Determining the Biological Role(s) of Ubiquitin Fold Modifier 1(UFM1)

Tehami, Yasmina

28 November 2013

Ubiquitin fold modifier 1 (Ufm1) is a member of the ubiquitin like protein (UBL) family. Like other UBLs, Ufm1 can be conjugated to protein substrates via specific E1 (Uba5), E2 (Ufc1) and E3 (Ufl1) enzymes, and removed from these substrates via the action of Ufm1-specific proteases. While Ufm1 has been implicated in endoplasmic reticulum (ER) function, its biological roles remain poorly understood. By identifying; (a) Ufm1 binding proteins, (b) protein interactors of the Ufm1 conjugation/deconjugation system, (c) Ufm1 conjugates, as well as (d) the intracellular localization of Ufm1 and its main interactors, I aimed to better characterize the biological role(s) of this poorly understood UBL.

Biochemistry

UBL

Ufm1

Ubiquitin like protein

0379

0307

0487

Determining the Biological Role(s) of Ubiquitin Fold Modifier 1(UFM1)

Tehami, Yasmina

28 November 2013

Ubiquitin fold modifier 1 (Ufm1) is a member of the ubiquitin like protein (UBL) family. Like other UBLs, Ufm1 can be conjugated to protein substrates via specific E1 (Uba5), E2 (Ufc1) and E3 (Ufl1) enzymes, and removed from these substrates via the action of Ufm1-specific proteases. While Ufm1 has been implicated in endoplasmic reticulum (ER) function, its biological roles remain poorly understood. By identifying; (a) Ufm1 binding proteins, (b) protein interactors of the Ufm1 conjugation/deconjugation system, (c) Ufm1 conjugates, as well as (d) the intracellular localization of Ufm1 and its main interactors, I aimed to better characterize the biological role(s) of this poorly understood UBL.

Biochemistry

UBL

Ufm1

Ubiquitin like protein

0379

0307

0487

Investigations of the Ufm1 pathway and its association with a familial form of hip dysplasia

Dudek, Michal

January 2013

Beukes Hip Dysplasia (BHD) is an autosomal dominant disorder where the abnormal shape of the hip joint leads to secondary osteoarthritis. The locus of BHD has been previously mapped to 4q35 and screening of candidate genes within this region revealed a mutation in the gene encoding the Ubiquitin-fold modifier 1 specific protease 2 (Ufsp2). The mutation prevents Ufsp2 from cleaving its target, Ufm1. Ufsp2 and Ufm1 are both components of a novel ubiquitin-like protein modification system which involves Ufm1 being processed via the E1, E2 and E3 enzymes (Uba5, Ufc1 and Ufl1, respectively) and attachment to target protein(s) one of which has been identified (Ddrgk1). The aim of this study was to investigate the link between the UFSP2 mutation and the BHD phenotype by: (i) examining the expression of components of the Ufm1 system in vivo and in vitro; (ii) development of an in vitro Ufm1 conjugation system; and (iii) generation and analysis of transgenic mice overexpressing the Ufsp2 gene with the BHD mutation. The expression of Ufsp2 was determined by radioactive RNA in situ hybridisation of mouse tissue sections. The analysis revealed Ufsp2 expression predominantly in the bone of the hip joint and in the bone and secondary ossification centres of the knee of 10 day old mice. Real-Time PCR analysis showed increased expression of components of the Ufm1 system during in vitro osteogenic and chondrogenic differentiation which coincided with induction of ER stress evidenced by upregulation of Bip. These components were also upregulated in response to chemically induced ER stress in vitro. Analysis of the promoter regions of Ufm1 system genes identified unfolded protein response elements in the upstream sequences of Uba5, Ufl1, Ufm1 and Lzap genes and the elements in Uba5 and Lzap were found to be required and responsive to ER stress using luciferase promoter assays. A Tandem Affinity Purification method was developed for isolation and identification of Ufm1 conjugation targets from cell lines expressing modified forms of Ufm1. Mass spectrometry analysis of Ufm1 conjugates purified from HEK293T cell line identified Uba5 and Ufc1 but no new Ufm1 targets. Western blot comparison of Ufm1 conjugated proteins purified from the HEK293T and 2T3 osteoblast cell lines identified putatative Ufm1 conjugation targets and increased conjugation in osteoblasts in response to ER stress. One of these targets was identified as Ddrgk1 but the remaining putative targets remain to be identified by mass spectrometry. Transgenic mice overexpressing the mutated Ufsp2 gene were generated and subjected to phenotypic analysis. No significant differences were found between transgenic and wild type mice following X-ray, histological and weight analysis. Higher expression of Ufsp2 in bone and secondary ossification centres as well as upregulation of components of the Ufm1 system in response to ER stress suggests that the molecular pathway between the UFSP2 mutation and the BHD phenotype may relate to abnormal ER stress responses during osteoblast differentiation. Further studies are however required to determine how the Ufm1 system modulates ER stress responses and how disruption of these processes caused by the UFSP2 mutation causes BHD.

617.5

Caractérisation de l’ubiquitin-fold modifier (UFM1) dans un modèle C. elegans

Demers-Lamarche, Julie

12 1900

L’ubiquitin-fold modifier (UFM1) fait partie de la classe 1 de la famille de protéine ubiquitin-like (Ubl). UFM1 et Ub ont très peu d’homologie de séquence, mais partagent des similarités remarquables au niveau de leur structure tertiaire. Tout comme l’Ub et la majorité des autres Ubls, UFM1 se lie de façon covalente à ses substrats par l’intermédiaire d’une cascade enzymatique. Il est de plus en plus fréquemment rapporté que les protéines Ubls sont impliquées dans des maladies humaines. Le gène Ufm1 est surexprimé chez des souris de type MCP développant une ischémie myocardique et dans les îlots de Langerhans de patients atteints du diabète de type 2. UFM1 et ses enzymes spécifiques, UBA5, UFL1 et UFC1, sont conservés chez les métazoaires et les plantes suggérant un rôle important pour les organismes multicellulaires. Le Caenorhabditis elegans est le modèle animal le plus simple utilisé en biologie. Sa morphologie, ses phénotypes visibles et ses lignées cellulaires ont été décrits de façon détaillée. De plus, son cycle de vie court permet de rapidement observer les effets de certains gènes sur la longévité. Ce modèle nous permet de facilement manipuler l’expression du gène Ufm1 et de mieux connaître ses fonctions. En diminuant l’expression du gène ufm-1 chez le C.elegans, par la technique de l’ARN interférence par alimentation, nous n’avons observé aucun problème morphologique grave. Les vers ressemblaient aux vers sauvages et possédaient un nombre de progéniture normal. Cependant, les vers sauvage exposés à l’ARNi d’ufm-1 vivent significativement moins longtemps que les contrôles et ce, de façon indépendante de la voie de signalisation de l’insuline/IGF. Chez le C. elegans la longévité et la résistance au stress cellulaire sont intimement liées. Nous n’avons remarqué aucun effet d’ufm-1 sur le stress thermal, osmotique ou oxydatif, mais il est requis pour la protection contre le stress protéotoxique. Il est également nécessaire au maintien de l’intégrité neuronale au cours du vieillissement des animaux. L’ensemble de nos données nous renseigne sur les fonctions putatives du gène Ufm1. / The ubiquitin-fold modifier (UFM1) is part of the type 1 class of the family of ubiquitin-like protein (Ubl). UFM1 and Ub have very little sequence homology but share remarkable similarities in their tertiary structure. Like Ub and most other UBLS, UFM1 binds covalently to its substrates through an enzymatic cascade. It is frequently reported that UBLs are involved in human diseases. UFM-1 is overexpressed in mice developing a myocardial ischemia and in the islets of patients suffering from type 2 diabetes. UFM1 and its specific enzymes, UBA5, UFL1, and UFC1 are conserved in metazoans and plants suggesting an important role in multicellular organisms. Caenorhabditis elegans is one of the the simplest animal models used in biology. Some features such as morphology, visible phenotypes and cell lineage have completely been described. The short lifecycle of C. elegans makes it easy to observe gene effects on longevity. This model allows us to easily manipulate the expression of the Ufm1 gene and learn more about its putative functions. To study putative functions of Ufm1, we decreased the expression of ufm-1 using RNA interference introduces through feeding. No gross morphological disturbances were observed; worms resembled wild type and had a normal brood size. However, worms exposed to ufm-1 RNAi had a significantly shorter lifespan than the controls. This effect is independent of the insulin/IGF pathway, which is a major axis of longevity genetics. In C. elegans longevity and cellular stress resistance are intimately linked. We have observed no effect of ufm-1 on thermal, osmotic or oxidative stress, but it is required for protection against proteotoxic stress. It is also necessary to maintain neuronal integrity during aging. Together, our results shed light on putative functions of Ufm1 gene.

Caenorhabditis elegans

Ufm1

Longévité

Vieillissement

ARN interférence

Intégrité neuronale

Caenorhabditis elegans

Ufm1

Longevity

Aging

RNA interference

Neuronal integrity

Caractérisation de l’ubiquitin-fold modifier (UFM1) dans un modèle C. elegans

Demers-Lamarche, Julie

12 1900

L’ubiquitin-fold modifier (UFM1) fait partie de la classe 1 de la famille de protéine ubiquitin-like (Ubl). UFM1 et Ub ont très peu d’homologie de séquence, mais partagent des similarités remarquables au niveau de leur structure tertiaire. Tout comme l’Ub et la majorité des autres Ubls, UFM1 se lie de façon covalente à ses substrats par l’intermédiaire d’une cascade enzymatique. Il est de plus en plus fréquemment rapporté que les protéines Ubls sont impliquées dans des maladies humaines. Le gène Ufm1 est surexprimé chez des souris de type MCP développant une ischémie myocardique et dans les îlots de Langerhans de patients atteints du diabète de type 2. UFM1 et ses enzymes spécifiques, UBA5, UFL1 et UFC1, sont conservés chez les métazoaires et les plantes suggérant un rôle important pour les organismes multicellulaires. Le Caenorhabditis elegans est le modèle animal le plus simple utilisé en biologie. Sa morphologie, ses phénotypes visibles et ses lignées cellulaires ont été décrits de façon détaillée. De plus, son cycle de vie court permet de rapidement observer les effets de certains gènes sur la longévité. Ce modèle nous permet de facilement manipuler l’expression du gène Ufm1 et de mieux connaître ses fonctions. En diminuant l’expression du gène ufm-1 chez le C.elegans, par la technique de l’ARN interférence par alimentation, nous n’avons observé aucun problème morphologique grave. Les vers ressemblaient aux vers sauvages et possédaient un nombre de progéniture normal. Cependant, les vers sauvage exposés à l’ARNi d’ufm-1 vivent significativement moins longtemps que les contrôles et ce, de façon indépendante de la voie de signalisation de l’insuline/IGF. Chez le C. elegans la longévité et la résistance au stress cellulaire sont intimement liées. Nous n’avons remarqué aucun effet d’ufm-1 sur le stress thermal, osmotique ou oxydatif, mais il est requis pour la protection contre le stress protéotoxique. Il est également nécessaire au maintien de l’intégrité neuronale au cours du vieillissement des animaux. L’ensemble de nos données nous renseigne sur les fonctions putatives du gène Ufm1. / The ubiquitin-fold modifier (UFM1) is part of the type 1 class of the family of ubiquitin-like protein (Ubl). UFM1 and Ub have very little sequence homology but share remarkable similarities in their tertiary structure. Like Ub and most other UBLS, UFM1 binds covalently to its substrates through an enzymatic cascade. It is frequently reported that UBLs are involved in human diseases. UFM-1 is overexpressed in mice developing a myocardial ischemia and in the islets of patients suffering from type 2 diabetes. UFM1 and its specific enzymes, UBA5, UFL1, and UFC1 are conserved in metazoans and plants suggesting an important role in multicellular organisms. Caenorhabditis elegans is one of the the simplest animal models used in biology. Some features such as morphology, visible phenotypes and cell lineage have completely been described. The short lifecycle of C. elegans makes it easy to observe gene effects on longevity. This model allows us to easily manipulate the expression of the Ufm1 gene and learn more about its putative functions. To study putative functions of Ufm1, we decreased the expression of ufm-1 using RNA interference introduces through feeding. No gross morphological disturbances were observed; worms resembled wild type and had a normal brood size. However, worms exposed to ufm-1 RNAi had a significantly shorter lifespan than the controls. This effect is independent of the insulin/IGF pathway, which is a major axis of longevity genetics. In C. elegans longevity and cellular stress resistance are intimately linked. We have observed no effect of ufm-1 on thermal, osmotic or oxidative stress, but it is required for protection against proteotoxic stress. It is also necessary to maintain neuronal integrity during aging. Together, our results shed light on putative functions of Ufm1 gene.

Caenorhabditis elegans

Ufm1

Longévité

Vieillissement

ARN interférence

Intégrité neuronale

Caenorhabditis elegans

Ufm1

Longevity

Aging

RNA interference

Neuronal integrity