熊猴存在TRIM5/TRIMCyp杂合子基因型

缺乏合适的动物模犁是制约艾滋病研究取得重大突破的关键瓶颈之一.细胞内的抗病毒蛋白被称为限制因子.研究不同灵长类动物抗HIV-1宿主限制因子的存在形式及作用机制对建立合适AIDS灵长类动物模型有十分重要的意义.TRIM5α是哺乳动物细胞中一种重要和关键的限制因子,它以物种依赖的方式限制包括HIV-1在内的逆转录病毒的感染.TRIM5-CypA融合基因是存在于新大陆猴与旧大陆猴中的一种独特的TRIM5基因形式.为了研究不同灵长类动物TRIM5基因的存在方式,该文对熊猴、藏婀猴、红面猴及中闰恒河猴4个物种共110只灵长类动物进行了TRIM5-CypA融合模式的研究.首次发现熊猴也存在TRIM5-CypA基因融合现象.熊猴TRIMCyp融合基因形成模式类似于北平顺猴TRIMCyp融合基因模式,即CypA假基因的cDNA序列通过逆转座方式插入到TRIM5基凶的3'-UTR区域.基因序列分析表明,该基因与北平顶猴相应基因序列高度相似;并且其TRIM5内含子6的3'-剪接位点也相应存存G-to-T突变现象(G/T).这提示熊猴也极有可能像北平顶猴一样表达TRIM5-CypA融合蛋白,从而导致熊猴可能跟北平顶猴一样可能被HIV-1感染.因此,熊猴极有希望成为一种新的HIV/AIDS灵长类动物模型.     

Retrovirus Restriction by TRIM5 Proteins Requires Recognition of Only a Small Fraction of Viral Capsid Subunits

The host restriction factors TRIM5α and TRIMCyp potently inhibit retrovirus infection by binding to the incoming retrovirus capsid. TRIM5 proteins are dimeric, and their association with the viral capsid appears to be enhanced by avidity effects owing to formation of higher-order oligomeric complexes. We examined the stoichiometric requirement for TRIM5 functional recognition by quantifying the efficiencies of restriction of HIV-1 and murine leukemia virus (MLV) particles containing various proportions of restriction-sensitive and -insensitive CA subunits. Both TRIMCyp and TRIM5α inhibited infection of retrovirus particles containing as little as 25% of the restriction-sensitive CA protein. Accordingly, we also observed efficient binding of TRIMCyp in vitro to capsid assemblies containing as little as one-fourth wild-type CA protein. Paradoxically, the ability of HIV-1 particles to abrogate TRIMCyp restriction in trans was more strongly dependent on the fraction of wild-type CA than was restriction of infection. Collectively, our results indicate that TRIM5 restriction factors bind to retroviral capsids in a highly cooperative manner and suggest that TRIM5 can engage a capsid lattice containing a minimum of three or fewer recognizable subunits per hexamer. Our study supports a model in which localized binding of TRIM5 to the viral capsid nucleates rapid polymerization of a TRIM5 lattice on the capsid surface.     

Antiretroviral activity of ancestral TRIM5alpha

The antiretroviral protein TRIM5α is known to have evolved different restriction capacities against various retroviruses, driven by positive Darwinian selection. However, how these different specificities have evolved in the primate lineages is not fully understood. Here we used ancestral protein resurrection to estimate the evolution of antiviral restriction specificities of TRIM5α on the primate lineage leading to humans. We used TRIM5α coding sequences from 24 primates for the reconstruction of ancestral TRIM5α sequences using maximum-likelihood and Bayesian approaches. Ancestral sequences were transduced into HeLa and CRFK cells. Stable cell lines were generated and used to test restriction of a panel of extant retroviruses (human immunodeficiency virus type 1 [HIV-1] and HIV-2, simian immunodeficiency virus [SIV] variants SIV_mac and SIV_agm, and murine leukemia virus [MLV] variants N-MLV and B-MLV). The resurrected TRIM5α variant from the common ancestor of Old World primates (Old World monkeys and apes, ~25 million years before present) was effective against present day HIV-1. In contrast to the HIV-1 restriction pattern, we show that the restriction efficacy against other retroviruses, such as a murine oncoretrovirus (N-MLV), is higher for more recent resurrected hominoid variants. Ancestral TRIM5α variants have generally limited efficacy against HIV-2, SIV_agm, and SIV_mac. Our study sheds new light on the evolution of the intrinsic antiviral defense machinery and illustrates the utility of functional evolutionary reconstruction for characterizing recently emerged protein differences.     

Wild type and <Emphasis Type="Italic">H43Y</Emphasis> variant of human <Emphasis Type="Italic">TRIM5α</Emphasis> show similar anti-human immunodeficiency virus type 1 activity both in vivo and in vitro

Polymorphisms in human genes have been shown to affect the rate of disease progression to acquired immune deficiency syndrome in human immunodeficiency virus type 1 (HIV-1)-infected individuals. Recently, tripartite motif 5α (TRIM5α) was identified as a factor that confers resistance to HIV-1 infection in Old World monkey cells. Subsequently, Sawyer et al. (Curr Biol 16:95–100, 2006) reported a single nucleotide polymorphism (H43Y) in the human TRIM5α gene and TRIM5α protein with 43Y was found to lose its ability to restrict HIV-1. In the present study, we reevaluated effects of this allele on in vitro anti-HIV-1 activity as well as on HIV-1 disease progression in European and Asian cohorts of HIV-1-infected individuals. Our epidemiological and molecular biological findings clearly indicate H43Y has a very minor effect on anti-HIV-1 activity of TRIM5α, suggesting that this allele is immaterial, at least in HIV-1-infected Europeans and Asians.     

Genetic association of the antiviral restriction factor TRIM5alpha with human immunodeficiency virus type 1 infection

The innate antiviral factor TRIM5alpha restricts the replication of some retroviruses through its interaction with the viral capsid protein, leading to abortive infection. While overexpression of human TRIM5alpha results in modest restriction of human immunodeficiency virus type 1 (HIV-1), this inhibition is insufficient to block productive infection of human cells. We hypothesized that polymorphisms within TRIM5 may result in increased restriction of HIV-1 infection. We sequenced the TRIM5 gene (excluding exon 5) and the 4.8-kb 5' putative regulatory region in genomic DNA from 110 HIV-1-infected subjects and 96 exposed seronegative persons, along with targeted gene sequencing in a further 30 HIV-1-infected individuals. Forty-eight single nucleotide polymorphisms (SNPs), including 20 with allele frequencies of >1.0%, were identified. Among these were two synonymous and eight nonsynonymous coding polymorphisms. We observed no association between TRIM5 polymorphism in HIV-1-infected subjects and their set-point viral load after acute infection, although one TRIM5 haplotype was weakly associated with more rapid CD4(+) T-cell loss. Importantly, a TRIM5 haplotype containing the nonsynonymous SNP R136Q showed increased frequency among HIV-1-infected subjects relative to exposed seronegative persons, with an odds ratio of 5.49 (95% confidence interval = 1.83 to 16.45; P = 0.002). Nonetheless, we observed no effect of individual TRIM5alpha nonsynonymous mutations on the in vitro HIV-1 susceptibility of CD4(+) T cells. Therefore, any effect of TRIM5alpha polymorphism on HIV-1 infection in primary lymphocytes may depend on combinations of SNPs or on DNA sequences in linkage disequilibrium with the TRIM5alpha coding sequence.     

The etiology of multiple sclerosis: genetic evidence for the involvement of the human endogenous retrovirus HERV-Fc1

We have investigated the role of human endogenous retroviruses in multiple sclerosis by analyzing the DNA of patients and controls in 4 cohorts for associations between multiple sclerosis and polymorphisms near viral restriction genes or near endogenous retroviral loci with one or more intact or almost-intact genes. We found that SNPs in the gene TRIM5 were inversely correlated with disease. Conversely, SNPs around one retroviral locus, HERV-Fc1, showed a highly significant association with disease. The latter association was limited to a narrow region that contains no other known genes. We conclude that HERV-Fc1 and TRIM5 play a role in the etiology of multiple sclerosis. If these results are confirmed, they point to new modes of treatment for multiple sclerosis.     

Cyclophilin A renders human immunodeficiency virus type 1 sensitive to Old World monkey but not human TRIM5 alpha antiviral activity

TRIM5alpha is an important mediator of antiretroviral innate immunity influencing species-specific retroviral replication. Here we investigate the role of the peptidyl prolyl isomerase enzyme cyclophilin A in TRIM5alpha antiviral activity. Cyclophilin A is recruited into nascent human immunodeficiency virus type 1 (HIV-1) virions as well as incoming HIV-1 capsids, where it isomerizes an exposed proline residue. Here we show that cyclophilin A renders HIV-1 sensitive to restriction by TRIM5alpha in cells from Old World monkeys, African green monkey and rhesus macaque. Inhibition of cyclophilin A activity with cyclosporine A, or reducing cyclophilin A expression with small interfering RNA, rescues TRIM5alpha-restricted HIV-1 infectivity. The effect of cyclosporine A on HIV-1 infectivity is dependent on TRIM5alpha expression, and expression of simian TRIM5alpha in permissive feline cells renders them able to restrict HIV-1 in a cyclosporine A-sensitive way. We use an HIV-1 cyclophilin A binding mutant (CA G89V) to show that cyclophilin A has different roles in restriction by Old World monkey TRIM5alpha and owl monkey TRIM-Cyp. TRIM-Cyp, but not TRIM5alpha, recruits its tripartite motif to HIV-1 capsid via cyclophilin A and, therefore, HIV-1 G89V is insensitive to TRIM-Cyp but sensitive to TRIM5alpha. We propose that cyclophilin A isomerization of a proline residue in the TRIM5alpha sensitivity determinant of the HIV-1 capsid sensitizes it to restriction by Old World monkey TRIM5alpha. In humans, where HIV-1 has adapted to bypass TRIM5alpha activity, the effects of cyclosporine A are independent of TRIM5alpha. We speculate that cyclophilin A alters HIV-1 sensitivity to a TRIM5alpha-independent innate immune pathway in human cells.     

Cyclophilin, TRIM5, and innate immunity to HIV-1

The peptidyl-prolyl isomerase cyclophilin A (CypA) binds a proline-rich loop on the surface of HIV-1 capsid (CA). This interaction increases HIV-1 infectivity in humans but promotes an anti-HIV-1 restriction activity in non-human primates. Efforts to understand these paradoxical effects of cyclophilin, along with more targeted approaches to uncover the genetic basis for HIV-1 restriction, led to the discovery of TRIM5 (tripartite motif protein 5), a CA-specific receptor for the retroviral core. The ensuing TRIM5 publication flurry established a paradigm of innate immunity in which the protein lattice of an invading retroviral core, rather than double-stranded RNA or lipopolysaccharide, is recognized by a multimeric, cytoplasmic receptor. CypA modulates HIV-1 virion core detection by this class of innate pattern recognition molecule, apparently by inducing subtle shifts in CA conformation.     

The eukaryotic cofactor for the human immunodeficiency virus type 1 (HIV-1) rev protein, eIF-5A, maps to chromosome 17p12–p13: three eIF-5A pseudogenes map to 10q23.3, 17q25, and 19q13.2

The eukaryotic initiation factor 5A (eIF-5A) has been identified as an essential cofactor for the HIV-1 trans-activator protein Rev. Rev plays a key role in the complex regulation of HIV-1 gene expression and thereby in the generation of infectious virus particles. Expression of eIF-5A is vital for Rev function, and inhibition of this interaction leads to a block of the viral replication cycle. In humans, four different eIF-5A genes have been identified. One codes for the eIF-5A protein and the other three are pseudogenes. Using a panel of somatic rodent—human cell hybrids in combination with fluorescence in situ hybridization analysis, we show that the four genes map to threedifferent chromosomes. The coding eIF-5A gene (EIF5A) maps to 17p12–p13, and the three pseudogenes EIF5AP1, EIF5AP2, and EIF5AP3 map to 10q23.3, 17q25, and 19q13.2, respectively. This is the first localization report for a eukaryotic cofactor for a regulatory HIV-1 protein.     

High-frequency persistence of an impaired allele of the retroviral defense gene TRIM5alpha in humans

The intracellular TRIM5alpha protein successfully inhibits HIV-1 infection in rhesus monkeys, but not in humans . A few amino acids in the virus-interacting SPRY domain were found to be responsible for most of this anti-viral specificity , raising the possibility that genetic variation among humans could result in TRIM5alpha proteins with a spectrum of potencies. We found several nonsynonymous SNPs at the human TRIM5 locus, but only one of these (H43Y) was found to have a significant functional consequence. We demonstrate that H43Y impairs TRIM5alpha restriction of two distantly related retroviruses. H43Y lies in the RING domain of TRIM5alpha and may negatively affect its putative E3 ubiquitin ligase activity. This detrimental allele dates back to before the African diaspora and is found at a frequency of 43% in indigenous Central and South Americans. We suggest that relaxed constraint due to a recent period of low retroviral challenge has allowed the deleterious H43Y mutation to persist and even to expand after the bottleneck that occurred upon human migration to the New World. The unexpectedly high frequency of an impaired retroviral restriction allele among humans is likely to have a significant impact on our ability to ward off future retroviral challenges.     

Characterisation of a cluster of TRIM-B30.2 genes in the chicken MHC B locus

We have identified and characterised a cluster of six TRIM-B30.2 genes flanking the chicken BF/BL region of the B complex. The TRIM-B30.2 proteins are a subgroup of the TRIM protein family containing the tripartite motif (TRIM), consisting of a RING domain, a B-box and a coiled coil region, and a B30.2-like domain. In humans, a cluster of seven TRIM-B30.2 genes has been characterised within the MHC on Chromosome 6p21.33. Among the six chicken TRIM-B30.2 genes two are orthologous to those of the human MHC, and two (TRIM41 and TRIM7) are orthologous to human genes located on Chromosome 5. In humans, these last two genes are adjacent to GNB2L1, a guanine nucleotide-binding protein gene, the ortholog of the chicken c12.3 gene situated in the vicinity of the TRIM-B30.2 genes. This suggests that breakpoints specific to mammals have occurred and led to the remodelling of their MHC structure. In terms of structure, like their mammalian counterparts, each chicken gene consists of five coding exons; exon 1 encodes the RING domain and the B-box, exons 2, 3 and 4 form the coiled-coil region, and the last exon represents the B30.2-like domain. Phylogenetic analysis led us to assume that this extended BF/BL region may be similar to the human extended class I region, because it contains a cluster of BG genes sharing an Ig-V like domain with the BTN genes (Henry et al. 1997a) and six TRIM-B30.2 genes containing the B30.2-like domain, shared with the TRIM-B30.2 members and the BTN genes.     

Investigation of the RH locus in gorillas and chimpanzees

The human Rh blood-group system is encoded by two homologous genes,RhD andRhCE. TheRH genes in gorillas and chimpanzees were investigated to delineate the phylogeny of the humanRH genes. Southern blot analysis with an exon 7-specific probe suggested that gorillas have more than twoRH genes, as has recently been reported for chimpanzees. Exon 7 was well conserved between humans, gorillas, and chimpanzees, although the exon 7 nucleotide sequences from gorillas were more similar to the humanD gene, whereas the nucleotide sequences of this exon in chimpanzees were more similar to the humanCE gene. The intron between exon 4 and exon 5 is polymorphic and can be used to distinguish the humanD gene from theCE gene. Nucleotide sequencing revealed that the basis for the intron polymorphism is anAlu element inCE which is not present in theD gene. Examination of gorilla and chimpanzee genomic DNA for this intron polymorphism demonstrated that theD intron was present in all the chimpanzees and in all but one gorilla. TheCE intron was found in three of six gorillas, but in none of the seven chimpanzees. Sequence data suggested that theAlu element might have previously been present in the chimpanzeeRH genes but was eliminated by excision or recombination. Conservation of theRhD gene was also apparent from the complete identity between the 3′-noncoding region of the human D cDNA and a gorilla genomic clone, including anAlu element which is present in both species. The data suggest that at least twoRH genes were present in a common ancestor of humans, chimpanzees, and gorillas, and that additionalRH gene duplication has taken place in gorillas and chimpanzees. TheRhCE gene appears to have diverged more thanRhD among primates. In addition, theRhD gene deletion associated with the Rh-negative phenotype in humans seems to have occurred after speciation. Correspondence to: C.M. Westhoff     

The −1030/−862-linked TNF promoter single-nucleotide polymorphisms are associated with the inability to control HIV-1 viremia

Control of HIV-1 viremia and progression to AIDS has been associated with specific HLA genes. The tumor necrosis factor (TNF) and the non-classical major histocompatibility (MHC) class I chain-related A (MICA) genes are located in the genomic segment between the HLA class I and II genes and variants of both genes have been identified. We thus analyzed TNF promoter and MICA variants in a well-characterized group of HIV-1 infected individuals with different abilities to control HIV-1 viremia. In our cohort, the –1030/–862-linked TNF promoter single-nucleotide polymorphisms (SNPs), but not MICA variants, are significantly associated with lack of control of HIV-1 viremia (P=0.03). This association is independent of those HLA-B35 alleles associated with HIV-1 disease progression with which the –862 TNF SNP has previously been independently associated. Thus, non-randomly associated genes near the TNF locus are likely involved in control of HIV-1 viremia.