Analyses biochimiques et fonctionnelles de protéines cibles de POFUT1 / Biochemical and functional analyses of POFUT1 target proteins

Pennarubia, Florian

14 December 2018

La O-fucosylation, catalysée par Pofut1, est une glycosylation rare qui consiste en l’ajout d’un fucose O-lié sur la sérine ou la thréonine d’une séquence consensus (C2X4(S/T)C3), portée par un domaine EGF-like (ELD) d’une glycoprotéine membranaire ou sécrétée. Notre analyse de la lignée murine Pofut1cax/cax, hypomorphe pour le gène Pofut1, a révélé une hypertrophie musculaire post-natale associée à une diminution du pool de cellules satellites. Ce phénotype est en partie associé à un défaut d’interaction entre les récepteurs NOTCH hypo-O-fucosylés des myoblastes dérivés de cellulessatellites (MDCS) et leurs ligands DSL, ce qui aboutit à une plus faible activation de la signalisation Notch. D’autres protéines potentiellement impliquées dans la myogenèse peuvent également être la cible de POFUT1. C’est notamment le cas de la protéine Wnt inhibitory factor 1 (WIF1), qui dispose de cinq ELDs, dont deux sont potentiellement aptes à recevoir un O-fucose (ELDs III et V). Par une approche phylogénétique, nous avons montré la conservation de ces deux sites de O-fucosylation et de deux sites de N-glycosylation chez la plupart des bilatériens. Nos expériences démontrent l’occupationde tous ces sites, excepté le site de O-fucosylation de l’ELD V, chez la protéine WIF1 murine. La capacité de l’ELD III, produit de manière isolée, à recevoir un fucose O-lié a été démontrée après O-fucosylation in vitro, par l’association de cycloaddition azide-alcyne assistée au cuivre (CuAAC) et de spectrométrie de masse en mode MRM. Cette nouvelle approche expérimentale a par la suite été standardisée et sa sensibilité évaluée en comparant deux autres ELDs (ELDs 12 et 26 de NOTCH1) connus pour être O-fucosylés mais présentant des affinités différentes pour POFUT1. De façonsurprenante, l’ELD V de WIF1 ne peut être O-fucosylé, probablement en raison d’un clash stérique entre cet ELD et POFUT1, prévenant ainsi leur interaction. L’analyse de la protéine WIF1 entière a confirmé les résultats obtenus sur les ELDs isolés et démontre l’occupation des deux sites de N-glycosylation. Enfin, nos résultats montrent également l’importance de ces deux N-glycanes, mais également celle du O-fucose de l’ELD III, pour une sécrétion optimale de la protéine WIF1 murine. / The, Pofut1-catalyzed O-fucosylation, is a rare glycosylation which consists of the addition of an O-linked fucose to the serine or threonine of a consensus sequence (C2X4(S/T)C3), carried by an EGF-like domain (ELD) of a membrane or secreted glycoprotein. Our analysis of the murine line Pofut1cax/cax, hypomorphic for the Pofut1 gene, revealed post-natal muscle hypertrophy associated with a decrease in the satellite cell pool. This phenotype was partly associated with a lack of interaction between hypo-O-fucosylated NOTCH receptors of satellite cell-derived myoblasts (SCDM) and their DSL ligands, which resulted in a lower activation of Notch signaling. Other proteins potentially involved in myogenesis may also be the target of POFUT1. This is indeed the case for the protein Wnt inhibitory factor 1 (WIF1), which has five ELDs, whose only two are potentially able to receive an O-fucose (ELDs III and V). Using a phylogenetic approach, we showed in most bilaterians that these two O-fucosylation sites and two N-glycosylation sites were conserved. Our experiments showed theoccupation of all these sites, except for the O-fucosylation site of murine WIF1 protein ELD V. The ability of the ELD III, produced as an isolated protein, to receive O-linked fucose was demonstrated after an in vitro O-fucosylation by combination of copper-catalysed azide-alkyne cycloaddition (CuAAC) and MRM-mass spectrometry. This new experimental approach was then standardized and its sensitivity was evaluated by comparing two other ELDs (NOTCH1 ELDs 12 and 26) known to beO-fucosylated but with different affinities for POFUT1. Surprisingly, WIF1's ELD V could not be O-fucosylated, probably due to a steric clash between this ELD and POFUT1, thus preventing their interaction. The analysis of the full-length WIF1 protein confirmed our results obtained with isolated ELDs and demonstrated the occupation of the two N-glycosylation sites. Finally, our results also showed the importance of these two N-glycans, but also the importance of ELD III’s O-fucose, foroptimal secretion of the murine WIF1 protein.

POFUT1

O-fucosylation

EGF-like

WIF1

CuAAC

POFUT1

O-fucosylation

EGF-like

WIF1

CuAAC

572.8

DELLA is O-Fucosylated by SPINDLY

Sui, Ning

January 2016

<p>Plant growth and development are strictly regulated by internal hormonal signaling networks, which integrate and coordinate to promote plants’ adaptation and survival in the changing environment. Among the diverse hormones, gibberellins (GAs) are the phytohormones that regulate various processes, from seed germination to fruit development. The conserved plant-specific GRAS family protein DELLAs, key repressors in the GA signaling pathway, serve as the central coordinator of multiple signaling networks through physical interactions with many key transcription factors/regulators in other pathways. </p><p>Diverse DELLA-interacting proteins (DIPs) from different signaling pathways and various protein families have been identified in recent years. All the DIPs interact with the C-terminal GRAS domain of DELLA, however, the mechanism of how the GRAS domain interacts with diverse proteins remains a mystery. To solve this problem, I expressed a number of DELLA proteins in E.coli and obtained high-purity protein for biochemical and structural analysis.</p><p>As the central coordinator of plant growth and development, DELLA’s activity and stability are regulated by post-translational modifications. Our lab recently showed that SECRET AGENT (SEC) modulates the activity of DELLA through O-linked N-acetylglucosamine (O-GlcNAc) modification in Arabidopsis. Nevertheless, SEC’s paralog SPINDLY (SPY), a putative O-GlcNAc transferase (OGT) identified 20 years ago, does not have OGT activity, and serves as opposite role to SEC in GA signaling with an unknown mechanism. </p><p>Our lab made the breakthrough in uncovering the SPY function, and showed it promotes the O-fucosylation of DELLA in planta. I further proved that SPY is a novel protein O-fucosyltransferase through biochemical analysis. SPY specifically transfers O-fucose from GDP-fucose to its substrate peptide, and SPY mutant proteins showed reduced or abolished transferase activity. This is the first work to identify O-fucosylation of nuclear proteins in any organism. O-fucosylation of DELLA activates DELLA by promoting its interaction with DIPs, opposite to repression of interaction with O-GlcNAcylation. Previous studies showed that SPY is involved in multiple cellular pathways such as GA signaling, cytokinin signaling and the circadian clock. Thus, SPY plays an important role in regulating plant growth and development through O-fucosylation of key components in diverse intracellular pathways. </p><p>SPY orthologs are conserved in bacteria, protists, algae and plants, while SEC orthologs are also present in fungi and animals. SPY-like and SEC-like proteins share high sequence similarity, except that two key residues important for the OGT activity of SEC is missing in SPY. Structure analysis of SPY (or its orthologs) would greatly facilitate our understanding of its unique substrate specificity. Toward this goal, I expressed Arabidopsis SPY proteins (as well as bacterial SPY orthologs) in E.coli and obtained high-purity protein for structural analysis. I further identified lead conditions that produce needle-cluster crystals. While optimization would be required, these studies will ultimately reveal the structure of SPY and the architecture of the active site, to show how SPY interacts with GDP-fucose for the transferase activity.</p> / Dissertation

Biology

Biochemistry

DELLA

GRAS

O-fucosylation

O-GlcNAcylation

SPINDLY (SPY)

Rôle(s) de la protéine O-fucosyltransférase 1 au cours de la différenciation myogénique / Role(s) of protein O-fucosyltransferase 1 during myogenic differentiation

Der Vartanian, Audrey

11 February 2015

Au cours de la myogenèse post-natale, la voie de signalisation de Notch participe au développement et à la régénération du muscle squelettique chez les mammifères. Elle permet le maintien de l'état prolifératif des myoblastes, contrôle la quiescence des cellules satellites in vivo et préserve une sous-population de cellules de réserve indifférenciées in vitro. L' activation de la voie et l'interaction du récepteur Notch avec ses ligands est dépendante de leur entité glucidique, notamment de leurs O-fucosylglycannes. La synthèse de ces derniers est initiée par la protéine O-fucosyltransférase 1 (Pofut1) qui greffe un O-fucose sur des domaines peptidiques particuliers appelés EGF-like. Bien que les acteurs moléculaires de la différenciation myogénique aient été largement étudiés par la communauté scientifique, la contribution de la glycosylation des protéines dans ce processus reste peu documentée. Une approche expérimentale in vitro basée sur l'utilisation de la lignée myoblastique murine C2C12 nous a permis d'identifier une expression importante de Pofut1 dans les cellules de réserve tandis qu' elle est restreinte dans les myotubes durant la différenciation myogénique. Plusieurs lignées de cellules C2C12 ont été générées pour qu' elles expriment de manière stable et différentielle Pofut1. Elles permettent ainsi d' évaluer l' importance du niveau d' expression de Pofut1 sur la différenciation myogénique.La sous-expression de Pofut1 réduit l' activation de la voie de signalisation de Notch conduisant à une entrée précoce des myoblastes dans le programme myogénique. Ceci a pour conséquence la dépletion des cellules de réserve Pax7+/MyoD- au profit d' une augmentation du nombre de myotubes. Des études morphométriques ont révélé un défaut d' accrétion nucléaire dans les myotubes sous-exprimant Pofut1, caractéristique d' une altération de la fusion secondaire. Ces observations sont accompagnées d' une diminution significative de l' expression du récepteur à l' interleukine 4 dans les cellules de reserve sous-exprimant Pofut1. Les lignées cellulaires ré-exprimant Pofut1 présentent une activation de la voie de signalisation de Notch et un processus de fusion myoblastique correctement restaurés.Ces travaux de thèse ont mis en exergue pour la première fois le rôle essentiel de Pofut1 dans le devenir cellulaire et la fusion des myoblastes au cours de la différenciation myogénique. / During post-natal myogenesis, Notch signaling pathway is involved in the development and regeneration of skeletal muscle in mammals. It maintains progenitor cell properties during the development of the myogenic lineage and controls the transition of satellite cells from a quiescent to an active state and preserves a subpopulation of reserve cells, in cell culture, in an undifferentiated state. The interaction between Notch and its ligands and the activation of this signaling is mainly controlled by the activity of protein O-fucosyltranferase 1 (Pofut1) and thus by the O-fucosylation state of the EGF-like repeats.Although the molecular players in myogenic differentiation have been extensively studied by the scientific community, the contribution of glycosylated proteins in this process remains poorly documented. An experimental in vitro study based on the C2C12 mouse myoblast cell line allowed us to identify a high expression of Pofut1 in reserve cells while a low expression was found in myotubes during myogenic differentiation. Several C2C12 cell lines were generated to express Pofut1 at different levels. They were used to evaluate the contribution of Pofut1 expression to the myogenic differentiation.The knockdown of Pofut1 repressed Notch signaling pathway activation leading to an earlier entrance of myoblasts in myogenic program. This resulted in the depletion of reserve cells Pax7+/MyoD- and an increase in the number of myotubes. Morphometric analysis revealed a nuclear accretion defect in Pofut1 knockdown myotubes. A significant decrease in the expression of the interleukin-4 receptor in Pofut1 knockdown reserve cells was also observed. Cell lines re-expressing correctly Pofut1 restored Notch signaling pathway and subsequently myoblast fusion process.This thesis work highlights, for the first time, the crucial role of Pofut1 in the cell fate decision and the fusion of myoblasts during myogenic differentiation.

Myogenèse

Différenciation myogénique

Fusion myoblastique

Voie de signalisation de Notch

Pofut1

O-fucosylation

C2C12

Cellules de réserve

Myotube

Myogenesis

Myogenic differentiation,

Myoblastic fusion

Notch signaling pathway Pofut1

O-fucosylation

C2C12

Reserve cells

Myotube

Pofut1

572.8