Structure-fonction de l’action pionnière de Pax7

Bascunana, Virginie

08 1900

Dans l’hypophyse, Pax7 spécifie l’état du lobe intermédiaire grâce à son action pionnière. Cette action implique dans un premier temps une liaison de cette protéine à certains sites d’hétérochromatine et, par la suite, le remodelage de cette hétérochromatine en euchromatine. Le remodelage de l’épigénome par Pax7 permet au facteur de transcription Tpit d’entrainer l’activation du transcriptome mélanotrope par opposition au destin hypophysaire corticotrope entraîné par Tpit en l’absence de Pax7. Pour étudier l’action pionnière de Pax7, différents membres du laboratoire Drouin ont utilisé un modèle de cellules corticotropes. L’expression ectopique du facteur pionnier Pax7 dans ces cellules permet leur transition d’un phénotype corticotrope à mélanotrope. En plus de l’isoforme prédominante de Pax7 exprimée dans hypophyse avec lequel les travaux de Budry et Mayran ont étaient faits, il existe trois autres isoformes de Pax7 qui diffèrent par quelques acides aminés (Q et GL) dans le domaine PAIRED liant l’ADN. Nous voulions savoir quels étaient les domaines protéiques de Pax7 impliqués pour son activité pionnière. Nous avons d’abord étudié les propriétés des différents isoformes naturelles de Pax7 présentant des variations dans le domaine PAIRED que ce soient pour leurs capacités de facteur transcription ou de facteur pionnier dans un modèle de cellules de corticotrope. Nous avons constaté que les quatre isoformes de Pax7, ainsi que Pax3, le facteur le plus homologue à Pax7 dans la famille Pax, présentent une capacité similaire à lier la chromatine fermée. Cependant, Pax3 et les isoformes de Pax7 (GL+) sont incapables d’ouvrir la chromatine sur un sous-groupe d’enhancers pionniers nécessaire à l’activation du transcriptome mélanotrope. Par la suite, par analyse structure-fonction, nous avons identifié une région de Pax7 importante pour sa liaison à soixante pour cent des sites présents dans l’hétérochromatine qui sont ciblés par l’action pionnière et une région importante pour l’ouverture de chromatine aux sites des pionniers sensibles à la variation GL. Collectivement, nos données ont montré que les acides aminés GL dans le domaine PAIRED en N-terminal et la partie C-terminale de la protéine Pax7 sont critiques pour l’ouverture de la chromatine à des enhancers spécifiques présents dans l’hétérochromatine dont l’activation est nécessaire au destin mélanotrope. D’autre part, les analyses de structure-fonctions nous ont permis d’identifier une région critique de Pax7 nécessaire à son interaction avec l’hétérochromatine sur ces même enhancers. / In the pituitary, Pax7 specifies the intermediate lobe state through a pioneer factor action that involves the binding of this protein to certain heterochromatin sites and, subsequently, the remodeling of this heterochromatin into euchromatin. Epigenome remodeling by Pax7 thus allows the transcription factor Tpit to determine the melanotrope fate as opposed to the corticotrope pituitary fate that is driven by Tpit in absence of Pax7. To study the pioneering action of Pax7, Budry et al, and Mayran et al, used a model of corticotrope cells which, following the expression of Pax7, transit from a corticotrope phenotype to melanotic phenotype thanks to its pioneering action. In addition to the predominant Pax7 isoform expressed in pituitary with which the work of Budry and Mayran were done, there are three other Pax7 isoforms that differ by a few amino acids (Q and GL) in the DNA-binding paired domain. We wanted to know what protein domains of Pax7 was involved in its pioneering activity. We have investigated the properties of the different Pax7 isoforms with respect to their transcriptional and pioneer capabilities in a model of corticotrope cells. We found that all four Pax7 isoforms together with the closely related factor Pax3, exhibit a similar ability to bind closed chromatin. However, Pax3 and the isoforms of Pax7 (GL+) failed to open the chromatin at a subset of enhancer necessary to activate the melanotrope transcriptome. In addition, we have identified by structure-function analysis a region of Pax7 that appears important for Pax7 binding at 60 percent of heterochromatin sites that are targeted for pioneering and one region important for chromatin opening to the pioneer sites GL-sensible. Collectively, our data suggest that the amino acids GL in the paired domain and the C-terminal part are critical for the chromatin opening to heterochromatin sites necessary to melanotrope transcriptome. On the other hand, structure-functions analyses allowed us to identify a critical region of Pax7 required for the interaction with heterochromatin on these same enhancers.

Différentiation

Hypophyse

Pax7

Action pionnière

Isoformes

Étude structure-fonction

Pituitary gland

Pioneer activity

Isoforms

Structure function study

A proteomic approach to the identification of cytochrome P450 isoforms in male and female rat liver by nanoscale liquid chromatography-electrospray ionization-tandem mass spectrometry.

Nisar, S., Lane, C.S., Wilderspin, A.F., Welham, K.J., Griffiths, W.J., Patterson, Laurence H.

January 2004

No / Nanoscale reversed-phase liquid chromatography (LC) combined with electrospray ionization-tandem mass spectrometry (ESI-MS/MS) has been used as a method for the direct identification of multiple cytochrome P450 (P450) isoforms found in male and female rat liver. In this targeted proteomic approach, rat liver microsomes were subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis followed by in-gel tryptic digestion of the proteins present in the 48- to 62-kDa bands. The resultant peptides were extracted and analyzed by LC-ESI-MS/MS. P450 identifications were made by searching the MS/MS data against a rat protein database containing 21,576 entries including 47 P450s using Sequest software (Thermo Electron, Hemel Hempstead, UK). Twenty-four P450 isoforms from the subfamilies 1A, 2A, 2B, 2C, 2D, 2E, 3A, 4A, 4F, CYP17, and CYP19 were positively identified in rat liver.

Cytochrome P450 (P450) isoforms

Rat liver

Cytochrome identification

The four major N- and C-terminal splice variants of the excitatory amino acid transporter GLT-1 form cell surface homomeric and heteromeric assemblies

Peacey, E., Miller, C.C., Dunlop, J., Rattray, Marcus

January 2009

No / The L-glutamate transporter GLT-1 is an abundant central nervous system (CNS) membrane protein of the excitatory amino acid transporter (EAAT) family that controls extracellular L-glutamate levels and is important in limiting excitotoxic neuronal death. Using reverse transcription-polymerase chain reaction, we have determined that four mRNAs encoding GLT-1 exist in mouse brain, with the potential to encode four GLT-1 isoforms that differ in their N and C termini. We expressed all four isoforms (termed MAST-KREK, MPK-KREK, MAST-DIETCI, and MPK-DIETCI according to amino acid sequence) in a range of cell lines and primary astrocytes and show that each isoform can reach the cell surface. In transfected human embryonic kidney (HEK) 293 or COS-7 cells, all four isoforms support high-affinity sodium-dependent L-glutamate uptake with identical pharmacological and kinetic properties. Inserting a viral epitope (tagged with V5, hemagglutinin, or FLAG) into the second extracellular domain of each isoform allowed coimmunoprecipitation and time-resolved Forster resonance energy transfer (tr-FRET) studies using transfected HEK-293 cells. Here we show for the first time that each of the four isoforms is able to combine to form homomeric and heteromeric assemblies, each of which is expressed at the cell surface of primary astrocytes. After activation of protein kinase C by phorbol ester, V5-tagged GLT-1 is rapidly removed from the cell surface of HEK-293 cells and degraded. This study provides direct biochemical evidence for oligomeric assembly of GLT-1 and reports the development of novel tools to provide insight into the trafficking of GLT-1.

Animals

Cells

Cultured

Excitatory amino acid transporter 2

Chemistry

Genetics

Physiology

Humans

Mice

Protein isoforms

Protein kinase C

Tetradecanoylphorbol Acetate

REF 2014

Quantitative analysis of cytochrome P450 isoforms in human liver microsomes by the combination of proteomics and chemical probe-based assay

Liu, X., Hu, L., Ge, G., Yang, B., Ning, J., Sun, S., Yang, L., Pors, Klaus, Gu, J.

January 2014

No / Cytochrome P450 (CYP) is one of the most important drug-metabolizing enzyme families, which participates in the biotransformation of many endogenous and exogenous compounds. Quantitative analysis of CYP expression levels is important when studying the efficacy of new drug molecules and assessing drug-drug interactions in drug development. At present, chemical probe-based assay is the most widely used approach for the evaluation of CYP activity although there are cross-reactions between the isoforms with high sequence homologies. Therefore, quantification of each isozyme is highly desired in regard to meeting the ever-increasing requirements for carrying out pharmacokinetics and personalized medicine in the academic, pharmaceutical, and clinical setting. Herein, an absolute quantification method was employed for the analysis of the seven isoforms CYP1A2, 2B6, 3A4, 3A5, 2C9, 2C19, and 2E1 using a proteome-derived approach in combination with stable isotope dilution assay. The average absolute amount measured from twelve human liver microsomes samples were 39.3, 4.3, 54.0, 4.6, 10.3, 3.0, and 9.3 (pmol/mg protein) for 1A2, 2B6, 3A4, 3A5, 2C9, 2C19, and 2E1, respectively. Importantly, the expression level of CYP3A4 showed high correlation (r = 0.943, p < 0.0001) with the functional activity, which was measured using bufalin-a highly selective chemical probe we have developed. The combination of MRM identification and analysis of the functional activity, as in the case of CYP3A4, provides a protocol which can be extended to other functional enzyme studies with wide application in pharmaceutical research.

Amino acid sequence

Cytochrome P-45- enzyme system

Humans

Isotope labelling

Microsomes

Molecular sequence data

Protein isoforms

Proteomics

Tandem mass spectroscopy

Biomedicine

Cytochrome P450

Mrm

Protein quantification

Understanding Isoform Expression and Alternative Splicing Biology through Single-Cell RNAseq

Arzalluz Luque, Ángeles

27 April 2024

[ES] La introducción de la secuenciación de ARN a nivel de célula única (scRNA-seq) en el ámbito de la transcriptómica ha redefinido nuestro entendimiento de la diversidad celular, arrojando luz sobre los mecanismos subyacentes a la heterogeneidad tisular. No obstante, al inicio de esta tesis, las limitaciones de a esta tecnología obstaculizaban su aplicación en el estudio de procesos complejos, entre ellos el splicing alternativo. A pesar de ello, los patrones de splicing a nivel celular planteaban incógnitas que esta tecnología tenía el potencial de resolver: ¿es posible observar, a nivel celular, la misma diversidad de isoformas que se detecta mediante RNA-seq a nivel de tejido? ¿Qué función desempeñan las isoformas alternativas en la constitución de la identidad celular? El objetivo de esta tesis es desbloquear el potencial del scRNA-seq para el análisis de isoformas, abordando sus dificultades técnicas y analíticas mediante el desarrollo de nuevas metodologías computacionales. Para lograrlo, se trazó una hoja de ruta con tres objetivos. Primero, se establecieron cuatro requisitos para el estudio de las isoformas mediante scRNA-seq, llevando a cabo una revisión de la literatura existente para evaluar su cumplimiento. Tras completar este marco con simulaciones computacionales, se identificaron las debilidades y fortalezas de los métodos de scRNA-seq y las herramientas computacionales disponibles. Durante la segunda etapa de la investigación, estos conocimientos se utilizaron para diseñar un protocolo óptimo de procesamiento de datos de scRNA-seq. En concreto, se integraron datos de lecturas largas a nivel de tejido con datos de scRNA-seq para garantizar una identificación adecuada de las isoformas así como su cuantificación a nivel celular. Este proceso permitió ampliar las estrategias computacionales disponibles para la reconstrucción de transcriptomas a partir de lecturas largas, mejoras que fueron implementadas en SQANTI3, software de referencia en transcriptómica. Por último, los datos procesados se utilizaron para desarrollar un nuevo método de análisis de co-expresión de isoformas a fin de desentrañar redes de regulación del splicing alternativo implicadas en la constitución de la identidad celular. Dada la elevada variabilidad de los datos de scRNA-seq, este método se basa en la utilización de una estrategia de correlación basada en percentiles que atenúa el ruido técnico y permite la identificación de grupos de isoformas co-expresadas. Una vez configurada la red de co-expresión, se introdujo una nueva estrategia de análisis para la detección de patrones de co-utilización de isoformas que suceden de forma independiente a la expresión a nivel de gen, denominada co-Differential Isoform Usage. Este enfoque facilita la identificación de una capa de regulación de la identidad celular atribuible únicamente a mecanismos post-transcripcionales. Para una interpretación biológica más profunda, se aplicó una estrategia de anotación computacional de motivos y dominios funcionales en las isoformas definidas con lecturas largas, revelando las propiedades biológicas de las isoformas involucradas en la red de co-expresión. Estas investigaciones culminan en el lanzamiento de acorde, un paquete de R que encapsula las diferentes metodologías desarrolladas en esta tesis, potenciando la reproducibilidad de sus resultados y proporcionando una nueva herramienta para explorar la biología de las isoformas alternativas a nivel de célula única. En resumen, esta tesis describe una serie de esfuerzos destinados a desbloquear el potencial de los datos de scRNA-seq para avanzar en la comprensión del splicing alternativo. Desde un contexto de escasez de herramientas y conocimiento previo, se han desarrollado soluciones de análisis innovadoras que permiten la aplicación de scRNA-seq al estudio de las isoformas alternativas, proporcionando recursos innovadores para profundizar en la regulación post-transcripcional y la función celular. / [CA] La introducció de la seqüenciació d'ARN a escala de cèl·lula única (scRNA-seq) en l'àmbit de la transcriptòmica ha redefinit el nostre enteniment de la diversitat cel·lular, projectant llum sobre els mecanismes subjacents a l'heterogeneïtat tissular. Malgrat les limitacions inicials d'aquesta tecnologia, especialment en el context de processos complexos com l'splicing alternatiu, els patrons d'splicing a escala cel·lular plantejaven incògnites amb potencial de resolució: és possible observar, a escala cel·lular, la mateixa diversitat d'isoformes que es detecta mitjançant RNA-seq en teixits? Quina funció tenen les isoformes alternatives en la constitució de la identitat cel·lular? L'objectiu d'aquesta tesi és desbloquejar el potencial del scRNA-seq per a l'anàlisi d'isoformes alternatives, abordant les seues dificultats tècniques i analítiques amb noves metodologies computacionals. Per a això, es va traçar una ruta amb tres objectius. Primerament, es van establir quatre requisits per a l'estudi de les isoformes mitjançant scRNA-seq, amb una revisió de la literatura existent per avaluar-ne el compliment. Després de completar aquest marc amb simulacions computacionals, es van identificar les debilitats i fortaleses dels mètodes de scRNA-seq i de les eines computacionals disponibles. Durant la segona etapa de la investigació, aquests coneixements es van utilitzar per dissenyar un protocol òptim de processament de dades de scRNA-seq. En concret, es van integrar dades de lectures llargues a escala de teixit amb dades de scRNA-seq per a garantir una identificació adequada de les isoformes així com la seua quantificació a escala cel·lular. Aquest procés va permetre ampliar les estratègies computacionals disponibles per a la reconstrucció de transcriptomes a partir de lectures llargues, millores que van ser implementades en SQANTI3, un programari de referència en transcriptòmica. Finalment, les dades processades es van fer servir per a desenvolupar un nou mètode d'anàlisi de coexpressió d'isoformes amb l'objectiu de desentranyar xarxes de regulació de l'splicing alternatiu implicades en la constitució de la identitat cel·lular. Donada l'elevada variabilitat de les dades de scRNA-seq, aquest mètode es basa en la utilització d'una estratègia de correlació basada en percentils que minimitza el soroll tècnic i permet la identificació de grups d'isoformes coexpressades. Un cop configurada la xarxa de coexpressió, es va introduir una nova estratègia d'anàlisi per a la detecció de patrons de co-utilització d'isoformes que succeeixen de forma independent a l'expressió del seu gen, denominada co-Differential Isoform Usage. Aquest enfocament facilita la identificació d'una capa de regulació de la identitat cel·lular atribuïble únicament a mecanismes post-transcripcionals. Per a una interpretació biològica més profunda, es va aplicar una estratègia d'anotació computacional de motius i dominis funcionals en les isoformes definides amb lectures llargues, revelant les propietats biològiques de les isoformes involucrades en la xarxa de coexpressió. Aquestes investigacions culminen en el llançament d'acorde, un paquet de R que encapsula les diferents metodologies desenvolupades en aquesta tesi, potenciant la reproducibilitat dels seus resultats i proporcionant una nova eina per a explorar la biologia de les isoformes alternatives a escala de cèl·lula única. En resum, aquesta tesi descriu una sèrie d'esforços destinats a desbloquejar el potencial de les dades de scRNA-seq per a avançar en la comprensió de l'splicing alternatiu. Des d'un context de manca d'eines i coneixement previ, s'han desenvolupat solucions d'anàlisi innovadores que permeten l'aplicació de scRNA-seq a l'estudi de les isoformes alternatives, proporcionant recursos innovadors per a aprofundir en la regulació post-transcripcional i la funció cel·lular. / [EN] In the world of transcriptomics, the emergence of single-cell RNA sequencing (scRNA-seq) ignited a revolution in our understanding of cellular diversity, unraveling novel mechanisms in tissue heterogeneity, development and disease. However, when this thesis began, using scRNA-seq to understand Alternative Splicing (AS) was a challenging frontier due the inherent limitations of the technology. In spite of this research gap, pertinent questions persisted regarding cell-level AS patterns, particularly concerning the recapitulation of isoform diversity observed in bulk RNA-seq data at the cellular level and the roles played by cell and cell type-specific isoforms. The work conducted in the present thesis aims to harness the potential of scRNA-seq for alternative isoform analysis, outlining technical and analytical challenges and designing computational methods to overcome them. To achieve this, we established a roadmap with three main aims. First, we set requirements for studying isoforms using scRNA-seq and conducted an extensive review of existing research, interrogating whether these requirements were met. Combining this acquired knowledge with several computational simulations allowed us to delineate the strengths and pitfalls of available data generation methods and computational tools. During the second research stage, this insight was used to design a suitable data processing pipeline, in which we jointly employed bulk long-read and short-read scRNA-seq sequenced from full-length cDNAs to ensure adequate isoform reconstruction as well as sensitive cell-level isoform quantification. Additionally, we refined available transcriptome curation strategies, introducing them as innovative modules in the transcriptome quality control software SQANTI3. Lastly, we harnessed single-cell isoform expression data and the rich biological diversity inherent in scRNA-seq, encompassing various cell types, in the design of a novel isoform co-expression analysis method. Percentile correlations effectively mitigated single-cell noise, unveiling clusters of co-expressed isoforms and exposing a layer of regulation in cellular identity that operated independently of gene expression. We additionally introduced co-Differential Isoform Usage (coDIU) analysis, enhancing our ability to interpret isoform cluster networks. This endeavour, combined with the computational annotation of functional sites and domains in the long read-defined isoform models, unearthed a distinctive functional signature in coDIU genes. This research effort materialized in the release of acorde, an R package that encapsulates all analyses functionalities developed throughout this thesis, providing a reproducible means for the scientific community to further explore the depths of alternative isoform biology within single-cell transcriptomics. This thesis describes a complex journey aimed at unlocking the potential of scRNA-seq data for investigating AS and isoforms: from a landscape marked by the scarcity of tools and guidelines, towards the development of novel analysis solutions and the acquisition of valuable biological insight. In a swiftly evolving field, our methodological contributions constitute a significant leap forward in the application of scRNA-seq to the study of alternative isoform expression, providing innovative resources for delving deeper into the intricacies of post-transcriptional regulation and cellular function through the lens of single-cell transcriptomics. / The research project was funded by the BIO2015-71658 and BES-2016-076994 grants awarded by the Spanish Ministry of Science and Innovation / Arzalluz Luque, Á. (2024). Understanding Isoform Expression and Alternative Splicing Biology through Single-Cell RNAseq [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/203888

Transcriptómica

Isoformas alternativas

Splicing alternativo

Bioinformática

Biología computacional

Computational biology

Bioinformatics

Alternative splicing

Alternative isoforms

Single-cell RNA-seq

Transcriptomics

ESTADISTICA E INVESTIGACION OPERATIVA

The effect of the TGF-β isoforms on progenitor cell recruitment and differentiation into cardiac and skeletal muscle

Schabort, Elske Jeanne

12 1900

Thesis (PhD (Physiology (Human and animal))-- University of Stellenbosch, 2007. / Definition: Stem cells are unspecialised cells with the capacity for long-term self-renewal and the ability to differentiate into multiple cell-lineages. The potential for the application of stem cells in clinical settings has had a profound effect on the future of regenerative medicine. However, to be of greater therapeutic use, selection of the most appropriate cell type, as well as optimisation of stem cell incorporation into the damaged tissue is required. In adult skeletal muscle, satellite cells are the primary stem cell population which mediate postnatal muscle growth. Following injury or in diseased conditions, these cells are activated and recruited for new muscle formation. In contrast, the potential of resident adult stem cell incorporation into the myocardium has been challenged and the response of cardiac tissue, especially to ischaemic injury, is scar formation. Following muscle damage, various growth factors and cytokines are released in the afflicted area which influences the recruitment and incorporation of stem cells into the injured tissue. Transforming Growth Factor-β (TGF-β) is a member of the TGF-β-superfamily of cytokines and has at least three isoforms, TGF-β1, -β2, and -β3, which play essential roles in the regulation of cell growth and regeneration following activation and stimulation of receptor-signalling pathways. By improving the understanding of how TGF-β affects these processes, it is possible to gain insight into how the intercellular environment can be manipulated to improve stem cell-mediated repair following muscle injury. Therefore, the main aims of this thesis were to determine the effect of the three TGF-β isoforms on proliferation, differentiation, migration and fusion of muscle progenitor cells (skeletal and cardiac) and relate this to possible improved mechanisms for muscle repair. The effect of short- and long-term treatment with all three TGF-β isoforms were investigated on muscle progenitor cell proliferation and differentiation using the C2C12 skeletal muscle satellite and P19 multipotent embryonal carcinoma cell-lineages as in vitro model systems. Cells were treated with 5 ng/mℓ TGF-β isoforms unless where stated otherwise. In C2C12 cells, proliferating cell nuclear antigen (PCNA) expression and localisation were analysed, and together with total nuclear counts, used to assess the effect of TGF-β on myoblast proliferation (Chapter 5). The myogenic regulatory factors MyoD and myogenin, and structural protein myosin heavy chain (MHC) were used as protein markers to assess early and terminal differentiation, respectively. To establish possible mechanisms by which TGF-β isoforms regulate differentiation, further analysis included determination of MyoD localisation and the rate of MyoD degradation in C2C12 cells. To assess the effect of TGF-β isoforms on P19 cell differentiation, protein expression levels of connexin-43 and MHC were analysed, together with the determination of embryoid body numbers in differentiating P19 cells (Chapter 6). Furthermore, assays were developed to analyse the effect of TGF-β isoforms on both C2C12 and P19 cell migration (Chapter 7), as well as fusion of C2C12 cells (Chapter 8). Whereas all three isoforms of TGF-β significantly increased proliferation of C2C12 cells, differentiation results, however, indicated that especially following long-term incubation, TGF-β isoforms delayed both early and terminal differentiation of C2C12 cells into myotubes. Similarly, myocyte migration and fusion were also negatively regulated following TGF-β treatment. In the P19 cell-lineage, results demonstrated that isoform-specific treatment with TGF-β1 could potentially enhance differentiation. Further research is however required in this area, especially since migration was greatly reduced in these cells. Taken together, results demonstrated variable effects following TGF-β treatment depending on the cell type and the duration of TGF-β application. Circulating and/or treatment concentrations of this growth factor could therefore be manipulated depending on the area of injury to improve regenerative processes. Alternatively, when selecting appropriate stem or progenitor cells for therapeutic application, the effect of the immediate environment and subsequent interaction between the two should be taken into consideration for optimal beneficial results.

TGF-B isoforms

Progenitor cells

Differentiation

Myogenesis

Transforming growth factors-beta

Stem cells -- Research

Stem cells -- Transplantation

Myocardium -- Regeneration

Cell differentiation

Theses -- Physiology (Human and animal)

Comparaison des mécanismes de régulation des isoformes a et b des récepteurs 5-HT4

Benmbarek, Saoussane

05 1900

Les actions thérapeutiques des antidépresseurs, disponibles actuellement, requièrent plusieurs semaines de traitement. Ce délai est dû aux adaptations des sites pré et post-synaptiques qui, respectivement, augmentent la disponibilité synaptique des monoamines sérotonine et noradrénaline (5-HT et NA), et entraînent les changements neuroplastiques modifiant la fonction neuronales dans les régions limbiques. Il a été récemment observé, chez un modèle animal de dépression, que l’agoniste RS67333 des récepteurs sérotoninergiques de type 5-HT4 produisait des changements comportementaux, électrophysiologiques, cellulaires et biochimiques, tel qu’observé chez les antidépresseurs. Ces changements apparaissent seulement après 3 jours de traitement tandis que les antidépresseurs nécessitent souvent plusieurs semaines. De plus, l’activation des récepteurs 5-HT4 ne générait pas de tolérance, et cela pendant 21 jours de traitement. Seulement, les propriétés de signalisation et de régulation de ces récepteurs sont très loin d’êtres établies. Nous avons alors voulu mieux caractériser ces deux aspects de leur fonction, en se concentrant d’avantage sur les isoformes a et b, fortement exprimés dans le système limbique. Pour cela, nous avons voulu évaluer d’abord leur capacité de production d’AMPc dans un système hétérologue. Les essais d’accumulation d’AMPc démontrent que les deux isoformes sont capables de moduler positivement et négativement des niveaux d’AMPc en présence de 5-HT. Par contre, la stimulation au RS67333 induit seulement une augmentation du niveau d’AMPc dans les deux cas. Ensemble, ces observations indiquent que les deux isoformes sont capables de coupler à l’adénylate cyclase à travers les protéines Gαs et Gαi. La quantification des récepteurs internalisés a montré que l’isoforme b internalisait plus efficacement que l’isoforme a suite à l’incubation à la 5-HT (61 ± 3 % pour le b vs 40 ± 2 % pour le a). Les protéines kinases PKA et PKC n’étaient pas impliquées dans cette différence, toutefois, la PKC a été trouvée essentielle à l’internalisation des deux isoformes. L’internalisation de l’isoforme b par 5-HT n’a pas été affecté par la surexpression de forme inactive de GRK2 (GRK2- K220R) et a été partiellement inhibé par un mutant négative de la β-arrestine (βarr(319-418)), tandis que l’internalisation de l’isoforme a a été bloquée par les deux. Ces observations indiquent que les mécanismes d’internalisation des deux isoformes du récepteur 5-HT4 les plus abondants dans le système nerveux central sont distincts. Des comportements spécifiques à chaque isoforme ont aussi été constatés au niveau de la régulation fonctionnelle suite à l’exposition au RS67333, qui désensibilise seulement l’isoforme b. D’après nos observations, nous avons conclu que les isoformes a et b diffèrent dans leur propriétés de signalisation et de régulation. L’incapacité du RS67333 à désensibiliser l’isoforme a fournit un substrat moléculaire pour les effets antidépressifs prolongés de cet agoniste dans les études pré-cliniques. / The therapeutic actions of antidepressants, currently available, require several weeks of treatment. This delay is due to pre-and post-synaptic sites adjustments, which, respectively, increase the availability of synaptic monoamines 5-HT and NA, and induce neuroplastic changes amending neuronal function in the limbic regions. We have recently observed in animal model of depression that serotonergic 4 receptor agonist RS67333 produces behavioural, electrophysiological, cellular and biochemical changes, as seen in antidepressants. More importantly, these changes appear only after 3 days of treatment while antidepressants often require several weeks. Moreover, activation of 5-HT4 receptors does not generate tolerance and that for 21 days of treatment. However, the signalling and regulation properties of these receptors haven’t been established yet. Here, we wanted to better characterize these two aspects of their function, and in particular for isoforms a and b, strongly expressed in the limbic system. First, we assessed their ability to produce cAMP in a heterologous system. Functional assays revealed that both isoforms were capable of positive and negative modulation of cAMP levels by 5-HT. Stimulation by RS67333 induced cAMP stimulation. Together, these observations indicate that that both isoforms are able to couple adenylate cyclase through Gαs and Gαi proteins. Moreover, quantification of receptors sequestration showed that isoform b internalised more efficiently than the isoform a, following incubation with 5-HT (61 ± 3 % for b, 40 ± 2 % for a). PKA and PKC proteins, two seconds messenger kinases activated by these receptors, are not involved in producing this difference. However, PKC is essential to the internalization of both isoforms. Isoform b internalization was not affected by an inactive GRK2 mutant (GRK2-K220R) and was partially inhibited by dominant negative β-arrestin (βarr(319-418), while isoform a internalization was dependant on both. These observations indicate that internalization mechanisms of the two isoforms, most abundantly expressed in the central nervous system, are different. Functional desensitization studies showned that RS67333 selectively desensitizes the isoform b, but not isoforme a. Based on these observations, we conclude that isoform a and b differ in their signalling and regulatory properties. Isoform a incapacity to desensitization by RS67333 provides a molecular substrate for prolonged antidepressant affects of this agonist in pre-clinical studies.

récepteurs 5-HT4

isoformes a et b

dépression

tolérance

longue latence

désensibilisation

régulation

signalisation

internalisation

5-HT

RS67333

5-HT4 receptors

a and b isoforms

depression

tolerance

long latency

signalisation

regulation

desensitization

internalization

5-HT

RS67333

Polymorphisms in G-quadruplex regions of the TP53 tumour suppressor gene : Impact on cancer susceptibility and expression of p53 N-terminal isoforms / Polymorphismes situés dans les régions de type G-quadruplexe du gène suppresseur de tumeur TP53 : Impact sur la susceptibilité au cancer et l’expression des isoformes en N-terminal de p53

Sagne, Charlotte

27 November 2013

Le gène TP53 est extrêmement polymorphique avec 85 polymorphismes décrits. Certains de ces polymorphismes sont associés à une augmentation du risque de cancer, par exemple rs10425222 peut moduler les fonctions de p53. Cependant, pour d’autres, comme le rs17878362 qui est le polymorphisme intronique le plus étudié, leur association avec une augmentation du riques au cancer est controversée.Pour analyser l’association entre le polymorphisme rs17878362 et la susceptibilité au cancer, nous avons analysé son rôle dans des contextes de cancers sporadiques et familiaux. Les résultats obtenus pour le polymorphisme rs17878362 sont paradoxaux avec une augmentation des cancers sporadiques associée avec le génotype A2A2 alors que l’allèle A2 est associé avec un effet « protectif » chez les patients atteints du syndrome de Li-Fraumeni porteurs d’une mutation germinale de TP53 situé sur l’haplotype A1. Ces observations suggèrent que des haplotypes spécifiques de TP53 pourraient moduler les capacités suppressives de p53. Une hypothèse possible est que les différents haplotypes de TP53 présenteraienrt des mutations somatiques à des fréquences différentes dans la population.De plus, le gène TP53 exprime différentes isoformes, comme le D40p53, inhibant l’activité suppressive de p53. Le D40p53 peut être produite par le maintien de l’intron 2 par épissage alternatif. Nous avons montré que les G-quadruplexes, des structures tridimensionnelles formées dans des régions riches en G, sont formés dans l’intron 3 et régulent la rétention de l’intron 2 et la formation du transcrit p53I2. Nous avons aussi observé que le polymorphisme rs1652785 (localisé dans l’intron 2) semble réguler la stabilité du p53I2. Ces résultats suggèrent que les polymorphismes de TP53 localisés dans une région de 412 pb située entre l’exon 2 et l’exon 4 régulent l’expression des isoformes de p53 dans une séquence temporelle d’évènements en modulant la formation des pré-ARNm (rs17878362), la stabilité des ARNm (rs1642785) et les fonctions protéiques (rs10425222).L’expression des isoformes de p53 est donc finement régulée par des mécanismes impliquant les polymorphismes de TP53 qui sont aussi associés avec une altération dans la susceptibilité au cancer. / The TP53 gene is a highly polymorphic gene with 85 polymorphisms described. Some of these have been associated with an increase of cancer susceptibility, for example rs10425222 that can modulate certain p53 activities. However for others such as rs17878362, the most studied intronic polymorphism, the association with cancer risk is more controversial. To investigate the influence of rs17878362 on cancer susceptibility, we analysed its role in sporadic and familial contexts. The results are paradoxical with an increase of sporadic cancer associated with the rs17878362 A2A2 genotype whereas the rs17878362 A2 allele is associated with a “protective” effect in the context of Li-Fraumeni patients carrying a TP53 germline mutation on an A1 haplotype. These observations suggest that specific TP53 haplotypes could modulate p53’s tumour suppression capacities. A possible hypothesis to explain this could be that somatic mutations are carried on different haplotypes of TP53 present at different allele frequencies in the population. In addition, TP53 is expressed as several protein isoforms, such as D40p53, which inhibits p53’s suppressive activity. D40p53 can be produced from an alternative spliced transcript that retains intron 2. We have shown that G-quadruplexes, tri-dimensional structures formed in G-rich sequences, are formed in intron 3 and regulate the retention of intron 2 and the formation of the p53I2 transcript. We also observed that rs1642785 (located in intron 2) could regulate p53I2’s stability. These results suggest that the TP53 polymorphisms located in a 412 bp region located between exon 2 and exon 4 regulate the expression of p53 isoforms in a temporal sequence of events by modulating the pre-mRNA formation (rs17878362), mRNA stability (rs1642785) and protein functions (rs1042522).p53 isoforms’ expression is thus finely regulated by mechanisms involving TP53 polymorphisms, which are also associated with altered cancer susceptibility.

Protéine suppresseur de tumeur

P53

Isoformes

Polymorphismes

Rs17878362

Épissage alternatif

Structure de type G-quadruplexe

Syndrome de Li-Fraumeni

Méta-analyse

Tumour suppressor protein

P53

Isoforms

Polymorphisms

Rs17878362

Alternative splicing

G-quadruplex structure

Li-Fraumeni syndrome

Meta-analysis

Translational Control Of p53 And Its Isoform By Internal Initiation

Grover, Richa

01 January 2008

Tumor suppressor p53, the guardian of the genome, has been intensely studied molecule owing to its central role in maintaining cellular integrity. While the level of p53 protein is maintained low in unstressed conditions, there is a rapid increase in the functional p53 protein levels during stress conditions. It is now well documented in literature that p53 protein accumulates in the cells following DNA damage by posttranslational modifications leading to increased stability and half life of protein. Additionally, recent studies have also highlighted the significance of increased p53 translation during stress conditions. Interestingly, an alternative initiation codon has been shown to be present within the coding region of p53 mRNA. Translation initiation from this internal AUG results in an N-terminally truncated p53 isoform, described as ΔN-p53. However, the mechanisms underlying co-translational regulation of p53 and ΔN-p53 are still poorly understood. Studies have suggested that synthesis of both p53 and its ΔN-p53 isoform is regulated during cell cycle and also stress and cell-type specific manner. Interestingly, reports also demonstrate continued synthesis of both p53 isoforms during stress conditions. In contrast, global rates of cap-dependent translation initiation are shown to be reduced during stress conditions. This translation attenuation is observed mainly due to restricted availability of critical initiation factors. Interestingly, preferential synthesis of a vital pool of survival factors persists even during these circumstances. Studies have suggested that this selective translation is mediated via alternative mechanisms of translation initiation. One of the important mechanisms used for protein synthesis during these conditions is internal initiation. In this mechanism, the ribosomes are recruited to a complex RNA structural element known as ‘Internal Ribosome Entry Site (IRES)’, generally present in the 5’ untranslated region (UTR) of mRNA. Therefore, it is possible that the translation of p53 and ΔN-p53 could also be regulated by IRES mediated translation, especially during stress conditions. In this thesis the role of internal initiation in translational control of p53 and ΔN-p53 has been investigated. Additionally, the putative secondary structure of p53 IRES RNA has been determined. Further, it has been shown that polypyrimidine tract binding (PTB) protein acts as an important regulator of p53 IRES activities. The probable mechanism of action of PTB protein has also been investigated. The results suggest that interaction with PTB alters the p53 IRES conformation which could facilitate translation initiation. Finally, the possible physiological significance of existence of p53 IRES elements has been addressed. In the first part of the thesis, the presence of internal ribosome entry site within p53 mRNA has been investigated. As a first step, the 5’UTRs mediating the translation of both p53 and ΔN-p53 were cloned in the intercistronic regions of bicistronic constructs. Results of in vivo transfection of these bicistronic constructs suggested the presence of two IRES elements within p53 mRNA, with activities comparable to known viral and cellular IRESs. The IRES directing the translation of p53 is in the 5'-untranslated region of the mRNA, whereas the IRES mediating the translation of ΔN-p53 extends further into the protein-coding region. To further validate, stringent assays were performed to rule out the possibility of any cryptic promoter activity, re-initiation/scanning or alternative splicing in the p53 mRNA. Transfection of in vitro synthesized bicistronic RNAs confirmed the presence of IRES elements within p53 mRNA. Incidentally, this constitutes the first report on translational control of p53 by internal initiation. In the second part of the thesis, the secondary structure of p53 IRES RNA has been investigated. Structural analysis of p53 RNA was performed using structure-specific nucleases and modifying chemicals. The results obtained from chemical modification and nuclease probing experiments were used to constrain Mfold predicted structures. Based on this, a putative secondary structure model for p53 IRES RNA has been derived. Sequence alignment suggested that the p53 IRES RNA showed significant sequence conservation across mammalian species. To study the effect of mutations on the IRES structure, mutant p53 IRESs were used that harbor silent mutations at critical locations within the p53 IRES element. Incidentally, one of the mutant constructs used in the study was observed to be a naturally occurring mutation in a chronic lymphocyte leukemia patient. RNA structure analyses of these two mutant p53 IRES RNAs were performed. The nuclease mapping data suggested conformational alteration in these mutant RNAs with respect to wild type. Consistently, a comparative Circular-Dichroism spectroscopy of the Wt and mutant RNAs also validated the conformational alteration of the mutant RNAs. This also suggested that the presence of mutations in p53 IRES might result in decreased induction of p53 protein following DNA damage due to altered RNA structure. This might constitute as one of the mechanisms leading to tumor development in some types of cancers. In the third part of the thesis, the role of important cellular proteins that might modulate p53 IRES mediated translation has been studied. These cellular proteins act as IRES interacting trans-acting factors (ITAFs). Polypyrimidine tract binding (PTB) protein is an important ITAF implicated in regulating IRES mediated gene expression during apoptosis. It was observed that PTB protein specifically interacts with both the IRES elements within p53 mRNA. Interestingly, the affinity of interaction of PTB protein with both p53 IRES RNAs was observed to be significantly different. In order to determine the contact points of PTB on p53 IRES, a foot-printing assay using structure specific nuclease and recombinant-PTB protein was performed on p53 RNA. The data from foot-printing as well as primer extension inhibition assay (toe-printing analysis) suggested the presence of multiple PTB binding sites on p53 IRES RNA. Based on these results, a deletion mutant was generated that showed reduced PTB binding and also reduced IRES activity as compared to wild type. Further, to study the role of PTB in mediating p53 translation, the expression of PTB gene was partially silenced by using PTB specific siRNA. Partial depletion of endogenous PTB protein showed a significant decrease in the p53 IRES activities. These results suggest that PTB protein is essential for the p53 IRES activities. To understand the probable mechanism by which PTB regulates p53 IRES mediated translation, CD spectroscopy analysis of p53 IRES RNA was performed in the absence and presence of PTB protein. Interestingly, CD spectra analysis of the p53 RNA in the presence of PTB suggested a specific conformational change in p53 IRES, which might probably facilitate ribosome loading during internal initiation. This also suggests that abnormal expression of p53 ITAFs might lead to reduced p53 induction following DNA damage conditions. It could also be another event leading to malignant transformation of cells bearing wild type p53. It is highly tempting to speculate that the levels of p53 ITAFs could also be used as tumor biomarkers. In the fourth part of the thesis, the physiological relevance of existence of IRES elements within p53 mRNA has been investigated. The levels of p53 and ΔN-p53 proteins are known to be regulated in a cell cycle phase-dependent manner. The IRES activities of both p53 IRES elements were investigated at different phases of cell cycle. The activity of the IRES responsible for translation of p53 protein was found to be highest at G2-M transition and the maximum IRES activity corresponding to ΔN-p53 synthesis was observed at G1-S transition. These results suggested that the p53 IRES activities are regulated in a cell-cycle phase-dependent manner. Next, the regulation of p53 IRES mediated translation during stress conditions was studied. Human lung carcinoma cell line, A549 cells (that endogenously express both the p53 isoforms), were exposed to DNA damaging drug, doxorubicin. The level of p53 protein was observed to increase in a time-dependent manner. Interestingly, PTB protein, which is predominantly nuclear, was found to translocate to the cytoplasm during stress condition in a time-dependent manner. Under similar conditions, p53 protein was observed to reverse translocate from the cytoplasm to nucleus, probably to function as a transcription factor. Next, the influence of partial PTB silencing on p53 isoforms in the presence of cell stress (mediated by doxorubicin) was investigated. The data indicated reduced levels of both p53 and ΔN-p53 when PTB gene expression was partially silenced. These observations constitute “the proof of concept” that relative abundance of an ITAF, such as PTB protein, might contribute to regulating the coordinated expression of the p53 isoforms. The thesis reveals the presence as well as the physiological relevance of existence of IRES elements within p53 mRNA. The novel discovery of p53 IRES elements may provide new insights into the underlying mechanism of translational regulation. The modulation of the p53 IRES activities by PTB protein suggests that the regulated expression of p53 isoforms depends on the integrity of IRES elements and availability of cellular proteins that can serve as p53 ITAFs. Thus, studies pertaining to the identification of mutations within p53 IRES region as well as abnormal expression of p53 ITAFs such as PTB in cancer cells may have far reaching implications. These studies might lead to further advances in the field of cancer detection, prognosis and design of novel therapeutic strategies.

Ribonucleic Acid (RNA)

Proteins

RNA Viruses

p53 Protein

p53 Protein Isoforms

p53 RNA - Structural Analysis

Protein Translation

Polypyrimidine Tract Binding Protein

Protein Regulation

IRES RNA

PTB Binding

p53 mRNA

Biochemical Genetics

14-3-3-Isoformen im Liquor cerebrospinalis bei Patienten mit verschiedenen molekularen Subtypen der sporadischen Creutzfeldt-Jakob-Krankheit / 14-3-3 isoforms in cerebrospinal fluid of patients with different molecular subtypes of sporadic Creutzfeldt-Jakob disease

Jategaonkar, Swati Ravindra

09 May 2012

No description available.

610 Medizin, Gesundheit

MED 532 Neurologische Diagnostik

Neuroradiologie

Medicine

sporadische Creutzfeldt-Jakob-Krankheit

14-3-3- Isoformen

Liquor cerebrospinalis

Diagnose

spradic Creutzfeldt-Jakob disease

14-3-3 isoforms

diagnosis

cerebrospinal fluid

44.90 Neurologie