The first and most extensively characterized function of Nef is its ability to dramatically reduce the steady state levels of CD4 on the cell surface 3864)) Human CD4 is downmodulated by Nefs from HIV-1 groups M, N, and O, and simian immunodeficiency virus from chimpanzees (SIV_CPZ) 65, in multiple mammalian cell types 3766, and even in Drosophila S2 cells 67. As mentioned above the major role for this Nef activity may be in overcoming the detrimental effects of high cellular CD4 expression in the producer cell 396869.

Nef-induced CD4 down-modulation involves the internalization of surface CD4 followed by degradation via the endosomal/lysosomal pathway (Figure 1, Red). Consistent with this mechanism Nef localizes to clathrin-coated pits 70 and increases the number of CD4 containing clathrin coated pits 71 Inhibition of lysosomal acidification blocks Nef induced CD4 degradation, without restoring CD4 surface expression 727374 Moreover, Nef induced CD4 downmodulation is blocked by transdominant-negative dynamin-1 co-expression 75, as well as, pharmacological inhibitors of clathrin coated pit mediated endocytosis 74.

The heterotetrameric clathrin-associated adaptor protein 2 (AP-2) is a key molecular mediator of Nef induced CD4 downmodulation 76, but other aspects of CD4 downregulation remain unclear. Unlike CD4 downmodulation by phorbol esters, Nef-induced downmodulation is independent of the phosphorylation of serine residues in the CD4 cytoplasmic tail 38. Data suggest that Nef may act as a connector between CD4 and the cell's endocytic machinery 40, by binding the membrane proximal segment of the cytoplasmic domain of CD4 373877 Furthermore, NMR analysis confirms that the membrane proximal segment of CD4 is necessary for a direct interaction with Nef 78 Nef residues W57 and L58 are predicted by NMR to be critical in this interaction and have also been functionally demonstrated to be important for CD4 downmodulation 79. The possible significance of this proposed interaction between Nef and the cytoplasmic tail of CD4 is obscured by the fact that it is weak, but the interaction of p56^lck and CD4 is strong and the p56^lck-CD4 complex is not subject to rapid endocytosis 8081 Further, it is unlikely that Nef binds directly with p56^lck intracellularly 82, even though Nef has been shown to induce endosomal accumulation of Lck 83. This latter effect of Nef on Lck does not appear to be related to CD4 downregulation since the L164A/L165A mutant of Nef alters the intracellular distribution of Lck but fails to downregulate CD4 8384. An alternate model to the direct binding of Nef to the cytoplasmic tail of CD4 has been proposed by Coleman et al. in which Nef disregulates endosomal trafficking 85.

In contrast to the poorly defined direct interaction of Nef with the cytoplasmic tail of CD4 the direct interaction of Nef with AP-2 has been described in detail 76. AP-2 binds to the just mentioned dileucine motif in Nef which is found in a structurally flexible loop that extends from amino acids 148 to 180 86. The dileucine motif in Nef exhibits a canonical ¹⁶⁰EXXXLL¹⁶⁵ sequence but it is not sufficient to account for the binding of Nef to AP-2. Also required are two acidic residues within the loop, ¹⁷⁴(E/D)D¹⁷⁵. Mutation of either the dileucines or the diacidic residues to alanines disables Nef binding to AP-2 in yeast three hybrid assays (Nef/AP-2α/AP-2σ2) and the CD4 downregulation function. In the absence of the diacidic residues there is weak binding by the dileucine motif because of a suboptimal sequence for the XXX residues (i.e. N, T and S). Replacing ¹⁶¹NTS¹⁶³ within the Nef dileucine motif with residues from the AP-2 interacting protein, tyrosinase, gives ¹⁶⁰E

RQP

Another well conserved property of Nef is its ability to downmodulate MHC class I molecules 44. As Nef is expressed early after infection, Nef induced downmodulation of MHC class I molecules could enable the infected cell to evade destruction by the immune system during active viral replication. In support, it has been demonstrated that Nef expression reduces the susceptibility of HIV infected cells to cytotoxic T lymphocyte (CTL) mediated lysis in vitro 5758. Therefore, determining the mechanism by which Nef downregulates MHCI has received a high priority. Early aspects of this field have been reviewed 88.

A long standing model proposed by Thomas and co-workers 8990 has been recently revised 41. In this model Nef initiates MHCI downregulation by interacting with PACS-2. The Nef/PACS-2 complex localizes to the trans-Golgi network (TGN) where PACS-2 is displaced and Nef binds to a src family kinase (SFK). The SFK would then bind and phosphorylate ZAP70/Syk on tyrosine enabling ZAP70/Syk to bind the SH2 domain of phosphatidylinositide 3-kinase (PI3K). The resulting activation of PI3K would lead to elevated PIP₃, stimulation of the guanine nucleotide exchange factor ARNO, and GTP loading of ARF6. At this point the rate of MHCI endocytosis is accelerated. For the increased rate of MHCI internalization to be effective in reducing MHCI cell surface levels Nef must also block the recycling of MHCI back to the plasma membrane. The revised model does not define an interaction between MHCI and Nef, but the suggestion was made that Nef induces PACS-1 to interact with the cytoplasmic tail of MHCI 41. However, a ternary complex between Nef, the cytoplasmic tail of MHCI and AP1 has been recently demonstrated separately by the Collins and the Guatelli laboratories 4345. This complex appears to activate a cryptic tyrosine sorting signal in the cytoplasmic tail of MHCI and diverts newly synthesized MHCI molecules from their transit to the plasma membrane to an internal compartment in the paranuclear region 434591. Nef appears to be acting as a facilitator since the cytoplasmic tail of MHCI does not bind to AP-1 4345. How the model of Thomas and co-workers can be adapted to include this complex is as yet unresolved (Figure 1, Yellow). It is interesting to note that this ternary complex engages Nef in a novel interaction with MHCI cytoplasmic tail and AP-1 which makes it potentially appealing for targeting by an anti-viral.

However, it should be noted that Nef does not render infected cells completely protected from immune surveillance as there is a strong CTL response to HIV antigens 92. Therefore, it appears that the downregulation of MHCI by Nef fails to block the cytotoxic T cell response to the virus, but the immune response is either misdirected or HIV-1 is able to escape by mutation or both 93. At this point the concept of viral evolution and its relationship to viral pathogenesis should be considered. That there are constraints placed on the virus by the cytotoxic T cell response is clear if the virus mutates to avoid the response 9495. This does not necessarily imply that the targeted HIV-1 or the HIV-1 bearing escape mutation(s) are different in pathogenic potential. In fact, Brumme et al. 94 found an inverse relationship between the number of apparent escape mutations in Nef and the level of CD4⁺ T cells in the blood. In other words, virus with a Nef containing 11 or more escape mutations was more pathogenic than virus with a Nef containing 0–2 mutations. This distressing finding likely reflects Nef having successfully evolved to readily side-step the vast majority of CTL responses. Nef has 63 very highly conserved residues out of 206 (99% identity), but they are scattered throughout the protein so that no more than five are in a row 33. As a result, susceptible epitopes in Nef mutate at variable residues to effectively escape CTLs, but Nef function is not affected.

A relatively small number of HLA epitopes in HIV-1 genes other than Nef have been reported that do involve escape mutations that reduce virulence. These epitopes have been suggested as the basis for a therapeutic vaccine 95. Although Nef amino acid sequences are doubtful contributors to the proposed vaccine an inhibitor of Nef's ability to downregulate MHCI could enhance the effectiveness of such a vaccine. In this regard the Italian male infected with a virus lacking nef subsequently evolved a virus with both a deleted nef and env. Calugi et al 31 interpreted this finding as an inability of the Nef deleted virus to protect itself from CTL attack. Unfortunately, this patient appears to be unique as the SBBC researchers did not find evidence of the development of deletions in other genes 32.

Disease progression may be directly associated with T cell activation 9697. It is also possible that Nef may regulate cellular activation through several kinases including Pak2 4849. and Hck 8298. Pak2 is the best characterized Nef-activated kinase. It has been demonstrated that Nef activation of Pak2 leads to merlin phosphorylation at serine 518 though it has yet to be demonstrated that HIV-1 infection is in anyway dependent on merlin phosphorylation 46. The obvious suggestion of this result that Nef regulates the actin cyotskeleton function is appealing, but the mechanism is controversial 99100101102.

Substantial agreement exists that Nef forms a complex with Pak2 (Figure 1, Orange) 65100103104. Nef not only complexes with Pak2 but also induces Pak2 activation 49105 The ability of Nef to activate Pak2 in multiple HIV-1 subtypes suggests a key role for this Nef function 33106. An interaction domain that is responsible for Pak2 activation has been observed to include residues 89 and 191 33. Lesser contributions are made by residues 85 and 188 103106107. Remarkably, H89 and F191 are highly conserved in subtype B Nefs, but in subtype E Nefs F89 and R191 are highly conserved instead 33. Since subtype E Nefs are active for Pak2 activation it appears that at least two different interaction domains are functional in HIV-1 Nefs. By substituting all four just mentioned residues in a subtype B Nef with residues that predominant in subtype E Nefs (L85F, H89F, R188A, and F191R) the subtype E Pak2 interaction surface can be created in a subtype B background. The quadruple mutant is fully functional though intermediate forms are generally defective 33. The significance of these alternate Pak2 activation domains remains to be determined. However, the presence of different structures to achieve the same function strongly suggests that maintaining the ability to activate Pak2 enhances viral fitness. The importance of Pak2 activation has been questioned on the basis of ex vivo experiments 108. One possibility is that Pak2 activation may be important for transmission or early in infection. However, only limited evidence currently exists to support this hypothesis 21. Regardless, the structural fluidity of Nef's Pak2 interaction surface could make this Nef interaction difficult to target with anti-virals. Investigations to uncover the common features of the alternative activation domains may clarify these issues.

Nef also activates the myeloid lineage specific tyrosine kinase, Hck (Figure 1, Pink). Co-expression of Nef and Hck in Rat-2 fibroblasts leads to cellular transformation 109. Moreover, Nef tightly binds to the Hck SH3 domain in vitro and activates its kinase activity 110. In Rat-2 cells enforced dimerization of Nef enhances Hck activation 98. Nef has also been shown to modestly activate endogenous Hck and, in turn, the Stat3 transcription factor in myeloid cells 111. Interestingly, Hck is the only cellular activity of Nef known to not require Nef myristoylation 111. The Hck/Nef interaction is mediated by an SH3 binding domain in Nef ⁷²PQVPLR⁷⁷ which may be too similar to cellular SH3 interactions to be readily targeted by an anti-viral. On the other hand, one distinctly virus-specific interaction would be Nef dimerization which may be required for Hck activation intracellularly. In fact, Nef spontaneously forms dimers and trimers 112. This may occur when the myristate moiety is buried in a cellular membrane. Disengagement from membrane appears to result in the myristoylated N-terminus of Nef self-associating with a hydrophobic patch on the surface of the structured core of Nef. In this latter conformation Nef is a monomer. Therefore, Nef lacking its N-terminal myristate may dimerize and activate Hck. The relevance of Hck activation for pathogenesis is unknown, but if Nef dimerization and trimerization are of pathological significance it could be a novel target for anti-virals.

Early work on this topic has been previously reviewed 88. Currently, there are three models of how Nef enhances the infectivity of HIV-1 as measured in single infection assays 5054113114. In these assays virus is produced in cells that do not express CD4 and the normalized infectivity is determined on indicator cell lines. Therefore, this effect represents increased infection efficiency for HIV-1 virions, and is distinct from Nef-dependent enhanced particle egress from infected macrophages 115. Campbell et al. noted that the disruption of the actin cytoskeleton in the target cell complemented the defect in infectivity in Nef minus virions (Figure 1, Blue). These authors concluded that cortical actin represents a barrier to infection and that the expression of Nef in the producer cell is able to overcome this barrier 54. In an alternate model Pizzato et al. suggest that there is an unknown cellular protein other than CD4 that blocks the function of Env in the virion. Nef enhances infectivity by downregulating this unknown protein in the producer cell and blocking its incorporation into the virion 50. It is interesting to note that the Nef dileucine motif (¹⁶⁴LL¹⁶⁵) that is required for CD4 downregulation is also required for enhancement of infectivity 116. However, the diacidic motif (¹⁷⁴DD¹⁷⁵) that is necessary for Nef to bind AP-2 is not. This genetically distinguishes enhancement of infectivity from CD4 downregulation. In this case it appears that Nef's canonical dileucine binding motif involving E160 (¹⁶⁰EXXXLL¹⁶⁵) associates with AP-1 and AP-3 85116117. It is not yet known if these results are related to the above mentioned results of Pizzato 50. Finally, Nef may protect the viral core from post-fusion degradation to allow reverse transcription to proceed 113114. This mechanism is consistent with the active degradation of HIV-1 virions that occurs upon entry 118. Despite the attractiveness of a drug that reduces the inherent infectivity of HIV-1 virions the prospects for inhibiting Nef-mediated enhancement of infectivity are presently remote.

Schindler et al. have proposed a surprising explanation for the lack of pathologic effects of most primate lentiviruses in their hosts in contrast to the virulence of HIV-1. Specifically, it was proposed that most simian viruses self-limit their inherent pathogenicity 22. For example, sooty mangabeys do not develop AIDS from their own SIV 119120. Schindler et al suggest this is the result of the SIV from sooty mangabey (SIV_SM) having a Nef that downregulates CD3 which prevents activation of the infected T cell and subsequent activation induced cell death. The authors further propose that the downregulation of CD3 evolved as a mechanism to maintain virus persistence in the presence of an intact host immune system. The CD3 downregulation function was lost in chimpanzee immunodeficiency virus (SIV_CPZ) prior to the infection of humans. Since HIV-1 Nef does not downregulate CD3 humans progress to AIDS as hyperactivation slowly destroys the immune system. The therapeutic implications of this concept are staggering since one must assume that during the course of natural SIV_SM infection there are mutations in nef that abrogate CD3 downregulation. The unanswered question is how these potentially pathogenic SIV_SM mutants are suppressed by the non-pathologic virus? If such a mechanism were to be demonstrated it may be possible to produce an HIV-1 with a Nef that downregulates CD3 and therefore a dominant, non-pathogenic virus.

A distinctly different explanation of non-pathogenicity is that the sooty mangabey itself has a special mechanism for suppressing the progression to AIDS not the virus 121. This would explain the fact that rhesus macaques develop AIDS when directly infected with blood from an infected sooty mangabey, but infection of virus-free sooty mangabeys does not 119. In other words, rhesus macaques die even though the infecting SIV_SM's Nef is downregulating CD3. An additional example of SIV_SM being pathogenic when a species barrier is crossed is SIV_SM causing AIDS in a black mangabey 122. Two additional lineages of SIV including African green monkey (SIV_AGM) and sun-tailed monkey (SIV_SUN) cause AIDS in pig-tailed macaques 123124, but not that from Sykes' monkey (SIV_SYK) 125. Like Nef from SIV_SM the Nefs from SIV_AGM, SIV_SUN, and SIV_SYK all downregulate CD3 22126. It should be further noted that the non-pathogenicity of SIV_SM is not absolute in sooty mangabeys. Ling et al. have reported a 21 year old sooty mangabey which developed AIDS 121. These investigators suggest that the evolutionary adaptation to SIV_SM is one of delayed progression beyond the usual lifespan of the animal which for sooty mangabeys is under 20 years. In the future it will be important to demonstrate SIV_SM and/or SIV_AGM specifically defective in CD3 downregulation are significantly pathogenic in their natural hosts.

Schindler et al. have generalized the hypothesis that CD3 downregulation prevents lentivirus pathogenesis by investigating human immunodeficiency virus 2 (HIV-2) 22. HIV-2 is a zoonotic virus derived from sooty mangabeys 127. It has reduced pathogenicity relative to HIV-1 overall, but progression to AIDS can occur 128. Consistent with reduced pathogenicity HIV-2 Nefs do downregulate CD3 129, but in the cases in which HIV-2 infection has progressed to AIDS one would expect that Nefs derived from these patients would not be functional for CD3 downregulation. This is not the case for Nefs from HIV-2_ROD, HIV-2_BEN, and HIV-2_CBL23 which all came from symptomatic patients and all downregulated CD3 129. The pathogenic phenotype of HIV-2 can also be observed in rhesus macaques 130131. To demonstrate that CD3 downregulation can block disease progression in humans it will be important to thoroughly investigate the relationship between HIV-2 AIDS and CD3 downregulation.

That a given species may be resistant to its own lentivirus without involvement of CD3 downregulation is clearly demonstrated by the non-pathogenic nature of SIV_CPZ. In the case of chimpanzees the downregulation of CD3 cannot serve as a mechanism for non-pathogenicity since SIV_CPZ Nef does not downregulate CD3 22. Humans lack the ability that chimps have to resist the chimpanzee virus and develop AIDS. Finally, there is evidence that virus with the capacity to downregulate CD3 can not delay HIV-1 pathogenesis. This is suggested by the cases of dual HIV-1/HIV-2 infection. Despite the ability of HIV-2 Nef to downregulate CD3 these patients suffer the greater virulence of HIV-1 132. Therefore, it would appear that the non-pathogenic phenotype attributed to Nefs that downregulate CD3 is not dominant over the pathogenic phenotype in humans.

Overall, we conclude that at present there are minimal prospects for therapeutic insights resulting from the attribution of HIV-1 pathogenicity to the inability of HIV-1 Nef to downregulate CD3. If this proposal is to be developed further, it will be necessary to molecularly define the structural correlates of CD3 downregulation. Then the determination could be made if HIV-1 with a Nef modified to downregulate CD3 has reduced pathogenesis in the humanized mouse model 133. Alternatively, the pathogenesis of HIV-2s with and without the ability to downregulate CD3 could be evaluated for virulence in humanized mice.