A disulfide-bound HIV-1 V3 loop sequence on the surface of human rhinovirus 14 induces neutralizing responses against HIV-1.

An immunogenic sequence from the V3 loop of the MN isolate of human immunodeficiency virus type 1 (HIV-1), His-Ile-Gly-Pro-Gly-Arg-Ala-Phe, was transplanted onto a surface loop of the VP2 capsid protein of human rhinovirus 14. To optimize for virus viability and immunogenicity of the transplanted sequence, the HIV sequence was flanked by (1) a cysteine residue that could form a disulfide bond and (2) randomized amino acids (in either of two arrangements) to generate numerous presentations of the Cys-Cys loop. The location for engineering in VP2 was chosen by searching the geometries of disulfide-bound loops in known protein structures. A model for the structure of the transplanted V3 loop sequence was developed using molecular dynamics and energy minimization calculations. Proteolytic digestion with and without reducing agent demonstrated the presence of the disulfide bond in the chimeric virus examined. Monoclonal and polyclonal antibodies directed against the V3 region of the HIV-1MN strain potently neutralized two chimeric viruses. Guinea pig antisera against two chimeric viruses were able to neutralize HIV-1MN and HIV-1ALA-1 in cell culture. The ability of chimeric viruses to elicit antibodies capable of neutralizing the source of the transplanted sequence could be favorable for vaccine development.

Human rhinovirus type 14:human immunodeficiency virus type 1 (HIV-1) V3 loop chimeras from a combinatorial library induce potent neutralizing antibody responses against HIV-1.

In an effort to develop a useful AIDS vaccine or vaccine component, we have generated a combinatorial library of chimeric viruses in which the sequence IGPGRAFYTTKN from the V3 loop of the MN strain of human immunodeficiency virus type 1 (HIV-1) is displayed in many conformations on the surface of human rhinovirus 14 (HRV14). The V3 loop sequence was inserted into a naturally immunogenic site of the cold-causing HRV14, bridged by linkers consisting of zero to three randomized amino acids on each side. The library of chimeric viruses obtained was subjected to a variety of immunoselection schemes to isolate viruses that provided the most useful presentations of the V3 loop sequence for potential use in a vaccine against HIV. The utility of the presentations was assessed by measures of antigenicity and immunogenicity. Most of the immunoselected chimeras examined were potently neutralized by each of the four different monoclonal anti-V3 loop antibodies tested. Seven of eight chimeric viruses were able to elicit neutralizing antibody responses in guinea pigs against the MN and ALA-1 strains of HIV-1. Three of the chimeras elicited HIV neutralization titers that exceeded those of all but a small number of previously described HIV immunogens. These results indicate that HRV14:HIV-1 chimeras may serve as useful immunogens for stimulating immunity against HIV-1. This method can be used to flexibly reconstruct varied immunogens on the surface of a safe and immunogenic vaccine vehicle.

Structure of poliovirus type 2 Lansing complexed with antiviral agent SCH48973: comparison of the structural and biological properties of three poliovirus serotypes.

BACKGROUND: Polioviruses are human pathogens and the causative agents of poliomyelitis. Polioviruses are icosahedral single-stranded RNA viruses, which belong to the picornavirus family, and occur as three distinct serotypes. All three serotypes of poliovirus can infect primates, but only type 2 can infect mice. The crystal structures of a type 1 and a type 3 poliovirus are already known. Structural studies of poliovirus type 2 Lansing (PV2L) were initiated to try to enhance our understanding of the differences in host range specificity, antigenicity and receptor binding among the three serotypes of poliovirus. RESULTS: The crystal structure of the mouse neurovirulent PV2L complexed with a potent antiviral agent, SCH48973, was determined at 2.9 A resolution. Structural differences among the three poliovirus serotypes occur primarily in the loop regions of the viral coat proteins (VPs), most notably in the loops of VP1 that cluster near the fivefold axes of the capsid, where the BC loop of PV2L is disordered. Unlike other known structures of enteroviruses, the entire polypeptide chain of PV2L VP4 is visible in the electron density and RNA bases are observed stacking with conserved aromatic residues (Tyr4020 and Phe4046) of VP4. The broad-spectrum antiviral agent SCH48973 is observed binding in a pocket within the beta-barrel of VP1, in approximately the same location that natural 'pocket factors' bind to polioviruses. SCH48973 forms predominantly hydrophobic interactions with the pocket residues. CONCLUSIONS: Some of the conformational changes required for infectivity and involved in the control of capsid stability and neurovirulence in mice may occur in the vicinity of the fivefold axis of the poliovirus, where there are significant structural differences among the three poliovirus serotypes in the surface exposed loops of VP1 (BC, DE, and HI). A surface depression is located at the fivefold axis of PV2L that is not present in the other two poliovirus serotypes. The observed interaction of RNA with VP4 supports the observation that loss of VP4 ultimately leads to the loss of viral RNA. A model is proposed that suggests dual involvement of the virion fivefold and pseudo-threefold axes in receptor-mediated initiation of infection by picornaviruses.

Chimeric rhinoviruses as tools for vaccine development and characterization of protein epitopes.

Chimeric human rhinoviruses (HRVs) have the potential to serve as vaccines against a wide variety of diseases. Such vaccines can be developed optimally by generating libraries of chimeric HRVs displaying immunogens from dangerous pathogens or tumor cells in many different conformations. Extremely large numbers of conformationally defined presentations of foreign epitopes can be produced efficiently by flanking transplanted epitopes with linkers, or adapters, of small segments of randomized amino acids. In addition, the individual residues of the immunogenic sequences can be encoded in proportion to their prevalence in databases, generating composite immunogens that function as mimotopes. The diversity of sequences and conformations improves the likelihood of generating immunologically valuable vaccine candidates. Chimeric viruses thus generated can be propagated and purified to select for viruses whose growth and physical stability are like those of wild-type HRV. Viruses containing a foreign epitope in antigenically relevant conformations can then be captured by immunoselection with neutralizing antibodies directed against the foreign pathogen. Using this approach, we have been able to generate HRV chimeras that present V3 loop sequences of the human immunodeficiency virus type 1 (HIV-1) in immunologically relevant conformations. Antisera directed against such chimeras can neutralize multiple strains of HIV-1 in cell culture, suggesting that the HRV14:HIV-1 chimeras may be presenting their V3 loop sequences in manners that mimic those of multiple strains of HIV. Immunologically interesting chimeras can be examined using X-ray crystallography to yield detailed information about the structures of chimeras with immunogenic epitopes. This information may lead to a greater understanding of key functional and structural elements of immunogenicity. The chimeric HRV system allows one to present virtually any protein epitope or mimitope thereof, identify viruses with immunological characteristics that mimic those of the foreign pathogen, and examine the structures of these immunogenic sequences at the atomic level.

Design and construction of rhinovirus chimeras incorporating immunogens from polio, influenza, and human immunodeficiency viruses.

This paper describes the design and construction of chimeric human rhinoviruses that contain immunogenic regions from other pathogens as part of their surface coat proteins. Segments encoding the poliovirus 3 Sabin VP1 and VP2 proteins, the influenza hemagglutinin (HA) glycoprotein, and the human immunodeficiency virus gp120 surface and gp41 transmembrane glycoproteins were inserted into a full-length clone of human rhinovirus 14 (HRV14) at regions corresponding to neutralizing immunogenic sites IA (NIm-IA) and II (NIm-II). Of 12 chimeric constructs described, 3 produced viable virus. An HRV14 chimeric virus containing five amino acids of influenza HA (corresponding to 300 A2 of solvent-accessible surface area) had wild-type HRV14 growth characteristics and was neutralized by four of four anti-influenza HA antisera with reciprocal neutralizing titers ranging from 180 to 330. However, antisera raised in two guinea pigs against the HRV14:influenza HA chimera did not show significant neutralization of relevant strains of influenza. These results are the first to demonstrate the feasibility of making viable chimeras of human rhinoviruses displaying heterologous immunogens.

Libraries of human rhinovirus-based HIV vaccines generated using random systematic mutagenesis.

Human rhinovirus (HRV), an immunogenic and relatively nonpathogenic virus, has been engineered to display HIV-1 immunogens with the intent of developing a vaccine against AIDS. HIV immunogens from the V3 loop have been placed into the neutralizing immunogenic (NIm) sites on the surface of HRV14 naturally recognized by the immune system. To increase the likelihood of recovering viable chimeras displaying the transplanted HIV-1 V3 loop sequences in conformations that mimic that of HIV, we have used random systematic mutagenesis to produce libraries of chimeric HRV14 in which the transplanted epitope from HIV-1 is flanked by one or more randomized amino acid residues. This allows the HIV epitope to be accommodated into the HRV coat proteins in many conformations, some of which should result in the production of viable, immunogenic hybrids. Using this approach, a library containing the sequence XXIGPGRAXX, where X could be any of the 20 amino acids, was generated. A nonrandom distribution of residues was found at the randomized positions, which may be a reflection of the structural requirements for viability. A subset of chimeras was identified that reacted with neutralizing anti-HIV-1 V3 loop antibody preparations, indicating that the antigenicity of the epitopes had been transplanted. Another chimeric virus library was designed to reflect the natural diversity of the V3 loop by incorporating amino acids at frequencies similar to those found among naturally occurring isolates of HIV-1. Powerful selection techniques utilizing anti-HIV-1 V3 loop neutralizing antibodies are being employed to isolate efficiently antigenic chimeras that could serve as potential vaccine candidates.

Use of random systematic mutagenesis to generate viable human rhinovirus 14 chimeras displaying human immunodeficiency virus type 1 V3 loop sequences.

Random systematic mutagenesis was used to generate a library of human rhinovirus 14 chimeras that each display a segment from the V3 loop of human immunodeficiency virus type 1. The sequence XXIGPGRAXX, where X could be any of the 20 amino acids, was inserted at the neutralizing immunogenic site II of human rhinovirus 14 between VP2 residues 159 and 160. Twenty-five unique chimeric viruses were isolated, and the identity of their randomized residues was determined. A nonrandom amino acid distribution that may reflect structural requirements for viability was observed at the randomized positions. Fifteen of 25 chimeras were neutralized by one or more of a panel of four anti-human immunodeficiency virus type 1 V3 loop antibody preparations, indicating that antigenicity had been successfully transplanted. Libraries of chimeric viruses produced by using the techniques described may be a source of vaccines and other immunotherapeutic reagents. The random systematic mutagenesis methodology described should be generally useful for the rapid transplantation of foreign sequences into viral coat and other proteins to produce libraries containing members with the desired properties.