Characterization of Ubiquitin/Proteasome-Dependent Regulation of Hap2/3/4/5 Complex In Saccharomyces cerevisiae

Hunter, Arielle Ruth

01 May 2012

The Hap2/3/4/5 complex is a heme-activated, CCAATT binding, global transcriptional activator of genes involved in respiration and mitochondrial biogenesis in the yeast species Saccharomyces cerevisiae. Hap4 is the regulatory subunit of the complex and its levelsdetermine the activity of the complex. Hap4 is known to play a signaling role in response toenvironmental conditions; however, little is known about the regulation of Hap4 levels or how it responses to a cell’s functional state. The activity of the Hap2-5 complex is known to be reduced in respiratory-deficient cells. In Liu Lab, it has previously been found that a link between Hap4 stability, mediated through 26S proteasome-dependent degradation, and dependence on mitochondrial functional state plays a regulatory role on downstream targets of the Hap complex. However, the mechanism behind this regulation is still largely unknown. In normally functioning yeast cells, Hap4 is a highly unstable protein with a half-life of ~10 min. We have observed that loss of mitochondrial DNA in respiratory deficient rho 0 cells has a role in the further destabilization of Hap4 to a half-life of ~4 min through the ubiquitin-proteasome pathway. Through the screening of a collection of mutants defective in E2 ubiquitin-conjugating enzymes, we show that Hap4 is greatly stabilized in ubc1Δubc4Δ double mutant cells. We also show that Hap4 stabilization in the ubc1Δubc4Δ mutant leads to increased activity of the Hap2-5 complex, indicating that mitochondrial biogenesis in yeast is regulated by the functional state of mitochondria through ubiquitin/proteasome-dependent degradation of Hap4. Furthermore, studies on Hap4 mutants involving two highly conserved cysteine residues led to a proposed mechanism behind the regulation of Ubc4 activity towards Hap4 in response to changes in the cellular redox state.

Hap2/3/4/5 complex

Hap4

mitochondrial biogenesis

glucose repression

rho0

rho+

ubiquitin-proteasome pathway

Chemical biology research on the UCHL1-HIF axis toward development of molecular targeted anticancer drugs / 分子標的抗がん剤開発を指向したUCHL1-HIF経路に関するケミカルバイオロジー研究

Li, Xuebing

23 March 2020

付記する学位プログラム名: 充実した健康長寿社会を築く総合医療開発リーダー育成プログラム / 京都大学 / 0048 / 新制・課程博士 / 博士(薬科学) / 甲第22400号 / 薬科博第122号 / 新制||薬科||13(附属図書館) / 京都大学大学院薬学研究科医薬創成情報科学専攻 / (主査)教授 掛谷 秀昭, 教授 二木 史朗, 教授 土居 雅夫 / 学位規則第4条第1項該当 / Doctor of Pharmaceutical Sciences / Kyoto University / DFAM

hypoxia-inducible factor 1

ubiquitin carboxylterminal hydrolase L1

drug repositioning

molecular docking

tumor malignancy

499.3

Avaliação proteômica das alterações no sistema ubiquitina proteassoma durante a transição epitélio-mesenquimal (EMT) / Proteomic analysis of alterations in the ubiquitin-proteasome system during epithelial to mesenchymal transition (EMT)

Silvestrini, Virgínia Campos

31 January 2019

Câncer se destaca no contexto de patologias por ser uma das doenças que mais acometem mortes por ano, sendo caracterizada como um conjunto de doenças multifatoriais que tem em comum o crescimento desordenado de células que invadem tecidos e órgãos, podendo espalhar-se para outras regiões do corpo, dando origem às metástases. Uma importante etapa da cascata metastática é a transição epitélio-mesenquimal (EMT), um processo bem orquestrado que resulta na perda do fenótipo epitelial e aquisição do fenótipo mesenquimal pelas células tumorais, que adquirem carácter invasivo e migratório, além de se tornarem mais resistentes às drogas. Durante este processo, ocorrem inúmeras alterações celulares que modificam a estabilidade proteica e/ou promovem sua translocação subcelular, o transporte de proteínas para a membrana, alterações no citoesqueleto e incluindo o envio de proteínas para degradação pelo proteassoma. A desregulação de fatores de transcrição e modificação pós traducional de proteínas são fatores que podem levar à EMT. Após a eficiente indução da EMT in vitro utilizando o inibidor de histonas deacetilase (SAHA) em células de adenocarcinoma de mama MCF-7, foram realizadas análises proteômicas envolvimento os inibidores relacionados ao sistema ubiquitina proteassoma, MG132 e P5091. A modulação por inibição de USP7 resultou em variação da expressão de diversas proteínas biomarcadoras da EMT (SNAIL, ?-Catenina, CDK1) e proteínas envolvidas no ciclo celular (P53 e CDK1). O estudo proteômico permitiu a correlação do processo da EMT por SAHA com as vias de modificações pós traducionais relacionadas ao sistema ubiquitina proteassoma, e ainda propõe USP7 como alvo de estudos detalhados para EMT com potencial proposta terapêutica / Cancer stands out in the context of pathologies because it is one of the diseases that most affect deaths per year, being characterized as a set of multifactorial diseases that has in common the disordered growth of cells that invade tissues and organs, being able to spread to other regions of the body, giving rise to metastases. An important step in the metastatic cascade is the epithelial-mesenchymal transition (EMT), a well-orchestrated process that results in the loss of the epithelial phenotype and acquisition of the mesenchymal phenotype by the tumor cells that acquire a more invasive and migratory character, and become more resistant to drugs. During this process, numerous cellular alterations occur that modify the protein stability and/or promote its subcellular translocation, the transport of proteins to the membrane, changes in the cytoskeleton and including the sending of proteins for degradation by the proteasome. Deregulation of transcription factors and posttranslational modification of proteins are factors that can lead to EMT. After an efficient induction of EMT using the histone deacetylase inhibitor (SAHA) in MCF-7 breast adenocarcinoma cells, proteomic analyzes were performed involving inhibitors related to the ubiquitin proteasome system, MG132 and P5091. Modulation by inhibition of USP7 resulted in varying expression of various EMT biomarker proteins (SNAIL, ?-Catenina, CDK1) and cell cycle (P53 e CDK1). The proteomic study allowed the correlation of the SAHA EMT process with the posttranslational modifications pathways related to the ubiquitin proteasome system and also proposes USP7 as the target of detailed studies for EMT with potential therapeutic proposal

EMT

EMT

MG132

MG132

P5091

P5091

SAHA

SAHA

Sistema ubiquitina proteassoma

Ubiquitin proteasome system

USP7

USP7

Schistosoma mansoni: caracterização do perfil de resposta aos estresses oxidativo, térmico e químico / Schistosoma mansoni: Caracterização do perfil de resposta aos estresses oxidativo, térmico e químico

Paula, Renato Graciano de

15 February 2013

A esquistossomose mansônica é a segunda maior endemia parasitária do mundo em termos de extensão das áreas endêmicas e do número de pessoas infectadas com 200 milhões de pessoas acometidas. Esta doença é causada pelo parasito trematódeo Schistosoma mansoni, o qual apresenta adequados mecanismos de resposta ao estresse envolvendo a regulação da expressão gênica e proteica, reparo ou substituição de moléculas danificadas, recuperação do balanço redox, controle do ciclo celular e apoptose. O sistema ubiquitina- proteassoma é importante para manter a homeostase proteica durante o estresse celular. Inibidores do proteassoma podem interferir em processos como crescimento, progressão do ciclo celular e replicação, e os seus efeitos vem sendo caracterizados em muitos parasitos. Nosso laboratório demonstrou que MG132 reduz o número de esquistossômulos, a carga parasitária e a ovoposição em camundongos infectados com S. mansoni. Neste trabalho, são descritos os efeitos in vitro do estresse oxidativo, choque térmico e estresse químico em vermes adultos de S. mansoni. Observou-se alteração no perfil de expressão proteica durante estresse oxidativo e térmico, sendo identificadas dezoito proteínas upreguladas nestas condições. Estas proteínas estão envolvidas em muitas vias intracelulares como dobramento de proteínas, proteólise, ligação a íons cálcio, regulação de proteínas e resposta a estresse. Além disso, o estresse oxidativo gerou mudanças em vermes adultos de S. mansoni em processos como produção de ovos, motilidade, morfologia do tegumento, viabilidade e pareamento dos vermes. O estresse químico induzido com Curcumina, IBMX e MG132 aumentou a produção de ROS intracelular e alterou o perfil de expressão de enzimas antioxidantes em S. mansoni. As enzimas SmGPx1 e SmPGx2 tiveram a expressão aumentada no estresse com Curcumina e IBMX, enquanto que SmSOD e SmTGR foram induzidas no estresse com Curcumina. As enzimas do proteassoma SmHul5 e SmUbp6 tiveram a expressão modulada durante o estresse oxidativo, choque térmico e estresse químico. Em adição, a análise de expressão no ciclo de vida de S. mansoni revelou que estes genes apresentam um nível alto de expressão em esporocistos, esquistossômulos e miracídios. Estes resultados sugerem que estas proteínas acessórias do proteassoma participam da resposta ao estresse e desenvolvimento do parasito. O nível de expressão de SmHul5 e SmUbp6 foi cerca 9 e 16 vezes menor em relação ao controle no estresse químico induzido com IBMX, respectivamente, sugerindo a desmontagem do proteassoma. Por outro lado, Curcumina, MG132, estresse oxidativo e choque térmico aumentaram o nível de expressão de SmHul5 e SmUbp6. Além disso, o nível de expressão da proteína de maturação do proteassoma (SmPOMP) aumentou no estresse com Curcumina, MG132 e estresse oxidativo, sugerindo a síntese de novas populações de proteassoma. Em relação ao estresse oxidativo, nós demonstramos o aumento no nível proteico de proteassoma 20S e da subunidade alfa-3 do proteassoma sugerindo que em S. mansoni as proteínas oxidadas são degradadas pelo proteassoma 20S. Além do mais, nós observamos que vermes adultos de S. mansoni parecem utilizar mecanismos de resposta similares para diferentes estresses. Nossos resultados demonstraram que o estresse oxidativo, choque térmico e estresse químico modificam o perfil de expressão de genes relacionados ao sistema ubiquitina-proteassoma e sugerem que o proteassoma é importante para as respostas celulares ao estresse neste parasito. / Schistosomiasis is a neglected tropical disease caused by blood flukes (genus Schistosoma) and affecting 200 million people worldwide. This disease continues to rank, following malaria, at the second position of the world\'s parasitic diseases in terms of the extent of endemic areas and the number of infected people. There are different types of stress and the organisms have many mechanisms to respond to these stressor agents. The responses involve the regulation of gene and protein expression and consist in events such as repair or substitution of damaged molecules, recovery of redox balance, cell cycle control and apoptosis. The proteasomal system is important to support the protein homeostasis during the cellular stress. Effect of proteasome inhibitors has been described in many protozoans, either inhibiting growth or cell cycle progression, or blocking replication. Our laboratory\'s results have shown that MG132 reduces the number of lung stage schistosomula, the worm burden and consequently decreases oviposition in S. mansoni-infected mice. Here, we describe the in vitro effects of oxidative stress, heat shock and chemical stress in S. mansoni adult worms. We report that the oxidative stress and heat shock cause drastic changes in the protein profile of S. mansoni adult worms, and we identified a total of eighteen upregulated proteins in these conditions. These proteins are involved with many intracellular pathways as protein folding, proteolysis, calcium ion binding, regulator proteins and stress response. In addition, oxidative stress induced with H2O2 generated significative changes in the adult worms concerning process such as egg production, motor activity, tegument morphology, viability and pairing of worms. Chemical stress induced with Curcumin, IBMX and MG132 increases ROS production and changes the gene expression profile of antioxidant enzymes of S. mansoni adult worms. The enzymes SmGPx1 and SmGPx2 were upregulated in Curcumin and IBMXinduced chemical stress, and both SmSOD and SmTGR were upregulated- Curcumin. The proteasomal enzymes SmHul5 and SmUbp6 had their gene expression modified during oxidative stress, heat shock and chemical stress. Besides of, expression analyses in the S. mansoni life cycle indicate that genes are different express in sporocyst, schistosomula and miracidia. These results suggest these accessory proteins proteasome participates of stress response and parasite development. The expression level of SmHul5 and SmUbp6 were 16 and 9 times less than the control in chemical stress induced by IBMX, and we suggest that these results are due to the proteasome disassembling. On the other hand, Curcumin, MG132, oxidative stress e heat shock increases the expression of SmHul5 and SmUbp6. Furthermore, the expression level of maturation proteasome protein (SmPOMP) increases in stress induced by Curcumin, MG132 and oxidative stress suggesting new proteasome synthesis. In addition, we demonstrate increase the both 20S level and alpha-3 subunit proteasome in the oxidative stress, suggesting that in S. mansoni oxidized protein formed due to oxidative damage are degrade by proteasome 20S. We observed that S. mansoni adult worms utilize similar mechanisms to respond different stresses. Ours results demonstrate that oxidative stress, heat shock and chemical stress modified the expression profile of genes related with the ubiquitinproteasome system and suggest that the proteasome is important to responses the cellular stresses in the parasite.

Expressão gênica

Gene expression

Schistosoma mansoni

Schistosoma mansoni

Sistema Ubiquitina-Proteassoma

Ubiquitin-Proteasome System

Development of fluorescent assays for biological analysis

Ladyman, Melissa Kate

January 2015

The work in this thesis is divided into two parts; the first is the synthesis of a ‘switch-on’ fluorophore to measure cell viability, and the second is the development of a fluorescent detection method for protein−peptide affinity assays applied in the identification of protein-protein inhibitors. Tetrazolium salts are often used in cytotoxicity assays as indicators of cell viability as they are reduced to deeply coloured formazans exclusively in healthy cells. However, measuring the absorbance of the formazan is prone to bias from other coloured species in the cell media, requires solubilisation and can be difficult to quantify. A preferable method of detection is direct fluorescence as it is easily quantified, more sensitive and would ideally remove the need to solubilise the insoluble dye. The aim of this project was to synthesise a tetrazolium salt that could be reduced to a soluble fluorescent formazan in healthy cells as an indicator of cell viability. A number of fluorescent formazans were synthesised by incorporation of a fluorophore. The corresponding tetrazolium salts were non-fluorescent and could be reduced to the formazan in vitro. Several formazans were synthesised to attempt to increase the emission wavelength and intensity to overcome cellular autofluorescence. Protein-protein interactions have been implicated in the pathogenesis of many human diseases but until recently were considered undruggable. However, peptides have emerged as ideal compounds for targeting the large and relatively featureless protein interfaces. Work focussed on the discovery of peptide inhibitors for the E3 ubiquitin ligase stationary-phase kinase associated protein (Skp2). Potential peptide inhibitors were identified using CelluSpot synthesis and array technology to screen peptide libraries. Qualitative analysis of the protein affinity assay results by enhanced chemiluminescent detection was found to be misleading, and so a quantifiable and more sensitive fluorescent detection method was developed.

572

Investigating the crosstalk between Nedd4 ubiquitin ligases and PIAS3 SUMO ligase

Fan, Jun

January 2017

Previously it has been shown that Rsp5p, a member of Nedd4 ubiquitin ligases in yeast, is modified by the ubiquitin-like protein SUMO and that this modification is performed by Siz1p, a member of PIAS SUMO ligases that are in turn substrates of Rsp5p-dependent ubiquitylation, thus defining a previously unidentified system of crosstalk between the ubiquitin and SUMO systems in yeast. This project aims to identify whether similar crosstalk pattern exists in human cells. In vitro ubiquitylation assays showed that some of the human Nedd4 family members (Nedd4.1, Nedd4.2, WWP1) are capable of ubiquitylating the human SUMO ligase PIAS3, while in contrast, Smurf2 does not appear to be able to modify this protein. This modification is partially WW-PY-motif-dependent as ubiquitylation level of PIAS3 mutants with altered PY motifs conducted by Nedd4.1 or Nedd4.2 was reduced, but not completely disrupted. Interestingly, in vitro SUMOylation assay revealed that Nedd4.1 is SUMOylated even in the absence of SUMO E3 ligases and an apparent interaction between the SUMO E2 (Ubc9) and Nedd4.1 was observed both in vitro and in vivo. I show that auto- SUMOylation of Nedd4.1 is accompanied with the formation of thioester-linked conjugates between Nedd4.1 and SUMO, but these do not involve cysteine residues (C867, C778, and C627) within the HECT domain itself and is not occurring at a predicted SUMOylation consensus site (K357). Furthermore, I have shown that Nedd4.1 and SUMO1/2 colocalize in HeLa cells, and that overexpression of epitope tagged Nedd4 and SUMO1/2, followed by denaturing pull-downs demonstrates that both Nedd4.1 and Nedd4.2 can be SUMOylated in vivo. Meanwhile, I have generated a SUMO trap based on SUMO interacting motifs (SIMs) and confirmed its ability of capturing SUMOylated proteins both in vivo and in vitro. Its use reveals that Nedd4 SUMO conjugates could be captured by SUMO trap when Nedd4 and SUMO were co-expressed in HeLa cells, again confirming Nedd4.1 as a substrate for SUMO1 or SUMO2. In conclusion, I show that SUMOylation of Nedd4.1 does exist in HeLa cells, and on the other hand, some of Nedd4 family members are responsible for PIAS3 ubiquitylation in vitro, providing evidence of a crosstalk between Nedd4 family of ubiquitin ligases and PIAS family of SUMO ligases in mammals.

Régulation de la stabilité de la protéine anti-apoptotique BCL2A1 / Regulation of the stability of the anti-apoptotic protein BCL2A1

Lionnard, Loïc

29 March 2018

L’apoptose ou mort cellulaire programmée joue un rôle prépondérant dans l’homéostasie cellulaire. Ce processus est très finement régulé par les protéines de la famille BCL-2 qui contrôlent la perméabilité de membrane mitochondriale externe et la libération du cytochrome c, deux événements majeurs précédant la mort cellulaire. Les protéines anti-apoptotiques de la famille BCL-2 contribuent à la tumorigenèse et sont impliquées dans la résistance des cancers aux molécules chimiothérapeutiques ; à ce titre, elles représentent des cibles importantes pour le développement de nouvelles thérapies. BCL2A1 est un membre anti-apoptotique de la famille BCL-2 impliqué dans la chimiorésistance de nombreuses tumeurs. La protéine BCL2A1 a pour caractéristique d’avoir une demi-vie courte due à sa dégradation constitutive par le système ubiquitine-protéasome. Ceci régule la stabilité et la fonction anti-apoptotique de BCL2A1 et représente un mécanisme suppresseur de tumeur majeur. Cependant, les enzymes qui contrôlent les modifications post-traductionnelles impliquées dans l’ubiquitination et la dégradation de BCL2A1 demeurent, à ce jour, inconnues. Dans la présente thèse, nous donnons un aperçu des acteurs et des mécanismes impliqués dans la régulation de l’ubiquitination de BCL2A1. Nous présentons des preuves que TRIM28 est une E3 ubiquitine-ligase pour BCL2A1. En effet, les protéines TRIM28 et BCL2A1 endogènes interagissent ensemble au niveau des mitochondries et la déplétion de TRIM28 diminue l’ubiquitination de BCL2A1. Nous montrons aussi que TRIM17 stabilise BCL2A1 en empêchant son interaction avec TRIM28 et son ubiquitination médiée par TRIM28, et que l’activité de GSK3 est impliquée dans l’inhibition de la dégradation de BCL2A1. Ainsi, BCL2A1 et son proche homologue MCL-1 sont régulés par des facteurs communs mais de façon opposé. Finalement, la surexpression de TRIM28 ou l’inactivation de TRIM17 diminue le niveau protéique de BCL2A1 et restaure la sensibilité des cellules de mélanomes aux thérapies utilisant des inhibiteurs de la kinase BRAF. Globalement, nos résultats décrivent un rhéostat moléculaire au sein duquel deux protéines de la famille TRIM régulent de façon antagoniste la stabilité de BCL2A1 et modulent ainsi la mort cellulaire. / Apoptosis or programmed cell death plays a crucial role in tissue homeostasis and is regulated by the Bcl-2 proteins, which control mitochondria membrane permeability and cytochrome c release, two events that precede cell demise. Anti-apoptotic Bcl-2 family members can contribute to tumorigenesis and cause resistance to anti-cancer regimens, therefore representing important targets for novel therapeutics. BCL2A1 is an anti-apoptotic member of the BCL-2 family that contributes to chemoresistance in a subset of tumors. BCL2A1 has a short half-life due to its constitutive processing by the ubiquitin-proteasome system. This constitutes a major tumor-suppressor mechanism regulating BCL2A1 function. However, the enzymes involved in the regulation of BCL2A1 protein stability are currently unknown. Here we provide the first insight into the regulation of BCL2A1 ubiquitination. We present evidence that TRIM28 is an E3 ubiquitin-ligase for BCL2A1. Indeed, endogenous TRIM28 and BCL2A1 bind to each other at the mitochondria and TRIM28 knock-down decreases BCL2A1 ubiquitination. We also show that TRIM17 stabilizes BCL2A1 by blocking TRIM28 from binding and ubiquitinating BCL2A1, and that GSK3 is involved in the phosphorylation-mediated inhibition of BCL2A1 degradation. BCL2A1 and its close relative MCL1 are thus regulated by common factors but with opposite outcome. Finally, overexpression of TRIM28 or knock-out of TRIM17 reduced BCLA1 protein levels and restored sensitivity of melanoma cells to BRAF-targeted therapy. Therefore, our data describe a molecular rheostat in which two proteins of the TRIM family antagonistically regulate BCL2A1 stability and modulate cell death.Sommaire

Apoptose

Famille BCL-2

Ubiquitine-Proteasome

Apoptosis

BCL-2 family

Ubiquitin-Proteasome

Investigating the role of ubiquitin in endosomal sorting and processing of amyloid precursor protein

Williamson, Rebecca Lynn

January 2017

Amyloid plaques, a neuropathological hallmark of Alzheimer’s disease (AD), are largely composed of amyloid beta (Aβ) peptide, derived from cleavage of amyloid precursor protein (APP) by β- and γ-secretase. The endosome is increasingly recognized as an important crossroads for APP and the secretases, with major implications for APP processing and amyloidogenesis. Amongst various posttranslational modifications affecting APP, ubiquitination of cytodomain lysines may represent a key signal controlling endosomal sorting. Here, we show that substitution of APP COOH-terminal lysines with arginines disrupts APP ubiquitination, though the pool of ubiquitinated APP is small or transient. Nonetheless, this small deficiency in ubiquitination can have a significant impact on APP, such that the number of lysines mutated trends toward an increase in APP metabolism. An APP mutant lacking all COOH-terminal lysines undergoes the most pronounced increase in processing, leading to accumulation of both secreted and intracellular Aβ40, without change in Aβ42. This phenotype is abolished by artificial ubiquitination of APP using rapalog-mediated proximity inducers. Lack of APP COOH-terminal lysines does not affect APP endocytosis, but leads to a redistribution of APP from endosomal intraluminal vesicles (ILVs) to the endosomal limiting membrane, with subsequent decrease in APP COOH-terminal fragment (CTF) content of secreted exosomes, but minimal effects on APP lysosomal degradation. Both the secreted and intracellular increase in Aβ40 is abolished by depletion of presenilin 2 (PSEN2), recently shown to be enriched on the endosomal limiting membrane compared to presenilin 1 (PSEN1). In a separate set of studies, we found that a familial AD mutant, L723P, which occurs immediately next to a string of three lysines in the juxtamembrane region, behaves more similarly to other FAD-causing mutations. APP L723P exhibits a selective increase in Aβ42, and a delay in degradation, but no change in exosomal content, despite some missorting to the endosomal limiting membrane. Our findings demonstrate that ubiquitin can act as a signal for endosomal sorting at five lysines in the APP cytodomain, disruption of which prevents sequestration of APP in ILVs and results in the processing of a larger pool of APP-CTF by PSEN2 on the endosomal membrane.

Amyloid beta-protein precursor

Ubiquitin

Endosomes

Nervous system--Diseases

Amyloid beta-protein

Neurosciences

Pathology

Molecular biology

Structural and functional analysis of SUMO specific proteases. / CUHK electronic theses & dissertations collection

January 2007

During the activation and transferring process, E1 and E2 form a thioester-linkage with SUMOs. By using an in vitro assay, it is demonstrated that SENP1 is able to cleave the thioester-linkage between SUMO-1/SUMO-3 and E1/E2. This finding suggests that SUMO proteases regulate the sumoylation pathway, not only during maturation and deconjugation, but also in the E1 activation and E2 conjugation processes. / Recently, reactive oxygen species have been demonstrated to influence the equilibrium of sumoylation-desumoylation. Here, by in vitro assay, it is shown that H2O2 induces formation of inter-molecular disulfide linkage of human SUMO protease SENP1, via the active-site Cys 603 and a unique residue Cys 613. Such reversible modification confers higher enzyme activity recovery which is also observed in yeast Ulp1, but not in human SENP2, suggesting its protective role against irreversible sulfhydryl oxidation. The physiological relevance of the disulfide-linked dimer of SENP1 is also detected in cultured cells upon oxidative stress. The modifications are further verified by the crystal structures of Ulp1 with catalytic cysteine oxidized to sulfenic, sulfinic and sulfonic acids. The current findings suggest that, in addition to SUMO conjugating enzymes, SUMO proteases may act as redox sensors and effectors, which modulate the desumoylation pathway and allow immediate specific cellular responses to oxidative stress. / SUMO (small ubiquitin-related modifier) is a member of the ubiquitin-like protein family that is highly conserved in all eukaryotic organisms and regulates cellular function of a variety of target proteins. SUMO proteins are expressed in their precursor forms and precursor processing involves cleavage of the residues after the conserved 'GG' region by the hydrolytic activity of SUMO-specific protease. The exposed second glycine then forms a covalent bond with the epsilon-amino group of a substrate lysine residue at the psiKxE motif by a cascade of SUMO El, E2 and E3 ligases. As a reversible modification, SUMO proteases can cleave SUMOs from their substrates during de-conjugation process. / To date, four SUMO family members, SUMO-1, -2, -3 and -4 and six SUMO proteases, SENP1--3 and 5-7 (where SENP stands for sentrin-specific protease) have been identified in human. By characterizing the maturation reactions of SUMO-1, -2 and -3 catalyzed by SENP1, it is demonstrated that SENP1 contains the highest maturation efficiency for SUMO-1, followed by SUMO-2 and SUMO-3. By mutagenesis study, it is further identified that the two amino acids immediately after GG motif could influence the maturation efficiency of SENP1. By comparison with another investigation which showed the preference of the maturation reaction of SUMO-2 by SENP2, the results suggest that SUMO proteases with specific tissue distribution control the availability of different mature SUMOs in human. / To gain a deeper insight into the molecular basis of maturation and de-conjugation processes catalyzed by SENP1, it has been determined, at 2.8 A resolution, the X-ray structure of a complex between the catalytic domain of SENP1C(C603S) and matured SUMO-1. The structure shows that the substituted serine residue does not undergo any local structural rearrangements at the active site as observed in the previously solved SENP2/SUMO-1 complex structure. This finding suggests that SUMO proteases require a self-conformational change prior to the cleavage reaction, and further disclose the cleavage mechanism of the hydrolytic reactions catalyzed by SUMO proteases. Moreover, analysis of the interface of SENP1 and SUMO1 has identified four amino acids that are unique in SENP1 sequence and facilitate the interaction of SENP1 and SUMO-1. / Xu, Zheng. / "July 2007." / Advisers: Shannon Au Wing Ngor; Tzi-Bun Ng. / Source: Dissertation Abstracts International, Volume: 69-01, Section: B, page: 0125. / Thesis (Ph.D.)--Chinese University of Hong Kong, 2007. / Includes bibliographical references (p. 181-194). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. [Ann Arbor, MI] : ProQuest Information and Learning, [200-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstracts in English and Chinese. / School code: 1307.

Proteolytic enzymes--Analysis

Ubiquitin

Peptide Hydrolases--analysis

Peptide Hydrolases--physiology

Ubiquitins

Regulation of proteotoxicity through atypical NEDDylation / Régulation de protéotoxicité via la NEDDylation atypique

Maghames, Chantal

10 November 2016

Les cellules sont constamment exposées à des stress « protéotoxiques » qui altèrent leurs protéines. Si les protéines endommagées ne sont pas réparées ou éliminées, elles peuvent former des agrégats toxiques pouvant conduire à l’émergence de plusieurs maladies, telle que les maladies neurodégénératives et le cancer. Pour éviter cette toxicité, les cellules ont développé plusieurs stratégies qui collaborent et communiquent afin d'assurer le contrôle de qualité des protéines et maintenir l’intégrité du protéome cellulaire. L’ensemble de ces stratégies forment le réseau de l’homéostasie protéique ou « protéostasie ». Ce réseau inclus les chaperonnes moléculaires, les systèmes protéolytiques (lysosomes, protéasomes) et des systèmes de séquestration des protéines endommagées. L’Ubiquitine et les protéines apparentées à l’Ubiquitine telle que SUMO et NEDD8, sont des effecteurs essentiels de ce réseau. Ces molécules modifient leurs substrats de façon covalente, grâce à l’action d’une cascade d’enzymes E1, E2 et E3. En principe, on considérait que chacune de ces voies employait sa propre cascade enzymatique pour la modification post-traductionnelle de ses substrats. L’Ubiquitination joue un rôle essentiel dans la réponse au stress cellulaire, surtout en assurant la dégradation protéasomique des protéines mal repliées. Récemment, notre laboratoire a trouvé que plusieurs stress protéotoxiques telle que l’inhibition du protéasome, un choc thermique et un stress oxydatif, causent une augmentation de NEDDylation. De manière remarquable, cette augmentation ne dépend pas de l’enzyme d’activation de NEDD8 NAE, mais plutôt de celle de l’Ubiquitine Ube1. De plus, elle se caractérise par la formation des chaînes poly-NEDD8 et des chaînes mixtes entre NEDD8 et Ubiquitine. Ce processus est réversible et une restauration cellulaire est obtenue une fois le stress atténué. Le but de notre projet est de caractériser la réponse de NEDD8 au stress cellulaire ou ce qu’on appelle « la NEDDylation atypique » en vue de comprendre son effet biologique pendant ces conditions. Nos résultats montrent que la NEDDylation atypique dépend des protéines de stress Hsp70/90 et qu’elle cible principalement les protéines nouvellement synthétisées et mal repliées. On montre que, suite à leur modification par NEDD8/Ubiquitin, ces protéines sont transloquées du cytosol au noyau, où elles sont dégradées par le protéasome. Cependant, des conditions de stress prolongé causent une atténuation de l’activité nucléaire des protéasomes 26S, ce qui provoque alors l’accumulation des protéines endommagées sous forme d’inclusions nucléaires. Ces dernières sont réversibles et peuvent être éliminées par le protéasome une fois le stress atténué. Afin d’identifier les cibles de NEDD8 dans des conditions de stress, nous avons développé une approche protéomique basée sur une stratégie de mutation ponctuelle (NEDD8R74K). Cette stratégie permet l’identification des sites spécifiques de NEDDylation au sein des protéines cibles. Cette approche en combinaison avec le SILAC a permis l’identification de NEDD8, Ubiquitine, SUMO-2 et les protéines ribosomiques en tant que principales cibles de NEDD8 en réponse au stress. Ce qui était plus intéressant est que, en appliquant l’étude protéomique SILAC, on a pu constater que le rôle essentiel de la NEDDylation atypique est d’induire l’agrégation/séquestration d’un ensemble spécifique de protéines au sein des inclusions nucléaires. De plus, nous avons montré que l’agrégation induite par NEDD8 protège les protéasomes nucléaires d’une sévère déficience et permet une meilleure survie cellulaire pendant le stress. Notre étude présente NEDD8 comme un nouvel effecteur dans le réseau de protéostasie, elle identifie une nouvelle inclusion nucléaire cytoprotectrice et montre que la NEDDylation atypique est essentielle pour la réponse cellulaire au stress. / Cells are continuously endangered by a variety of proteotoxic stresses that cause protein misfolding and accumulation. Defects in repair or elimination of protein damage can lead to the formation of toxic aggregates that have been associated with diseases, such as neurodegenerative disorders and cancer. To prevent this toxicity, cells have evolved multiple quality control processes that interact and cooperate to maintain protein homeostasis leading to cellular fitness. These processes form “the proteostasis network”, and include molecular chaperones, proteolytic machineries (lysosomes, proteasomes) and pathways for protein damage sequestration. One of the main effectors of this network is the Ubiquitin and the Ubiquitin-like molecules, such as SUMO and NEDD8. These molecules covalently modify proteins through the action of E1, E2 and E3 enzymes. Historically, it was believed that each pathway employed its own and unique set of enzymes to post-translationally modify its substrates. Ubiquitination is essential for the cellular response to stress, especially by targeting misfolded proteins for proteasomal degradation. However, we recently discovered that proteotoxic stresses including proteasome inhibition, heat shock and oxidative stress induce a global increase in protein NEDDylation. Surprisingly, this increase does not depend on the NEDD8 activating enzyme NAE, but rather on the Ubiquitin activating enzyme Ube1, and is characterized by the formation of poly-NEDD8 chains and mixed chains between NEDD8 and Ubiquitin. Importantly, this process is reversible and cell recovery is accomplished once stress is alleviated. In this study, we focused on characterizing the NEDD8 response to stress or “atypical NEDDylation” in order to understand its biological relevance under these conditions.Our results showed that atypical NEDDylation depends on Hsp70/90 and targets mainly newly synthesized damaged proteins. We showed that, after their NEDDylation/Ubiquitination, misfolded proteins are progressively translocated from the cytosol into the nucleus for proteasomal degradation. However, upon prolonged stress conditions, the activity of nuclear 26S proteasome is compromised, resulting in the accumulation of these conjugates into nuclear inclusions. These inclusions are reversible and eliminated by nuclear proteasomes once stress is alleviated. In order to identify NEDD8 targets upon these conditions, we developed a proteomic approach based on a point mutation strategy (NEDD8R74K) that enables a site-specific analysis of NEDDylated proteins. This approach in combination with SILAC allowed the identification of NEDD8, Ubiquitin, SUMO-2, and ribosomal proteins as the major NEDD8 targets upon stress. Interestingly, by SILAC proteomics we found that the main function of atypical NEDDylation is to induce the aggregation/sequestration of a specific subset of proteins within the nuclear inclusions. We showed that this NEDD8-induced aggregation protects nuclear proteasomes from a severe impairment and allows a better cell survival upon proteotoxic stress.Our study defines NEDD8 as a new effector in the proteostasis network, identifies a new cytoprotective nuclear inclusion and shows that atypical NEDDylation is essential for the cellular response to stress.

Protéostasie

Protéines

Ubiquitine

Nedd8

Agrégats

Protéasome

Proteostasis

Proteins

Ubiquitin

Nedd8

Aggregates

Proteasme