A Novel Exocyst-Based Mechanism for HIV Nef-Mediated Enhancement of Intercellular Nanotube Formation

Mukerji, Joya

January 2012

HIV-1 Nef protein contributes to pathogenesis via multiple functions that include enhancement of viral replication and infectivity, alteration of intracellular trafficking, and modulation of cellular signaling pathways. Nef stimulates formation of tunnelling nanotubes and virological synapses, and is transferred to bystander cells via these intercellular contacts and secreted microvesicles. Nef associates with and activates Pak2, a kinase that regulates T-cell signaling and actin cytoskeleton dynamics, but how Nef promotes nanotube formation is unknown. In this dissertation, we developed and characterized a lentiviral vector-based system to express Nef in T-cell lines and primary human peripheral blood mononuclear cells, and then used this system to perform a proteomic screen to identify Nef-associated host cell factors and better understand how Nef hijacks the T-cell machinery to maximize HIV production and dissemination. Bioinformatic and cell-based analysis of the resulting host factors revealed a mechanism by which Nef enhances nanotube formation. To identify Nef binding partners involved in Pak2-association dependent Nef functions, we employed tandem mass spectrometry analysis of Nef immunocomplexes from Jurkat cells expressing wild-type Nef or Nef mutants defective for the ability to associate with Pak2 (F85L, F89H, H191F and A72P, A75P in NL4-3). Wild-type, but not mutant Nef, was associated with 5 components of the exocyst complex (EXOC1, EXOC2, EXOC3, EXOC4, and EXOC6), an octameric complex that tethers vesicles at the plasma membrane, regulates polarized exocytosis, and recruits membranes and proteins required for nanotube formation. Additionally, Pak2 kinase was associated exclusively with wild-type Nef. Association of EXOC1, EXOC2, EXOC3, and EXOC4 with wild-type, but not mutant Nef, was verified by co-immunoprecipitation assays in Jurkat cells. Furthermore, shRNA-mediated depletion of EXOC2 in Jurkat cells abrogated Nef-mediated enhancement of nanotube formation. Using bioinformatic tools, we visualized protein interaction networks that reveal functional linkages between Nef, the exocyst complex, and the cellular endocytic and exocytic trafficking machinery. Together, our findings identify the exocyst complex as a key effector of Nef-mediated enhancement of nanotube formation, and possibly microvesicle secretion. Furthermore, linkages revealed between Nef and the exocyst complex suggest a new paradigm of exocyst involvement in polarized targeting for intercellular transfer of viral proteins and viruses.

exocyst

HIV-1

nanotube

Nef

proteomics

T-cell

virology

Approche théorique de la réactivité des isonitriles en chimie organique

Chéron, Nicolas

18 November 2011

Les isonitriles sont des espèces connues depuis longtemps, mais étudiées depuis peu. Une approche théorique a permis de s'intéresser en détails aux réactions de Nef et de Ugi. Nous nous sommes tout d'abord focalisés sur la première. Après en avoir élucidé le mécanisme, nous avons étudié l'effet du solvant et nous avons proposé de nouvelles conditions expérimentales. Nous avons ensuite étudié l'influence des groupements de l'acyl, de l'isonitrile et du groupe partant. L'ensemble des variations considérées a pu être rationalisé en reliant l'énergie d'activation au pKa du groupe partant. En parallèle, nous avons étudié la réaction de Ugi. Le mécanisme proposé par Ugi pour cette réaction complexe n'avait toujours pas été vérifié 50 ans après sa découverte. Une étude quasi-exhaustive des différents mécanismes possibles a été menée, en utilisant une approche originale mêlant théorie et expériences. Le mécanisme de cette réaction a ainsi été démontré, tant dans le méthanol que dans le toluène. Les étapes cinétiquement déterminantes et les forces motrices ont été mises en lumière et diffèrent de celles proposées par Ugi. Une variation de la réaction de Ugi est le couplage Ugi-Smiles pour lequel de nombreux résultats expérimentaux n'ont toujours pas trouvé d'explications. Nous nous sommes donc intéressés au réarrangement de Smiles. Nous avons montré l'importance d'une liaison hydrogène intramoléculaire sur la faisabilité de la réaction, et nous avons étendu cette observation aux réactions intermoléculaires. Nous avons également étudié l'influence des substituants des quatre réactifs sur les barrières afin de construire un modèle prédictif.

[CHIM:OTHE] Chemical Sciences/Other

Réaction de Nef

Etats de transition

SnAr

DFT

Proteomics in viral disease

Gangadharan, Bevin

January 2006

The separation, identification, and characterisation of the proteins present in a tissue or biological sample is called ‘proteomics’. This technique can be used for example to identify biomarkers and investigate signalling pathways. Increasingly, proteomics is being applied to the analysis of virus related samples; here two such examples are described. Presently there is no reliable non-invasive way of assessing liver fibrosis. Here a novel 2D-PAGE based proteomics study was used to identify potential fibrosis biomarkers. Serum from patients with varying degrees of hepatic scarring induced by infection with the hepatitis C virus (HCV) was analysed. Several proteins associated with liver scarring and/or viral infection were identified. The most prominent changes were observed when comparing serum samples from cirrhotic patients with healthy controls: Expression of inter-α-trypsin inhibitor heavy chain H4 fragments, α1 antichymotrypsin, apolipoprotein L1 (Apo L1), prealbumin and albumin was decreased in cirrhotic serum, whereas CD5 antigen like protein (CD5L) and β2 glycoprotein I (β2GPI) increased. In general, α2 macroglobulin (a2M) and immunoglobulin components increased with hepatic fibrosis whereas haptoglobin and complement components (C3, C4 and factor H-related protein 1) decreased. Novel proteins associated with HCV-induced fibrosis include the inter-alpha-trypsin inhibitor heavy chain H4 fragments, complement factor H-related protein 1, CD5L, Apo L1, β2GPI and the increase in thiolester cleaved products of a2M. The relationship between these changes is discussed. One of the accessory genes of the HIV viral genome encodes for the Nef protein. Nef is present in lipid rafts and increases viral replication within infected host cells by binding to a guanine nucleotide exchange factor, Vav. This leads to activation of a GTPase, Cdc42, however, the signalling pathway is poorly understood. 2D-PAGE based proteomics was used to identify differentially expressed raft-associated proteins by comparing T cells in the presence and absence of Nef. A ubiquitin conjugating enzyme UbcH7, which acts in conjugation with c-Cbl, was absent from the rafts of Nef-transfected cells. Vav ubiquitination was also absent from these rafts. In collaboration with Dr. Alison Simmons and Prof. Andrew McMichael the absence of UbcH7 in rafts was found to be caused by β-Pix forming a ternary complex with c-Cbl and activated Cdc42. Vav ubiquitination was restored and viral replication was diminished when β-Pix was knocked down providing a new candidate target for inhibiting HIV replication. This thesis demonstrates the use of proteomics in providing novel information for virus related samples. This influential technology benefits in both biomarker discovery to aid clinicians with early diagnosis of diseased individuals and in the elucidation of novel signalling pathways in infected cells to provide new candidate targets.

616.36230756

Étude du rôle de nef dans l'altération de la transduction du signal chez les souris transgéniques CD4C/HIV NEF

Vincent, Patrick

January 2006

No description available.

VIH

Souris transgénique

Nef

PAK2

Rac

Cellules primaires

Macrophages péritonéaux

Mechanisms of HIV-Nef Induced Endothelial Cell Stress: Implications of HIV-Nef Protein Persistence in Aviremic HIV Patients

Chelvanambi, Sarvesh

05 1900

Indiana University-Purdue University Indianapolis (IUPUI) / HIV-associated cardio-pulmonary vascular pathologies such as coronary artery disease, pulmonary hypertension and emphysema remain a major issue in the HIVinfected population even in the era of antiretroviral therapy (ART). The continued production of HIV encoded pro-apoptotic protein, such as Nef in latently HIV-infected cells is a possible mechanism for vascular dysfunction underlying these diseases. HIVNef persists in two compartments in these patients: (i) extracellular vesicles (EV) of plasma and bronchoalveolar lavage (BAL) fluid and (ii) PBMC and BAL derived cells. Here I demonstrate that the presence of HIV-Nef protein in cells and EV is capable of stressing endothelial cells by inducing ROS production leading to endothelial cell apoptosis. HIV-Nef protein hijacks host cell signaling by interacting with small GTP binding protein Rac1 which activates PAK2 to promote the release of pro-apoptotic cargo containing EV and surface expression of pro-apoptotic protein Endothelial Monocyte Activating Polypeptide II (EMAPII). Using this mechanism, Nef protein robustly induces apoptosis in Human Coronary Artery Endothelial Cells and Human Lung microvascular endothelial cells. Endothelial specific expression of HIV-Nef protein in transgenic mice was sufficient to induce vascular pathologies as evidenced by impaired endothelium mediated vasodilation of the aorta and vascular remodeling and emphysema like alveolar rarefaction in the lung. Furthermore, EV isolated from HIV patients on ART was capable of inducing endothelial apoptosis in a Nef dependent fashion. Of therapeutic interest, EMAPII neutralizing antibodies to block EMAPII mediated apoptosis and statin treatment to ameliorate Nef induced Rac1 signaling was capable of blocking Nef induced endothelial stress in both in vivo and in vitro. In conclusion, HIV-Nef protein uses a Rac1-Pak2 signaling axis to promote its dissemination in EV, which in turn induces endothelial cell stress after its uptake.

EMAPII

HIV-Nef

Cardiovascular disease

Endothelial

Pulmonary

Vascular dysfunction

Estudo da função de AP1y2 e Alix no direcionamento de proteínas para degradação em lisossomos ou liberação em vesículas extracelulares / Study of AP1y2 and Alix function in the targeting of proteins for degradation in lysosomes or release in extracellular vesicles

Januário, Mara Elisama da Silva

21 June 2017

A degradação lisossomal de proteínas de membrana endocitadas ocorre por meio do direcionamento destas proteínas para vesículas intralumenais (ILVs), formadas no lúmen dos corpos multivesiculares (MVBs), e subsequente fusão dos MVBs com lisossomos. Apesar de sua importância na degradação de proteínas transmembrana, os MVBs possuem outra importante função, a de produzir e liberar vesículas extracelulares (EVs). Neste processo os MVBs não se fundem com lisossomos, mas sim com a membrana plasmática o que resulta na liberação das vesículas residentes no interior dos MVBs para o meio extracelular. Diversas proteínas participam do direcionamento de cargas para os MVBs. Os estudos que delinearam a via de tráfego mediada por AP1 concentraram-se nos complexos contendo a subunidade ?1 que medeia o transporte de proteínas entre a rede trans-Golgi (TGN) e endossomos. Contudo, o genoma humano codifica uma segunda isoforma desta subunidade, denominada ?2, e evidências presentes na literatura e também observadas por nosso grupo indicam que AP1?2 pode regular uma via de tráfego distinta da via classicamente atribuída a AP1. Utilizando ensaios de uptake de EGF em condições onde foi realizado o KD de ?1 ou ?2, foi observado que o silenciamento de ?2 prejudica a degradação de EGF internalizado por seu receptor. Efeito também observado para o próprio receptor de EGF (EGFR) em ensaios de biotinilação da superfície celular. Demonstrando que a degradação lisossomal do complexo EGF-EGFR pela via canônica dos MVBs requer o complexo AP1?2, mas não AP1?1. Em conjunto com este estudo também foi analisado o mecanismo molecular de direcionamento da proteína Nef do HIV-1 para os MVBs associados a liberação de EVs. A proteína Nef do HIV é determinante na modulação do ambiente intracelular favorecendo a replicação do vírus e progressão à AIDS. Nef é ativamente secretado em EVs e sua liberação pode levar a apoptose de células vizinhas aceptoras dessas vesículas. Nef também medeia a redução dos níveis de CD4 e moléculas de MHC-I em EVs. Ainda não é conhecido o mecanismo molecular utilizado por Nef para ser exportado em EVs, mas sabe-se que Nef interage fisicamente com a proteína II acessória da maquinaria ESCRT, Alix, importante no processo de formação das ILVs e seleção das cargas que serão internalizadas nos MVBs. EVs coletadas de células HeLa e linfócitos T CD4+ silenciados para Alix demostraram reduções significativas na liberação de Nef. Estes resultados indicam que Nef requer Alix para sua eficiente liberação em EVs. / Lysosomal degradation of endocytosed membrane proteins occurs through the targeting of these proteins to intraluminal vesicles (ILVs), formed in the multivesicular bodies (MVBs) lumen, and the subsequent fusion of MVBs with lysosomes. Despite its importance in the degradation of transmembrane proteins, MVBs have another important function, the production and release of extracellular vesicles (EVs). In this process, the MVBs do not fuse with lysosomes, but fuse with the plasma membrane resulting in the release of these vesicles that reside within MVBs to the extracellular environment. Several proteins regulate the targeting of cargo to MVBs. Studies that delineated the functions of AP1 in protein trafficking, focused on complexes containing the ?1 subunit, which mediates transport between trans-Golgi network (TGN) and endosomes. However, the human genome encodes a second isoform of this subunit, named ?2. Evidences from the literature, as well as results from our research group, indicate that AP1?2 regulates transport pathways that are distinct from the pathways classically attributed to AP1. By performing EGF-uptake assays under ?1 or ?2 knockdown (KD) conditions, it was observed that ?2 is required for degradation of internalized EGF, effect also observed for the EGF receptor (EGFR) using cell surface biotinylation assays. These results demonstrate that the lysosomal degradation of the EGFEGFR complexes via the canonical MVBs pathway requires the AP1?2 complex, but not AP1?1. In parallel with this study, we also analyzed the molecular mechanism of HIV-1 Nef targeting to MVBs associated with the EVs release. Nef is an important determinant in the modulation of the intracellular environment for efficient HIV replication and progression to AIDS. Nef is actively secreted via EVs and its release may lead to apoptosis of bystander acceptor cells. Moreover, Nef reduces the levels of CD4 and MHC-I molecules in EVs. Despite the importance of Nef release in EVs, the molecular mechanism used by Nef to be exported via EVs is unknown. Nef physically interacts with the ESCRT machinery accessory protein Alix, an important player in the process of ILVs formation and cargo selection. EVs released from HeLa cells and CD4+ T lymphocytes under Alix KD conditions demonstrated a significant IV reduction in Nef release via EVs. These results indicate that Nef requires Alix for its efficient release in EVs.

Alix

Alix

AP1y1

AP1y1

AP1y2

AP1y2

Complexo EGF-EGFR

EGF-EGFR complex

EVs

EVs

MVB

MVB

Nef

Nef

Estudo da função de AP1y2 e Alix no direcionamento de proteínas para degradação em lisossomos ou liberação em vesículas extracelulares / Study of AP1y2 and Alix function in the targeting of proteins for degradation in lysosomes or release in extracellular vesicles

Mara Elisama da Silva Januário

21 June 2017

A degradação lisossomal de proteínas de membrana endocitadas ocorre por meio do direcionamento destas proteínas para vesículas intralumenais (ILVs), formadas no lúmen dos corpos multivesiculares (MVBs), e subsequente fusão dos MVBs com lisossomos. Apesar de sua importância na degradação de proteínas transmembrana, os MVBs possuem outra importante função, a de produzir e liberar vesículas extracelulares (EVs). Neste processo os MVBs não se fundem com lisossomos, mas sim com a membrana plasmática o que resulta na liberação das vesículas residentes no interior dos MVBs para o meio extracelular. Diversas proteínas participam do direcionamento de cargas para os MVBs. Os estudos que delinearam a via de tráfego mediada por AP1 concentraram-se nos complexos contendo a subunidade ?1 que medeia o transporte de proteínas entre a rede trans-Golgi (TGN) e endossomos. Contudo, o genoma humano codifica uma segunda isoforma desta subunidade, denominada ?2, e evidências presentes na literatura e também observadas por nosso grupo indicam que AP1?2 pode regular uma via de tráfego distinta da via classicamente atribuída a AP1. Utilizando ensaios de uptake de EGF em condições onde foi realizado o KD de ?1 ou ?2, foi observado que o silenciamento de ?2 prejudica a degradação de EGF internalizado por seu receptor. Efeito também observado para o próprio receptor de EGF (EGFR) em ensaios de biotinilação da superfície celular. Demonstrando que a degradação lisossomal do complexo EGF-EGFR pela via canônica dos MVBs requer o complexo AP1?2, mas não AP1?1. Em conjunto com este estudo também foi analisado o mecanismo molecular de direcionamento da proteína Nef do HIV-1 para os MVBs associados a liberação de EVs. A proteína Nef do HIV é determinante na modulação do ambiente intracelular favorecendo a replicação do vírus e progressão à AIDS. Nef é ativamente secretado em EVs e sua liberação pode levar a apoptose de células vizinhas aceptoras dessas vesículas. Nef também medeia a redução dos níveis de CD4 e moléculas de MHC-I em EVs. Ainda não é conhecido o mecanismo molecular utilizado por Nef para ser exportado em EVs, mas sabe-se que Nef interage fisicamente com a proteína II acessória da maquinaria ESCRT, Alix, importante no processo de formação das ILVs e seleção das cargas que serão internalizadas nos MVBs. EVs coletadas de células HeLa e linfócitos T CD4+ silenciados para Alix demostraram reduções significativas na liberação de Nef. Estes resultados indicam que Nef requer Alix para sua eficiente liberação em EVs. / Lysosomal degradation of endocytosed membrane proteins occurs through the targeting of these proteins to intraluminal vesicles (ILVs), formed in the multivesicular bodies (MVBs) lumen, and the subsequent fusion of MVBs with lysosomes. Despite its importance in the degradation of transmembrane proteins, MVBs have another important function, the production and release of extracellular vesicles (EVs). In this process, the MVBs do not fuse with lysosomes, but fuse with the plasma membrane resulting in the release of these vesicles that reside within MVBs to the extracellular environment. Several proteins regulate the targeting of cargo to MVBs. Studies that delineated the functions of AP1 in protein trafficking, focused on complexes containing the ?1 subunit, which mediates transport between trans-Golgi network (TGN) and endosomes. However, the human genome encodes a second isoform of this subunit, named ?2. Evidences from the literature, as well as results from our research group, indicate that AP1?2 regulates transport pathways that are distinct from the pathways classically attributed to AP1. By performing EGF-uptake assays under ?1 or ?2 knockdown (KD) conditions, it was observed that ?2 is required for degradation of internalized EGF, effect also observed for the EGF receptor (EGFR) using cell surface biotinylation assays. These results demonstrate that the lysosomal degradation of the EGFEGFR complexes via the canonical MVBs pathway requires the AP1?2 complex, but not AP1?1. In parallel with this study, we also analyzed the molecular mechanism of HIV-1 Nef targeting to MVBs associated with the EVs release. Nef is an important determinant in the modulation of the intracellular environment for efficient HIV replication and progression to AIDS. Nef is actively secreted via EVs and its release may lead to apoptosis of bystander acceptor cells. Moreover, Nef reduces the levels of CD4 and MHC-I molecules in EVs. Despite the importance of Nef release in EVs, the molecular mechanism used by Nef to be exported via EVs is unknown. Nef physically interacts with the ESCRT machinery accessory protein Alix, an important player in the process of ILVs formation and cargo selection. EVs released from HeLa cells and CD4+ T lymphocytes under Alix KD conditions demonstrated a significant IV reduction in Nef release via EVs. These results indicate that Nef requires Alix for its efficient release in EVs.

Alix

AP1y1

AP1y2

Complexo EGF-EGFR

EVs

MVB

Nef

Alix

AP1y1

AP1y2

EGF-EGFR complex

EVs

MVB

Nef

La protéine Nef du VIH-1 : Contribution des complexes adaptateurs de la voie d'endocytose aux fonctions de Nef / The Nef protein of HIV-1 : Contribution of adapter complexes to the endocytic functions of Nef

Rafie, Salomeh

05 November 2012

La protéine Nef des virus de l’immunodéficience humaine (VIH-1 et VIH-2) joue un rôle essentiel dans la physiopathologie de l’infection et induction du SIDA. La capacité de Nef à perturber le trafic intracellulaire de protéines membranaires, et notamment du récepteur CD4, circulant entre les compartiments de la voie d’endocytose pourrait rendre compte de son importance comme facteur de virulence au cours de l’infection naturelle. Les mécanismes responsables des perturbations de la voie d’endocytose induites par Nef au cours de l’infection ne sont pas totalement élucidés, mais il est admis qu’elles résultent d’interactions avec les complexes adaptateurs (AP) associés à la clathrine et participant au transport vésiculaire entre les différents compartiments de la voie d’endocytose. Notre objectif était de déterminer les mécanismes par lesquels Nef influe positivement sur le pouvoir infectieux du VIH-1 en interagissant avec la machinerie cellulaire de la voie d’endocytose. Notre programme s’est organisé autour de deux axes principaux: le premier a consisté à étudier l’implication respective des différents types de complexes AP (AP-1, -2 et -3) sur les perturbations du fonctionnement de la voie d’endocytose induites par Nef en analysant son impact sur le niveau d’expression de surface de CD4; le deuxième axe a consisté à évaluer l’impact de l’interaction de Nef avec les complexes AP sur les capacités infectieuses des particules virales. Le rôle respectif des différents complexes AP dans ces fonctions de Nef a donc été étudié après déplétion de l’expression des complexes AP-1, AP-2 et AP-3 par une approche d’ARN interférence. Les résultats obtenus montrent que contrairement à certaines données de la littérature, la déplétion des complexes AP de la voie d’endocytose ne semble pas avoir un impact majeur sur la capacité de Nef à moduler l’expression de surface de CD4, même si une légère diminution de l’activité de Nef a pu être révélée dans notre étude réalisée sur des cellules HeLa-CD4 transduites par les shRNA ciblant les complexes AP-2. Inversement, nos résultats confirment que la déplétion des complexes AP-1, AP-2 et AP-3 dans les cellules productrices des particules virales se traduit par une diminution importante des propriétés infectieuses de ces particules sur lesquelles l’impact positif de Nef n’est plus alors capable de se manifester. En conclusion, ce travail a donc permis de montrer que les complexes AP de la voie d’endocytose sont indispensables pour que Nef puisse exercer son rôle positif sur le pouvoir infectieux du VIH-1. Il est maintenant important de confirmer ces résultats en analysant le rôle fonctionnel des complexes AP sur les activités de Nef dans les cibles cellulaires naturelles du VIH-1, lymphocytes et macrophages. / Nef protein of human immunodeficiency virus (HIV-1 and HIV-2) plays an essential role in the pathophysiology of infection and induction of AIDS. The ability of Nef to disrupt intracellular trafficking of membrane proteins, including the CD4 receptor, moving between the compartments of the endocytic pathway could account for its importance as a virulence factor during natural infection. The mechanisms responsible for disruption of the endocytic pathway induced by Nef during infection are not fully understood, but it is accepted that they arise from interactions with adaptor complexes (AP) associated with clathrin and participant in vesicular transport between the different compartments of the endocytic pathway. Our objective was to determine the mechanisms by which Nef positively affects the infectivity of HIV-1 by interacting with the cellular machinery of the endocytic pathway. Our program has been organized around two main axes: the first was to investigate the respective involvement of different types of complexes (AP-1, -2 and -3) on the Nef induced disruption of the endocytic pathway by analyzing its impact on the level of surface expression of CD4; the second axis was to evaluate the impact of the interaction of Nef with AP complexes on the infectious capacity of the viral particles. The respective roles of the different AP complexes in these functions of Nef has been studied after depletion of the expression of complex AP-1, AP-2 and AP-3 by RNA interference approach. The results show that, contrary to some literature data, depletion of AP complex endocytic pathway does not appear to have a major impact on the ability of Nef to modulate the surface expression of CD4, although a slight decreased activity of Nef could be revealed in our study on HeLa-CD4 cells transduced with the shRNA targeting complex AP-2. Conversely, our results confirm that the depletion of complex AP-1, AP-2 and AP-3 in the cells producing viral particles resulted in a significant decrease in infectious properties of these particles on which the positive impact of Nef is no longer able to manifest. In conclusion, this work has shown that complex AP of endocytic pathway are essential for Nef to exercise its positive role in the infectivity of HIV-1. It is now important to confirm these findings by analyzing the functional role of AP complexes on the activities of Nef in the natural cellular targets of HIV-1, lymphocytes and macrophages.

VIH-1

Protéine Nef

CD4

Complexes adaptateurs

Pouvoir infectieux

HIV-1

Nef protein

CD4

Adaptor complex

Infectivity

610

Etude de la spécificité des interactions protéine-protéine : application au complexe Alix-domaine SH3 des Src Kinases / Studies on protein-protein interaction : and its applications in ALIX/SFKs-SH3 complexes

Shi, Xiaoli

10 February 2011

Les domaines SH3 (Src Homology domain) représentent l'un des modules protéiques le plus largement répandu dans la nature. Ils participent à des interactions intra- et intermoléculaires avec d’autre partenaires au travers de la formation et de la dissociation de complexes multi-protéiques. Le gène nef du Virus d'Immunodéficience Humain (VIH-1) code pour la protéine nef, importante pour la réplication du virus et le développement optimal du SIDA (Syndrome d’Immunodéficience Acquise) chez les personnes infectées. De précédentes études ont mis en évidence que la protéine nef utilise un mode « tertiaire » d’interaction pour mettre en place une affinité et une sélectivité élevées envers les domaines SH3 des kinases de la famille Src (SFKs). Savoir si cette stratégie de reconnaissance tertiaire des domaines SH3 peut être retrouvée dans des protéines cellulaires humaines est donc une question importante pour évaluer le degré de spécificité de la protéine nef comme cible anti-HIV. Nous avons identifié Alix (ALG-2 [apoptosis-linked gene 2]-interacting protein X) comme protéine originale interagissant avec le domaine SH3 de la kinase de cellules Hématopoïétique (Hck). Alix possède une sélectivité comparable à nef envers les domaines SH3 de SFKs. Nous avons combiné une analyse biophysique et structurale, alliant des méthodes telles que la microcalorimetrie à titration isotherme(‘ITC’), la Résonance Plasmonique de Surface (‘SPR’), des méthodes in vitro dites de ‘GST pulldown’, l'interférométrie (‘NPOI’), la Résonance Magnétique Nucléaire (‘NMR’ - HSQC) et la diffusion des rayons X aux petits angles (SAXS) pour explorer les caractéristiques définissant le mode d’interaction entre Alix et le domaine SH3 de la kinase Hck. Cette étude démontre que la protéine cellulaire Alix est unique, structurellement différente mais fonctionnellement semblable à nef. / Src homology (SH) 3 domains is one of the most wide-spreaded protein modules found in nature. They mediate both inter- and intra-molecular protein-protein interactions (PPIs) through the formation and dissociation of multi-protein complexes. These SH3-mediated interactions are responsible for signal transduction, cytoskeleton organization and other cellular processes. The nef gene of Human immunodeficiency virus (HIV-1) encodes the HIV-1 Nef protein, which is important for optimal virus replication and development of AIDS (acquired immunize deficiency syndrome) in HIV-1 infected persons. Previous studies show that the HIV-1 Nef protein uses a “tertiary” binding mode to achieve high affinity and selectivity toward SH3 domains of Src-family kinases (SFKs). Whether this strategy of ‘tertiary’ binding mode of SH3 domains can be found in human cellular proteins, besides HIV-1 Nef, is an important question in the specificity of the HIV-1 Nef protein as an anti-HIV target. We identified Alix (ALG-2 [apoptosis-linked gene 2]-interacting protein X) as a novel protein interacting with Hemopoietic cell kinase (Hck) SH3 domain. Alix has similar selectivity towards SH3 domains of SFKs as the HIV-1 Nef. We have combined biophysical and structural biology analysis, including ITC (isothermal titration calorimetry), SPR (surface Plasmon resonance), GST (glutathione S-transferase) pull-down, interferometry, HSQC (heteronuclear single quantum coherence) and SAXS (small-angle X-ray scattering) to explore the characteristics of Alix-SH3 recognition mode. This study shows that Alix as a unique cellular protein, which is structurally different but functionally similar in recognizing HIV-1 Nef. The structural information of the Alix-Hck association facilitates the understanding of how Hck and Alix assist viral budding and cell surface receptor regulation.

Interaction Protéine-Protéine

Vih

Nef

Src Kinase

Domaine SH3

Alix

Protein-Protein Interaction

Hiv

Nef

Src Kinase

SH3 domain

Alix

Approche théorique de la réactivité des isonitriles en chimie organique / Theoretical aspects of the reactivity of isocyanides in organic chemistry

Chéron, Nicolas

18 November 2011

Les isonitriles sont des espèces connues depuis longtemps, mais étudiées depuis peu. Une approche théorique a permis de s'intéresser en détails aux réactions de Nef et de Ugi. Nous nous sommes tout d'abord focalisés sur la première. Après en avoir élucidé le mécanisme, nous avons étudié l'effet du solvant et nous avons proposé de nouvelles conditions expérimentales. Nous avons ensuite étudié l'influence des groupements de l'acyl, de l'isonitrile et du groupe partant. L'ensemble des variations considérées a pu être rationalisé en reliant l'énergie d'activation au pKa du groupe partant. En parallèle, nous avons étudié la réaction de Ugi. Le mécanisme proposé par Ugi pour cette réaction complexe n'avait toujours pas été vérifié 50 ans après sa découverte. Une étude quasi-exhaustive des différents mécanismes possibles a été menée, en utilisant une approche originale mêlant théorie et expériences. Le mécanisme de cette réaction a ainsi été démontré, tant dans le méthanol que dans le toluène. Les étapes cinétiquement déterminantes et les forces motrices ont été mises en lumière et diffèrent de celles proposées par Ugi. Une variation de la réaction de Ugi est le couplage Ugi-Smiles pour lequel de nombreux résultats expérimentaux n'ont toujours pas trouvé d'explications. Nous nous sommes donc intéressés au réarrangement de Smiles. Nous avons montré l'importance d'une liaison hydrogène intramoléculaire sur la faisabilité de la réaction, et nous avons étendu cette observation aux réactions intermoléculaires. Nous avons également étudié l'influence des substituants des quatre réactifs sur les barrières afin de construire un modèle prédictif. / Isocyanides are known for a long time, but have been studied only recently. A theoretical approach allowed us to investigate in details the Nef and the Ugi reactions. We first focused on the former. After elucidating its mechanism, we studied solvent effects and proposed new experimental conditions. We then studied the acyl moiety and isocyanide influences, such as the leaving group one. All the variations were rationalized by linking the activation energy to the leaving group pKa. Simultaneously, we studied the Ugi reaction. The mechanism proposed by Ugi for this complex reaction was still unverified 50 years after its discovery. A thorough and quasi-complete study of all the possible mechanisms were lead, using a mixed theoretical and experimental approach. The mechanism of this reaction was demonstrated, in both methanol and toluene. Rate determining steps and driving forces were highlighted and differ from those proposed by Ugi. A variation of the Ugi reaction is the Ugi-Smiles coupling, for which numerous experimental results are still unexplained. We thus studied the Smiles rearrangement. We showed the key-role of an intramolecular hydrogen bond on the reaction feasibility, and extended this observation to intermolecular reactions. We also studied the four substituent influence on the barrier, aiming to build a predictive model.

Réaction de Nef

Etats de transition

SnAr

DFT

Nef reaction

Transition states

Hydrogen bond

Ugi reaction

Mechanisms

SnAr

DFT