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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Characterization of moving neurofilaments in cultured neurons

Yan, Yanping 06 January 2006 (has links)
No description available.
2

The essentiality of DivIVA<sub>Ef</sub> oligomerization for proper cell division in <i>enterococcus faecalis</i> and interaction with a novel cell division protein

Hedlin, Cherise Elizabeth 15 April 2009
DivIVA is a Gram-positive cell division protein involved in chromosome segregation, midcell placement of the cell division machinery, complete septum closure, and polar growth and morphogenesis. Although well conserved across various Gram-positive species, DivIVA is believed to be relatively species specific. One similarity among DivIVA homologues is the ability to oligomerize through coiled-coil interaction into complexes comprising 10-12 monomers. To date, the importance of DivIVA oligomerization and the N-terminal coiled-coil for its proper function in bacterial cell division has not been reported. This study examined the biological significance of DivIVA oligomerization and the N-terminal coiled-coil in bacterial cell division. This research provides evidence that the N-terminal coiled-coil and oligomerization is essential for the proper biological function of DivIVA<sub>Ef</sub> in <i>Enterococcus faecalis</i> cell division. Introduction of point mutations into chromosomal <i>divIVA</i><sub>Ef</sub> known to disrupt either the N-terminal coiled-coil or the two central coiled-coils, involved in oligomerization, were found to be lethal unless rescued by <i>in trans</i> expression of wild type DivIVA<sub>Ef</sub>. Using this rescue method, the N-terminal <i>divIVA</i><sub>Ef</sub> mutant strain, <i>E. faecalis</i> MWMR5, and the mutant strain with partial disruption of oligomerization, <i>E. faecalis</i> MWMR10, were successfully rescued. Differential Interference Contrast (DIC) and Transmission Electron Microscopy (TEM) were utilized to determine the phenotypes of <i>divIVA</i><sub>Ef</sub> mutant strains <i>E. faecalis</i> MWMR5 and MWMR10. Both these strains showed asymmetrical division, loss of normal lancet shape, and irregular chains. Full disruption of oligomerization with point mutations in both central coiled-coils resulted in a dominant lethal phenotype. These results demonstrate the essentiality of the N-terminal coiled-coil and oligomerization of DivIVA<sub>Ef</sub> for its proper biological function in <i>E. faecalis</i> cell division.<p> Previous detection of DivIVA interaction with a novel cell division protein, MLJD1, by screening a Yeast Two-Hybrid (Y2H) was weak. GST-pulldown and immunoprecipitation did indicate DivIVA<sub>Ef</sub> interaction with MLJD1, but another in vivo assay was required to support these results. In this study I demonstrate a strong interaction, using an in vivo Bacterial Two-Hybrid (B2H) assay, between DivIVA<sub>Ef</sub> and a fragment of MLJD1 containing two cystathionine-beta-synthase (CBS) domains. The <i>in vitro</i> and <i>in vivo</i> results thus confirm interaction between DivIVA<sub>Ef</sub> and MLJD1.<p> Another objective of this study was to determine the localization of DivIVA and MLJD1 in <i>E. faecalis</i>. Localization of DivIVA<sub>Ef</sub> in <i>E. faecalis</i> was found to be similar to DivIVA localization in <i>Bacillus subtilis</i> and <i>Streptococcus pneumonia</i>. DivIVA<sub>Ef</sub> was diffused along the cell membrane and, as chromosome replication and segregation and cell division proceeded, DivIVA<sub>Ef</sub> migrated to the cell poles and then concurrently to the division site. Intriguingly, MLJD1 was found to localize in the same pattern as DivIVA<sub>Ef</sub> in <i>E. faecalis</i>, further implicating MLJD1 as a bacterial cell division protein.<p> Since MLJD1 has potential DNA binding capabilities a proposed model of its role in cell division has been proposed. I hypothesize that MLJD1 could be forming a bridge between DivIVA<sub>Ef</sub> and the chromosome to aid in proper chromosomal replication and segregation. This model could explain how DivIVA<sub>Ef</sub> is involved in chromosome replication. This model is similar to the role of RacA in sporulation in <i>B. subtilis</i> where RacA directs the chromosome during sporulation through direct interaction with DivIVA<sub>Bs</sub> and Spo0J.<p> This study has set some important and essential ground work for developing a novel model of cell division for the elusive Gram-positive coccal bacterial strains.
3

The essentiality of DivIVA<sub>Ef</sub> oligomerization for proper cell division in <i>enterococcus faecalis</i> and interaction with a novel cell division protein

Hedlin, Cherise Elizabeth 15 April 2009 (has links)
DivIVA is a Gram-positive cell division protein involved in chromosome segregation, midcell placement of the cell division machinery, complete septum closure, and polar growth and morphogenesis. Although well conserved across various Gram-positive species, DivIVA is believed to be relatively species specific. One similarity among DivIVA homologues is the ability to oligomerize through coiled-coil interaction into complexes comprising 10-12 monomers. To date, the importance of DivIVA oligomerization and the N-terminal coiled-coil for its proper function in bacterial cell division has not been reported. This study examined the biological significance of DivIVA oligomerization and the N-terminal coiled-coil in bacterial cell division. This research provides evidence that the N-terminal coiled-coil and oligomerization is essential for the proper biological function of DivIVA<sub>Ef</sub> in <i>Enterococcus faecalis</i> cell division. Introduction of point mutations into chromosomal <i>divIVA</i><sub>Ef</sub> known to disrupt either the N-terminal coiled-coil or the two central coiled-coils, involved in oligomerization, were found to be lethal unless rescued by <i>in trans</i> expression of wild type DivIVA<sub>Ef</sub>. Using this rescue method, the N-terminal <i>divIVA</i><sub>Ef</sub> mutant strain, <i>E. faecalis</i> MWMR5, and the mutant strain with partial disruption of oligomerization, <i>E. faecalis</i> MWMR10, were successfully rescued. Differential Interference Contrast (DIC) and Transmission Electron Microscopy (TEM) were utilized to determine the phenotypes of <i>divIVA</i><sub>Ef</sub> mutant strains <i>E. faecalis</i> MWMR5 and MWMR10. Both these strains showed asymmetrical division, loss of normal lancet shape, and irregular chains. Full disruption of oligomerization with point mutations in both central coiled-coils resulted in a dominant lethal phenotype. These results demonstrate the essentiality of the N-terminal coiled-coil and oligomerization of DivIVA<sub>Ef</sub> for its proper biological function in <i>E. faecalis</i> cell division.<p> Previous detection of DivIVA interaction with a novel cell division protein, MLJD1, by screening a Yeast Two-Hybrid (Y2H) was weak. GST-pulldown and immunoprecipitation did indicate DivIVA<sub>Ef</sub> interaction with MLJD1, but another in vivo assay was required to support these results. In this study I demonstrate a strong interaction, using an in vivo Bacterial Two-Hybrid (B2H) assay, between DivIVA<sub>Ef</sub> and a fragment of MLJD1 containing two cystathionine-beta-synthase (CBS) domains. The <i>in vitro</i> and <i>in vivo</i> results thus confirm interaction between DivIVA<sub>Ef</sub> and MLJD1.<p> Another objective of this study was to determine the localization of DivIVA and MLJD1 in <i>E. faecalis</i>. Localization of DivIVA<sub>Ef</sub> in <i>E. faecalis</i> was found to be similar to DivIVA localization in <i>Bacillus subtilis</i> and <i>Streptococcus pneumonia</i>. DivIVA<sub>Ef</sub> was diffused along the cell membrane and, as chromosome replication and segregation and cell division proceeded, DivIVA<sub>Ef</sub> migrated to the cell poles and then concurrently to the division site. Intriguingly, MLJD1 was found to localize in the same pattern as DivIVA<sub>Ef</sub> in <i>E. faecalis</i>, further implicating MLJD1 as a bacterial cell division protein.<p> Since MLJD1 has potential DNA binding capabilities a proposed model of its role in cell division has been proposed. I hypothesize that MLJD1 could be forming a bridge between DivIVA<sub>Ef</sub> and the chromosome to aid in proper chromosomal replication and segregation. This model could explain how DivIVA<sub>Ef</sub> is involved in chromosome replication. This model is similar to the role of RacA in sporulation in <i>B. subtilis</i> where RacA directs the chromosome during sporulation through direct interaction with DivIVA<sub>Bs</sub> and Spo0J.<p> This study has set some important and essential ground work for developing a novel model of cell division for the elusive Gram-positive coccal bacterial strains.
4

O envolvimento da proteína adaptadora 1 (AP-1) no mecanismo de regulação negativa do receptor CD4 por Nef de HIV-1 / The involvement of Adaptor Protein 1 (AP-1) on the Mechanism of CD4 Down-regulation by Nef from HIV-1

Tavares, Lucas Alves 05 August 2016 (has links)
O Vírus da Imunodeficiência Humana (HIV) é o agente etiológico da Síndrome da Imunodeficiência Adquirida (AIDS). A AIDS é uma doença de distribuição mundial, e estima-se que existam atualmente pelo menos 36,9 milhões de pessoas infectadas com o vírus. Durante o seu ciclo replicativo, o HIV promove diversas alterações na fisiologia da célula hospedeira a fim de promover sua sobrevivência e potencializar a replicação. A rápida progressão da infecção pelo HIV-1 em humanos e em modelos animais está intimamente ligada à função da proteína acessória Nef. Dentre as diversas ações de Nef está a regulação negativa de proteínas importantes na resposta imunológica, como o receptor CD4. Sabe-se que esta ação resulta da indução da degradação de CD4 em lisossomos, mas os mecanismos moleculares envolvidos ainda são totalmente elucidados. Nef forma um complexo tripartite com a cauda citosólica de CD4 e a proteína adaptadora 2 (AP-2), em vesículas revestidas por clatrina nascentes, induzindo a internalização e degradação lisossomal de CD4. Pesquisas anteriores demonstraram que o direcionamento de CD4 aos lisossomos por Nef envolve a entrada do receptor na via dos corpos multivesiculares (MVBs), por um mecanismo atípico, pois, embora não necessite da ubiquitinação de carga, depende da ação de proteínas que compõem os ESCRTs (Endosomal Sorting Complexes Required for Transport) e da ação de Alix, uma proteína acessória da maquinaria ESCRT. Já foi reportado que Nef interage com subunidades dos complexos AP-1, AP-2, AP-3 e Nef não parece interagir com subunidades de AP-4 e AP-5. Entretanto, o papel da interação de Nef com AP-1 e AP-3 na regulação negativa de CD4 ainda não está totalmente elucidado. Ademais, AP-1, AP-2 e AP-3 são potencialmente heterogêneos devido à existência de isoformas múltiplas das subunidades codificadas por diferentes genes. Todavia, existem poucos estudos para demonstrar se as diferentes combinações de isoformas dos APs são formadas e se possuem propriedades funcionais distintas. O presente trabalho procurou identificar e caracterizar fatores celulares envolvidos na regulação do tráfego intracelular de proteínas no processo de regulação negativa de CD4 induzido por Nef. Mais especificamente, este estudo buscou caracterizar a participação do complexo AP-1 na modulação negativa de CD4 por Nef de HIV-1, através do estudo funcional das duas isoformas de ?-adaptina, subunidades de AP-1. Utilizando a técnica de Pull-down demonstramos que Nef é capaz de interagir com ?2. Além disso, nossos dados de Imunoblot indicaram que a proteína ?2-adaptina, e não ?1-adaptina, é necessária no processo de degradação lisossomal de CD4 por Nef e que esta participação é conservada para degradação de CD4 por Nef de diferentes cepas virais. Ademais, por citometria de fluxo, o silenciamento de ?2, e não de ?1, compromete a diminuição dos níveis de CD4 por Nef da membrana plasmática. A análise por imunofluorêsncia indireta também revelou que a diminuição dos níveis de ?2 impede a redistribuição de CD4 por Nef para regiões perinucleares, acarretando no acúmulo de CD4, retirados por Nef da membrana plasmática, em endossomos primários. A depleção de ?1A, outra subunidade de AP-1, acarretou na diminuição dos níveis celulares de ?2 e ?1, bem como, no comprometimento da eficiente degradação de CD4 por Nef. Além disso, foi possível observar que, ao perturbar a maquinaria ESCRT via super-expressão de HRS (uma subunidade do complexo ESCRT-0), ocorreu um acumulo de ?2 em endossomos dilatados contendo HRS-GFP, nos quais também detectou-se CD4 que foi internalizado por Nef. Em conjunto, os resultados indicam que ?2-adaptina é uma importante molécula para o direcionamento de CD4 por Nef para a via ESCRT/MVB, mostrando ser uma proteína relevante no sistema endo-lisossomal. Ademais, os resultados indicaram que as isoformas ?-adaptinas não só possuem funções distintas, mas também parecem compor complexos AP-1 com diferentes funções celulares, já que apenas a variante AP-1 contendo ?2, mas não ?1, participa da regulação negativa de CD4 por Nef. Estes estudos contribuem para o melhor entendimento dos mecanismos moleculares envolvidos na atividade de Nef, que poderão também ajudar na melhor compreensão da patogênese do HIV e da síndrome relacionada. Em adição, este trabalho contribui para o entendimento de processos fundamentais da regulação do tráfego de proteínas transmembrana no sistema endo-lisossomal. / The Human Immunodeficiency Virus (HIV) is the etiologic agent of Acquired Immunodeficiency Syndrome (AIDS). AIDS is a disease which has a global distribution, and it is estimated that there are currently at least 36.9 million people infected with the virus. During the replication cycle, HIV promotes several changes in the physiology of the host cell to promote their survival and enhance replication. The fast progression of HIV-1 in humans and animal models is closely linked to the function of an accessory protein Nef. Among several actions of Nef, one is the most important is the down-regulation of proteins from the immune response, such as the CD4 receptor. It is known that this action causes CD4 degradation in lysosome, but the molecular mechanisms are still incompletely understood. Nef forms a tripartite complex with the cytosolic tail of the CD4 and adapter protein 2 (AP-2) in clathrin-coated vesicles, inducing CD4 internalization and lysosome degradation. Previous research has demonstrated that CD4 target to lysosomes by Nef involves targeting of this receptor to multivesicular bodies (MVBs) pathway by an atypical mechanism because, although not need charging ubiquitination, depends on the proteins from ESCRTs (Endosomal Sorting Complexes Required for Transport) machinery and the action of Alix, an accessory protein ESCRT machinery. It has been reported that Nef interacts with subunits of AP- 1, AP-2, AP-3 complexes and Nef does not appear to interact with AP-4 and AP-5 subunits. However, the role of Nef interaction with AP-1 or AP-3 in CD4 down-regulation is poorly understood. Furthermore, AP-1, AP-2 and AP-3 are potentially heterogeneous due to the existence of multiple subunits isoforms encoded by different genes. However, there are few studies to demonstrate if the different combinations of APs isoforms are form and if they have distinct functional properties. This study aim to identify and characterize cellular factors involved on CD4 down-modulation induced by Nef from HIV-1. More specifically, this study aimed to characterize the involvement of AP-1 complex in the down-regulation of CD4 by Nef HIV-1 through the functional study of the two isoforms of ?-adaptins, AP-1 subunits. By pull-down technique, we showed that Nef is able to interact with ?2. In addition, our data from immunoblots indicated that ?2- adaptin, not ?1-adaptin, is required in Nef-mediated targeting of CD4 to lysosomes and the ?2 participation in this process is conserved by Nef from different viral strains. Furthermore, by flow cytometry assay, ?2 depletion, but not ?1 depletion, compromises the reduction of surface CD4 levels induced by Nef. Immunofluorescence microscopy analysis also revealed that ?2 depletion impairs the redistribution of CD4 by Nef to juxtanuclear region, resulting in CD4 accumulation in primary endosomes. Knockdown of ?1A, another subunit of AP-1, resulted in decreased cellular levels of ?1 and ?2 and, compromising the efficient CD4 degradation by Nef. Moreover, upon artificially stabilizing ESCRT-I in early endosomes, via overexpression of HRS, internalized CD4 accumulates in enlarged HRS-GFP positive endosomes, where co-localize with ?2. Together, the results indicate that ?2-adaptin is a molecule that is essential for CD4 targeting by Nef to ESCRT/MVB pathway, being an important protein in the endo-lysosomal system. Furthermore, the results indicate that ?-adaptins isoforms not only have different functions, but also seem to compose AP-1 complex with distinct cell functions, and only the AP-1 variant comprising ?2, but not ?1, acts in the CD4 down-regulation induced by Nef. These studies contribute to a better understanding on the molecular mechanisms involved in Nef activities, which may also help to improve the understanding of the HIV pathogenesis and the related syndrome. In addition, this work contributes with the understanding of primordial process regulation on intracellular trafficking of transmembrane proteins.
5

O envolvimento da proteína adaptadora 1 (AP-1) no mecanismo de regulação negativa do receptor CD4 por Nef de HIV-1 / The involvement of Adaptor Protein 1 (AP-1) on the Mechanism of CD4 Down-regulation by Nef from HIV-1

Lucas Alves Tavares 05 August 2016 (has links)
O Vírus da Imunodeficiência Humana (HIV) é o agente etiológico da Síndrome da Imunodeficiência Adquirida (AIDS). A AIDS é uma doença de distribuição mundial, e estima-se que existam atualmente pelo menos 36,9 milhões de pessoas infectadas com o vírus. Durante o seu ciclo replicativo, o HIV promove diversas alterações na fisiologia da célula hospedeira a fim de promover sua sobrevivência e potencializar a replicação. A rápida progressão da infecção pelo HIV-1 em humanos e em modelos animais está intimamente ligada à função da proteína acessória Nef. Dentre as diversas ações de Nef está a regulação negativa de proteínas importantes na resposta imunológica, como o receptor CD4. Sabe-se que esta ação resulta da indução da degradação de CD4 em lisossomos, mas os mecanismos moleculares envolvidos ainda são totalmente elucidados. Nef forma um complexo tripartite com a cauda citosólica de CD4 e a proteína adaptadora 2 (AP-2), em vesículas revestidas por clatrina nascentes, induzindo a internalização e degradação lisossomal de CD4. Pesquisas anteriores demonstraram que o direcionamento de CD4 aos lisossomos por Nef envolve a entrada do receptor na via dos corpos multivesiculares (MVBs), por um mecanismo atípico, pois, embora não necessite da ubiquitinação de carga, depende da ação de proteínas que compõem os ESCRTs (Endosomal Sorting Complexes Required for Transport) e da ação de Alix, uma proteína acessória da maquinaria ESCRT. Já foi reportado que Nef interage com subunidades dos complexos AP-1, AP-2, AP-3 e Nef não parece interagir com subunidades de AP-4 e AP-5. Entretanto, o papel da interação de Nef com AP-1 e AP-3 na regulação negativa de CD4 ainda não está totalmente elucidado. Ademais, AP-1, AP-2 e AP-3 são potencialmente heterogêneos devido à existência de isoformas múltiplas das subunidades codificadas por diferentes genes. Todavia, existem poucos estudos para demonstrar se as diferentes combinações de isoformas dos APs são formadas e se possuem propriedades funcionais distintas. O presente trabalho procurou identificar e caracterizar fatores celulares envolvidos na regulação do tráfego intracelular de proteínas no processo de regulação negativa de CD4 induzido por Nef. Mais especificamente, este estudo buscou caracterizar a participação do complexo AP-1 na modulação negativa de CD4 por Nef de HIV-1, através do estudo funcional das duas isoformas de ?-adaptina, subunidades de AP-1. Utilizando a técnica de Pull-down demonstramos que Nef é capaz de interagir com ?2. Além disso, nossos dados de Imunoblot indicaram que a proteína ?2-adaptina, e não ?1-adaptina, é necessária no processo de degradação lisossomal de CD4 por Nef e que esta participação é conservada para degradação de CD4 por Nef de diferentes cepas virais. Ademais, por citometria de fluxo, o silenciamento de ?2, e não de ?1, compromete a diminuição dos níveis de CD4 por Nef da membrana plasmática. A análise por imunofluorêsncia indireta também revelou que a diminuição dos níveis de ?2 impede a redistribuição de CD4 por Nef para regiões perinucleares, acarretando no acúmulo de CD4, retirados por Nef da membrana plasmática, em endossomos primários. A depleção de ?1A, outra subunidade de AP-1, acarretou na diminuição dos níveis celulares de ?2 e ?1, bem como, no comprometimento da eficiente degradação de CD4 por Nef. Além disso, foi possível observar que, ao perturbar a maquinaria ESCRT via super-expressão de HRS (uma subunidade do complexo ESCRT-0), ocorreu um acumulo de ?2 em endossomos dilatados contendo HRS-GFP, nos quais também detectou-se CD4 que foi internalizado por Nef. Em conjunto, os resultados indicam que ?2-adaptina é uma importante molécula para o direcionamento de CD4 por Nef para a via ESCRT/MVB, mostrando ser uma proteína relevante no sistema endo-lisossomal. Ademais, os resultados indicaram que as isoformas ?-adaptinas não só possuem funções distintas, mas também parecem compor complexos AP-1 com diferentes funções celulares, já que apenas a variante AP-1 contendo ?2, mas não ?1, participa da regulação negativa de CD4 por Nef. Estes estudos contribuem para o melhor entendimento dos mecanismos moleculares envolvidos na atividade de Nef, que poderão também ajudar na melhor compreensão da patogênese do HIV e da síndrome relacionada. Em adição, este trabalho contribui para o entendimento de processos fundamentais da regulação do tráfego de proteínas transmembrana no sistema endo-lisossomal. / The Human Immunodeficiency Virus (HIV) is the etiologic agent of Acquired Immunodeficiency Syndrome (AIDS). AIDS is a disease which has a global distribution, and it is estimated that there are currently at least 36.9 million people infected with the virus. During the replication cycle, HIV promotes several changes in the physiology of the host cell to promote their survival and enhance replication. The fast progression of HIV-1 in humans and animal models is closely linked to the function of an accessory protein Nef. Among several actions of Nef, one is the most important is the down-regulation of proteins from the immune response, such as the CD4 receptor. It is known that this action causes CD4 degradation in lysosome, but the molecular mechanisms are still incompletely understood. Nef forms a tripartite complex with the cytosolic tail of the CD4 and adapter protein 2 (AP-2) in clathrin-coated vesicles, inducing CD4 internalization and lysosome degradation. Previous research has demonstrated that CD4 target to lysosomes by Nef involves targeting of this receptor to multivesicular bodies (MVBs) pathway by an atypical mechanism because, although not need charging ubiquitination, depends on the proteins from ESCRTs (Endosomal Sorting Complexes Required for Transport) machinery and the action of Alix, an accessory protein ESCRT machinery. It has been reported that Nef interacts with subunits of AP- 1, AP-2, AP-3 complexes and Nef does not appear to interact with AP-4 and AP-5 subunits. However, the role of Nef interaction with AP-1 or AP-3 in CD4 down-regulation is poorly understood. Furthermore, AP-1, AP-2 and AP-3 are potentially heterogeneous due to the existence of multiple subunits isoforms encoded by different genes. However, there are few studies to demonstrate if the different combinations of APs isoforms are form and if they have distinct functional properties. This study aim to identify and characterize cellular factors involved on CD4 down-modulation induced by Nef from HIV-1. More specifically, this study aimed to characterize the involvement of AP-1 complex in the down-regulation of CD4 by Nef HIV-1 through the functional study of the two isoforms of ?-adaptins, AP-1 subunits. By pull-down technique, we showed that Nef is able to interact with ?2. In addition, our data from immunoblots indicated that ?2- adaptin, not ?1-adaptin, is required in Nef-mediated targeting of CD4 to lysosomes and the ?2 participation in this process is conserved by Nef from different viral strains. Furthermore, by flow cytometry assay, ?2 depletion, but not ?1 depletion, compromises the reduction of surface CD4 levels induced by Nef. Immunofluorescence microscopy analysis also revealed that ?2 depletion impairs the redistribution of CD4 by Nef to juxtanuclear region, resulting in CD4 accumulation in primary endosomes. Knockdown of ?1A, another subunit of AP-1, resulted in decreased cellular levels of ?1 and ?2 and, compromising the efficient CD4 degradation by Nef. Moreover, upon artificially stabilizing ESCRT-I in early endosomes, via overexpression of HRS, internalized CD4 accumulates in enlarged HRS-GFP positive endosomes, where co-localize with ?2. Together, the results indicate that ?2-adaptin is a molecule that is essential for CD4 targeting by Nef to ESCRT/MVB pathway, being an important protein in the endo-lysosomal system. Furthermore, the results indicate that ?-adaptins isoforms not only have different functions, but also seem to compose AP-1 complex with distinct cell functions, and only the AP-1 variant comprising ?2, but not ?1, acts in the CD4 down-regulation induced by Nef. These studies contribute to a better understanding on the molecular mechanisms involved in Nef activities, which may also help to improve the understanding of the HIV pathogenesis and the related syndrome. In addition, this work contributes with the understanding of primordial process regulation on intracellular trafficking of transmembrane proteins.

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