Restriction factors: a defense against retroviral infection

Susceptibility to retroviral infection is determined, in part, by host genes with antiviral activity. The Fv1 gene, which inhibits murine leukemia virus infection in mice, encodes one such resistance factor, and was long thought to be unique in that it restricts post-entry, pre-integration steps of retroviral replication. However, recent findings suggest the existence of similar restriction factors in primates, including humans. These factors, termed Lv1 and Ref1, can inhibit a range of retroviruses, including human immunodeficiency virus type 1 and its relatives. Fv1, Lv1 and Ref1 target capsid determinants to block infection but can be saturated by incoming virions. Primate- and murine-retrovirus restriction factors have diverse and overlapping specificities, and some variants of Lv1, as well as Ref1, apparently recognize and inhibit infection by widely divergent retroviruses.     

Capsid-dependent and -independent postentry restriction of primate lentivirus tropism in rodent cells

Retrovirus tropism can be restricted by cellular factors such as Fv1, Ref1, and Lv1 that inhibit infection by targeting the incoming viral capsid. Here, we show that rodent cells exhibit differential sensitivity to infection by vesicular stomatitis virus G-pseudotyped lentiviruses and that differences between human immunodeficiency virus type 1 and simian immunodeficiency virus (SIVmac) infectivity are sometimes, but not always, governed by determinants in capsid-p2. In at least one case, resistance to SIVmac infection could be eliminated by saturation of target cells with noninfectious SIVmac particles. However, cross-saturation experiments and analysis of Fv1-null cells engineered to express natural or artificial Fv1 proteins revealed that lentivirus restriction in mouse cells is independent of Fv1. Overall, these findings indicate that novel restriction factors in rodents can modulate sensitivity to specific primate lentiviruses.     

Capsid processing requirements for abrogation of Fv1 and Ref1 restriction

Murine leukemia virus is restricted in mouse cells lines by a host factor known as Fv1 and in human cell lines by Ref1. Genetic evidence indicates that these restriction factors target the virus capsid (CA) protein. Restriction can be overcome by adding virus at a high multiplicity of infection, indicating that the restriction factors can be saturated. Cells preexposed to restricted virus will allow infection by a second virus which would normally be restricted. This phenomenon is known as abrogation; it provides us with a tool with which to study the interaction of virus with restriction factors. We tested the abilities of several Gag processing mutants to abrogate restriction. Our results show that CA must be cleaved from both p12 and nucleocapsid in order for the incoming virion to interact with the restriction factor. Endogenous expression of properly processed CA, however, failed to abrogate restriction. These results suggest that as well as being processed, CA must also be properly assembled in the form of a condensed viral core in order to interact with Fv1 and Ref1. This polymeric structure may contain restriction factor binding sites not present in monomeric CA.     

Retroviral capsid determinants of Fv1 NB and NR tropism

The specificity determinants for susceptibility to resistance by the Fv1 n and b alleles map to amino acid 110 of the murine leukemia virus CA protein. To study the interaction between Fv1 and CA, we examined changes in CA resulting in the loss of susceptibility to Fv1 resistance in naturally occurring NB- and NR-tropic viruses. A variety of amino acid changes affecting Fv1 tropism were identified, at CA positions 82, 92 to 95, 105, 114, and 117, and they all were mapped to the apparent exterior of virion-associated CA. These amino acids may form a binding surface for Fv1.     

A single amino acid change in the SPRY domain of human Trim5alpha leads to HIV-1 restriction

Retroviral restriction factors are cellular proteins that interfere with retrovirus replication at a postpenetration, preintegration stage in the viral life cycle. The first restriction activity described was the mouse Fv1 gene. Three different alleles of Fv1, capable of restricting different murine leukaemia viruses (MLV), have been characterized at the molecular level. Two further activities, Ref1, which acts on MLV, and Lv1, which acts on lentiviruses, have been identified in other mammalian species. Recently, it has become clear that Ref1 and Lv1 are encoded by the same gene, Trim5alpha, which inhibits retrovirus replication in a species-specific manner. A series of chimeras between the human and rhesus monkey Trim5 genes were created to map and identify these specificity determinants. The Trim5alpha SPRY domain was found to be responsible for targeting HIV-1 restriction. By contrast, N-MLV restriction appears dependent on both the coiled-coil domain and the SPRY domain. A single amino acid substitution (R332P) in the human Trim5alpha can confer the ability to restrict HIV-1, suggesting that small changes during evolution may have profound effects on our susceptibility to cross-species infection.     

Creating directed double-strand breaks with the Ref protein: a novel RecA-dependent nuclease from bacteriophage P1

The bacteriophage P1-encoded Ref protein enhances RecA-dependent recombination in vivo by an unknown mechanism. We demonstrate that Ref is a new type of enzyme; that is, a RecA-dependent nuclease. Ref binds to ss- and dsDNA but does not cleave any DNA substrate until RecA protein and ATP are added to form RecA nucleoprotein filaments. Ref cleaves only where RecA protein is bound. RecA functions as a co-nuclease in the Ref/RecA system. Ref nuclease activity can be limited to the targeted strands of short RecA-containing D-loops. The result is a uniquely programmable endonuclease activity, producing targeted double-strand breaks at any chosen DNA sequence in an oligonucleotide-directed fashion. We present evidence indicating that cleavage occurs in the RecA filament groove. The structure of the Ref protein has been determined to 1.4 Å resolution. The core structure, consisting of residues 77–186, consists of a central 2-stranded β-hairpin that is sandwiched between several α-helical and extended loop elements. The N-terminal 76 amino acid residues are disordered; this flexible region is required for optimal activity. The overall structure of Ref, including several putative active site histidine residues, defines a new subclass of HNH-family nucleases. We propose that enhancement of recombination by Ref reflects the introduction of directed, recombinogenic double-strand breaks.     

Restriction of multiple divergent retroviruses by Lv1 and Ref1

The mouse gene Fv1 encodes a saturable restriction factor that selectively blocks infection by N-tropic or B-tropic murine leukemia virus (MLV) strains. Despite the absence of an Fv1 gene, a similar activity is present in humans that blocks N-MLV infection (Ref1). Moreover, some non-human primate cell lines express a potentially related inhibitor of HIV-1 and/or SIVmac infection (Lv1). Here, we examine the spectrum of retrovirus-restricting activities expressed by human and African green monkey cell lines. Human cells restrict N-MLV and equine infectious anemia virus (EIAV), but not HIV-1, HIV-2, SIVmac or SIVagm, whilst AGM cells restrict N-MLV, EIAV, HIV-1, HIV-2 and SIVmac. Remarkably, in each example examined, restriction of infection by a given retrovirus can be abrogated at least partially by saturation with another retrovirus, provided that it is also restricted but regardless of whether it is closely related. These data suggest that restriction factors in human and non-human primate cells are able to recognize and block infection by multiple, widely divergent retroviruses and that the factors themselves may be related.     

Evolution of the Retroviral Restriction Gene Fv1: Inhibition of Non-MLV Retroviruses

Fv1 is the prototypic restriction factor that protects against infection by the murine leukemia virus (MLV). It was first identified in cells that were derived from laboratory mice and was found to be homologous to the gag gene of an endogenous retrovirus (ERV). To understand the evolution of the host restriction gene from its retroviral origins, Fv1s from wild mice were isolated and characterized. Most of these possess intact open reading frames but not all restricted N-, B-, NR-or NB-tropic MLVs, suggesting that other viruses could have played a role in the selection of the gene. The Fv1s from Mus spretus and Mus caroli were found to restrict equine infectious anemia virus (EIAV) and feline foamy virus (FFV) respectively, indicating that Fv1 could have a broader target range than previously thought, including activity against lentiviruses and spumaviruses. Analyses of the Fv1 sequences revealed a number of residues in the C-terminal region that had evolved under positive selection. Four of these selected residues were found to be involved in the novel restriction by mapping studies. These results strengthen the similarities between the two capsid binding restriction factors, Fv1 and TRIM5α, which support the hypothesis that Fv1 defended mice against waves of retroviral infection possibly including non-MLVs as well as MLVs.     

Identification of the regions of Fv1 necessary for murine leukemia virus restriction

The Fv1 gene restricts murine leukemia virus replication via an interaction with the viral capsid protein. To study this interaction, a number of mutations, including a series of N-terminal and C-terminal deletions, internal deletions, and a number of single-amino-acid substitutions, were introduced into the n and b alleles of the Fv1 gene and the effects of these changes on virus restriction were measured. A significant fraction of the Fv1 protein was not required for restriction; however, retention of an intact major homology region as well as of domains toward the N and C termini was essential. Binding specificity appeared to be a combinatorial property of a number of residues within the C-terminal portion of Fv1.     

Characterization of an amino-terminal dimerization domain from retroviral restriction factor Fv1

The Fv1 protein is an endogenous factor in mice that confers resistance to infection by certain classes of murine leukemia virus, a phenomenon referred to as restriction. The mechanism of restriction is not understood, and the low endogenous level of Fv1 in cells has prevented any biochemical or biophysical analysis of the protein. We have now purified recombinant Fv1(n) protein from a baculovirus system and demonstrate that Fv1 exists in a multimeric form. Furthermore, we have mapped the position of two domains within the protein using limited proteolysis. Biophysical characterization of the N-terminal domain reveals that it comprises a highly helical and extended dimeric structure. Based on these biochemical and biophysical data, we propose a model for the arrangement of domains in Fv1 and suggest that dimerization of the N-terminal domain is necessary for Fv1 function to allow the protein to interact with multiple capsid protomers in retroviral cores.     

Preparation of the Fv fragment from a short-chain mouse IgG2a anti-dansyl monoclonal antibody and use of selectively deuterated Fv analogues for two-dimensional 1H NMR analyses of the antigen-antibody interactions

The Fv fragment, a univalent antigen-binding unit with a molecular weight of 25,000, has successfully been prepared in high yield by limited proteolysis with clostripain of a short-chain mouse IgG2a anti-dansyl monoclonal antibody in which the entire CH1 domain is deleted [Igarashi, T., Sato, M., Takio, K., Tanaka, T., Nakanishi, M., & Arata, Y. (1990) Biochemistry 29, 5727-5733]. The Fv fragment obtained is stable at room temperature and retains its full antigen-binding capability. It has been shown that selective deuterium labeling of the Fv fragment, which is half the size of the Fab fragment, provides 1H NMR spectral data at a sufficient resolution for a detailed structural analysis of the antigen-combining site. NOESY spectra of an Fv analogue, in which all aromatic protons except for His C2'-H and Tyr C3',5'-H had been deuterated, were measured in the presence of varying amounts of dansyl-L-lysine. On the basis of the NOESY data obtained, it was possible to assign all the ring proton resonances for the dansyl group that is bound to the Fv fragment. It was also possible to obtain information about His and Tyr residues of the Fv fragment in the absence and presence of the antigen. On the basis of the NMR data obtained, we have shown that at least two Tyr residues along with one of the amide groups are directly involved in antigen binding. The mode of interaction of the dansyl ring with these residues in the Fv fragment has briefly been discussed.     

森林草莓全基因组MADS-box转录因子基因的鉴定及凤梨草莓果实FaMADS1基因克隆

本文利用生物信息学方法对森林草莓（Fragaria vesca）基因组数据库中MADS-box基因的数量、结构类型、序列特征及染色体定位进行分析。结果表明,获得70个含SRF-TF结构域的森林草莓Fv MADS基因,DNA长度289~14 596 bp,编码66~1 437个氨基酸残基,有21个Fv MADS没有内含子,在7条染色体上呈不均匀分布;68个Fv MADS蛋白序列含有保守基序Motif 1,最佳匹配序列为＂RQVTFSKRRNGLLKKAYELSVLCDAEVALIIFSSRGKLYEF＂。另外,从栽培品种‘丰香’草莓果实中克隆了Fa MADS1基因,该基因属于MADS-box基因家族,c DNA全长1 167 bp,编码区750 bp,推导编码249个氨基酸,具有MADS结构域和K-box结构域。     

Molecular phylogeny of Fv1

Alleles at the Fv1 gene of inbred mice confer resistance to infection and spread of vertically or horizontally transmitted murine leukemia viruses (MuLV). The nucleotide sequence of Fv1 bears similarity to the gag of a human endogenous retrovirus, HERV-L, but is more closely related to the gag-coding sequence of a newly described class of HERV-L-related mouse endogenous retroviruses designated MuERV-L. Both observations suggest an origin of Fv1 from endogenous gag sequences. The molecular definition of Fv1 provided an opportunity to determine the phylogeny of the gene among wild mice and its relation to MuERV-L. PCR primers, chosen to include most of the coding region of Fv1 for both the n and b alleles, were used to amplify sequences from animals of the genus Mus, which were then sequenced. Closely related products were obtained from almost all animals examined that evolved after the separation from Rattus, in which the homologous gene was shown to be absent. A phylogenetic tree generated with Fv1 sequence data differs noticeably from that developed with sequence data from other genes. In addition, non-synonymous changes were found to be present twice as frequently as synonymous changes, a fact that departs from the standard behavior of a structural gene. These observations suggest that the Fv1 gene may have been subjected to possible horizontal transfers as well as to positive Darwinian selection. Received: 9 January 1998 / Accepted: 17 August 1998     

A cis proline turn linking two beta-hairpin strands in the solution structure of an antibody-bound HIV-1IIIB V3 peptide

The refined solution structure of an 18-residue HIV-1IIIB V3 peptide in complex with the Fv fragment of an anti-gp120 antibody reveals an unexpected type VI beta-turn comprising residues RGPG at the center of a beta-hairpin. The central glycine and proline of this turn are linked by a cis peptide bond. The residues of the turn interact extensively with the antibody Fv. 15N[1H] NOE measurements show that the backbone of the peptide, including the central QRGPGR loop, is well ordered in the complex. The solution structure is significantly different from the X-ray structures of HIV-1MN V3 peptides bound to anti-peptide antibodies. These differences could be due to a two-residue (QR) insertion preceding the GPGR sequence in the HIV-1IIIB strain, and the much longer peptide epitope immobilized by the anti-gp120 antibody.     

Control of sigma virus multiplication by the ref(2)P gene of Drosophila melanogaster: an in vivo study of the PB1 domain of Ref(2)P

Ref(2)P has been described as one of the Drosophila proteins that interacts with the sigma virus cycle. We generated alleles to identify critical residues involved in the restrictive (inhibiting viral multiplication) or permissive (allowing viral multiplication) character of Ref(2)P. We demonstrate that permissive alleles increase the ability of the sigma virus to infect Drosophila when compared to null alleles and we confirm that restrictive alleles decrease this capacity. Moreover, we have created alleles unfunctional in viral cycling while functional for Ref(2)P fly functions. This type of allele had never been observed before and shows that fly- and virus-related activities of Ref(2)P are separable. The viral status of Ref(2)P variants is determined by the amino-terminal PB1 domain polymorphism. In addition, an isolated PB1 domain mimics virus-related functions even if it is similar to a loss of function toward fly-related activities. The evolutionary tree of the Ref(2)P PB1 domain that we could build on the basis of the natural allele sequences is in agreement with an evolution of PB1 domain due to successive transient selection waves.     

Species-specific tropism determinants in the human immunodeficiency virus type 1 capsid

Retroviral tropism is determined in part by cellular restriction factors that block infection by targeting the incoming viral capsid. Indeed, human immunodeficiency virus type 1 (HIV-1) infection of many nonhuman primate cells is inhibited by one such factor, termed Lv1. In contrast, a restriction factor in humans, termed Ref1, does not inhibit HIV-1 infection unless nonnatural mutations are introduced into the HIV-1 capsid protein (CA). Here, we examined the infectivity of a panel of mutant HIV-1 strains carrying substitutions in the N-terminal CA domain in cells that exhibit restriction attributable to Lv1 or Ref1. Manipulation of HIV-1 CA could alter HIV-1 tropism, and several mutations were identified that increased or decreased HIV-1 infectivity in a target-cell-specific manner. Many residues that affected HIV-1 tropism were located in the three variable loops that lie on the outer surface of the modeled HIV-1 conical capsid. Some tropism determinants, including the CypA binding site, coincided with residues whose mutation conferred on HIV-1 CA the ability to saturate Ref1 in human cells. Notably, a mutation that reverses the infectivity defect in human cells induced by CypA binding site mutation inhibits recognition by Ref1. Overall, these findings demonstrate that exposed variable loops in CA and a partial CypA "coat" can modulate restriction and HIV-1 tropism and suggest a model in which the exposed surface of the incoming retroviral capsid is the target for inhibition by host cell-specific restriction factors.     

鼠抗人纤维蛋白抗体单链Fv片段的人源化分子设计

产生免疫原性的残基都是位于蛋白表面的暴露残基,为了消除鼠抗体对人的免疫原性,利用表面再塑方法对本室克隆的鼠抗人纤维蛋白抗体单链Fv片断进行了人源化分子设计。首先确定了鼠及人Fv表面残基,在此基础上分析了鼠与人Fv间表面残基的差异,将有差异的鼠表面残基换成人的。提出了残基最高频率人源化及最相似链人源化两种人源化方案。人源化后鼠抗人纤维蛋白抗体单链Fv的结构经Profile-3D验证是合理的,置换的表面残基溶液可及性未变,且未影响CDRs的结构,应不会影响与纤维蛋白的亲和力,为鼠抗体人源化实验研究奠定了基础。     

鼠抗人纤维蛋白抗体单链Fv片段的人源化分子设计

产生免疫原性的残基主要是位于蛋白表面的暴露残基,为了消除鼠抗体对人的免疫原性,利用表面再塑的方法对本室克隆的鼠抗人纤维蛋白抗体单链Ｆｖ片段进行了人源化分子设计．首先确定了鼠及人Ｆｖ片段的表面残基,在此基础上分析了鼠与人抗体Ｆｖ片段表面残基的差异,将存在差异的鼠抗体的表面残基换成人的,从而实现鼠抗体的人源化．提出了残基最高频率人源化及最相似链人源化两种分子设计方案．人源化的鼠抗人纤维蛋白抗体单链Ｆｖ片段的结构经Ｐｒｏｆｉｌｅｓ－３Ｄ检测证明合理,替换的表面残基的溶剂可及性未变,而且未对ＣＤＲｓ的空间构象产生明显影响,应不会影响与纤维蛋白的亲和力,为鼠抗体人源化实验研究奠定了基础．     

Use of 2D NMR, protein engineering, and molecular modeling to study the hapten-binding site of an antibody Fv fragment against 2-phenyloxazolone

Two-dimensional (2D) 1H NMR spectroscopy was used to study the hapten-binding site of a recombinant antibody Fv fragment expressed in Escherichia coli. Point mutations of residues in the CDR loops of the Fv fragment were designed in order to investigate their influence on hapten binding and to make site-specific assignments of aromatic NMR proton signals. Two tyrosines giving NOEs to the ligand 2-phenyloxazolone were identified, residue 33 in CDR1 of the heavy chain and residue 32 in CDR1 of the light chain. The benzyl portion of 2-phenyloxazolone is located between these two residues. The binding site is close to the surface of the Fv fragment. Comparison with a different anti-2-phenyloxazolone antibody, the crystal structure of which has recently been solved, shows that the general location of the hapten-binding site in both antibodies is similar. However, in the crystallographically solved antibody, the hapten is bound farther from the surface in a pocket created by a short CDR3 loop of the heavy chain. In the binding site identified in the Fv fragment studied in this report, this space is probably filled by the extra seven residues of the CDR3.     

Crystal structure of the disulfide-stabilized Fv fragment of anticancer antibody B1: Conformational influence of an engineered disulfide bond

A recombinant Fv construct of the B1 monoclonal antibody that recognizes the Lewis^Y-related carbohydrate epitope on human carcinoma cells has been prepared. The Fv is composed of the polypeptide chains of the V_H and V_L domains expressed independently and isolated as inclusion bodies. The Fv is prepared by combining and refolding equimolar amounts of guanidine chloride solubilized inclusion bodies. The Fv is stabilized by an engineered interchain disulfide bridge between residues V_L100 and V_H44. This construct has a similar binding affinity as that of the single-chain construct (Benhar and Pastan, Clin. Cancer Res. 1:1023–1029, 1995). The B1 disulfide-stabilized Fv (B1dsFv) crystallizes in space group P6₁22 with the unit cell parameters a = b = 80.1 Å, and c = 138.1 Å. The crystal structure of the B1dsFv has been determined at 2.1-Å resolution using the molecular replacement technique. The final structure has a crystallographic R-value of 0.187 with a root mean square deviation in bond distance of 0.014 Å and in bond angle of 2.74°. Comparisons of the B1dsFv structure with known structures of Fv regions of other immunoglobulin fragments shows closely related secondary and tertiary structures. The antigen combining site of B1dsFv is a deep depression 10-Å wide and 17-Å long with the walls of the depression composed of residues, many of which are tyrosines, from complementarity determining regions L1, L3, H1, H2, and H3. Model building studies indicate that the Lewis^Y tetrasaccharide, Fuc–Gal–Nag–Fuc, can be accommodated in the antigen combining site in a manner consistent with the epitope predicted in earlier biochemical studies (Pastan, Lovelace, Gallo, Rutherford, Magnani, and Willingham, Cancer Res. 51:3781–3787, 1991). Thus, the engineered disulfide bridge appears to cause little, if any, distortion in the Fv structure, making it an effective substitute for the B1 Fab. Proteins 31:128–138, 1998. Published 1998 Wiley-Liss, Inc.

1 This article is a US Government work and, as such, is in the public domain in the United States of America.