Global ETD Search

61	Étude de l’activité de Staufen1 dans la régulation traductionnelle de certains ARNm Dugré-Brisson, Samuel 12 1900 (has links) Le transport et la traduction localisée des ARN messagers sont observés chez plusieurs organismes et sont requis pour de multiples phénomènes tels la mémoire, la division cellulaire asymétrique et l’établissement des axes durant le développement. Staufen, une protéine liant l’ARN double-brin, a été identifié dans un premier temps chez la mouche à fruits Drosophila melanogaster. Il a été montré, chez cet organisme, que Staufen est requis pour la localisation des messagers bicoid et oskar aux pôles antérieur et postérieur de l’ovocyte, respectivement. Également, Staufen est requis afin que la répression traductionnelle du messager oskar soit levée une fois qu’il est bien localisé. Chez les mammifères, Stau1 est une protéine ubiquiste qui est présente dans des complexes prenant la forme de granules dans les dendrites des neurones. Également, Stau1 peut interagir de façon indépendante de l’ARN avec le ribosome et cofractionner tant avec la sous-unité 40S qu’avec la sous-unité 60S du ribosome dans un gradient de saccharose. L’implication de Stau1 dans un mécanisme permettant la dérépression traductionnelle de certains ARNm chez les mammifères était donc une voie d’investigation intéressante. Nous avons donc décidé de vérifier si Stau1 mammifère avait la capacité de stimuler la traduction d’un ARNm cellulaire via un mécanisme régulé. Au moment où cette thèse a été entreprise, aucun ARNm cellulaire lié par Stau1 n’avait été identifié chez les mammifères. Des structures d’ARN double-brin ont donc été employées afin de réprimer la traduction d’un ARNm rapporteur. C’est ainsi que nous avons montré que Stau1 peut stimuler la traduction d’un ARNm lorsqu’il lie celui-ci dans sa région 5’ non-traduite. Par la suite, en employant des micropuces d’ADN, nous avons identifié des messagers cellulaires dont la distribution dans les polysomes lourds est modifiée par Stau1. En effet, un groupe de messagers est enrichi dans les polysomes lourds suite à une surexpression de Stau1, ce qui suggère que Stau1 stimule la traduction de cette population d’ARNm. Afin d’identifier un mécanisme potentiel de régulation de l’activité traductionnelle de Stau1, nous nous sommes intéressés à la capacité d’auto-association de cette protéine. Nous avons montré que Stau1, tout comme plusieurs protéines liant l’ARN double-brin, est en mesure de s’associer à lui-même, et ce, d’une façon indépendante de l’ARN. Nous avons identifié les déterminants impliqués mettant ainsi au jour un nouveau mécanisme pouvant influencer les activités cellulaires de Stau1. Les résultats présentés dans cette thèse suggèrent donc que Stau1 est en mesure de stimuler la traduction d’une sous-population précise d’ARN messagers au sein de la cellule permettant ainsi de jeter un regard nouveau sur l’implication de cette protéine dans divers phénomènes au sein de l’organisme. / Transport and local translation of RNA are found in several organisms and are required for multiple phenomena such as memory, asymmetric cell division and establishment of the axis during development. Staufen, a double-stranded RNA binding protein, was first identified in Drosophila melanogaster. In the fruitfly, it was shown that Staufen is required for the proper localization of the bicoid and oskar transcripts to the anterior and posterior ends of the oocyte, respectively. It was also found that Staufen is important for the translational derepression of oskar once it is adequately localized. In mammals, Stau1 is a ubiquitous protein found in granules in the dendrites of neurons. Also, Stau1 can bind the ribosome in a RNA-independent manner and cofractionates with both ribosomal subunits in a sucrose gradient. The implication of Stau1 in a mechanism allowing translational derepression of certain RNAs in mammals was therefore an interesting path to explore. Accordingly, we decided to verify if mammalian Stau1 had the capacity to stimulate the translation of cellular RNAs through a regulated mechanism. When this thesis was initiated, no cellular RNA target of Stau1 had been identified in mammals. Therefore, double-stranded RNA structures were used to repress the translation of a reporter mRNA. With this model, we showed that Stau1 can stimulate the translation of a transcript when it is bound to its 5’ UTR. With the use of DNA microarrays, we identified cellular mRNAs which distribution in heavy polysomes was altered by Stau1. When Stau1 is overexpressed, this group of mRNAs is enriched heavy polysomes, suggesting a translational stimulation of this population by Stau1. To identify a regulatory mechanism that could influence Stau1’s translational activity, we studied the self-association capacity of this protein. We showed that Stau1, like several double-stranded RNA binding proteins, can self-associate in a RNA-independent manner. We have identified the determinants required for this interaction that as the potential to be important for the regulation of the cellular activities of Stau1. The results presented in this thesis suggest that Stau1 can stimulate the translation of a specific subset of mRNAs in the cell, letting us look at Stau1’s implication in different processes from a new point of view. Stau1 ARN messager Traduction ARN double-brin Auto-association Domaine de liaison à l'ARN double-brin Messenger RNA Translation Double-stranded RNA Self-Association Double-stranded RNA binding domain
62	Importance of dimerization in aggregation and neurotoxicity of Prion and [alpha]-Synuclein in prion and Parkinson's diseases Roostaee, Alireza January 2012 (has links) Abstract: Neurodegenerative diseases are associated with progressive loss of structure or function of neurons which results in cell death. Recent evidence indicate that all neurodegenerative disorders, sporadic or transmissible, may have a common pathological mechanism at the molecular level. This common feature consists of protein aggregation and accumulation of harmful aggregates in neuronal cells resulting in cellular apoptosis and neurotoxicity. Neurodegenerative diseases can affect abstract thinking, skilled movements, emotional feelings, cognition, memory and other abilities. This diverse group of diseases includes Alzheimer's disease (AD), Parkinson's disease (PD), Huntington's disease (HD), prion diseases or transmissible spongiform encephalopathies (TSEs) and amyotrophic lateral sclerosis. In my project I worked on the molecular mechanism of protein aggregation, propagation and neurotoxicity in Parkinson's disease and prion disease. Prion disease and PD are associated with misfolding and aggregation of PrPc and a-Synuclein (a-Syn), respectively. Despite being two important neurodegenerative disorders, molecular mechanisms of a-Syn or PrPC aggregation and amyloidogenesis are still unclear in PD and prion disease. Furthermore, the toxic protein species in PD have not been characterized yet. In this study we characterize the mechanism of a-Syn and PrPc misfolding in a physiological-like cell free condition in the absence of a-Syn aggregates, PrPc ggregated isoform (Pre's), denaturants or acidic environment. A number of studies indicate that dimerization of PrPc or a-Syn may be a key step in the aggregation process. To test this hypothesis we verified if enforced dimerization of PrPc or a-Syn may induce a conformational change reminiscent of the conversion of PrPc or a-Syn to PrPR' or a-Syn aggregates, respectively. We used a well-described inducible dimerization strategy where a dimerizing domain called FK506-binding protein (Fv) was fused to PrPc or a-Syn in order to produce chimeric proteins Fv-PrP and a-SynF'''. A divalent ligand AP20187 was used to induce protein dimerization. Addition of AP20187 to recombinant Fv-PrP in physiological-like conditions resulted in a rapid conformational change characterized by an increase in beta-sheet (13-Sheet) structure and simultaneous aggregation of the proteins. However, non-dimerized PrP formed 13-Sheet conformation in very slower rates. In the presence of AP20187, we also report a rapid random coil into 13-sheet conformational transformation of a-SynF" within 24 h, whereas wild type a-Syn showed 24 h delay to achieve P-sheet structure after 48 h. Electron microscopy experiments demonstrated that dimerization induced amyloid fibril formation after 48 h for both Fv-PrP and a-Syr?", whereas in the absence of dimerizing ligand AP20187, PrP or a-Syn converted into amyloid fibrils after 3 days or even later. Dimerization-induced Fv-PrP aggregates were partially resistant to PK digestion which is a characteristics of the naturally occurring PrPR'. The rates of amyloidogenesis in the presence of dimerization was also characterized by Thioflavin T (ThT) fluorescence probing. Whereas the stable structure of Fv-PrP showed no ThT binding for over 60 h of incubation at 37°C, the addition of AP20187 to Fv-PrP resulted in a time-dependent increase in ThT binding. As for a-SynR, dimerization accelerated the rate of ThT binding and amyloid formation comparing to the slower amyloidogenesis rate of wild type a-Syn in the absence of dimerizer AP20187. The impact of dimerization on a-Syn aggregation was further determined by Fluorescence ANS probing, indicating a higher affinity of dimerization-induced a-SynF" aggregates for binding to ANS comparing to wild type a-Syn aggregates. These results indicate that dimerization increases the aggregation and amyloidogenesis processes for Fv-PrP and a-SynF". Both Fv-PrP and a-SynF" amyloids were successfully propagated in vitro by protein misfolding amplification (PMCA) cycle. These results ar in agreement with the theory that all protein aggregates in neurodegenerative diseases propagate with the same molecular mechanism. Neurotoxicity of recombinant Fv-PrP and a-SynF" aggregates was determined in cellulo and in vivo, respectively. Aggregates of Fv-PrP were toxic to cultured cells whilst soluble Fv-PrP and amyloid fibres were harmless to the cells. When injected to the mice brain, both a-Syni" and a-Syn pre-fibrillar aggregates internalized cells and induced neurotoxicity in the hippocampus of wild-type mice. These recombinant toxic aggregates further converted into non-toxic amyloids which were successfully amplified by PMCA method, providing the first evidence for the in vitro propagation of synthetic a-Syn aggregates. These results suggest an important role for protein dimerization in aggregation and amyloidogenesis, and therefore, in the pathology of PD and prion disease. The similarities between aggregation, amyloidogenesis and toxicity of PrPC and ct-Syn provide further evidence on the existance of a prion-like mechanism in all neurodegenerative disorders. // Résumé: Les maladies neurodégénératives sont associées à la perte progressive des propriétés structurales ou fonctionnelles des neurones, ce qui engendre la mort des cellules. De récentes études indiquent que tous les désordres neurodégénératifs, sporadiques ou transmissibles, peuvent avoir un mécanisme pathologique commun au niveau moléculaire. Ce dispositif commun se compose de l'agrégation de protéines, de la propagation des agrégats, et de l'accumulation d’agrégats toxiques dans les cellules neuronales, menant à l'apoptose et à la neurotoxicité cellulaire. Les maladies neurodégénératives peuvent affecter la pensée abstraite, les mouvements habiles, les sentiments émotifs, la connaissance, la Mémoire et d'autres capacités cognitives. Ce groupe divers de maladies inclut la maladie d'Alzheimer (AD), de Parkinson (PD), de Huntington (HD), les maladies à prions ou encéphalopathies spongiformes transmissibles (TSEs) et la sclérose latérale amyotrophique (ALS). [symboles non conformes] Protein misfolding cyclic amplification PMCA Parkinson's disease PD FK506 binding domain Fv [alpha]-Synuclein [alpha]-Syn Protease-resistant prion protein PrP[superscript Res] Cellular prion protein PrP[superscript C]
63	Functional analyses of polymorphisms in the promoters of the KLK3 and KLK4 genes in prostate cancer Lai, John January 2006 (has links) This PhD aimed to elucidate the mechanisms by which polymorphisms may alter androgen-induced transactivation of androgen receptor (AR) target genes which may be important in prostate cancer aetiology. The second aspect of this PhD focused on identifying and characterising functional polymorphisms that may have utility as predictive risk indicators for prostate cancer and which may aid in earlier therapeutic intervention and better disease management. Analyses were carried out on the kallikrein-related peptidase 3 (KLK3), also known as the prostate specific antigen (PSA), gene and the kallikrein-related peptidase 4 (KLK4) gene. The PSA and KLK4 genes are part of the serine protease family that have trypsin or chymotrypsin like activity and are thought to play a role in the development of hormone-dependent cancers in tissues such as those in the prostate, breast, endometrium and ovaries. In the prostate, PSA is regulated by androgens and three androgen response elements (AREs) have been described in the promoter and upstream enhancer region. The PSA ARE I harbours a polymorphism at -158 bp from the transcription initiation site (TIS) that results in a G to A transition (G-158A). This PhD investigated the functional significance of the PSA G-158A polymorphism which has been reported to be associated with prostate cancer risk. Electromobility shift assays (EMSAs) investigating the interaction of ARE I variants with the AR DNA binding domain (AR-DBD) demonstrated that the A allele had a two-fold increased binding affinity for the AR-DBD when compared with the G allele. This was confirmed with endogenous AR in limited proteolysis-EMSA experiments. The limited proteolysis-EMSA experiments also demonstrated differential sensitivities of PSA ARE I alleles to trypsin digestion, which suggests that the G-158A polymorphism has an allosteric effect on the AR that alters AR/ARE I complex stability. Furthermore, Chromatin Immunoprecipitation (ChIP) assays suggest that the A allele more readily recruited the AR in vivo when compared with the G allele and is consistent with the in vitro binding data. Luciferase reporter assays carried out in both LNCaP and 22Rv1 prostate cancer cells, and using the natural (dihydrotestosterone; DHT) ligand demonstrated that the A allele was more responsive to androgens in LNCaP cells. Hence, this study has elucidated the potential mechanisms by which the G-158A polymorphism may differentially regulate PSA expression (of which up-regulation of PSA is thought to be important in prostate cancer development and progression). KLK4 has similar tissue-restricted expression as PSA and is up-regulated by steroid hormones in many endocrine cells including those in the prostate. A putative ARE (KLK4-pARE) located at -1,005 to -1019 relative to the more predominantly used transcription initiation site, TIS3, was initially found in supershift assays using AR antibodies to interact with endogenous AR. However, subsequent EMSA analysis using purified AR-DBD suggest that KLK4-pARE may be interacting with the AR indirectly. To investigate this hypothesis, a tandem construct of KLK4-pARE was cloned into the pGL3-Promoter vector for hormone-induced reporter assays. However, reporter assays did not demonstrate any responsiveness of KLK4-pARE to androgens, estradiol or progestins. Consequently, Real-Time PCR was carried out to reassess the hormonal regulation of KLK4 at the mRNA level. Consistent with the literature, data from this study suggests that KLK4 may be up-regulated by androgens, progestins and estradiol in a cyclical manner. Hormone-induced luciferase reporter assays were then carried out on seven promoter constructs that span 2.8 kb of the KLK4 promoter from TIS3. However, none of the seven promoter constructs demonstrated any significant responsiveness to androgens, estradiol or progestins. This study suggests that hormone response elements (HREs) that may drive the hormonal regulation of KLK4 in prostate cancer may be located further upstream from the promoter region investigated in this PhD, or alternatively, may lie 3' of TIS3. The characterisation of KLK4 promoter polymorphisms and their flanking sequences were also carried out in parallel to the functional work with the intent to assess the functional significance of any polymorphisms that may be located within HREs. In total 19 polymorphisms were identified from the public databases and from direct sequencing within 2.8 kb of the KLK4 promoter from TIS3. However, the functional and clinical significance of these 19 polymorphisms were not further pursued given the negative findings from the functional work. The PSA AR enhancer region was also assessed for potential polymorphisms that may be associated with prostate cancer risk. A total of 12 polymorphisms were identified in the PSA enhancer of which two (A-4643G and T-5412C) have been reported to alter functionality of the enhancer region and thus, prioritised for further analysis. Association analysis for prostate cancer risk was then carried out on these PSA enhancer polymorphisms as none of the KLK4 promoter polymorphisms were found in functional HREs. No significant association for either the A-4643G or T-5412C polymorphism with prostate cancer risk was found at the P = 0.05 level. However, under an age-adjusted dominant model a 1.22- (95% CI = 1.16-1.26) and 1.23-fold (95% CI = 1.17-1.29) increased risk for prostate cancer was found for the A-4643G or T-5412C polymorphisms, respectively. Both polymorphisms were also assessed for association with tumour grade and stage and PSA levels. Genotypes were significantly different for the A-4643G and T-5412C polymorphisms with tumour stage and PSA levels, respectively. However, these results are likely to be biased by the case population which consist primarily of men who presented with incidental (pT1) and organ-confined (pT2) tumours. To summarise, the A-4643G and T-5412C polymorphisms are unlikely to be associated with prostate cancer risk, PSA levels or stage/grade of disease. However, further analyses in a larger cohort is warranted given that these polymorphisms alter androgen responsiveness of the PSA enhancer and that elevated PSA levels are indicative of men with prostate cancer. To summarise, this PhD has elucidated the functional significance of the PSA G-158A polymorphism in prostate cancer and which may be important in prostate cancer patho-physiology. This PhD has also furthered the understanding of the hormonal regulation of KLK4 in prostate cancer cells. Finally, this PhD has carried out a pilot study on two functional PSA enhancer polymorphisms (A-4643G and T-5412C) with prostate cancer risk. prostate cancer single nucleotide polymorphism (SNP) kallikreins (KLKs) kallikrein 4 (KLK4) prostate specific antigen (PSA) androgens hormones androgen receptor (AR) androgen response element (ARE) electromobility shift assay (EMSA) luciferase reporter assay
64	Ubiquitin-binding domains in polyubiquitin chain synthesis Pluska, Lukas 21 August 2020 (has links) Ubiquitinierung ist eine essentielle posttranslationale Proteinmodifikation (PTM), die vielfältige Prozesse in eukaryotischen Zellen steuert. Ubiquitin wird zu unterschiedlichen polymeren Ketten zusammengesetzt, wobei E2-Ubiquitin-konjugierende Enzyme häufig eine entscheidende Rolle spielen. Im Rahmen meiner Promotion habe ich die molekularen Grundlagen der Ub Kettensynthese durch die E2-Enzyme Ubc1 und Ubc7 untersucht. Dies geschah mithilfe von in vitro Ubiquitinierungs-Reaktionen, biochemischen und strukturellen Untersuchungen sowie zellbiologischen Experimenten. Ich konnte zeigen, dass zugehörige Ubiquitin-Binde-Domänen (UBDs) die Funktion der E2-Enzyme maßgeblich regulieren. Als einziges unter elf E2-Enzymen in S. cerevisiae enthält Ubc1 eine Ub-bindende UBA Domäne, deren Funktion bisher unklar blieb. Ubc1 modifiziert ausschließlich Lysin 48 (K48) in Ub und wurde mit Proteinqualitätskontrolle sowie der Regulation des Zellzyklus in Verbindung gebracht. Meine Ergebnisse zeigen, dass Ubc1 mithilfe seiner UBA-Domäne vorzugsweise mit K63-verknüpftem Polyubiquitin interagiert, wodurch K48/K63 verzweigte Ub-Ketten entstehen. Basierend auf vorhandenen Strukturinformationen und meinen eigenen röntgenkristallographischen Untersuchungen zeige ich eine Modellstruktur für die Reaktion auf. Meine Ergebnisse stellen eine wesentliche Untersuchungsgrundlage für verzweigten Ub-Ketten dar, über deren Vorkommen und Funktion bisher wenig bekannt ist. Ubc7 assembliert mithilfe seines Kofaktors Cue1 K48-verknüpfte Ub-Ketten im Rahmen des Endoplasmatisches-Retikulum-assoziierten Proteinabbaus (ERAD). In einem kollaborativen Projekt haben wir die Ub-bindende CUE-Domäne in Cue1, die hierfür eine Schlüsselrolle spielt, untersucht. Sie ermöglicht die Ausrichtung des E2-Enzyms an der distalen Spitze der Ub-Kette für eine schnelle Kettenverlängerung, besitzt einzigartige auf den Prozess angepasste Bindungseigenschaften und ihre Beeinträchtigung stört den Abbau des ERAD-Substrates Ubc6. / Ubiquitination is an essential posttranslational protein modification (PTM) that regulates widespread intracellular processes in eukaryotic cells. Ubiquitin (Ub) can be assembled into polymeric chains through its seven internal lysine residues and the N-terminus enabling the formation of a complex "Ubiquitin Code". Factors that guide the molecular machinery which produces this code remain poorly understood. In this study, I demonstrate that ubiquitin binding domains (UBDs) associated with the E2 enzymes Ubc1 and Ubc7 substantially contribute to the assembly of particular Ub chains. Uniquely among the eleven E2 enzymes of S. cerevisiae Ubc1 contains a ubiquitin binding UBA domain. Ubc1 exclusively modifies lysine 48 (K48) in Ub and has been implicated in protein quality control and cell cycle progression. However, the function of its UBA domain remained elusive. I identified Ubc1 to preferentially target specific Ub molecules in K63-linked polyubiquitin via its UBA domain. This activity results in the assembly of K48/K63 branched Ub chains. Based on existing structural information and my own X-ray crystallographic experiments, I propose a structure for the transition state of branched chain assembly by Ubc1. My findings provide a basis for the study of this unusual Ub chain type. Ubc7 has previously been shown to be activated by its co-factor Cue1 to assemble Ub chains linked through lysine 48 (K48) in the context of endoplasmic reticulum associated protein degradation (ERAD). In collaboration with Dr. Maximilian von Delbrück and Dr. Andreas Kniss, we identified the ubiquitin binding CUE domain in Cue1 to play a key role in aligning Ubc7 with the distal tip of a K48-linked Ub chain for rapid chain elongation. Furthermore, we showed how binding of Ub by the CUE domain is well adapted towards the chain elongation process and how its disruption impairs degradation of the ERAD substrate Ubc6. Ubiquitin-konjugierendes Enzym Polyubiquitin Ubiquitin-bindende Domäne Enzymatischer Reaktionsmechanismus K48 K63 verzweigte Ubiquitinkette ubiquitin conjugating enzyme polyubiquitin ubiquitin-binding domain enzyme mechanism K48 K63 branched ubiquitin chain 572 Biochemie WD 5100 WE 2200 ddc:572
65	Étude sur la reconnaissance de l'ubiquitine par les domaines de transactivation acides des activateurs de transcription Lussier-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. Activateur de transcription Domaine de liaison à l'ubiquitine p53 Résonance magnétique nucléaire Interaction protéine-protéine Acidic transactivating domains Domaine d'activation et de dégradation Degradation activation domain (DAD) Ubiquitin binding domain (UBD) Protein-protein interaction (PPI) Ubiquitin (UBI) Nuclear magnetic resonance (NMR) Erythroid Kruppel-like factor (EKLF)
66	Unfolding the Mechanism of Notch1 Receptor Activation : Implications in Cancer Stem Cell Targeting Sharma, Ankur January 2013 (has links) (PDF) Notch receptors and ligands are single-pass transmembrane proteins which play important roles in cell-cell communication. Notch in ‘harmony’ with other signaling pathways regulate the entire diversity of metazoan life (Artavanis-Tsakonas & Muskavitch, 2010). These signaling pathways also play key roles in regulatingseveral developmental processes. Given the importance of Notch signaling in various developmental decisions, it is not surprising that aberrant gain or loss-of-function of Notch pathway leads to several human diseases including cancer (Ranganathan et al, 2011). Notch signaling has also been implicated in various human cancers, most notably in T-cell acute lymphoblastic leukemia (T-ALL) (Weng et al, 2004). In view of the importance of Notch signaling in cancers, therapeutic molecules targeting this pathway are making their way into clinical trials (Rizzo et al, 2008). This underscores the importance of understanding the mechanism of Notch receptor activation in normal and patho-physiological conditions. In this thesis, antibodies against different domains of human Notch1 receptor have been used as tools to understand the mechanism of receptor activation. This work has provided insights into the role of Notch1 extracellular domain in ligand-dependent receptor activation. Further, the mechanism of ligand-independent receptor activation in T-ALL associated mutant Notch1 has also been investigated. This understanding of ligand-dependent and independent receptor activation facilitated development of mechanistic inhibitors of Notch signaling for therapeutic targeting of the cancer stem cells (CSCs) across the pectrum of cancers. The thesis is divived into two parts. Part-I focuses on understanding the role of Notch1 extracellular domain in receptor-ligand interactions using antibodies as a tool. In part-II, implications of these antibodies in therapeutic targeting of CSCs has been investigated. Part-I Unfolding the Mechanism of Notch1 Receptor Activation The extracellular domain of Notch1 receptor consists of 36 EGF-like repeats that contribute to ligand binding (Kopan & Ilagan, 2009). Despite extensive studies on the downstream consequences of Notch signaling, the initial events of ligandreceptor interactions have not been clearly elucidated. In the absence of structural insights into the receptor-ligand interactions, it was important to decipher the roles of various receptor domains in ligand-binding and consequent signaling. In this study, antibodies have been employed as tools for in-depth analyses of Notch receptorligand, interactions. Studies in Drosophila Notch receptor suggest that EGF-like repeats 11-12 are necessary and sufficient for ligand binding (Rebay et al, 1991). However, the role of these repeats in human Notch1 receptor-ligand interaction(s) was not clearly elucidated. Antibodies were generated against Notch1 EGF-like repeats 11-15. Further, these antibodies were characterized for their specificity for Notch1 receptor in various ligand-binding and signaling assays. The results suggest that the monoclonal antibodies (MAbs) against EGF-like repeats 11-12 were more potent inhibitors of ligand-binding compared to the antibodies against EGF-like repeats 13-15. As a part of these investigations, the Notch ligands Jagged1 and Jagged2, Delta-like1 and Delta-like4 were purified and characterized in various assays. Ability of these ligands to interact with Notch1 EGF-like repeat 11-15 was determined using Surface Plasmon Resonance. The Jagged family of ligands demonstrated higher affinity for this recept or fragment when compared to the Delta family of ligands. The relatively low affinities (μM) of all the ligands suggested possibile involvement of other EGF-like repeats in ligand-binding. This was further investigated using antibodies against other EGF-like repeats of Notch1. In Drosophila Notch EGF-like repeats 24-29 have been implicated in the ligand-dependent gain-of-function phenotype, suggesting a plausible involvement of this region in receptor activation (Pei & Baker, 2008). Therefore, role of human Notch1 EGF-like repeats 21-30 in ligand-binding and signaling was investigated. These EGF-like repeats demonstrated specific interaction with the ligand-binding domain (EGF-like repeats 11-15). This suggested that in the absence of the ligand, these inter-domain interactions keep the receptor in an auto-inhibited conformation. Further, ligand binding to EGF-like repeats 11-15 dissociated pre-formed interdomain interactions. These results suggested that, the binding of ligand to EGF-like repeat 11-12 overcomes the negative constraint imposed by the intra-domain interactions which might lead to receptor activation. Next, to understand the role of EGF-like repeats 21-30 in ligand binding, polyclonal antibodies were generated against the same and extensively characterized in various solid-phase and cell-based assays. These antibodies demonstrated partial inhibition of ligand-binding. Further, using immunoaffinity purified antibodies it was demonstrated that antibodies against EGF-like repeats 25-26 were most potent inhibitors of ligand-binding compared to antibodies against EGF-like repeats 21-24 and 27-30. These results provided novel insights into Notch1 receptor activation. The model proposed on the basis of these results suggested that ligand-binding to EGF-like repeats 11-12 competes with the inter-domain interaction, in turn dissociating EGF-like repeats 21-30 from the ligandbinding domain. It emerged that this altered conformation of the receptor creates a secondary ligand-binding site at EFG-like repeats 25-26. Overall these results provided novel insight into the mechanism of Notch receptor-ligand interaction(s). Part-II Implication in Cancer Stem Cell Targeting Recent studies have suggested existence of the CSC population in various cancers (Clevers, 2011). Notch signaling plays an important role in maintenance of these CSCs (Pannuti et al, 2010). Thus, targeting Notch signaling may provide a potential therapeutic tool for CSC targeting. Several studies have indicated that Notch1 receptor and ligands are overexpressed in breast cancer cells compared to the normal breast epithelium (Mittal et al, 2009; Reedijk et al, 2005; Reedijk et al, 2008). Moreover, it has been suggested that Notch1 signaling plays a key role in breast carcinogenesis (Stylianou et al, 2006). Monoclonal antibodies (MAbs) were used as mechanistic inhibitors of aberrant Notch1 signaling for therapeutic targeting of CSCs. One such antibody, MAb 602.101, against Notch1 ligand-binding domain (EGF-like repeat 11-12) inhibited proliferation and depleted breast CSCs. This MAb also modulated genes associated with stemness and epithelial to mesenchymal transition (EMT). Furthermore, MAb 602.101 irreversibly inhibited the sphere-forming potential of breast cancer cells by modulating long-term self renewing capacity of breast CSCs. Inhibition of Notch1 signaling by the MAb also depleted the chemoresistant CD44Hi/CD24Low sub-population in breast cancer cells. Interestingly, antibody treatment led to elevated expression of genes associated with myoepithelial lineage, which suggested that inhibition of Notch1 signaling might induce a differentiation program leading to reduction in the CSC population. This study demonstrated the importance of Notch1 signaling in CSCs and effectiveness of antibodies as a tool for specific targeting of individual Notch receptors in cancer therapeutics. While aberrant expression of receptors and ligands leads to breast cancer (Reedijk et al, 2005), gain-of-function mutations are associated with 40-50% of TALL\ patients (Weng et al, 2004). These mutations lead to ligand-independent receptor activation (Malecki et al, 2006). Despite several attempts of successful antibodymediated therapeutic targeting of Notch1 (Aste-Amézaga et al, 2010; Wu et al, 2010), specific antibodies recognizing T-ALL associated mutant Notch1 remains elusive. Using homology modeling, the mutation induced conformational change in T-ALL associated mutant Notch1 was predicted. These results suggested that mutation led to conformational changes in the Notch1 negative regulatory region (NRR) This conformation change might result in the constitutive activation of Notch1 signaling leading to pathogenesis. Next, MAbs were generated against the wild-type Notch1 NRR and characterized in flow-cytometry based assays for identification of conformation specific antibodies. These antibodies were classified as either wild-type specific, mutant specific or unbiased to receptor conformations. One such mutant specific MAb 604.107 demonstrated higher binding to mutant Notch1 in flowcytometer and SPR based experiments. This MAb also demonstrated specific inhibition of T-ALL associated mutant Notch1 signaling without affecting the wildtype signaling. Moreover, antibody treatment also inhibited proliferation and depleted leukemia initiating sub-population in patient derived T-ALL cells. Taken together, this study provides a novel tool for specific targeting of mutant Notch1 receptors in TALL. CSCs are inherently chemo-resistant and lead to tumor relapse (Chen et al, 2012). Recent studies have demonstrated a strong correlation between Notch1 signaling in lung CSCs and chemotherapy resistance (Hassan et al, 2013). In this study, Notch1 heterogeneity in solid tumors viz. breast and colon cancers was investigated. Using the antibodies generated previously in this study, Notch1High and Notch1Low sub-populations from MDA-MB-231 (breast cancer) and HCT-116 (colon cancer) cell lines were flow-sorted. It was demonstrated that the Notch1High subpopulation represented the sphere-forming CSCs in breast and colon cancer. The Notch1High sub-population also demonstrated chemo-resistant properties and expressed higher level of EMT and stemness markers. These results suggested explicit involvement of Notch1 signaling in EMT and maintenance of CSCs subpopulation in these cancers. The anti-Notch1 MAb also inhibited proliferation of the chemo-resistant Notch1High sub-population. Further, treatment with MAb inhibited expression of ABCC1 transporters in these drug-resistant cells leading to augmentation of chemotherapeutic response. Using mouse xenograft assays, it was demonstrated that Notch1 signaling plays an important role in the maintenacne of tumor-initiating sub-population in breast and colon cancer cells. Prior exposure of breast and colon cancer cells to MAb inhibited the tumor forming potential of these cells in xenotransplantation assays. Treatment with MAb alone or in combination with chemotherapy led to regression of pre-formed tumors in breast and colon xenograft models. These results demonstrated existence of Notch1 heterogeneity in breast and colon cancer cells and emphasised the importance of targeting Notch1 signaling to overcome drug-resistance in these cancers. The results described above have provided important insights into Notch1 receptor activation and this understanding was translated into therapeutic targeting of CSCs. This “proof-of-principle” demonstration has significant mechanistic and applied implications in Notch and cancer biology. Cancer Stem Cell Targeting Notch Receptors Notch Signaling Notch Receptor Activation Notch Receptor-Ligand Interactions Human Notch1 Receptors Breast Cancer Stem Cell Targeting Notch1 Antibodies - Cancer Therapy Notch1 Receptor Activation Notch1 Signaling Notch Notch1 Ligand Binding Domain Molecular Biology
67	Charakterisierung der Punktmutante E449A in der DNA-Bindedomäne des humanen Transkriptionsfaktors STAT1 / Characterization of the point mutation E449A in the DNA binding domain of the human transcription factor STAT1 Schiffmann, Jannis Christian 23 June 2020 (has links) No description available. 610 STAT-Protein JAK-Protein JAK STAT STAT/JAK-Signalweg Importin-alpha-5 E449A-Mutante DNA-Bindedomäne JAK STAT protein JAK protein STAT JAK/STAT signaling pathway Janus Kinase IFN gamma E449A DNA binding domain Importin-alpha-5 GOK-MEDIZIN
68	Small molecule compounds targeting DNA binding domain of STAT3 for inhibition of tumor growth and metastasis Huang, Wei January 2014 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / Signal transducer and activator of transcription 3 (STAT3) is constitutively activated in malignant tumors, and its activation is associated with high histological grade and advanced cancer stage. STAT3 has been shown to play important roles in multiple aspects of cancer aggressiveness including proliferation, survival, self-renewal, migration, invasion, angiogenesis and immune response by regulating the expression of diverse downstream target genes. Thus, inhibiting STAT3 promises to be an attractive strategy for treatment of advanced tumors with metastatic potential. We firstly identified a STAT3 inhibitor, inS3-54, by targeting the DNA-binding site of STAT3 using an in-silico screening approach; however, inS3-54 was finally found not to be appropriate for further studies because of low specificity on STAT3 and poor absorption in mice. To develop an effective and specific STAT3 inhibitor, we identified 89 analogues for the structure-activity relationship analysis. By using hematopoietic progenitor cells isolated from wild-type and STAT3 conditional knockout mice, further studies showed that three analogues (A18, A26 and A69) only inhibited STAT3-dependent colony formation of hematopoietic progenitor cells, indicating a higher selectivity for STAT3 than their parental compound, inS3-54. These compounds were found to (1) inhibit STAT3-specific DNA binding activity; (2) bind to STAT3 protein; (3) suppress proliferation of cancer cells harboring aberrant STAT3 signaling; (4) inhibit migration and invasion of cancer cells and (5) inhibit STAT3-dependent expression of downstream targets by blocking the binding of STAT3 to the promoter regions of responsive genes in cells. In addition, A18 can reduce tumor growth in a mouse xenograft model of lung cancer with little effect on body weight. Taken together, we conclude that it is feasible to inhibit STAT3 by targeting its DNA-binding domain for discovery of anticancer therapeutics. STAT3 DNA binding domain Inhibitor Structure-based drug discovery Signaling pathway Cancer Chemoprevention -- Research Cancer -- Chemotherapy Pathology, Molecular Genetic transcription -- Regulation Mobile genetic elements Drug development Carcinogenesis Enzyme inhibitors -- Therapeutic use
69	IDENTIFICATION OF TARGETS AND AUXILIARY PROTEINS OF PYR/PYL/RCAR ABA RECEPTORS: PROTEIN PHOSPHATASES TYPE 2C (PP2Cs) AND C2-DOMAIN ABA-RELATED PROTEINS (CARs) Rodríguez Solovey, Leisa Natacha 16 December 2015 (has links) [EN] ABSTRACT Abscisic acid (ABA) signaling plays a critical role in regulating root growth and root system architecture. ABA-mediated growth promotion and root tropic response under water stress are key responses for plant survival under limiting water conditions. In this work, we have explored the role of Arabidopsis (Arabidopsis thaliana) PYR/PYL/RCAR receptors (PYRABACTIN RESISTANCE1 (PYR1)/PYR1 LIKE (PYL)/REGULATORY COMPONENTS OF ABA RECEPTORS) for root ABA signaling. As a result, we discovered that PYL8 plays a nonredundant role for the regulation of root ABA sensitivity. Unexpectedly, given the multigenic nature and partial functional redundancy observed in the PYR/PYL family, the single pyl8 mutant showed reduced sensitivity to ABA-mediated root growth inhibition. This effect was due to the lack of PYL8-mediated inhibition of several clade A phosphatases type 2C (PP2Cs), since PYL8 interacted in vivo with at least five PP2Cs, namely HYPERSENSITIVE TO ABA1 (HAB1), HAB2, ABAINSENSITIVE1 (ABI1), ABI2, and PP2CA/ABA-HYPERSENSITIVE GERMINATION3 as revealed by tandem affinity purification and mass spectrometry proteomic approaches. Membrane-delimited abscisic acid (ABA) signal transduction plays a critical role in early ABA signaling, but the molecular mechanisms linking core signaling components to the plasma membrane are unclear. We show that transient calciumdependent interactions of PYR/PYL/RCAR ABA receptors with membranes are mediated through a 10-member family of C2-domain ABA-related (CAR) proteins in Arabidopsis thaliana. Specifically, we found that PYL4 interacted in an ABA-independent manner with CAR1 in both the plasma membrane and nucleus of plant cells. CAR1 belongs to a plant-specific gene family encoding CAR1 to CAR10 proteins, and bimolecular fluorescence complementation and coimmunoprecipitation assays showed that PYL4-CAR1 as well as other PYR/PYL-CAR pairs interacted in plant cells. The crystal structure of CAR4 was solved, which revealed that, in addition to a classical calcium-dependent lipid binding C2 domain, a specific CAR signature is likely responsible for the interaction with PYR/PYL/RCAR receptors and their recruitment to phospholipid vesicles. This interaction is relevant for PYR/PYL/RCAR function and ABA signaling, since different car triple mutants affected in CAR1, CAR4, CAR5, and CAR9 genes showed reduced sensitivity to ABA in seedling establishment and root growth assays. In summary, we identified PYR/PYL/RCAR-interacting partners that mediate a transient Ca2+-dependent interaction with phospholipid vesicles, which affects PYR/PYL/RCAR subcellular localization and positively regulates ABA signaling. / [ES] RESUMEN La señalización por la hormona vegetal ácido abscísico (ABA) desempeña un papel crítico en la regulación del crecimiento de la raíz y en la arquitectura del sistema radical. La promoción de crecimiento de la raíz en condiciones de estrés hídrico mediada por ABA es clave para la supervivencia de las plantas bajo condiciones limitantes de agua. En este trabajo, hemos explorado el papel de los receptores PYR/PYL/RCAR (PYRABACTIN RESISTANCE1 (PYR1)/PYR1 LIKE (PYL)/ REGULATORY COMPONENTS OF ABA RECEPTORS) de Arabidopsis (Arabidopsis thaliana) en la ruta de señalización de ABA en raíz. Así, hemos descubierto que el receptor de ABA PYL8 juega un papel no redundante en la regulación de la percepción de ABA en raíz. Inesperadamente, dada la naturaleza multigénica y la redundancia funcional parcial observada en la familia PYR/PYL/RCAR, el mutante pyl8 fue el único mutante sencillo de pérdida de función de los receptores PYR/PYL/RCAR que mostraba una sensibilidad reducida a la inhibición del crecimiento mediada por ABA en raíz. Este efecto se debe a la falta de inhibición mediada por PYL8 de varias fosfatasas del grupo A tipo 2C (PP2Cs), ya que PYL8 es capaz de interactuar in vivo con al menos cinco PP2Cs, denominadas HYPERSENSITIVE TO ABA1 (HAB1), HAB2, ABAINSENSITIVE1 (ABI1), ABI2, and PP2CA/ABA-HYPERSENSITIVE GERMINATION3 según lo han revelado la purificación por afinidad en tándem (TAP por sus siglas en inglés) y estudios proteómicos de espectrometría de masas. La transducción de la señal del ABA localizada en la membrana plasmática celular juega un papel crucial en los pasos iniciales de la señalización de la fitohormona, pero los mecanismos moleculares que unen los componentes básicos de la señalización y la membrana plasmática no están claros. Estudiando las interacciones de los receptores del ABA PYR/PYL/RCAR con la membrana plasmática hemos encontrado que éstos pueden interaccionar transitoriamente con ella de forma dependiente de calcio gracias a una familia de proteínas con dominios C2 relacionadas con la ruta de señalización de ABA (denominadas C2-domain ABA-related (CAR) proteins). Específicamente, se encontró que PYL4 interacciona de manera independiente de ABA con CAR1 tanto en la membrana plasmática como en el núcleo de las células vegetales. La proteína CAR1 pertenece a una familia multigénica constituida por 10 miembros en Arabidopsis thaliana, desde CAR1 hasta CAR10, y que solo se encuentra en plantas. Los ensayos de complementación bi-molecular de fluorescencia y de co-immunoprecipitación confirmaron la interacción en células vegetales tanto de PYL4-CAR1 como de otras parejas de PYR/PYL-CAR. La cristalización de la proteína CAR4 reveló que, además de un dominio C2 clásico de unión a lípidos dependiente de calcio, las proteínas de la familia CAR presentan un dominio específico que probablemente es responsable de la interacción con los receptores PYR/PYL/RCAR y de su posterior reclutamiento a las vesículas de fosfolípidos. Esta interacción es relevante para la función de los receptores PYR/PYL/RCAR en la señalización del ABA, ya que diferentes mutantes triples car de pérdida de función, que tienen afectados los genes CAR1, CAR4, CAR5, y CAR9, demostraron una reducción de la sensibilidad al ABA en ensayos de establecimiento de plántula y crecimiento de la raíz. En resumen, hemos identificado nueva familia de proteínas que son capaces mediar las interacciones transitorias dependientes de Ca2+ con vesículas de fosfolípidos, lo que a su vez afecta localización de PYR/PYL/RCAR y regula positivamente la señalización de ABA. / [CAT] RESUM La senyalització per l'hormona vegetal àcid abcíssic (ABA) exerceix un paper crític en la regulació del creixement de l'arrel i també en l'arquitectura del sistema radical. La promoció del creixement de l'arrel en condicions d'estrés hídric, regulada per ABA és clau per la supervivència de les plantes sota condicions limitants d'aigua. Amb aquest treball, hem investigat el paper dels receptors PYR/PYL/RCAR (PYRABACTIN RESISTANCE1 (PYR1)/PYR1 LIKE (PYL)/ REGULATORY COMPONENTS OF ABA RECEPTORS) d'Arabidopsis (Arabidopsis thaliana) en el camí de senyalització d'ABA en arrel. Així, hem descobert que el receptor d'ABA PYL8 exerceix un paper no redundant en la regulació de la percepció d'ABA en arrel. Inesperadament, donada la naturalesa multigènica i la redundància funcional parcial que s'observa en la família PYR/PYL/RCAR, el mutant pyl8 va ser l'únic mutant senzill de pèrdua de funció dels receptors PYR/PYL/RCAR que mostrava una sensibilitat reduïda a la inhibició del creixement mitjançada per l'ABA en l'arrel. Doncs aquest efecte es deu a la falta d'inhibició regulada per PYL8 de diverses fosfatases del grup A tipus 2C (PP2Cs), ja que PYL8 té la capacitat d'interactuar in vivo almenys amb cinc PP2Cs, anomenades HYPERSENSITIVE TO ABA1 (HAB1), HAB2, ABAINSENSITIVE1 (ABI1), ABI2, and PP2CA/ABAHYPERSENSITIVE GERMINATION3 segons ho han revelat per una banda la purificació per afinitat en tàndem (TAP són les seues sigles en anglés) i per altra banda, estudis proteòmics d'espectrometria de masses. Pel que fa a la transducció del senyal del l'ABA, la qual es localitza en la membrana plasmàtica cel¿lular, juga un paper molt important en els primers instants de la senyalització de la fitohormona, no obstant això els mecanismes moleculars que uneixen els components bàsics d'aquesta senyalització amb la membrana plasmàtica, no es troben del tot clars. Per tant, s'han estudiat les interaccions que tenen els receptors del ABA PYR/PYL/RCAR amb la membrana plasmàtica, i hem trobat que aquests tenen la capacitat d'interaccionar transitòriament amb la membrana de forma dependent al calci, gràcies a una família de proteïnes amb domini C2, les quals es troben relacionades amb la ruta de senyalització d'ABA(anomenades C2domain ABArelated (CAR) proteins).Específicament, es va trobar que PYL4 interacciona d'una manera independent al ABA amb CAR1, tant en la membrana plasmàtica, com en el nucli de les cèl¿lules vegetals. La proteïna CAR1 pertany a la família multigènica constituïda per 10 components en Arabidopsis thaliana, des de CAR1 fins CAR10, que tan sols es troba en plantes. Els assajos de complementació bimolecular de fluorescència i de co-immunoprecipitació, van confirmar la interacció en cèl¿lules vegetals, tant de PYL4CAR1 com d'altres parelles de PYR/PYL-CAR. La cristal¿lització de la proteïna CAR4 va revelar que, a més d'un domini C2 clàssic de unió a lípids dependent del calci, les proteïnes de la família CAR presenten un domini PYR/PYL/RCAR, i del seu posterior reclutament a les vesícules fosfolipídiques. Doncs, aquesta interacció és rellevant en la funció dels receptors PYR/PYL/RCAR, ja que participa en la senyalització del l'ABA. Aquesta interacció es clau per a la funció dels receptors, ja que diferents mutants triples car de pèrdua de funció, els quals posseïxen afectats els gens CAR1, CAR4, CAR5 i CAR9, van mostrar una reducció de la sensibilitat a l'ABA en assajos d'establiment de plàntula i creixement de l'arrel. En conclusió, hem identificat una nova família de proteïnes amb la capacitat d'organitzar les interaccions transitòries dependents del calci amb vesícules de fosfolípids, fet que al seu torn afecta la localització de PYR/PYL/RCAR i regula positivament la senyalització d'ABA. / Rodríguez Solovey, LN. (2015). IDENTIFICATION OF TARGETS AND AUXILIARY PROTEINS OF PYR/PYL/RCAR ABA RECEPTORS: PROTEIN PHOSPHATASES TYPE 2C (PP2Cs) AND C2-DOMAIN ABA-RELATED PROTEINS (CARs) [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/58862 / TESIS Abscisic acid (ABA) Arabidopsis thaliana, Abiotic Stress C2-DOMAIN ABA-RELATED PROTEINS (CARs) CLADE A PROTEIN PHOSPHATASE 2C (PP2C) Protein Binding Targets Ca2+-Dependent Lipid-Binding Domain Subcellular Localization Plasma-membrane binding Signal transduction Root ABA Response Yeast Two-Hybrid Tandem Affinity Purification (TAP) Crystal Structure MICROBIOLOGIA BIOQUIMICA Y BIOLOGIA MOLECULAR

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