Vpu: a multifunctional protein that enhances the pathogenesis of human immunodeficiency virus type 1.

The Vpu protein is the smallest of the proteins encoded by human immunodeficiency virus type 1 (HIV-1). This transmembrane protein interacts with the CD4 molecule in the rough endoplasmic reticulum (RER), resulting in its degradation via the proteasome pathway. Vpu also has been shown to enhance virion release from infected cells. While much has been learned about the function of Vpu in cell culture systems, its exact role in HIV-1 pathogenesis is still unknown. This has been primarily due to the lack of a suitable primate model system since vpu is found only in HIV-1 and simian immunodeficiency viruses isolated from chimpanzees (SIVcpz), and three species of old world monkeys within the genus Cercopithecus. Several laboratories have developed pathogenic molecular clones of simian-human immunodeficiency virus (SHIV) in which the tat, rev, vpu and env genes of HIV-1 are expressed in the genetic background of SIV. The availability of such clones has allowed investigators to assess the role of Vpu in pathogenesis using a relevant animal model. This review will focus on the current understanding of the structure-function relationships of Vpu protein and recent advances using the SHIV model to assess the role of Vpu in HIV-1 pathogenesis.

Presence of Intact vpu and nef genes in nonpathogenic SHIV is essential for acquisition of pathogenicity of this virus by serial passage in macaques.

Use of the macaque model of human immunodeficiency virus (HIV) pathogenesis has shown that the accessory genes nef and vpu are important in the pathogenicity of simian immunodeficiency virus (SIV) and simian-human immunodeficiency virus (SHIV). We examined the ability of two nonpathogenic SHIVs, SHIV(PPC) and DeltavpuDeltanefSHIV(PPC), to gain pathogenicity by rapid serial passage in macaques. In this study, each virus was passaged by blood intravenously four times at 4-week intervals in macaques. Animals were monitored for 40 weeks for levels of CD4 T cells and quantitative measures of virus infection. DeltavpuDeltanefSHIV(PPC) maintained a limited phase of productive replication in the four animals, with no loss of CD4(+) T cells, whereas SHIV(PPC) became more pathogenic in later passages, judging by plasma viral load and viral mRNA in lymph nodes, infectious peripheral blood mononuclear cells and CD4(+) T cell loss. The nef, LTR, and env of the SHIV(PPC) viruses underwent numerous mutations, compared to DeltavpuDeltanefSHIV(PPC). This study confirms the seminal role that nef, LTR, and vpu could play in regulation of pathogenesis of HIV infection.

[The function of accessory genes of HIV-1].

Human immunodeficiency virus type 1 (HIV-1) has 4 auxiliary genes, vpr, vpu, nef, and vif, which are dispensable for viral replication in vitro. However, many studies with animal model revealed that these genes play important roles on the viral replication and the development of AIDS in vivo through many complicated mechanisms. Although several key factors involved in the function have been identified, further studies are required for the complete understandings of the action mechanisms. The elucidation of the function of the auxiliary genes on molecular bases leads to the discovery of new therapeutic strategies against HIV and the understanding of basic cellular mechanisms. In this review, we summarize new observations mainly about the interactions between auxiliary genes and host cell functions.

HIV-1 replication in CD4+ T cell lines: the effects of adaptation on co-receptor use, tropism, and accessory gene function.

We studied the replication of HIV-1 macrophage-tropic CCR5-using strains (R5) in CD4+ T cell lines to better understand the switch in co-receptor use of such strains during disease progression and to assess resulting changes in cell tropism. We found that the majority of R5 strains cannot replicate in CD4+ T cell lines without adaptation by serial passage. A small minority of primary R5 isolates, however, were able to infect two T cell lines, Molt4 and SupT1. This expanded tropism was due to the use of undetectable levels of CCR5 rather than CXCR4 or alternative receptors. In contrast, HIV-1sF162 adaptation for replication in the C8166 T cell line was due to the emergence of variant strains that could use CXCR4. Of two variants, one was dual-tropic and one T-tropic, although both could use CCR5 as well as CXCR4. A single mutation in the start codon of the accessory gene vpu accounted for the T-tropic phenotype of the second variant, indicating that a non-functional vpu impairs macrophage tropism. Thus, in vitro and in the absence of an immune response, R5 strains naturally adapt to infect CXCR4+ T cell lines. Such adaptation resembles the rare R5 to X4 switch that occurs in vivo. Mutations in accessory genes (e.g., vpu) not required for replication in rapidly dividing cell lines may also occur in vitro, abrogating replication in primary cell types such as macrophages. Such mutations, however, are normally selected against in vivo.

Aspectos biomoleculares de la infección por el virus de la inmunodeficiencia humana / Biomolecular aspects of the human immunodeficiency virus infection

El presente artículo de revisión se centra en las consideraciones fundamentales sobre la biología molecular del virus de la inmunodeficiencia humana, el principal de los retrovirus que infectan a los hombres, destacando sus aspectos constitutivos así como genéticos y las alteraciones con la célula huésped. Se presenta además los aspectos morfofuncionales básicos de los linfocitos T CD4 y las interacciones que a nivel de membrana se producen para favorecer la infección por el virus y que explican su fisiopatología. Finalmente, se destacan los eventos intracelulares que conducen a la replicación y ensamblaje viral que producen la muerte celular y explican la inmunosupresión del huésped

Control of human immunodeficiency virus replication by the tat, rev, nef and protease genes.

Immediately after infection, human immunodeficiency virus directs the synthesis of three regulatory proteins tat, rev and nef that together allow the synthesis of the structural proteins of the virus after a delay of several hours. Viral mRNA production is controlled by the tat gene, which appears to stimulate elongation by RNA polymerase II, and the rev gene, which allows the accumulation of unspliced or partially spliced mRNAs in the cytoplasm. The nef gene is dispensible for virus growth but may limit virus spread by downregulating the levels of cellular surface proteins such as the CD4 receptor. Virus maturation also depends critically on the protease gene which allows the orderly rearrangement of the viral core structures in newly budded virions as well as the vpu and vif genes which allow efficient production of mature envelope glycoprotein.

Molecular biology of the human immunodeficiency virus type 1.

The immunodeficiency virus type 1 is a complex retrovirus. In addition to genes that specify the proteins of the virus particle and the replicative enzymes common to all retroviruses, HIV-1 specifies at least six additional proteins that regulate the virus life cycle. Two of these regulatory genes, tat and rev, specify proteins essential for replication. These proteins bind to specific sequences of newly synthesized virus RNA and profoundly affect virus protein expression. Tat and rev appear to be prototypes of novel eukaryotic regulatory proteins. These two genes may play a central role in regulating the rate of virus replication. Three other viral genes, vif, vpu, and vpr, affect the assembly and replication capacity of newly made virus particles. These genes may play a critical role in spread of the virus from tissue to tissue and from person to person. Our understanding of the contribution of each of the virus structural proteins and regulatory genes to the complex life cycle of the virus in natural infections is incomplete. However, enough insight has been gained into the structure and function of each of these components to provide a firm basis for rational antiviral drug development.