A dileucine motif in HIV-1 Nef acts as an internalization signal for CD4 downregulation and binds the AP-1 clathrin adaptor.

Human immunodeficiency virus 1 (HIV-1) Nef downregulates surface expression of CD4, an integral component of the functional HIV receptor complex, through accelerated endocytosis of surface receptors and diminished transport of CD4 from the Golgi network to the plasma membrane. HIV-1 Nef also diminishes surface expression of major histocompatibility complex (MHC) class I antigens. In the case of HIV-2 and simian immunodeficiency virus 1 (SIV-1) Nef, aminoterminal tyrosine-based motifs mediate the binding of Nef to the AP-1 and AP-2 adaptors and this interaction appears to be required for CD4 downregulation. As these tyrosine motifs are not present in the HIV-1 Nef protein, the molecular basis for the presumed interaction of Nef with components of the endocytic machinery is unknown. Here, we identify a highly conserved dileucine motif in HIV-1 Nef that is required for downregulation of CD4. This motif acts as an internalization signal in the context of a CD8-Nef chimera or in a fusion of the interleukin-2 receptor alpha with an 11-amino-acid region from Nef containing the dileucine motif. Finally, HIV-1 Nef binds to the AP-1 adaptor, both in vitro and in vivo, in a dileucine-dependent manner. We conclude that this conserved dileucine motif in HIV-1 Nef serves as a key interface for interaction with components of the host protein trafficking machinery. Our findings also reveal an evolutionary difference between HIV-1 and HIV-2/SIV in which the Nef proteins utilize structurally distinct motifs for binding cellular adaptors.

Activation of the heterodimeric IkappaB kinase alpha (IKKalpha)-IKKbeta complex is directional: IKKalpha regulates IKKbeta under both basal and stimulated conditions.

Signal-induced nuclear expression of the eukaryotic NF-kappaB transcription factor involves the stimulatory action of select mitogen-activated protein kinase kinase kinases on the IkappaB kinases (IKKalpha and IKKbeta) which reside in a macromolecular signaling complex termed the signalsome. While genetic studies indicate that IKKbeta is the principal kinase involved in proinflammatory cytokine-induced IkappaB phosphorylation, the function of the equivalently expressed IKKalpha is less clear. Here we demonstrate that assembly of IKKalpha with IKKbeta in the heterodimeric signalsome serves two important functions: (i) in unstimulated cells, IKKalpha inhibits the constitutive IkappaB kinase activity of IKKbeta; (ii) in activated cells, IKKalpha kinase activity is required for the induction of IKKbeta. The introduction of kinase-inactive IKKalpha, activation loop mutants of IKKalpha, or IKKalpha antisense RNA into 293 or HeLa cells blocks NIK (NF-kappaB-inducing kinase)-induced phosphorylation of the IKKbeta activation loop occurring in functional signalsomes. In contrast, catalytically inactive mutants of IKKbeta do not block NIK-mediated phosphorylation of IKKalpha in these macromolecular signaling complexes. This requirement for kinase-proficient IKKalpha to activate IKKbeta in heterodimeric IKK signalsomes is also observed with other NF-kappaB inducers, including tumor necrosis factor alpha, human T-cell leukemia virus type 1 Tax, Cot, and MEKK1. Conversely, the theta isoform of protein kinase C, which also induces NF-kappaB/Rel, directly targets IKKbeta for phosphorylation and activation, possibly acting through homodimeric IKKbeta complexes. Together, our findings indicate that activation of the heterodimeric IKK complex by a variety of different inducers proceeds in a directional manner and is dependent on the kinase activity of IKKalpha to activate IKKbeta.

Protein kinase C-theta participates in NF-kappaB activation induced by CD3-CD28 costimulation through selective activation of IkappaB kinase beta.

The NF-kappaB/Rel family of eukaryotic transcription factors plays an essential role in the regulation of inflammatory, antiapoptotic, and immune responses. NF-kappaB is activated by many stimuli including costimulation of T cells with ligands specific for the T-cell receptor (TCR)-CD3 complex and CD28 receptors. However, the signaling intermediates that transduce these costimulatory signals from the TCR-CD3 and CD28 surface receptors leading to nuclear NF-kappaB expression are not well defined. We now show that protein kinase C-theta (PKC-theta), a novel PKC isoform, plays a central role in a signaling pathway induced by CD3-CD28 costimulation leading to activation of NF-kappaB in Jurkat T cells. We find that expression of a constitutively active mutant of PKC-theta potently induces NF-kappaB activation and stimulates the RE/AP composite enhancer from the interleukin-2 gene. Conversely, expression of a kinase-deficient mutant or antisense PKC-theta selectively inhibits CD3-CD28 costimulation, but not tumor necrosis factor alpha-induced activation of NF-kappaB in Jurkat T cells. The induction of NF-kappaB by PKC-theta is mediated through the activation of IkappaB kinase beta (IKKbeta) in the absence of detectable IKKalpha stimulation. PKC-theta acts directly or indirectly to stimulate phosphorylation of IKKbeta, leading to activation of this enzyme. Together, these results implicate PKC-theta in one pathway of CD3-CD28 costimulation leading to NF-kappaB activation that is apparently distinct from that involving Cot and NF-kappaB-inducing kinase (NIK). PKC-theta activation of NF-kappaB is mediated through the selective induction of IKKbeta, while the Cot- and NIK-dependent pathway involves induction of both IKKalpha and IKKbeta.

Molecular determinants of NF-kappaB-inducing kinase action.

NF-kappaB corresponds to an inducible eukaryotic transcription factor complex that is negatively regulated in resting cells by its physical assembly with a family of cytoplasmic ankyrin-rich inhibitors termed IkappaB. Stimulation of cells with various proinflammatory cytokines, including tumor necrosis factor alpha (TNF-alpha), induces nuclear NF-kappaB expression. TNF-alpha signaling involves the recruitment of at least three proteins (TRADD, RIP, and TRAF2) to the type 1 TNF-alpha receptor tail, leading to the sequential activation of the downstream NF-kappaB-inducing kinase (NIK) and IkappaB-specific kinases (IKKalpha and IKKbeta). When activated, IKKalpha and IKKbeta directly phosphorylate the two N-terminal regulatory serines within IkappaB alpha, triggering ubiquitination and rapid degradation of this inhibitor in the 26S proteasome. This process liberates the NF-kappaB complex, allowing it to translocate to the nucleus. In studies of NIK, we found that Thr-559 located within the activation loop of its kinase domain regulates NIK action. Alanine substitution of Thr-559 but not other serine or threonine residues within the activation loop abolishes its activity and its ability to phosphorylate and activate IKKalpha. Such a NIK-T559A mutant also dominantly interferes with TNF-alpha induction of NF-kappaB. We also found that ectopically expressed NIK both spontaneously forms oligomers and displays a high level of constitutive activity. Analysis of a series of NIK deletion mutants indicates that multiple subregions of the kinase participate in the formation of these NIK-NIK oligomers. NIK also physically assembles with downstream IKKalpha; however, this interaction is mediated through a discrete C-terminal domain within NIK located between amino acids 735 and 947. When expressed alone, this C-terminal NIK fragment functions as a potent inhibitor of TNF-alpha-mediated induction of NF-kappaB and alone is sufficient to disrupt the physical association of NIK and IKKalpha. Together, these findings provide new insights into the molecular basis for TNF-alpha signaling, suggesting an important role for heterotypic and possibly homotypic interactions of NIK in this response.

Functional isoforms of IkappaB kinase alpha (IKKalpha) lacking leucine zipper and helix-loop-helix domains reveal that IKKalpha and IKKbeta have different activation requirements.

The activity of the NF-kappaB family of transcription factors is regulated principally by phosphorylation and subsequent degradation of their inhibitory IkappaB subunits. Site-specific serine phosphorylation of IkappaBs by two IkappaB kinases (IKKalpha [also known as CHUK] and IKKbeta) targets them for proteolysis. IKKalpha and -beta have a unique structure, with an amino-terminal serine-threonine kinase catalytic domain and carboxy-proximal helix-loop-helix (HLH) and leucine zipper-like (LZip) amphipathic alpha-helical domains. Here, we describe the properties of two novel cellular isoforms of IKKalpha: IKKalpha-DeltaH and IKKalpha-DeltaLH. IKKalpha-DeltaH and IKKalpha-DeltaLH are differentially spliced isoforms of the IKKalpha mRNA lacking its HLH domain and both its LZip and HLH domains, respectively. IKKalpha is the major RNA species in most murine cells and tissues, except for activated T lymphocytes and the brain, where the alternatively spliced isoforms predominate. Remarkably, IKKalpha-DeltaH and IKKalpha-DeltaLH, like IKKalpha, respond to tumor necrosis factor alpha stimulation to potentiate NF-kappaB activation in HEK293 cells. A mutant, catalytically inactive form of IKKalpha blocked IKKalpha-, IKKalpha-DeltaH-, and IKKalpha-DeltaLH-mediated NF-kappaB activation. Akin to IKKalpha, its carboxy-terminally truncated isoforms associated with the upstream activator NIK (NF-kappaB-inducing kinase). In contrast to IKKalpha, IKKalpha-DeltaLH failed to associate with either itself, IKKalpha, IKKbeta, or NEMO-IKKgamma-IKKAP1, while IKKalpha-DeltaH complexed with IKKbeta and IKKalpha but not with NEMO. Interestingly, each IKKalpha isoform rescued HEK293 cells from the inhibitory effects of a dominant-negative NEMO mutant, while IKKalpha could not. IKKalpha-DeltaCm, a recombinant mutant of IKKalpha structurally akin to IKKalpha-DeltaLH, was equally functional in these assays, but in sharp contrast, IKKbeta-DeltaCm, a structurally analogous mutant of IKKbeta, was inactive. Our results demonstrate that the functional roles of seemingly analogous domains in IKKalpha and IKKbeta need not be equivalent and can also exhibit different contextual dependencies. The existence of cytokine-inducible IKKalpha-DeltaH and IKKalpha-DeltaLH isoforms illustrates potential modes of NF-kappaB activation, which are not subject to the same in vivo regulatory constraints as either IKKalpha or IKKbeta.

Human T-cell leukemia virus type 1 Tax induction of NF-kappaB involves activation of the IkappaB kinase alpha (IKKalpha) and IKKbeta cellular kinases.

Tax corresponds to a 40-kDa transforming protein from the pathogenic retrovirus human T-cell leukemia virus type 1 (HTLV-1) that activates nuclear expression of the NF-kappaB/Rel family of transcription factors by an unknown mechanism. Tax expression promotes N-terminal phosphorylation and degradation of IkappaB alpha, a principal cytoplasmic inhibitor of NF-kappaB. Our studies now demonstrate that HTLV-1 Tax activates the recently identified cellular kinases IkappaB kinase alpha (IKKalpha) and IKKbeta, which normally phosphorylate IkappaB alpha on both of its N-terminal regulatory serines in response to tumor necrosis factor alpha (TNF-alpha) and interleukin-1 (IL-1) stimulation. In contrast, a mutant of Tax termed M22, which does not induce NF-kappaB, fails to activate either IKKalpha or IKKbeta. Furthermore, endogenous IKK enzymatic activity was significantly elevated in HTLV-1-infected and Tax-expressing T-cell lines. Transfection of kinase-deficient mutants of IKKalpha and IKKbeta into either human Jurkat T or 293 cells also inhibits NF-kappaB-dependent reporter gene expression induced by Tax. Similarly, a kinase-deficient mutant of NIK (NF-kappaB-inducing kinase), which represents an upstream kinase in the TNF-alpha and IL-1 signaling pathways leading to IKKalpha and IKKbeta activation, blocks Tax induction of NF-kappaB. However, plasma membrane-proximal elements in these proinflammatory cytokine pathways are apparently not involved since dominant negative mutants of the TRAF2 and TRAF6 adaptors, which effectively block signaling through the cytoplasmic tails of the TNF-alpha and IL-1 receptors, respectively, do not inhibit Tax induction of NF-kappaB. Together, these studies demonstrate that HTLV-1 Tax exploits a distal part of the proinflammatory cytokine signaling cascade leading to induction of NF-kappaB. The pathological alteration of this cytokine pathway leading to NF-kappaB activation by Tax may play a central role in HTLV-1-mediated transformation of human T cells, clinically manifested as the adult T-cell leukemia.

Increased DNA synthesis and repair-enzyme expression in lymphocytes from patients with chronic lymphocytic leukemia resistant to nitrogen mustards.

Resistance to the nitrogen mustards in patients with chronic lymphocytic leukemia (CLL) correlates with an enhanced removal of melphalan-induced DNA interstrand cross-links. This finding suggests that DNA repair enzymes may be involved in this process. The activity of 3-methyladenine-DNA glycosylase, which can release altered bases, including adducts at the N-7 position of guanine, was increased significantly in lymphocytes from patients with resistant CLL compared with those from untreated CLL patients. Since glycosylase activity varies with cell proliferation, the amount of [3H]thymidine incorporated into DNA was determined and found to be elevated almost threefold in lymphocytes from patients with resistant CLL. The ratio of glycosylase activity to level of thymidine incorporation did not differ between these two groups of patients. Northern blot analysis of ERCC1 gene (a putative DNA repair enzyme involved in nucleotide excision repair) expression in lymphocytes from patients with CLL revealed multiple gene transcripts (1.1, 3.4, and 3.8 kilobases). In addition, analysis of two samples revealed the presence of a 2.6-kilobase transcript. The 2.6-kilobase transcript was recognized by specific RNA probes that hybridize to antisense ERCC1 transcripts. Levels of expression of the 1.1-kilobase protein encoding transcript in lymphocytes from patients with resistant CLL were increased twofold to threefold above those of untreated patients with CLL. These results indicate that increased expression of ERCC1 and increased activity of 3-methyladenine-DNA glycosylase occur with the development of resistance to the nitrogen mustards in patients with CLL, suggesting a role for enhanced DNA repair in this process.

Human T-cell leukemia virus type I tax activates transcription of the human monocyte chemoattractant protein-1 gene through two nuclear factor-kappaB sites.

Infection by human T-cell leukemia virus type (HTLV) I leads to adult T-cell leukemia and is also associated with the neurodegenerative disease HTLV-I-associated myelopathy/tropical spastic paraparesis. Leukocytes are attracted to sites of inflammation by chemokines. One such chemokine is monocyte chemoattractant protein (MCP)-1, a member of the C-C subfamily of chemokines. We investigated whether HTLV-I infection causes up-regulation of MCP-1, which may in turn cause recruitment of leukocytes to HTLV-I-infected areas. We now report that MCP-1 mRNA levels are elevated in HTLV-I-infected T-cell lines, when compared with uninfected ones. We further confirmed secretion of MCP-1 by HTLV-I-infected T-cell lines. MCP-1 mRNA was also expressed in leukemic cells from patients with adult T-cell leukemia. The 5' transcriptional regulatory region of the MCP-1 gene was activated by the HTLV-I-encoded transactivator Tax in the human T-cell line Jurkat, in which endogenous MCP-1 is induced by Tax. By using site-specific point mutations, we have identified two closely spaced nuclear factor (NF)-kappaB sites, A1 and A2, to be important for Tax-mediated transactivation of the MCP-1 gene. Through the use of an electrophoretic mobility shift assay, we demonstrated that Tax induced NF-kappaB binding to both MCP-1 kappaB sites. This is the first report to demonstrate that Tax can transactivate the MCP-1 gene through the induction of NF-kappaB. Our results thus reveal how Tax disrupts the normally regulated MCP-1 gene and leads to its constitutive expression in HTLV-I-infected cells. These findings may have important implications for our understanding of HTLV-I-associated diseases.

The generation of nfkb2 p52: mechanism and efficiency.

nfkb2 encodes two members of the NF-kappa B/Rel family of proteins: p52 and p100. The p100 polypeptide has been proposed to serve as a precursor of p52, which corresponds to the N-terminal half of p100. While p52 functions as a Rel transcription factor, the larger p100 protein acts as a cytoplasmic inhibitor of select NF-kappa B/Rel transcription factor complexes. Because of their distinct functions, we have studied the biochemical basis for the production of these two nfkb2-derived gene products. Like the p50 product of the nfkb1 gene, p52 is principally generated in a cotranslational manner involving proteolytic processing by the proteasome. The generation of p52 is dependent on a glycine-rich region (GRR) located upstream of the p52 C-terminus, and repositioning of this GRR alters the location of proteasome processing. In most cells, small amounts of p52 are produced relative to the levels of p100, unlike the usually balanced production of nfkb1-derived p50 and p105. Using p100/p105 chimeras containing different segments of the nfkb1 and nfkb2 genes, we have found that diminished p52 processing is a property conferred by peptide sequences located downstream of the GRR, flanking the site of p52 processing.

NF-kappa B signaling promotes both cell survival and neurite process formation in nerve growth factor-stimulated PC12 cells.

Nerve growth factor binds to the TrkA and p75(NTR) (p75) and generates signals leading to neuronal cell survival, differentiation, and programmed cell death. Here we describe a series of experiments involving selective activation of either TrkA or p75 in which distinct cell-signaling intermediates promote different cellular consequences. We analyzed pheochromocytoma 12 (PC12) cells stably expressing chimeras consisting of the extracellular domain of PDGF receptor (PDGFR) fused to the transmembrane and cytoplasmic segments of p75 or TrkA. Because PC12 cells lack endogenous PDGFR, addition of PDGF to these cell lines permits selective activation of the p75 or TrkA responses without stimulating endogenous receptors. Although both p75 and TrkA activated nuclear factor-kappaB (NF-kappaB), we show that distinct proximal-signaling intermediates are used by each receptor. A dominant-negative mutant of TRAF6 blocked p75- but not TrkA-mediated induction of NF-kappaB. Conversely a dominant-negative mutant of Shc inhibited TrkA but not p75 activation of NF-kappaB. Both of these distinct signaling pathways subsequently converge, leading to activation of the IkappaB kinase complex. Moreover, the activation of NF-kappaB by these distinct pathways after stimulation of either TrkA or p75 leads to different physiological consequences. Blocking p75-mediated activation of NF-kappaB by ecdysone-inducible expression of a nondegradable mutant of IkappaBalpha significantly enhanced apoptosis. In contrast, blocking NF-kappaB induction via TrkA significantly inhibited neurite process formation in PC12 cells. Together these findings indicate that, although both of these receptors lead to the activation of NF-kappaB, they proceed via distinct proximal-signaling intermediates and contribute to different cellular outcomes.

HIV-1 associated down-modulation of CD4 gene expression is differentially restricted in lymphocytic and monocytic cell lines.

We previously demonstrated that chronic infection of a monocytic cell line (U-937) with human immunodeficiency virus type 1 (HIV-1) was not accompanied by down-modulation of CD4 transcription, unlike the situation with CD4+ T lymphocyte lines. To better understand the refractoriness of monocytes to alterations in levels of CD4 mRNA, we treated HIV-IIIB chronically infected U-937 cells with phorbol myristate acetate (PMA), a known stimulus of HIV gene expression. Although PMA caused a significant increase in HIV mRNA levels that was sustained over 7 days, no effect on CD4 transcript levels was noted. Clonal derivatives of HIV-IIIB-infected U-937 cells, which produced a variety of infectious and defective particles, were likewise not affected in ability to produce CD4 mRNA. To rule out the possibility that U-937 cells select out HIV-1 variants unable to modulate CD4 mRNA levels, we passaged infectious virus from a U-937 clonal derivative (UHC1) onto different monocytic and T lymphocytic cell lines. In monocytic cell lines (U-937, PLB-985, THP-1), we observed an avirulent infection that did not affect CD4 mRNA levels, whereas UHC1 infection of each of two T lymphocytic cell lines (CEM-T4, Jurkat) caused both cytopathic replication and reductions in CD4 mRNA levels. In one case (Jurkat), variants expressing low CD4 mRNA may have emerged, because the outgrowth no longer expressed viral products. In the other case (CEM-T4), high expression of viral genes was accompanied by CD4 mRNA down-modulation, suggesting either that low-CD4-expressing variants were selected that maintained viral gene expression or that CD4 gene expression was repressed by viral products.

Diminution of CD4 surface protein but not CD4 messenger RNA levels in monocytic cells infected by HIV-1.

As expected, the productive infection of several monocytic cell lines by HIV-1 led to a diminution of cell-surface CD4 antigen. However, unlike findings reported for HIV-1-infected T cells, this decrease was not accompanied by a similar reduction in levels of CD4 transcripts. OKT4 monoclonal antibodies (MAbs) to CD4 were used in immunoprecipitation experiments to show that intracellular CD4 levels were diminished in U-937 monocytic cells that had been infected by HIV-1. These MAbs also coprecipitated viral gp120, indicating that CD4-gp120 complexes are present in infected monocytes. Our results therefore demonstrate that cell-surface down-modulation of CD4 is exclusively a post-transcriptional event in HIV-1 infected monocytic cells. These data suggest that HIV-1-mediated depletion of cell-surface CD4 in monocytes does not involve transcript down-modulation as has been reported in T lymphocytes.

Increased soluble tumor necrosis factor receptor expression and release by human immunodeficiency virus type 1 infection.

High levels of circulating soluble tumor necrosis factor receptors (sTNF-R) are associated with HIV-1 infection and disease. To understand better this association, we have investigated p55 and p75 TNF-R expression on peripheral blood mononuclear cell (PBMC) subsets and in the promonocytic cell line U937, with or without HIV infection. Using flow cytometry and monoclonal antibodies both to sTNF-R and to PBMC subsets, TNF-R were found to be expressed mostly by monocytes and in decreasing amounts and intensity in the following order: CD14+ cells > CD8+ cells > CD4+ cells. Expression of TNF-R was higher on cells obtained from HIV-infected than from noninfected subjects, and expression of p75 sTNF-R was much higher than that of p55 sTNF-R. Studying the U937 cells revealed that over 80% of the cells expressed both sTNF-R, but with greater fluorescence intensity in the HIV-1 chronically infected cells (U-937-IIIB). Treatment of the cells with PMA caused an accelerated release into the medium of both sTNF-R, with a sharp decline in their cell surface expression. Basal levels of mRNA transcripts for p75 TNF-R were higher in the U-937-IIIB cells than in the uninfected cells, but p55 TNF-R mRNA was expressed only in the HIV-1-infected cells. These findings show that HIV-1 infection is accompanied by predominant elevation of p75 TNF-R surface expression on monocytes and CD8+ lymphocytes, and results in both increased message and expression of these receptors in monocytes.(ABSTRACT TRUNCATED AT 250 WORDS)

Clinical correlates and molecular basis of HIV drug resistance.

It has been widely reported that zidovudine (ZDV)-resistant variants of human immunodeficiency virus type 1 (HIV-1) can be isolated from patients undergoing prolonged therapy with this drug. At the same time, treatment of HIV-infected individuals with ZDV and other forms of nucleotide therapy, including didanosine (ddI), have enabled patients to live longer than would otherwise be the case and to enjoy improved quality of life. HIV resistance to ZDV, ddI, and other nucleosides is attributable to a series of point mutations within the pol gene of HIV-1 that encodes the viral enzyme, reverse transcriptase (RT). This is not surprising as the virus is known to replicate at high rates in infected individuals; moreover the RT that mediates transcription of proviral DNA from viral genomic RNA is known to be highly error prone. Thus, mutants of HIV-1, which possess a drug-resistance phenotype and genotype, may be expected to emerge under the selective pressure of long-term antiviral chemotherapy. This article describes a novel mutation at site 184 within the pol gene that accounts for resistance against both ddI and zalcitibine (ddC). HIV drug resistance occurs most commonly in individuals with low CD4 cell counts who have progressed to more serious forms of disease. Moreover, viruses obtained from patients with AIDS generally display higher levels of resistance, relative to pretreatment isolates, than do viruses from patients with more-limited illness. Although observations of drug resistance can be correlated with disease progression and a weakened immune system, it is still unclear whether a cause-and-effect relationship exists. Because of the error-prone nature of viral RT and the fact that the HIV-1 genome can mutate efficiently, it can be anticipated that viral drug resistance may emerge for all forms of nucleotide therapy to be offered in the future. In addition, resistance may also become apparent with regard to drugs that block HIV replication by acting at sites within the viral replication cycle other than RT.

The role and fate of the CD4 molecule in lymphocytes and monocytes infected by HIV-1.

Infection by HIV-1 of monocyte cell lines, in contrast to T lymphocytes, did not lead to decreased steady-state levels of CD4 mRNA. Similar results were also obtained using clonal derivatives of infected U-937 cells that produced either competent, highly replicative progeny viruses or defective non-infectious particles. In each case, the infected U-937 cells or clonal derivatives were found to be significantly deficient with regard to surface representation of CD4 protein, in spite of the presence of high levels of CD4 mRNA. However, both HIV-1-infected U-937 cells, as well as clonal derivatives which produced high levels of viral env mRNA and non-infectious viral structures that lacked envelope glycoproteins, contained diminished levels of OKT4-immunoprecipitable CD4 protein, in comparison with uninfected U-937 cells. Thus, expression of viral env mRNA but neither the efficient synthesis or packaging of viral glycoproteins or viral assembly is required for disappearance of cell surface CD4 to occur. Furthermore, viral gp160 co-precipitated with CD4 in both the parental and cloned cell lines. We have also shown that the generation of intracellular complexes of gp160 and CD4 is directly responsible for the disappearance of cell surface CD4 in HIV-1-infected U-937 cells. In this system, expression of gp160 was both necessary and sufficient to result in CD4 receptor down-modulation. Finally, in vitro co-translation studies revealed that the presence or synthesis of viral gp160 led to a failure to efficiently generate CD4 protein.

Inhibition of CD4 translation mediated by human immunodeficiency virus type 1 envelope protein in a cell-free system.

The human immunodeficiency virus type 1 (HIV-1) employs a number of complex strategies to interfere with the synthesis, stability, and subcellular localization of its specific cellular receptor CD4. To define better the mechanisms of inhibition of CD4 expression, we used a rabbit reticulocyte lysate in vitro system, in which cDNAs derived from HIV-1-infected cells were used to generate mRNA for the Tat, Vpu, and gp160 envelope proteins that were translated together with CD4-encoding mRNA. In the presence of microsomal membranes, we observed that cotranslation of Env mRNA resulted in a dose-dependent inhibition of CD4 translation. This effect was enhanced further when an mRNA-encoding Vpu in addition to Env mRNA was utilized. However, the activity of Vpu was mostly post-translational, since translation of Vpu alone, but not Env, was able to destabilize CD4 molecules presynthesized into microsomes. The Env-mediated inhibitory effect was specifically targeted at CD4 and did not affect the synthesis or stability of the CD8 molecule. Interestingly, mutated CD4 species, with a 20-fold lower affinity for HIV-1 Env than wild-type, were less sensitive to cotranslational inhibition. Our report identifies the envelope as the HIV-1 protein responsible for down-regulation of CD4 translation. We further propose a mechanism whereby direct interactions between gp160 and nascent CD4 molecules can cause interference with and premature termination of CD4 protein elongation.

The human immunodeficiency virus type 1 (HIV-1) CD4 receptor and its central role in promotion of HIV-1 infection.

Interactions between the viral envelope glycoprotein gp120 and the cell surface receptor CD4 are responsible for the entry of human immunodeficiency virus type 1 (HIV-1) into host cells in the vast majority of cases. HIV-1 replication is commonly followed by the disappearance or receptor downmodulation of cell surface CD4. This potentially renders cells nonsusceptible to subsequent infection by HIV-1, as well as by other viruses that use CD4 as a portal of entry. Disappearance of CD4 from the cell surface is mediated by several different viral proteins that act at various stages through the course of the viral life cycle, and it occurs in T-cell lines, peripheral blood CD4+ lymphocytes, and monocytes of both primary and cell line origin. At the cell surface, gp120 itself and in the form of antigen-antibody complexes can trigger cellular pathways leading to CD4 internalization. Intracellularly, the mechanisms leading to CD4 downmodulation by HIV-1 are multiple and complex; these include degradation of CD4 by Vpu, formation of intracellular complexes between CD4 and the envelope precursor gp160, and internalization by the Nef protein. Each of the above doubtless contributes to the ultimate depletion of cell surface CD4, although the relative contribution of each mechanism and the manner in which they interact remain to be definitively established.

[Antiviral strategies in the replication of human immunodeficiency virus]. / Stratégies d'interférences avec la réplication du virus d'immunodéficience humaine.

The replication cycle of any virus involves a number of steps, beginning with specific attachment to a cell surface receptor leading eventually to production of progeny viruses by infected cells. In the case of the immunodeficiency virus type-1 (HIV-1), the first step involves a specific interaction between the gp120 viral envelope surface protein and specific CD4 receptor sites at the cell surface. This is followed by penetration of the virus into cells and the formation of proviral double-stranded DNA from single-stranded viral RNA, a process mediated through the action of the viral enzyme called reverse transcriptase. This, in turn, leads to the migration of proviral DNA into the nucleus of the cell and the integration of such DNA within the host cell genome. Finally both viral RNA and viral proteins are produced by the cell's genetic apparatus and new viruses are assembled at the cell surface. The fact that integration of viral DNA into host cell chromosomes occurs means that any cellular replication event will be accompanied by replication of viral DNA. Each of these steps represents a potential target for anti-viral chemotherapy. To date, most efforts to treat HIV-associated disease have focused on the reverse transcription step. In this respect, zidovudine (AZT) has been the most widely used anti-viral drug studied. However, the relative toxicity and lack of efficiency of this drug means that our efforts to develop new therapeutic strategies to combat HIV infection must continue.(ABSTRACT TRUNCATED AT 250 WORDS)