely at the level of pre-mRNA processing (5’ capping, splicing and polyadenylation), nuclear export, mRNA localisation and translation. Erythroid krüppel-like factor (Eklf) is the founding member of the Krüppel-like factor (Klf) family of transcription factors and plays an important role in erythropoiesis. In addition to its nuclear presence, Eklf was recently found to localise to the cytoplasm and this observation prompted us to examine whether this protein has a role as an RNA-binding protein, in addition to its well-characterised DNA-binding function. In this thesis we demonstrate that Eklf displays RNA-binding activity in an in vitro and in vivo context through the use of its classical zinc finger (ZF) domains. Furthermore, using two independent in vitro assays, we show that Eklf has a preference for A and U RNA homoribopolymers. These results represent the first description of RNA-binding by a member of the Klf family. We developed a dominant negative mutant of Eklf by expressing its ZF region in murine erythroleukaemia (MEL) cells. We used this to investigate the importance of this protein in haematopoietic lineage decisions by examining its effect on the multipotent K562 cell line. We provide evidence that Eklf appears to be critical not only for the promotion of erythropoiesis, but also for the inhibition of megakaryopoiesis.
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Characterisation of the zinc fingers of Erythroid Kruppel-Like FactorHallal, Samantha January 2008 (has links)
Doctor of Philosophy (PhD) / Gene expression is known to be regulated at the level of transcription. Recently, however, there has been a growing realisation of the importance of gene regulation at the post-transcriptional level, namely at the level of pre-mRNA processing (5’ capping, splicing and polyadenylation), nuclear export, mRNA localisation and translation. Erythroid krüppel-like factor (Eklf) is the founding member of the Krüppel-like factor (Klf) family of transcription factors and plays an important role in erythropoiesis. In addition to its nuclear presence, Eklf was recently found to localise to the cytoplasm and this observation prompted us to examine whether this protein has a role as an RNA-binding protein, in addition to its well-characterised DNA-binding function. In this thesis we demonstrate that Eklf displays RNA-binding activity in an in vitro and in vivo context through the use of its classical zinc finger (ZF) domains. Furthermore, using two independent in vitro assays, we show that Eklf has a preference for A and U RNA homoribopolymers. These results represent the first description of RNA-binding by a member of the Klf family. We developed a dominant negative mutant of Eklf by expressing its ZF region in murine erythroleukaemia (MEL) cells. We used this to investigate the importance of this protein in haematopoietic lineage decisions by examining its effect on the multipotent K562 cell line. We provide evidence that Eklf appears to be critical not only for the promotion of erythropoiesis, but also for the inhibition of megakaryopoiesis.
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Étude sur la reconnaissance de l'ubiquitine par les domaines de transactivation acides des activateurs de transcriptionLussier-Price, Mathieu 03 1900 (has links)
Les domaines de transactivation (TAD) acides sont présents dans plusieurs protéines oncogéniques, virales et dans des facteurs de différenciation de cellules souches. Ces domaines acides contrôlent la transcription à travers une myriade d’interactions avec divers partenaires ce qui provoque l’activation de la transcription ou leur propre élimination. Cependant, dans la dernière décennie, de plus en plus de recherches ont démontré que les TAD possédaient un sous-domaine activation/dégradation (DAD) responsable pour une fonction d'activation de la transcription dépendante de la dégradation de la protéine. Un tel phénomène peut être accompli par plusieurs moyens tels que des modifications post-traductionnelles, l’association à des cofacteurs ou la formation d’un réseau d’interaction complexe en chaînes. Or, aucune preuve concrète n’a pu clairement démontrer le fonctionnement de la dépendance paradoxale entre ces deux fonctions sur un activateur de transcription.
Le DAD, a été observé dans plusieurs facteurs de transcription incluant la protéine suppresseur de tumeur p53 et le facteur de différenciation érythrocyte EKLF. Un aspect particulier des DAD est que la composition de leur séquence d’acide aminé est fortement similaire à celle des domaines de liaison à l’ubiquitine (UBD) qui jouent un rôle clé dans le contrôle de la transcription à travers leur interaction non-covalente avec l’ubiquitine.
Ainsi, dans ce mémoire, nous avons étudié la possibilité que les TAD acides soient capables d’agir comme UBD pour réguler leur fonction paradoxale à travers des interactions non-covalentes avec l’ubiquitine. L’analyse est faite en utilisant la résonnance magnétique nucléaire (RMN) ainsi qu’avec des essais fonctionnels de dégradation. En somme, cette étude amène une plus grande compréhension des protéines impliquées dans le contrôle des TAD et caractérise le tout premier exemple de TAD capable d’interagir avec l’ubiquitine. / Acidic transactivating domains have been shown to be potential targets for a number of different therapies but their dynamic nature and their ability to bind many interacting partners has made it difficult to fully understand their functioning mechanisms. What we do know about these domains is that they readily control transcription through a myriad of interactions capable of either activating specific aspects of their function or simply, signal for their own demise. Within the acidic TADs lies an unusual degradation/activation domain (DAD) capable of activating transcription at the cost of its degradation. In other words, DAD transcriptional activation is dependent on the degradation of the protein. Such a phenomenon could be explained by a wide variety of hypotheses like the play of post-translational modifications, co-factors, or maybe just a really sophisticated time scaled network of interactions. However, no concrete explanation of how this dual dependent functioning domain works has yet to surface.
The DAD has been observed within acidic TADs of several transcription factors including the tumor suppressor p53 and the red blood cell differentiation factor EKLF. Interestingly though, the amino acid sequence composition of DADs share a strong similarity with several types of sequences from domains that bind ubiquitin (UBDs). These domains have been shown in the past to, in addition to their role in degradation, play a key role in regulating transcription through non-covalent interaction with ubiquitin. Hence, in this project, we investigated weather acidic TADs had the ability to function as UBDs and form non-covalent interactions with ubiquitin and also to determine the functional significance of this interaction in regards to the dual function of acidic TADs.
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