Structure of antibody F425-B4e8 in complex with a V3 peptide reveals a new binding mode for HIV-1 neutralization

F425-B4e8 (B4e8) is a monoclonal antibody isolated from a human immunodeficiency virus type 1 (HIV-1)-infected individual that recognizes the V3 variable loop on the gp120 subunit of the viral envelope spike. B4e8 neutralizes a subset of HIV-1 primary isolates from subtypes B, C and D, which places this antibody among the very few human anti-V3 antibodies with notable cross-neutralizing activity. Here, the crystal structure of the B4e8 Fab′ fragment in complex with a 24-mer V3 peptide (RP142) at 2.8 Å resolution is described. The complex structure reveals that the antibody recognizes a novel V3 loop conformation, featuring a five-residue α-turn around the conserved GPGRA apex of the β-hairpin loop. In agreement with previous mutagenesis analyses, the Fab′ interacts primarily with V3 through side-chain contacts with just two residues, Ile^P309 and Arg^P315, while the remaining contacts are to the main chain. The structure helps explain how B4e8 can tolerate a certain degree of sequence variation within V3 and, hence, is able to neutralize an appreciable number of different HIV-1 isolates.     

Structural basis of enhanced binding of extended and helically constrained peptide epitopes of the broadly neutralizing HIV-1 antibody 4E10

Potent, broadly HIV-1 neutralizing antibodies (nAbs) may be invaluable for the design of an AIDS vaccine. 4E10 is the broadest HIV-1 nAb known to date and recognizes a contiguous and highly conserved helical epitope in the membrane-proximal region of gp41. The 4E10 epitope is thus an excellent target for vaccine design as it is also highly amenable to peptide engineering to enhance its helical character. To investigate the structural effect of both increasing the peptide length and of introducing helix-promoting constraints in the 4E10 epitope, we have determined crystal structures of Fab 4E10 bound to an optimized peptide epitope (NWFDITNWLWYIKKKK-NH(2)), an Aib-constrained peptide epitope (NWFDITNAibLWRR-NH(2)), and a thioether-linked peptide (NWFCITOWLWKKKK-NH(2)) to resolutions of 1.7 A, 2.1 A, and 2.2 A, respectively. The thioether-linked peptide is the first reported structure of a cyclic tethered helical peptide bound to an antibody. The introduced helix constraints limit the conformational flexibility of the peptides without affecting interactions with 4E10. The substantial increase in affinity (10 nM versus 10(4) nM of the IC(50) of the original KGND peptide template) is largely realized by 4E10 interaction with an additional helical turn at the peptide C terminus that includes Leu679 and Trp680. Thus, the core 4E10 epitope was extended and modified to a WFX(I/L)(T/S)XX(L/I)W motif, where X does not play a major role in 4E10 binding and can be used to introduce helical-promoting constraints in the peptide epitope.     

Crystal structure of vascular endothelial growth factor-B in complex with a neutralising antibody Fab fragment

Vascular endothelial growth factor (VEGF) B effects blood vessel formation by binding to VEGF receptor 1. To study the specifics of the biological profile of VEGF-B in both physiological and pathological angiogenesis, a neutralising anti-VEGF-B antibody (2H10) that functions by inhibiting the binding of VEGF-B to VEGF receptor 1 was developed. Here, we present the structural features of the ‘highly ordered’ interaction of the Fab fragment of this antibody (Fab-2H10) with VEGF-B. Two molecules of Fab-2H10 bind to symmetrical binding sites located at each pole of the VEGF-B homodimer, giving a unique U-shaped topology to the complex that has not been previously observed in the VEGF family. VEGF-B residues essential for binding to the antibody are contributed by both monomers of the cytokine. Our detailed analysis reveals that the neutralising effect of the antibody occurs by virtue of the steric hindrance of the receptor-binding interface. These findings suggest that functional complementarity between VEGF-B and 2H10 can be harnessed both in analysing the therapeutic potential of VEGF-B and as an antagonist of receptor activation.     

Structure-based design of a protein immunogen that displays an HIV-1 gp41 neutralizing epitope

Antibody Z13e1 is a relatively broadly neutralizing anti-human immunodeficiency virus type 1 antibody that recognizes the membrane-proximal external region (MPER) of the human immunodeficiency virus type 1 envelope glycoprotein gp41. Based on the crystal structure of an MPER epitope peptide in complex with Z13e1 Fab, we identified an unrelated protein, interleukin (IL)-22, with a surface-exposed region that is structurally homologous in its backbone to the gp41 Z13e1 epitope. By grafting the gp41 Z13e1 epitope sequence onto the structurally homologous region in IL-22, we engineered a novel protein (Z13-IL22-2) that contains the MPER epitope sequence for use as a potential immunogen and as a reagent for the detection of Z13e1-like antibodies. The Z13-IL22-2 protein binds Fab Z13e1 with a K_d of 73 nM. The crystal structure of Z13-IL22-2 in complex with Fab Z13e1 shows that the epitope region is faithfully replicated in the Fab-bound scaffold protein; however, isothermal calorimetry studies indicate that Fab binding to Z13-IL22-2 is not a lock-and-key event, leaving open the question of whether conformational changes upon binding occur in the Fab, in Z13-IL-22, or in both.     

X-ray Crystallographic Study of an HIV-1 Fusion Inhibitor with the gp41 S138A Substitution

The S138A substitution of fusion inhibitory peptides derived from the C-terminal heptad repeat (C-HR) of the human immunodeficiency virus type 1 (HIV-1) gp41 leads to enhanced binding affinity to the N-terminal heptad repeat (N-HR). As such, these peptides exhibit highly potent anti-HIV-1 activity. X-ray crystallographic analysis was performed to understand the effect of the substitution on binding affinity. The comparison of the native and S138A crystal structures indicated that the increase in the hydrophobicity of the S138A substitution may aid the stabilization of the N-HR/C-HR complex through additional hydrophobic contacts. Free-energy calculations suggest that the difference between the desolvation free energies of the C-HR-derived peptides with and without the S138A mutation dominates the observed difference in anti-HIV-1 activity.     

Structural details of HIV-1 recognition by the broadly neutralizing monoclonal antibody 2F5: epitope conformation, antigen-recognition loop mobility, and anion-binding site

2F5 is a monoclonal antibody with potent and broadly neutralizing activity against HIV-1. It targets the membrane-proximal external region (MPER) of the gp41 subunit of the envelope glycoprotein and interferes with the process of fusion between viral and host cell membranes. This study presents eight 2F5 F_ab′ crystal structures in complex with various gp41 peptide epitopes. These structures reveal several key features of this antibody-antigen interaction. (1) Whenever free of contacts caused by crystal artifacts, the extended complementarity-determining region H3 loop is mobile; this is true for ligand-free and epitope-bound forms. (2) The interaction between the antibody and the gp41 ELDKWA epitope core is absolutely critical, and there are also close and specific contacts with residues located N-terminal to the epitope core. (3) Residues located at the C-terminus of the gp41 ELDKWA core do not interact as tightly with the antibody. However, in the presence of a larger peptide containing the gp41 fusion peptide segment, these residues adopt a conformation consistent with the start of an α-helix. (4) At high sulfate concentrations, the electron density maps of 2F5 F_ab′-peptide complexes contain a peak that may mark a binding site for phosphate groups of negatively charged lipid headgroups. The refined atomic-level details of 2F5 paratope-epitope interactions revealed here should contribute to a better understanding of the mechanism of 2F5-based virus neutralization, in general, and prove important for the design of potential vaccine candidates intended to elicit 2F5-like antibody production.     

Structural and kinetic analysis of pyrrolidine-based inhibitors of the drug-resistant Ile84Val mutant of HIV-1 protease

Human immunodeficiency virus (HIV) protease is a well-established drug target in HIV chemotherapy. However, continuously increasing resistance towards approved drugs inevitably requires the development of new inhibitors preferably showing no susceptibility against resistant HIV protease strains. Recently, symmetric pyrrolidine-3,4-bis-N-benzyl-sulfonamides have been developed as a new class of HIV-1 protease inhibitors. The most promising candidate exhibited a K_i of 74 nM towards a wild-type protease. Herein, we report the influence of the active-site mutations Ile50Val and Ile84Val on these inhibitors by structural and kinetic analysis. Although the Ile50Val mutation leads to a significant decrease in affinity for all compounds in this series, they retain or even show increased affinity towards the important Ile84Val mutation. By detailed analysis of the crystal structures of two representatives in complex with wild-type and mutant proteases, we were able to elucidate the structural basis of this phenomenon.     

Molecular Insight into the Conformational Dynamics of the Elongin BC Complex and Its Interaction with HIV-1 Vif

The human immunodeficiency virus type 1 virion infectivity factor (Vif) inhibits the innate viral immunity afforded by the APOBEC3 family of cytidine deaminases. Vif targets the APOBEC3 family for poly-ubiquitination and subsequent proteasomal degradation by linking the Elongin-BC-dependent ubiquitin ligase complex with the APOBEC3 proteins. The interaction between Vif and the heterodimeric Elongin BC complex, which is mediated by Vif's viral suppressor of cytokine signaling box, is essential for Vif function. The biophysical consequences of the full-length Vif:Elongin BC interaction have not been extensively reported. In this study, hydrogen exchange mass spectrometry was used to dissect the Vif:Elongin BC interaction. Elongin C was found to be highly dynamic in the Elongin BC complex while Elongin B was much more stable. Recombinant full-length Vif interacted with the Elongin BC complex in vitro with a K_d of 1.9 μM and resulted in observable changes in deuterium uptake in both Elongin C and B. Upon binding to Elongin BC, no significant global conformational changes were detected in Vif by hydrogen exchange mass spectrometry, but a short fragment of Vif that consisted of the viral suppressor of cytokine signaling box showed decreased deuterium incorporation upon Elongin BC incubation, suggesting that this region folds upon binding.     

Rapid Structural Characterization of Human Antibody-Antigen Complexes through Experimentally Validated Computational Docking

If we understand the structural rules governing antibody (Ab)-antigen (Ag) interactions in a given virus, then we have the molecular basis to attempt to design and synthesize new epitopes to be used as vaccines or optimize the antibodies themselves for passive immunization. Comparing the binding of several different antibodies to related Ags should also further our understanding of general principles of recognition.To obtain and compare the three-dimensional structure of a large number of different complexes, however, we need a faster method than traditional experimental techniques. While biocomputational docking is fast, its results might not be accurate. Combining experimental validation with computational prediction may be a solution.As a proof of concept, here we isolated a monoclonal Ab from the blood of a human donor recovered from dengue virus infection, characterized its immunological properties, and identified its epitope on domain III of dengue virus E protein through simple and rapid NMR chemical shift mapping experiments. We then obtained the three-dimensional structure of the Ab/Ag complex by computational docking, using the NMR data to drive and validate the results. In an attempt to represent the multiple conformations available to flexible Ab loops, we docked several different starting models and present the result as an ensemble of models equally agreeing with the experimental data. The Ab was shown to bind a region accessible only in part on the viral surface, explaining why it cannot effectively neutralize the virus.     

Membrane-transferring sequences of the HIV-1 Gp41 ectodomain assemble into an immunogenic complex

The membrane-proximal stem region of gp41 has been postulated to host the two conserved membrane-transferring domains that promote HIV-1 fusion: the amino-terminal fusion peptide (FP) and the highly aromatic pre-transmembrane sequence. Our results confirm that the hydrophobic FP and membrane-proximal sequences come into contact and form structurally defined complexes. These complexes are immunogenic and evoke responses in rabbits that compete with the recognition of native functional gp41 by the 2F5 monoclonal antibody. We conclude that co-assembly of the FP and the pre-transmembrane sequences might exert a constraint that helps maintain a gp41 stem region pre-fusion structure.     

Crystal structure of the complex between the F(ab)' fragment of the cross-neutralizing anti-HIV-1 antibody 2F5 and the F(ab) fragment of its anti-idiotypic antibody 3H6

The monoclonal antibody 2F5 neutralizes a broad range of human immunodeficiency virus-1 isolates via a conserved epitope on the viral glycoprotein gp41. The conformation of the principal epitope is a type I β-turn centered on gp41 residues ⁶⁶⁴DKW⁶⁶⁶; in addition, binding studies indicate that residues N- and C-terminal to this core as well as structurally more distant parts of gp41 also contribute to the interaction. Ab2/3H6 is an anti-idiotypic antibody that inhibits the interaction between 2F5 and gp41 and as such, Ab2/3H6 may, in principle, possess a paratope that mimics the gp41 epitope. To establish the potential of Ab2/3H6 to serve as a guide for the design of vaccine components against human immunodeficiency virus, we investigated the crystal structure of the heterodimeric complex of Ab2/3H6 F_ab and 2F5 F_ab′. Ab2/3H6 F_ab binds to 2F5 F_ab′ via a helix-like protrusion formed by residues ^58(H)RYSPSLNTRL^67(H) of the 2F5 F_ab′ variable domain and proximal to but not overlapping with the gp41 ⁶⁶⁴DKW⁶⁶⁶ epitope-binding pocket. This defines Ab2/3H6 as an anti-idiotypic antibody of the Ab2γ class, i.e., an antigen-inhibitable idiotype that does not carry the internal image of the linear primary gp41 ⁶⁶²ELDKWAS⁶⁶⁸ epitope.     

人免疫缺陷病毒I型Vif蛋白的原核表达、纯化及单克隆抗体制备

目的：克隆、表达、纯化人免疫缺陷病毒I型（HIV-1）Vif蛋白,制备其单克隆抗体。方法：提取感染了HIV的细胞基因组DNA,PCR扩增vif基因,插入表达载体pET32a,转化大肠杆菌BL21（DE3）获得工程菌株,IPTG诱导蛋白表达,Western印迹鉴定目的蛋白,亲和层析纯化目的蛋白;免疫BALB／c小鼠,制备单克隆抗体。结果：构建了Vif蛋白的原核表达载体vif-pET32a,并在大肠杆菌中获得高表达,目的蛋白以包涵体形式存在;纯化获得高纯度的重组Vif蛋白,蛋白浓度可达0．56mg／mL;建立了抗Vif蛋白单克隆抗体细胞株,制备了腹水,滴度可达1：16×10^6,抗体纯化后保持了活性和特异性。结论：在原核表达系统中表达、纯化了重组Vif蛋白,制备了针对Vif蛋白的单克隆抗体,为研究Vif蛋白的功能和抗原性奠定了基础。     

Structural Basis of the Action of Glucosyltransferase Lgt1 from Legionella pneumophila

The glucosyltransferase Lgt1 is one of three glucosylating toxins of Legionella pneumophila, the causative agent of Legionnaires disease. It acts through specific glucosylation of a serine residue (S53) in the eukaryotic elongation factor 1A and belongs to type A glycosyltransferases. High-resolution crystal structures of Lgt1 show an elongated shape of the protein, with the binding site for uridine disphosphate glucose at the bottom of a deep cleft. Lgt1 shows only a low sequence identity with other type A glycosyltransferases, and structural conservation is limited to a central folding core that is usually observed within this family of proteins. Domains and protrusions added to the core motif represent determinants for the specific recognition and binding of the target. Manual docking experiments based on the crystal structures of toxin and target protein suggest an obvious mode of binding to the target that allows for efficient transfer of a glucose moiety.     

Allosteric loss-of-function mutations in HIV-1 Nef from a long-term non-progressor

Activation of Src family kinases by human immunodeficiency virus type 1 (HIV-1) Nef may play an important role in the pathogenesis of HIV/AIDS. Here we investigated whether diverse Nef sequences universally activate Hck, a Src family member expressed in macrophages and other HIV-1 target cells. In general, we observed that Hck activation is a highly conserved Nef function. However, we identified an unusual Nef variant from an HIV-positive individual that did not develop AIDS which failed to activate Hck despite the presence of conserved residues linked to Hck SH3 domain binding and kinase activation. Amino acid sequence alignment with active Nef proteins revealed differences in regions not previously implicated in Hck activation, including a large internal flexible loop absent from available Nef structures. Substitution of these residues in active Nef compromised Hck activation without affecting SH3 domain binding. These findings show that residues at a distance from the SH3 domain binding site influence Nef interactions allosterically with a key effector protein linked to AIDS progression.     

HIV-1 Nef-associated Factor 1 Enhances Viral Production by Interacting with CRM1 to Promote Nuclear Export of Unspliced HIV-1 gag mRNA

HIV-1 depends on host-cell-encoded factors to complete its life cycle. A comprehensive understanding of how HIV-1 manipulates host machineries during viral infection can facilitate the identification of host targets for antiviral drugs or gene therapy. The cellular protein Naf1 (HIV-1 Nef-associated factor 1) is a CRM1-dependent nucleo-cytoplasmic shuttling protein, and has been identified to regulate multiple receptor-mediated signal pathways in inflammation. The cytoplasm-located Naf1 can inhibit NF-κB activation through binding to A20, and the loss of Naf1 controlled NF-κB activation is associated with multiple autoimmune diseases. However, the effect of Naf1 on HIV-1 mRNA expression has not been characterized. In this study we found that the nucleus-located Naf1 could promote nuclear export of unspliced HIV-1 gag mRNA. We demonstrated that the association between Naf1 and CRM1 was required for this function as the inhibition or knockdown of CRM1 expression significantly impaired Naf1-promoted HIV-1 production. The mutation of Naf1 nuclear export signals (NESs) that account for CRM1 recruitment for nuclear export decreased Naf1 function. Additionally, the mutation of the nuclear localization signal (NLS) of Naf1 diminished its ability to promote HIV-1 production, demonstrating that the shuttling property of Naf1 is required for this function. Our results reveal a novel role of Naf1 in enhancing HIV-1 production, and provide a potential therapeutic target for controlling HIV-1 infection.     

我国HIV-1B'/C重组流行株Tat蛋白的表达、纯化及功能分析

根据全国HIV分子流行病学研究发现,B'和C亚型HIV-1在我国发生了重组,并以优势株形式在我国广泛流行.为了探讨这种HIV-1B'/C重组毒株tat基因的变异与其表型之间的关系,利用pET表达系统在大肠杆菌中高效表达了三种不同基因变异类型的Tat蛋白,重组蛋白占菌体总蛋白的26%,Western blot显示较好的反应原性,并通过金属鏊合层析纯化了目的蛋白.荧光素酶活性检测表明:体外表达的Tat蛋白具有明显的生物学活性,可以反式激活HIV LTR引导的报告基因的表达;三种Tat蛋白在激活活性上的差异与流行现场检测的病毒载量的高低存在明显的对应关系,说明tat基因的变异可以引起病毒生物学特性的改变,进而影响病毒的流行特征.此结果为进一步研究我国HIV重组毒株的基因变异特征及变异规律奠定了基础.     

Ultra-high resolution crystal structure of HIV-1 protease mutant reveals two binding sites for clinical inhibitor TMC114

TMC114 (darunavir) is a promising clinical inhibitor of HIV-1 protease (PR) for treatment of drug resistant HIV/AIDS. We report the ultra-high 0.84 A resolution crystal structure of the TMC114 complex with PR containing the drug-resistant mutation V32I (PR(V32I)), and the 1.22 A resolution structure of a complex with PR(M46L). These structures show TMC114 bound at two distinct sites, one in the active-site cavity and the second on the surface of one of the flexible flaps in the PR dimer. Remarkably, TMC114 binds at these two sites simultaneously in two diastereomers related by inversion of the sulfonamide nitrogen. Moreover, the flap site is shaped to accommodate the diastereomer with the S-enantiomeric nitrogen rather than the one with the R-enantiomeric nitrogen. The existence of the second binding site and two diastereomers suggest a mechanism for the high effectiveness of TMC114 on drug-resistant HIV and the potential design of new inhibitors.