HIV-1 Nef in Macrophage-Mediated Disease Pathogenesis

Combined anti-retroviral therapy (cART) has significantly reduced the number of AIDS-associated illnesses and changed the course of HIV-1 disease in developed countries. Despite the ability of cART to maintain high CD4+ T-cell counts, a number of macrophage-mediated diseases can still occur in HIV-infected subjects. These diseases include lymphoma, metabolic diseases, and HIV-associated neurological disorders. Within macrophages, the HIV-1 regulatory protein “Nef” can modulate surface receptors, interact with signaling pathways, and promote specific environments that contribute to each of these pathologies. Moreover, genetic variation in Nef may also guide the macrophage response. Herein, we review findings relating to the Nef–macrophage interaction and how this relationship contributes to disease pathogenesis.     

HIV-1 Nef通过Erk/Mapk途径调节内皮细胞黏附分子ICAM-1的表达

目的:研究HIV-1Nef基因对内皮细胞ECV304细胞ICAM-1表达的影响及其信号途径。方法:选用Nef基因稳定表达细胞株ECV304-Nef和对照细胞株ECV304pcDNA3.1(+),应用Westernblot分析ECV304-Nef细胞ERK的磷酸化水平,利用ERK磷酸化抑制剂通过Westernblot、流式细胞术分析ECV304-Nef细胞ICAM-1的表达水平与信号分子ERK磷酸化的相关性。结果:Westernblot显示ECV304-Nef细胞ICAM-1和p-ERK蛋白的表达水平均高于对照组;流式细胞术检测结果表明ECV304-Nef细胞和对照组ICAM-1阳性细胞百分率分别为(35.3±2.2)%和(12.5±0.8)%(P0.01)。加入p-ERK抑制剂PD98059后,ECV304-Nef细胞p-ERK水平被显著抑制,ICAM-1降至对照组水平,ECV304-Nef细胞和对照组细胞ICAM-1阳性细胞百分率分别为(11.4±1.1)%和(10.4±1.5)%(P0.05)。结论:HIV-1Nef基因上调血管内皮细胞细胞黏附分子ICAM-1的表达与ERK信号分子磷酸化有关,为HIV-1感染的致病机制及临床治疗提供实验基础。     

HIV-1Nef调节内皮细胞黏附分子ICAM-1的表达

目的研究HIV-1的调节基因Nef对ECV304细胞ICAM-1表达的影响,从而为分析HIV-1感染引起内皮细胞生物学活性的变化,以及为阐明Nef参与HIV-1致病的分子机制奠定基础。方法应用本实验室已经建立保存的HIV-1Nef基因在内皮细胞的稳定表达细胞株ECV304-Nef和其阴性对照细胞株ECV304 pcDNA 3.1(+),通过RT-PCR、实时定量PCR(real-time PCR)、Western blot、FCM和细胞黏附试验分析ECV304-Nef细胞ICAM-1的表达水平。结果 RT-PCR、real-time PCR结果显示ECV304-Nef细胞ICAM-1 mRNA表达水平明显升高,为对照组的(4.3±0.2)倍;Western blot结果示ECV304-Nef细胞I-CAM-1蛋白的表达水平高于对照组;FCM分析显示ECV304-Nef细胞和对照组细胞ICAM-1阳性细胞百分率分别为(35.3±2.2)%和(12.5±0.8)%(P0.01),两组间ICAM-1表达有显著差异。细胞黏附实验观察到ECV304-Nef细胞黏附的Jurkat细胞数明显多于对照组,荧光仪定量分析结果显示ECV304-Nef细胞黏附的Jurkat细胞的荧光强度值显著高与对照组(P0.05)。结论本实验证实了HIV-1Nef基因可以上调血管内皮细胞细胞黏附分子ICAM-1的表达。     

HIV-1 Nef binding protein expressed on the surface of murine blood cells

The Nef protein of HIV-1 binds to and induces apoptotic cytolysis of a broad spectrum of uninfected blood cells of humans and mice independently of CD95 (Fas). A 24-kDa glycoprotein responsible for Nef binding and the Nef-induced apoptosis has been identified on the surface of human CD4⁺ T cells. Using mouse monoclonal antibodies (mAbs) against the human Nef-binding protein and flow cytometry, we analyzed the expression of a corresponding protein on murine cells. The mAbs were shown to bind to the surface of various murine cell lines including T and B lymphocytes and macrophages, in a fashion similar to the binding by soluble Nef protein. The mAbs competed with the Nef protein in binding to the cell surfaces. Immunoprecipitation of cell membranes revealed a 25-kDa protein recognized by the mAbs. Treatment of the soluble Nef protein with anti-Nef (C terminus) mAb, but not anti-Nef (N terminus) mAb, deprived the Nef of the cell binding activity, indicating that binding site is located in the C-terminal domain. Cross-linking of the cell-bound mAbs with secondary antibodies induced apoptotic cytolysis, which occurred independently of CD95 (Fas). On the other hand, neither the mAbs nor the soluble Nef protein reacted with primary lymphocytes in a resting stage obtained from lymph nodes, thymus and spleen of 5-week-old mice. However, some of the cells, predominantly comprising CD4⁺ T cells, became positive for the both reactions after mitogenic stimulation with phytohemagglutinin, concanavalin A or lipopolysaccharide of Escherichia coli. These results suggest that the 25-kDa protein on murine cell surfaces corresponds to the human Nef binding protein and is responsible for the Nef-induced apoptosis, and that its expression on the cell surface depends on cellular activation. Received: 23 December 1997     

Consequences of HLA-associated mutations in HIV-1 subtype C Nef on HLA-I downregulation ability

Identification of CD8+ T lymphocyte (CTL) escape mutations that compromise the pathogenic functions of the Nef protein may be relevant for an HIV-1 attenuation-based vaccine. Previously, HLA-associated mutations 102H, 105R, 108D, and 199Y were individually statistically associated with decreased Nef-mediated HLA-I downregulation ability in a cohort of 298 HIV-1 subtype C infected individuals. In the present study, these mutations were introduced by site-directed mutagenesis into different patient-derived Nef sequence backgrounds of high similarity to the consensus C Nef sequence, and their ability to downregulate HLA-I was measured by flow cytometry in a CEM-derived T cell line. A substantial negative effect of 199Y on HLA-I downregulation and Nef expression was observed, while 102H and 105R displayed negative effects on HLA-I downregulation ability and Nef expression to a lesser extent. The total magnitude of CTL responses in individuals harboring the 199Y mutation was lower than those without the mutation, although this was not statistically significant. Overall, a modest positive relationship between Nef-mediated HLA-I downregulation ability and total magnitude of CTL responses was observed, suggesting that there is a higher requirement for HLA-I downregulation with increased CTL pressure. These results highlight a region of Nef that could be targeted by vaccine-induced CTL to reduce HLA-I downregulation and maximize CTL efficacy.     

HIV-1 Nef基因在THP-1细胞的表达和活性检测

目的将HIV-1 Nef基因转染THP-1细胞,获得稳定表达Nef蛋白的细胞克隆,为研究Nef对巨噬细胞生物学活性的影响奠定实验基础。方法将质粒pcDNA3.1(+)-Nef和pcDNA3.1(+()阴性对照)转染THP-1细胞,通过逆转录-聚合酶链反应(RT-PCR)、Western blot、细胞免疫荧光等方法检测目的蛋白在真核细胞内的表达及定位,采用共转染法将荧光报告基因转染THP-1Nef和THP-13.1细胞,通过测定荧光(RLU)值来评价Nef蛋白的生物学活性。结果转染细胞经G418筛选后获得稳定表达Nef的THP-1细胞株,RT-PCR及Western blot结果表明Nef在真核细胞中成功表达,细胞免疫荧光结果显示,THP-1-Nef细胞表达的Nef蛋白主要定位于细胞质中。荧光酶标仪检测转染了HIV-1LTR-Luc和NFκB-Luc荧光报告基因的THP-1-Nef和THP-1-3.1细胞的RLU值。结论成功建立了THP-1-Nef细胞稳定表达细胞株,检测了其生物学活性,为进一步研究其作用机制实验奠定基础。     

Interaction of HIV-1 Gag with the clathrin-associated adaptor AP-2

The capsid (CA) sequence of human immunodeficiency virus type 1 (HIV-1) Gag protein consists of two independently folded domains named the N-terminal domain (NTD) and C-terminal domain (CTD) that are connected by a flexible linker. Most of the CTD sequence adopts rigid structure except for the last 11 amino acids (positions 354 to 364) that are disordered even in the context of the downstream SP1 and nucleocapsid (NC) sequence. Although disordered, this short peptide region plays a crucial role in HIV-1 replication. In this study, we identified three second-site mutations within Gag named A238T, G358S, and N373K that rescued a deleterious mutation R362A located at the C-terminus of CA. A238T is located within the NTD of CA, G358S and N373K are positioned proximal to R362A. One of the mechanisms underlying this compensation event is correction of reduced packaging of viral RNA into the R362A mutated viruses, as shown by the results of RNase protection assays, native Northern blots experiments as well as filter-binding assays. These data suggest that one potential function for the C-terminal disordered sequence of CA in HIV-1 replication is to regulate HIV-1 RNA packaging.     

HIV-1 virion fusion assay: uncoating not required and no effect of Nef on fusion

We recently described a sensitive and specific assay that detects the fusion of HIV-1 virions to a broad range of target cells, including primary CD4 cells. This assay involves the use of virions containing beta-lactamase-Vpr (BlaM-Vpr) and the loading of target cells with CCF2, a fluorogenic substrate of beta-lactamase. Since Vpr strongly associates with the viral core, uncoating of the viral particle might be required for effective cleavage of CCF2 by BlaM-Vpr. Here, we show that BlaM-Vpr within mature viral cores effectively cleaves CCF2, indicating that this assay measures virion fusion independently of uncoating. We also show that wildtype and Nef-deficient HIV-1 virions fuse with equivalent efficiency to HeLa-CD4 cells, SupT1 T cells, and primary CD4 T cells. Since Nef enhances cytoplasmic delivery of viral cores and increases viral infectivity, these findings indicate that Nef enhances an early post-fusion event in the multistep process of viral entry. Possible sites of Nef action include enlargement of the fusion pore, enhanced uncoating of viral particles, and more efficient passage of viral cores through the dense cortical actin network located immediately beneath the plasma membrane.     

Nef enhances HIV-1 infectivity via association with the virus assembly complex

The HIV-1 accessory protein Nef enhances virus infectivity by facilitating an early post-entry step of infection. Nef acts in the virus producer cell, leading to a beneficial modification to HIV-1 particles. Nef itself is incorporated into HIV-1 particles, where it is cleaved by the viral protease during virion maturation. To probe the role of virion-associated Nef in HIV-1 infection, we generated a fusion protein consisting of the host protein cyclophilin A (CypA) linked to the amino terminus of Nef. The resulting CypA-Nef protein enhanced the infectivity of Nef-defective HIV-1 particles and was specifically incorporated into the virions via association with Gag during particle assembly. Pharmacologic or genetic inhibition of CypA-Nef binding to Gag prevented incorporation of CypA-Nef into virions and inhibited infectivity enhancement. Our results indicate that infectivity enhancement by Nef requires its association with a component of the assembling HIV-1 particle.     

HIV-1 down-regulates the expression of CD1d via Nef

HIV-1 has evolved several strategies to subvert host immune responses to the infected cells. One is to inhibit CTL recognition by HIV-1 Nef-mediated down-regulation of MHC-I expression on the surface of infected cells. Here we report that Nef also reduces the expression of the non-classical MHC-I like CD1d molecule, a third lineage of antigen-presenting molecule, which presents lipid antigens. Nef achieves this by increasing internalization of CD1d molecules from the cell surface and retaining CD1d in the trans-Golgi-network (TGN). This effect depends on a tyrosine-based motif present in CD1 cytoplasmic tail as well as the actions of four Nef motifs, which are known to be involved in the down-regulation of MHC-I or CD4. These results suggest that Nef regulates intracellular trafficking of CD1d via a distinct but shared pathway with MHC-I and CD4. Thus, HIV-1 reduces the visibility of its infected cells not only to MHC-I-restricted T cells but also to CD1d-restricted NKT cells. Given that CD1d-restricted T cells have unique effector and regulatory functions in innate and adapted immune responses as compared with their counterpart MHC-restricted T cells, our data provide additional new insights into molecular basis of HIV-1-mediated damage to the immune system.     

In vivo mutational analysis of the N-terminal region of HIV-1 Nef reveals critical motifs for the development of an AIDS-like disease in CD4C/HIV transgenic mice

HIV-1 Nef is a critical determinant of pathogenicity in humans and transgenic (Tg) mice. To gain a better understanding of the molecular mechanisms by which Nef induces an AIDS-like disease in Tg mice, a mutational analysis of the N-terminal domain, involved in anchoring Nef to the plasma membrane, was carried out. The pathogenic effects of these Nef mutant alleles were evaluated in Tg mice by FACS analysis and by histopathological assessment. Mutation of the myristoylation site (G2A) completely abrogated the development of the AIDS-like organ disease in Tg mice, although partial downregulation of the CD4 cell surface protein and depletion of peripheral CD4+ T-cells, but not of CD4(+)CD8+ thymocytes, still occurred. Despite that, the peripheral CD4+ T cells expressing Nef(G2A) show normal spontaneous proliferation in vivo or after stimulation in vitro, including in an allogenic mixed leukocyte reaction (MLR). Three other internal deletion mutants of Nef, spanning amino acids 8-17 (Nef(Delta8-17)), 25-35 (Nef(Delta25-35)), and 57-66 (Nef(Delta57-66)), were also studied. Nef(Delta8-17) retained full pathogenic potential, although Nef(Delta25-35) and Nef(Delta57-66) Tg mice were free of organ disease. However, Nef(Delta25-35) Tg mice exhibited disorganization of thymic architecture and a partial depletion of peripheral CD4+ T cells. These data indicate that myristoylation and other regions at the N-terminus of Nef (aa 25-35 and 57-66) are involved in mediating severe T-cell phenotypes and organ disease, although residues 8-17 are dispensable for these Nef functions. In addition, these results indicate that at least some of the CD4+ T-cell phenotypes can develop independently of the other AIDS-like organ phenotypes. This apparent segregation of different Nef-mediated phenotypes suggests distinct mechanisms of Nef action in different populations of target cells, and may be relevant to human AIDS.     

Impaired cell surface expression of human CD1d by the formation of an HIV-1 Nef/CD1d complex

The HIV-1 Nef protein causes a decrease in major histocompatibility complex (MHC) class I and CD4 molecule expression on the cell surface. To determine if Nef can affect components of the innate immune response, we assessed the ability of Nef to alter the cell surface expression of human CD1d. In cells co-expressing CD1d and Nef, a substantial reduction in the cell surface level of CD1d was observed, with a concomitant reduction in the activation of CD1d-restricted NKT cells. Nef had a minimal effect on the cell surface expression of a mutant CD1d molecule in which the last 6 or 10 amino acids of the cytoplasmic tail were deleted. Additionally, it was found that Nef physically interacted with wild-type (but not tail-deleted) CD1d. Therefore, one means by which HIV-1 may be able to establish a foothold in an infected individual is by directly interfering with the functional cell surface expression of CD1d.     

HIV-1 Nef mutations abrogating downregulation of CD4 affect other Nef functions and show reduced pathogenicity in transgenic mice

HIV-1 Nef has the ability to downmodulate CD4 cell surface expression. Several studies have shown that CD4 downregulation is required for efficient virus replication and high infectivity. However, the pathophysiological relevance of this phenomenon in vivo, independently of its role in sustaining high virus loads, remains unclear. We studied the impact of the CD4 downregulation function of Nef on its pathogenesis in vivo, in the absence of viral replication, in the CD4C/HIV transgenic (Tg) mouse model. Two independent Nef mutants (RD35/36AA and D174K), known to abrogate CD4 downregulation, were tested in Tg mice. Flow cytometry analysis showed that downregulation of murine CD4 was severely decreased or abrogated on Tg T cells expressing respectively Nef(RD35/36AA) and Nef(D174K). Similarly, the severe depletion of double-positive CD4+CD8+ and of single-positive CD4+CD8- thymocytes, usually observed with Nef(Wt), was not detected in Nef(RD35/36AA) and Nef(D174K) Tg mice. However, both mutant Tg mice showed a partial depletion of peripheral CD4+ T cells. This was accompanied, as previously reported for Net(Wt) Tg mice, by the presence of an activated/memory-like phenotype (CD69+, CD25+, CD44+, CD45RB(Low), CD62(Low)) of CD4+ T cells expressing Nef(RD35/36AA) and to a lesser extent Nef(D174K). In addition, both mutants retained the ability to block CD4+ T cell proliferation in vitro after anti-CD3 stimulation, but not to enhance apoptosis/death of CD4+ T cells. Therefore, it appears that Nef-mediated CD4 downregulation is associated with thymic defects, but segregates independently of the activated/memory-like phenotype, of the partial depletion and of the impaired in vitro proliferation of peripheral CD4+ T cells. Histopathological assessment revealed the total absence of or decrease severity and frequency of organ AIDS-like diseases (lung, heart and kidney pathologies) in respectively Nef(RD35/36AA) and Nef(D174K) Tg mice, relative to those developing in Nef(Wt) Tg mice. Our data suggest that the RD35/36AA and D174K mutations affect other Nef functions, namely those involved in the development of lung and kidney diseases, in addition to their known role in CD4 downregulation. Similarly, in HIV-1-infected individuals, loss of CD4 downregulation by Nef alleles may reflect their lower intrinsic pathogenicity, independently of their effects on virus replication.     

Selective elimination of HIV-1-infected cells by Env-directed, HIV-1-based virus-like particles

We recently showed that both replicating and resting cells cultivated with ganciclovir (GCV) were killed when challenged with vesicular stomatitis virus G glycoprotein pseudotyped HIV-1-based virus-like particles (VLPs) carrying the Nef7 (i.e., an HIV-1 Nef mutant incorporating in virions at high levels)/herpes simplex virus-1 thymidine kinase (HSV-TK) fusion product. On this basis, a novel anti-HIV therapeutic approach based on Nef7/TK VLPs expressing X4 or R5 HIV cell receptor complexes has been attempted. We here report that (CD4-CXCR4) and (CD4-CCR5) Nef7-based VLPs efficiently enter cells infected by X4- or R5-tropic HIV-1 strains, respectively. Importantly, the delivery of the VLP-associated Nef7/TK led to cell death upon GCV treatment. Of interest, VLPs were effective also against non-replicating, HIV-1-infected primary human monocyte-derived macrophages. HIV-targeted VLPs represent a promising candidate for the treatment of persistently HIV-1-infected cells that are part of virus reservoirs resistant to HAART therapies.     

Human immunodeficiency virus type 1 Nef protein mediates neural cell death: a neurotoxic role for IP-10

HIV-1 Nef is expressed in astrocytes, but a contribution to neuropathogenesis and the development of HIV-associated dementia (HAD) remains uncertain. To determine the neuropathogenic actions of the HIV-1 Nef protein, the brain-derived (YU-2) and blood-derived (NL4-3) Nef proteins were expressed in neural cells using an alphavirus vector, which resulted in astrocyte death (P < 0.001). Supernatants from Nef-expressing astrocytes also caused neuronal death, suggesting the release of neurotoxic molecules by astrocytes. Analysis of pro-inflammatory gene induction in astrocytes expressing Nef revealed increased IP-10 mRNA expression (4000-fold) that was Nef sequence dependent. Recombinant IP-10 caused selective cell death in neurons (P < 0.001) but not astrocytes, and the cytotoxicity of supernatant from astrocytes expressing Nef YU-2 was blocked by an antibody directed against the chemokine receptor CXCR3 (P < 0.001). SCID/NOD mice implanted with a Nef YU-2-expressing vector displayed abnormal motor behavior (P < 0.05), neuroinflammation, and neuronal loss relative to controls. Analysis of mRNA levels in brains from patients with HAD also revealed increased expression of IP-10 (P < 0.05), which was confirmed by immunoreactivity detected principally in astrocytes. Phylogenetic and protein structure analyses of Nef sequences derived from HIV/AIDS patients with and without HAD suggested viral evolution toward a neurotropic Nef protein. These results indicate that HIV-1 Nef contributes to neuropathogenesis by directly causing astrocyte death together with indirect neuronal death through the cytotoxic actions of IP-10 on neurons. Furthermore, Nef molecular diversity was evident in brain tissue among patients with neurological disease and which may influence IP-10 production by astrocytes.     

Structural constraints on human immunodeficiency virus type 1 Nef function

HIV-1 Nef is a multifunctional protein that exerts its activities through interactions with multiple cellular partners. Nef uses different domains and mechanisms to exert its functions including cell surface down-modulation of CD4 and MHC-I receptors and activation of the serine/threonine kinase PAK-2. We inserted tags at the C-terminus and proximal to the N-terminus of Nef and the effects on Nef's structure/function relationships were examined. We discovered significant defects in MHC-I down-modulation with the insertion of HA/FLAG tags at either region. We also found impaired PAK-2 activation with a C-terminal fusion with GFP. Interestingly, Nef-GFP and Nef-GH(7) induced MHC-I down-modulation, suggesting that the negative charge of the HA/FLAG tag could contribute to the observed defect. Together, these observations highlight elements of Nef's functional complexity and demonstrate previously unsuspected structural requirements for PAK-2 activation and MHC-1 down-modulation in Nef's flexible N- and C-terminal regions.     

CD4 and MHC-I downregulation are conserved in primary HIV-1 Nef alleles from brain and lymphoid tissues, but Pak2 activation is highly variable

HIV-1 compartmentalization in the CNS has been demonstrated for gag, pol, and env genes. However, little is known about tissue compartmentalization of nef genes and their functional characteristics in brain. We have cloned 97 nef genes and characterized 10 Nef proteins from autopsy brain and lymphoid tissues from 2 patients with AIDS and HIV-1-associated dementia. Distinct compartmentalization of brain versus lymphoid nef genes was demonstrated within each patient. CD4 and MHC-I downregulation were conserved in all tissue-derived Nefs. However, MHC-I downregulation by brain-derived Nefs was weaker than downregulation by lymphoid-derived Nefs. The motifs KEEE- or EKEE- at the PACS-1 binding site represented brain-specific signature patterns in these 2 patients and contributed to the reduced MHC-I downregulation activity of brain-derived Nefs from these patients. Pak2 association was highly variable in Nefs from both patients. Three of 10 tissue-derived Nefs coimmunoprecipitated activated Pak2, with strong association demonstrated for only 2 Nefs. The ability of Nef to associate with activated Pak2 did not correlate with brain or lymphoid tissue origin. Nef genes from viruses isolated from brain by coculture with PBMC were not closely related to sequences amplified directly from brain tissue, suggesting that viral selection or adaptation occurred during coculture. This study of tissue-derived HIV-1 Nefs demonstrates that CD4 and MHC-I downregulation are highly conserved Nef functions, while Pak2 association is variable in late stage AIDS patients.     

A European multicientre study on the comparison of HIV-1 viral loads between VERIS HIV-1 Assay and Roche COBAS® TAQMAN® HIV-1 test,Abbott RealTime HIV-1 Assay,and Siemens VERSANT HIV-1 Assay

BackgroundViral load monitoring is essential for patients under treatment for HIV. Beckman Coulter has developed the VERIS HIV-1 Assay for use on the novel, automated DxN VERIS Molecular Diagnostics System.^¥ObjectivesEvaluation of the clinical performance of the new quantitative VERIS HIV-1 Assay at multiple EU laboratories.Study designMethod comparison with the VERIS HIV-1 Assay was performed with 415 specimens at 5 sites tested with COBAS^® AmpliPrep/COBAS^® TaqMan^® HIV-1 Test, v2.0, 169 specimens at 3 sites tested with RealTime HIV-1 Assay, and 202 specimens from 2 sites tested with VERSANT HIV-1 Assay. Patient monitoring sample results from 4 sites were also compared.ResultsBland-Altman analysis showed the average bias between VERIS HIV-1 Assay and COBAS HIV-1 Test, RealTime HIV-1 Assay, and VERSANT HIV-1 Assay to be 0.28, 0.39, and 0.61 log₁₀ cp/mL, respectively. Bias at low end levels below 1000 cp/mL showed predicted bias to be <0.3 log₁₀ cp/mL for VERIS HIV-1 Assay versus COBAS HIV-1 Test and RealTime HIV-1 Assay, and <0.5 log₁₀ cp/mL versus VERSANT HIV-1 Assay. Analysis on 174 specimens tested with the 0.175 mL volume VERIS HIV-1 Assay and COBAS HIV-1 Test showed average bias of 0.39 log₁₀ cp/mL. Patient monitoring results using VERIS HIV-1 Assay demonstrated similar viral load trends over time to all comparators.ConclusionsThe VERIS HIV-1 Assay for use on the DxN VERIS System demonstrated comparable clinical performance to COBAS^® HIV-1 Test, RealTime HIV-1 Assay, and VERSANT HIV-1 Assay.     

HIV-1 Nef protein expression in human CD34+ progenitors impairs the differentiation of an early T/NK cell precursor

HIV-1 impairs the production of T cells, through mechanisms that are still unknown. Here, we investigated the effect of the expression of HIV-1 Nef on the T-cell potential of human hematopoietic CD34(+) precursors. Those progenitors were transduced by using lentiviral vectors expressing Nef and cultured on OP9-DL1 cells allowing the differentiation of T cell from human hematopoietic precursors. We demonstrate that Nef impairs the generation of a CD3epsilon(+)CD5(+) CD1a(+) precursor stage that has initiated a D-J rearrangement of the TCRbeta locus. Onward stages of T-cell development were also affected with a quantitative reduction of CD4(+) intraCD3epsilon(+) Immature single positive cells (ISP), Double Positive (DP) CD4(+)CD8(+) TCRalphabeta T cells and CD56(+) NK cells. But B cell production was not affected. Limiting dilution analyses demonstrated a significant reduction in the frequency of T/NK progenitors among Nef-expressing CD34(+) cells. Altogether, these data demonstrate that Nef interferes with the differentiation of a primitive lymphoid human precursor with a T/NK potential.