Feline Leukemia Virus-B Envelope Together With its GlycoGag and Human Immunodeficiency Virus-1 Nef Mediate Resistance to Feline SERINC5

Human SERINC5 (SER5) protein is a recently described restriction factor against human immunodeficiency virus-1 (HIV-1), which is antagonized by HIV-1 Nef protein. Other retroviral accessory proteins such as the glycosylated Gag (glycoGag) from the murine leukemia virus (MLV) can also antagonize SER5. In addition, some viruses escape SER5 restriction by expressing a SER5-insensitive envelope (Env) glycoprotein. Here, we studied the activity of human and feline SER5 on HIV-1 and on the two pathogenic retroviruses in cats, feline immunodeficiency virus (FIV) and feline leukemia virus (FeLV). HIV-1 in absence of Nef is restricted by SER5 from domestic cats and protected by its Nef protein. The sensitivity of feline retroviruses FIV and FeLV to human and feline SER5 is considerably different: FIV is sensitive to feline and human SER5 and lacks an obvious mechanism to counteract SER5 activity, while FeLV is relatively resistant to SER5 inhibition. We speculated that similar to MLV, FeLV-A or FeLV-B express glycoGag proteins and investigated their function against human and feline SER5 in wild type and envelope deficient virus variants. We found that the endogenous FeLV recombinant virus, FeLV-B but not wild type exogenous FeLV-A envelope mediates a strong resistance against human and feline SER5. GlycoGag has an additional but moderate role to enhance viral infectivity in the presence of SER5 that seems to be dependent on the FeLV envelope. These findings may explain, why in vivo FeLV-B has a selective advantage and causes higher FeLV levels in infected cats compared to infections of FeLV-A only.     

HIV-1 Nef control of cell signalling molecules: Multiple strategies to promote virus replication

HIV-1 has at its disposal numerous proteins encoded by its genome which provide the required arsenal to establish and maintain infection in its host for a considerable number of years. One of the most important and enigmatic of these proteins is Nef. The Nef protein of HIV-1 plays a fundamental role in the virus life cycle. This small protein of approximately 27 kDa is required for maximal virus replication and disease progression. The mechanisms by which it is able to act as a positive factor during virus replication is an area of intense research and although some controversy surrounds Nef much has been gauged as to how it functions. Its ability to modulate the expression of key cellular receptors important for cell activation and control signal transduction elements and events by interacting with numerous cellular kinases and signalling molecules, including members of the Src family kinases, leading to an effect on host cell function is likely to explain at least in part its role during infection and represents a finely tuned mechanism where this protein assists HIV-1 to control its host.     

Dysregulation of autophagy by HIV-1 Nef in human astrocytes

Viruses often exploit autophagy, a common cellular process of degradation of damaged proteins, organelles, and pathogens, to avoid destruction. HIV-1 dysregulates this process in several cell types by means of Nef protein. Nef is a small HIV-1 protein which is expressed abundantly in astrocytes of HIV-1-infected brains and has been suggested to have a role in the pathogenesis of HIV-Associated Neurocognitive Disorders (HAND). In order to explore its effect in the CNS with respect to autophagy, HIV-1 Nef was expressed in primary human fetal astrocytes (PHFA) using an adenovirus vector (Ad-Nef). We observed that Nef expression triggered the accumulation of autophagy markers, ATG8/LC3 and p62 (SQSMT1). Similar results were obtained with Bafilomycin A1, an autophagy inhibitor which blocks the fusion of autophagosome to lysosome. Furthermore co-expression of tandem LC3 vector (mRFP-EGFP-LC3) and Ad-Nef in these cells produced mainly yellow puncta (mRFP+, EGFP+) strongly suggesting that autophagosome fusion to lysosome is blocked in PHFA cells in the presence of Nef. Together these data indicate that HIV-1 Nef mimics Bafilomycin A1 and blocks the last step of autophagy thereby helping HIV-1 virus to avoid autophagic degradation in human astrocytes.     

Nef of HIV-1 interacts directly with calcium-bound calmodulin

It was recently found that the myristoyl group of CAP-23/NAP-22, a neuron-specific protein kinase C substrate, is essential for the interaction between the protein and Ca(2+)-bound calmodulin (Ca(2+)/CaM). Based on the N-terminal amino acid sequence alignment of CAP-23/NAP-22 and other myristoylated proteins, including the Nef protein from human immunodeficiency virus (HIV), we proposed a new hypothesis that the protein myristoylation plays important roles in protein-calmodulin interactions. To investigate the possibility of direct interaction between Nef and calmodulin, we performed structural studies of Ca(2+)/CaM in the presence of a myristoylated peptide corresponding to the N-terminal region of Nef. The dissociation constant between Ca(2+)/CaM and the myristoylated Nef peptide was determined to be 13.7 nM by fluorescence spectroscopy analyses. The NMR experiments indicated that the chemical shifts of some residues on and around the hydrophobic clefts of Ca(2+)/CaM changed markedly in the Ca(2+)/CaM-Nef peptide complex with the molar ratio of 1:2. Correspondingly, the radius of gyration determined by the small angle X-ray scattering measurements is 2-3 A smaller that of Ca(2+)/CaM alone. These results demonstrate clearly that Nef interacts directly with Ca(2+)/CaM.     

Dynamic interaction of HIV-1 Nef with the clathrin-mediated endocytic pathway at the plasma membrane

The HIV-1 Nef protein perturbs the trafficking of membrane proteins such as CD4 by interacting with clathrin-adaptor complexes. We previously reported that Nef alters early/recycling endosomes, but its role at the plasma membrane is poorly documented. Here, we used total internal reflection fluorescence microscopy, which restricts the analysis to a approximately 100 nm region of the adherent surface of the cells, to focus on the dynamic of Nef at the plasma membrane relative to that of clathrin. Nef colocalized both with clathrin spots (CS) that remained static at the cell surface, corresponding to clathrin-coated pits (CCPs), and with approximately 50% of CS that disappeared from the cell surface, corresponding to forming clathrin-coated vesicles (CCVs). The colocalization of Nef with clathrin required the di-leucine motif essential for Nef binding to AP complexes and was independent of CD4 expression. Furthermore, analysis of Nef mutants showed that the capacity of Nef to induce internalization and downregulation of CD4 in T lymphocytes correlated with its localization into CCPs. In conclusion, this analysis shows that Nef is recruited into CCPs and into forming CCVs at the plasma membrane, in agreement with a model in which Nef uses the clathrin-mediated endocytic pathway to induce internalization of some membrane proteins from the surface of HIV-1-infected T cells.     

HIV‐1 Nef: Taking Control of Protein Trafficking

The Nef protein of the human immunodeficiency virus is a crucial determinant of viral pathogenesis and disease progression. Nef is abundantly expressed early in infection and is thought to optimize the cellular environment for viral replication. Nef controls expression levels of various cell surface molecules that play important roles in immunity and virus life cycle, by directly interfering with the itinerary of these proteins within the endocytic and late secretory pathways. To exert these functions, Nef physically interacts with host proteins that regulate protein trafficking. In recent years, considerable progress was made in identifying host‐cell‐interacting partners for Nef, and the molecular machinery used by Nef to interfere with protein trafficking has started to be unraveled. Here, we briefly review the knowledge gained and discuss new findings regarding the mechanisms by which Nef modifies the intracellular trafficking pathways to prevent antigen presentation, facilitate viral particle release and enhance the infectivity of HIV‐1 virions.      

HIV-1 Nef protein: purification, crystallizations, and preliminary X-ray diffraction studies.

Human immunodeficiency virus Nef protein accelerates virulent progression of AIDS by its interaction with specific cellular proteins involved in cellular activation and signal transduction. Here we report the purification and crystallization of the conserved core of HIV-1LAI Nef protein in the unliganded form and in complex with the wild-type SH3 domain of the P59fyn protein-tyrosine kinase. One-dimensional NMR experiments show that full-length protein and truncated fragment corresponding to the product of HIV-1 protease cleavage have a well-folded compact tertiary structure. The ligand-free HIV-1 Nefcore protein forms cubic crystals belonging to space group P23 with unit cell dimensions of a = b = c = 86.4 A. The Nef-Fyn SH3 cocrystals belong to the space group P6(1)22 or its enantiomorph, P6(5)22, with unit cell dimensions of a = b = 108.2 A and c = 223.7 A. Both crystal forms diffract to a resolution limit of 3.0 A resolution using synchrotron radiation, and are thus suitable for X-ray structure determination.     

Interaction of HIV-1 Nef Protein with the Host Protein Alix Promotes Lysosomal Targeting of CD4 Receptor

Nef is an accessory protein of human immunodeficiency viruses that promotes viral replication and progression to AIDS through interference with various host trafficking and signaling pathways. A key function of Nef is the down-regulation of the coreceptor CD4 from the surface of the host cells. Nef-induced CD4 down-regulation involves at least two independent steps as follows: acceleration of CD4 endocytosis by a clathrin/AP-2-dependent pathway and targeting of internalized CD4 to multivesicular bodies (MVBs) for eventual degradation in lysosomes. In a previous work, we found that CD4 targeting to the MVB pathway was independent of CD4 ubiquitination. Here, we report that this targeting depends on a direct interaction of Nef with Alix/AIP1, a protein associated with the endosomal sorting complexes required for transport (ESCRT) machinery that assists with cargo recruitment and intraluminal vesicle formation in MVBs. We show that Nef interacts with both the Bro1 and V domains of Alix. Depletion of Alix or overexpression of the Alix V domain impairs lysosomal degradation of CD4 induced by Nef. In contrast, the V domain overexpression does not prevent cell surface removal of CD4 by Nef or protein targeting to the canonical ubiquitination-dependent MVB pathway. We also show that the Nef-Alix interaction occurs in late endosomes that are enriched in internalized CD4. Together, our results indicate that Alix functions as an adaptor for the ESCRT-dependent, ubiquitin-independent targeting of CD4 to the MVB pathway induced by Nef.     

TRIM proteins regulate autophagy: TRIM5 is a selective autophagy receptor mediating HIV-1 restriction

The tripartite motif protein family (TRIM) constitutes a class of immune-regulated proteins with antiviral, immune, cancer, and other properties reminiscent of those ascribed to autophagy. We show that TRIMs have dual roles in autophagy: as regulators and as cargo receptors. As regulators, TRIMs nucleate the core autophagy machinery by acting as platforms that assemble ULK1 and BECN1 into a functional complex in preparation for autophagy. TRIMs also act as novel selective autophagy receptors as exemplified by TRIM5/TRIM5α, a known HIV-1 restriction factor with a hitherto poorly defined mode of action. TRIM5 recognizes and targets HIV-1 for autophagic destruction. TRIM5 interactions with mammalian Atg8 proteins are required for this effector function. This establishes TRIM family members as regulators of autophagy, explains the antiretroviral mechanism of TRIM5, and defines a new basis for selective autophagy.     

TRIM proteins regulate autophagy: TRIM5 is a selective autophagy receptor mediating HIV-1 restriction

The tripartite motif protein family (TRIM) constitutes a class of immune-regulated proteins with antiviral, immune, cancer, and other properties reminiscent of those ascribed to autophagy. We show that TRIMs have dual roles in autophagy: as regulators and as cargo receptors. As regulators, TRIMs nucleate the core autophagy machinery by acting as platforms that assemble ULK1 and BECN1 into a functional complex in preparation for autophagy. TRIMs also act as novel selective autophagy receptors as exemplified by TRIM5/TRIM5α, a known HIV-1 restriction factor with a hitherto poorly defined mode of action. TRIM5 recognizes and targets HIV-1 for autophagic destruction. TRIM5 interactions with mammalian Atg8 proteins are required for this effector function. This establishes TRIM family members as regulators of autophagy, explains the antiretroviral mechanism of TRIM5, and defines a new basis for selective autophagy.     

Neutron Reflectometry and Molecular Simulations Demonstrate HIV-1 Nef Homodimer Formation on Model Lipid Bilayers

The HIV-1 Nef protein plays a critical role in viral infectivity, high-titer replication in vivo, and immune escape of HIV-infected cells. Nef lacks intrinsic biochemical activity, functioning instead through interactions with diverse host cell signaling proteins and intracellular trafficking pathways. Previous studies have established an essential role for Nef homodimer formation at the plasma membrane for most if not all its functions. Here we combined neutron reflectometry of full-length myristoylated Nef bound to model lipid bilayers with molecular simulations based on previous X-ray crystal structures of Nef homodimers. This integrated approach provides direct evidence that Nef associates with the membrane as a homodimer with its structured core region displaced from the membrane for partner protein engagement. Parallel studies of a dimerization-defective mutant, Nef-L112D, demonstrate that the helical dimerization interface present in previous crystal structures stabilizes the membrane-bound dimer. X-ray crystallography of the Nef-L112D mutant in complex with the SH3 domain of the Nef-associated host cell kinase Hck revealed a monomeric 1:1 complex instead of the 2:2 dimer complex formed with wild-type Nef. Importantly, the crystal structure of the Nef-L112D core and SH3 interface are virtually identical to the wild-type complex, indicating that this mutation does not affect the overall Nef fold. These findings support the intrinsic capacity of Nef to homodimerize at lipid bilayers using structural features present in X-ray crystal structures of dimeric complexes.     

The ABCA1 domain responsible for interaction with HIV-1 Nef is conformational and not linear

HIV-1 Nef is an accessory protein responsible for inactivation of a number of host cell proteins essential for anti-viral immune responses. In most cases, Nef binds to the target protein and directs it to a degradation pathway. Our previous studies demonstrated that Nef impairs activity of the cellular cholesterol transporter, ABCA1, and that Nef interacts with ABCA1. Mutation of the ²²²⁶DDDHLK motif in the C-terminal cytoplasmic tail of ABCA1 disrupted interaction with Nef. Here, we tested Nef interaction with the ABCA1 C-terminal cytoplasmic fragment using yeast 2-hybrid system assay and co-immunoprecipitation analysis in human cells. Surprisingly, analysis in a yeast 2-hybrid system did not reveal any interaction between Nef and the C-terminal cytoplasmic fragment of ABCA1. Using co-immunoprecipitation from HEK 293T cells expressing these polypeptides, only a very weak interaction could be detected. The ²²²⁶DDDHLK motif in the C-terminal cytoplasmic tail of ABCA1 found previously to be essential for interaction between ABCA1 and Nef is insufficient to bestow strong binding to Nef. Molecular modeling suggested that interaction with Nef may be mediated by a conformational epitope composed of the sequences within the cytoplasmic loop of ABCA1 and the C-terminal cytoplasmic domain. Studies are now underway to characterize this epitope.     

Macropinocytosis and TAK1 mediate anti-inflammatory to pro-inflammatory macrophage differentiation by HIV-1 Nef

Macrophages (MΦ) are functionally classified into two types, anti-inflammatory M2 and pro-inflammatory M1. Importantly, we recently revealed that soluble HIV-1 proteins, particularly the pathogenetic protein Nef, preferentially activate M2-MΦ and drive them towards an M1-like MΦ, which might explain the sustained immune activation seen in HIV-1-infected patients. Here, we show that the preferential effect of Nef on M2-MΦ is mediated by TAK1 (TGF-β-activated kinase 1) and macropinocytosis. As with MAP kinases and NF-κB pathway, Nef markedly activated TAK1 in M-CSF-derived M2-MΦ but not in GM-CSF-derived M1-MΦ. Two Nef mutants, which were unable to activate MAP kinases and NF-κB pathway, failed to activate TAK1. Indeed, the TAK1 inhibitor 5Z-7-oxozeaenol as well as the ectopic expression of a dominant-negative mutant of TAK1 or TRAF2, an upstream molecule of TAK1, inhibited Nef-induced signaling activation and M1-like phenotypic differentiation of M2-MΦ. Meanwhile, the preferential effect of Nef on M2-MΦ correlated with the fact the Nef entered M2-MΦ more efficiently than M1-MΦ. Importantly, the macropinosome formation inhibitor EIPA completely blocked the internalization of Nef into M2-MΦ. Because the macropinocytosis activity of M2-MΦ was higher than that of M1-MΦ, our findings indicate that Nef enters M2-MΦ efficiently by exploiting their higher macropinocytosis activity and drives them towards M1-like MΦ by activating TAK1.     

The HIV-1 accessory protein Nef increases surface expression of the checkpoint receptor Tim-3 in infected CD4+ T cells

Prolonged immune activation drives the upregulation of multiple checkpoint receptors on the surface of virus-specific T cells, inducing their exhaustion. Reversing HIV-1-induced T cell exhaustion is imperative for efficient virus clearance; however, viral mediators of checkpoint receptor upregulation remain largely unknown. The enrichment of checkpoint receptors on T cells upon HIV-1 infection severely constrains the generation of an efficient immune response. Herein, we examined the role of HIV-1 Nef in mediating the upregulation of checkpoint receptors on peripheral blood mononuclear cells. We demonstrate that the HIV-1 accessory protein Nef upregulates cell surface levels of the checkpoint receptor T-cell immunoglobulin mucin domain-3 (Tim-3) and that this is dependent on Nef''s dileucine motif LL_164/165. Furthermore, we used a bimolecular fluorescence complementation assay to demonstrate that Nef and Tim-3 form a complex within cells that is abrogated upon mutation of the Nef dileucine motif. We also provide evidence that Nef moderately promotes Tim-3 shedding from the cell surface in a dileucine motif–dependent manner. Treating HIV-1-infected CD4⁺ T cells with a matrix metalloprotease inhibitor enhanced cell surface Tim-3 levels and reduced Tim-3 shedding. Finally, Tim-3-expressing CD4⁺ T cells displayed a higher propensity to release the proinflammatory cytokine interferon-gamma. Collectively, our findings uncover a novel mechanism by which HIV-1 directly increases the levels of a checkpoint receptor on the surface of infected CD4⁺ T cells.     

Structure, dynamics, and Hck interaction of full-length HIV-1 Nef

Nef is an HIV accessory protein that plays an important role in the progression of disease after viral infection. It interferes with numerous signaling pathways, one of which involves serine/threonine kinases. Here, we report the results of an NMR structural investigation on full-length Nef and its interaction with the entire regulatory domain of Hck (residues 72-256; Hck32L). A helical conformation was found at the N-terminus for residues 14-22, preceding the folded core domain. In contrast to the previously studied truncated Nef (Nef Δ1-39), the full-length Nef did not show any interactions of Trp57/Leu58 with the hydrophobic patch formed by helices α1 and α2. Upon Hck32L binding, the N-terminal anchor domain as well as the well-known SH3-binding site of Nef exhibited significant chemical shift changes. Upon Nef binding, resonance changes in the Hck spectrum were confined mostly to the SH3 domain, with additional effects seen for the connector between SH3 and SH2, the N-terminal region of SH2 and the linker region that contains the regulatory polyproline motif. The binding data suggest that in full-length Nef more than the core domain partakes in the interaction. The solution conformation of Hck32L was modeled using RDC data and compared with the crystal structure of the equivalent region in the inactivated, full-length Hck, revealing a notable difference in the relative orientations of the SH3 and SH2 domains. The RDC-based model combined with (15)N backbone dynamics data suggest that Hck32L adopts an open conformation without binding of the polyproline motif in the linker to the SH3 domain.     

Targeting of HIV-1 Nef to the centrosome: implications for antigen processing

To gain a better understanding of the intracellular sites of antigen processing we have looked at the localization of human immunodeficiency virus (HIV)-1 Nef protein by confocal microscopic and biochemical means. We found that ubiquitin (Ub)-Nef fusion proteins were localized to the centrosome in transfected COS-7 cells, and that the colocalization was inhibited by the microtubule-disrupting agent, nocodazole. Interestingly, we found that Ub-Nef trafficking to the centrosome was not dependent upon the metabolic stability of Ub-Nef nor on the inhibition of proteasome activity. We also analyzed the MHC class I antigen processing of a reporter epitope linked to the Ub-Nef fusion proteins and found that Ub-Nef was processed in COS-7 cells. In addition, we show that this processing was inhibited by nocodazole. We suggest that the centrosome may serve as a site of antigen processing in vivo.     

Inhibition of ER stress-mediated apoptosis in macrophages by nuclear-cytoplasmic relocalization of eEF1A by the HIV-1 Nef protein

HIV-1 Nef protein has key roles at almost all stages of the viral life cycle. We assessed the role of the Nef/eEF1A (eukaryotic translation elongation factor 1-alpha) complex in nucleocytoplasmic shuttling in primary human macrophages. Nuclear retention experiments and inhibition of the exportin-t (Exp-t) pathway suggested that cytoplasmic relocalization of eEF1A, mediated by Exp-t, occurs in Nef-treated monocyte-derived macrophages (MDMs). We observed the presence of tRNA in the Nef/eEF1A complexes. Nucleocytoplasmic relocalization of the Nef/eEF1A complexes prevented stress-induced apoptosis of MDMs treated with brefeldin-A. Blockade of stress-induced apoptosis of MDMs treated with HIV-1 Nef resulted from enhanced nucleocytoplasmic transport of eEF1A with decreased release of mitochondrial cytochrome c, and from increased tRNA binding to cytochrome c, ultimately leading to an inhibition of caspase activation. Our results indicate that HIV-1 Nef, through the nucleocytoplasmic relocalization of eEF1A and tRNAs, enhances resistance to stress-induced apoptosis in primary human macrophages.     

病毒负性调节因子在内皮细胞稳定表达细胞株的建立

建立HIV-1的调节基因Nef基因在内皮细胞稳定表达的细胞株ECV304-Nef,为研究Nef对血管内皮细胞生物学活性的影响奠定试验基础。构建真核表达载体pcDNA3.1(+)-Nef,将其质粒和pcDNA3.1(+)质粒(阴性对照)分别转染血管内皮细胞ECV304,G418筛选。通过RT-PCR检测NefmRNA在细胞中的表达;细胞免疫荧光法检测Nef蛋白的表达及定位;Western blotting检测Nef蛋白的特异性表达,获得稳定表达的细胞株。构建的重组质粒pcDNA3.1(+)-Nef经BamHI和EcoRI双酶切鉴定,得到的片段大小与理论值相符,分别为载体的5400bp和目的基因的621bp。测序结果显示碱基序列与GenBank(登录号:K03455)序列相同。转染细胞经G418筛选后获得稳定表达Nef的ECV304细胞株,RT-PCR显示转染pcD-NA3.1(+)-Nef质粒的ECV304细胞出现621bp条带,对照组无目的条带出现;荧光显微镜下观察转染pcDNA3.1(+)-Nef质粒的ECV304细胞表达的Nef蛋白主要定位于细胞质中。Western blotting结果显示,转染pcDNA3.1(+)-Nef质粒的ECV304细胞约27kD处检测到目的条带,表明pcDNA3.1(+)-Nef表达正确。