Identification and Characterization of SNAPIN as a Novel Antagonist of HIV-1 Egress: A Dissertation

Younan, Patrick

05 April 2010

Vpu has been shown to possess two distinct roles in the pathogenesis of HIV. First, Vpu has been shown to down-regulate the expression of CD4 molecules at the plasma membrane of infected cells by targeting CD4 molecules for degradation in the endoplasmic reticulum. Second, Vpu promotes viral egress in specific cell lines termed non-permissive cells by mechanism that remain relatively unclear. Therefore, experiments were conducted in order to identify cellular factors involved in the Vpu-dependent phenotype. Using full-length Vpu as bait in yeast two-hybrid experiments, several candidate cellular factors were identified. One protein, SNAPIN, was identified as a cellular factor putatively involved in the Vpu-dependent phenotype. Further experiments determined that not only do SNAPIN and Vpu interact, but that Vpu also leads to the degradation of SNAPIN by both proteasomal and lysosomal degradation pathways. Over-expression of SNAPIN in cell lines that do not normally require Vpu expression for viral production resulted in a Vpu-dependent phenotype. While over-expression of SNAPIN in otherwise permissive cell lines significantly reduced Vpu-deficient virus production, wild type levels remained relatively constant. Importantly, no defective viral structural protein production was observed; however, intracellular p24/p55 did not accumulate suggesting that in SNAPIN expressing cells, Gag is also targeted for degradation. In addition, the reduction of SNAPIN expression in non-permissive cell lines significantly increased viral titers in supernatants. Of particular interest, even in cells expressing Bst-2 (a previously identified cellular factor involved in the Vpu-phenotype), siRNA mediated knockdown of SNAPIN led to increased viral titers. In addition, the co-transfection of siRNAs targeting both SNAPIN and Bst-2 resulted in an additive effect, in which Vpu-deficient viral titers were nearly equivalent to wild-type titers. Surprisingly, siRNA-mediated knockdown of SNAPIN in Jurkat cells was sufficient to overcome any restriction in viral egress imposed by the deletion of Vpu. Conversely, siRNA targeting Bst-2 had little or no effect on viral titers in Jurkat cells regardless of whether it was transfected alone or in combination with siRNAs targeting SNAPIN. These experiments provide evidence of an alternate cellular restriction mechanism involved in viral egress that is countered by the HIV-1 accessory protein, Vpu. In addition, this research may provide further insight into the complex cellular networks involved in the trafficking of Gag through cellular endosomal pathways.

Human Immunodeficiency Virus Proteins

Viral Regulatory and Accessory Proteins

Vesicular Transport Proteins

Genes

vpu

HIV-1

Virus Release

Gene Products

gag

Amino Acids, Peptides, and Proteins

Cells

Genetic Phenomena

Pathology

Viruses

Investigating the Roles of NEDD4.2s and Nef in the Release and Replication of HIV-1: A Dissertation

Weiss, Eric R.

13 September 2012

Replication of HIV-1 requires the assembly and release of mature and infectious viral particles. In order to accomplish this goal, HIV-1 has evolved multiple methods to interact with the host cell. HIV-1 recruits the host cell ESCRT machinery to facilitate the release of nascent viral particles from the host cell membrane. Recruitment of these cellular factors is dependent on the presence of short motifs in Gag referred to as Late-domains. Deletion or mutation of these domains results in substantial decrease in the release of infectious virions. However, previously published work has indicated that over-expression of the E3 ubiquitin ligase, NEDD4.2s is able to robustly rescue release of otherwise budding-defective HIV-1 particles. This rescue is specific to the NEDD4.2s isoform as related E3 ubiquitin ligases display no ability to rescue particle release. In addition, rescue of particle release is dependent on the presence of the partial C2 domain and a catalytically active HECT domain of NEDD4.2s. Here I provide evidence supporting the hypothesis that a partial C2 domain of NEDD4.2s constitutes a Gag interacting module capable of targeting the HECT domains of other E3 ubiquitin ligases to HIV-1 Gag. Also, by generating chimeras between HECT domains shown to form poly-ubiquitin chains linked through either K48 or K63 of ubiquitin, I demonstrate that the ability of NEDD4.2s to catalyze the formation of K63-polyubiquitin chains is required for its stimulation of HIV-1 L-domain mutant particle release. In addition, I present findings from on-going research into the role of the HIV-1 accessory protein Nef during viral replication using the culture T-cell line, MOLT3. My current findings indicate that downregulation of CD4 from the host cell membrane does not solely account for the dramatic dependence of HIV-1 replication on Nef expression in this system. In addition, I present evidence indicating that Nef proteins from diverse HIV-1 Groups and strains are capable of enhancing HIV-1 replication in this system. Analysis of a range of mutations in Nef known to impact interaction with cellular proteins suggest that the observed replication enhancement requires Nef targeting to the host cell membrane and may also require the ability to interact with select Src-kinases. Lastly, we find that the ability of Nef to enhance replication in this system is separate from any increase in viral particle infectivity, in agreement with current literature.

Virus Replication

Virus Release

HIV-1

Ubiquitin-Protein Ligases

nef Gene Products

Human Immunodeficiency Virus

Amino Acids, Peptides, and Proteins

Cells

Enzymes and Coenzymes

Genetic Phenomena

Immunology and Infectious Disease

Microbiology

Virology

Viruses