Structural comparison of the external glycoproteins of human and simian immunodeficiency virus.

The structural variability of the external glycoproteins of primate immunodeficiency viruses, has, so far, been investigated exclusively by sequence comparison of the respective proviral genomes. We have examined the structural relationship amount the external glycoproteins from three specific human immunodeficiency viruses (HIF-1, HIV-2), three specific simian immunodeficiency viruses from macaques (SIVmac) and three specific SIV from African green monkeys (SIVagm) by peptide mapping. Differences among glycoproteins were most pronounced between HIV-1 and SIVmac, as well as HIV-2. Two specific glycoproteins from independent SIVagm isolates were closely related to HIV-1, whereas the glycoprotein from a third SIVagm isolate was more similar to those of SIVmac and HIV-2. Our analysis reflects the classification of primate immunodeficiency viruses into three groups, the HIV-2 and SIVmac viruses, the green monkey isolates and HIV-1.

Update on the virology of AIDS

This article looks at the history, development, progress and research of the Human Immunodeficiency Virus (HIV) which causes AIDS. The author reports of the ongoing research into a vaccine for HIV, he examines the viral life cycle and indicates the points at which the virus can be attacked, and classifies antiviral strategies

Isolation and characterization of simian immunodeficiency viruses from two subspecies of African green monkeys.

Cercopithecus aethiops (African Green monkey), a nonhuman primate species distributed throughout subsaharan Africa, has been shown to have high seroprevalence rates of antibodies to simian immunodeficiency virus (SIV), and therefore, has been proposed as a natural reservoir for immunodeficiency viruses. Our laboratories have isolated SIV-like viruses from two East African subspecies of C. aethiops designated grivet and vervet monkeys. Analysis of the structural proteins based on the molecular weights and immunologic cross-reactivity to the prototypic SIV(MAC), HIV-1, and HIV-2 isolates suggests that these viruses are distinctly different. Heterogeneity was observed in the molecular weights of the gag, pol, and env gene products between SIV isolates from vervets [SIV(AGM(VER))] and grivets [SIV(AGM(GRI))]. Phenotypically, SIV(AGM(VER)) isolates were distinguishable from SIV(AGM(GRI)) isolates by the apparent size difference of the major core antigen p24. All SIV(AGM(GRI)) and SIV(AGM(VER)) isolates were found to encode a transmembrane protein of approximately 40 kD (gp40) in contrast to gp32 of SIV(MAC). Furthermore, the transmembrane protein was shown to be encoded by the entire env open reading frame, unlike gp32 of SIC(MAC) or gp36 of SIV(AGM(TYO-1)). These data indicate that viruses from C. aethiops share common features with SIV(MAC) and HIV-1, but represent diverse SIV-like viruses which may vary according to subspecies and geographic location.

Characterization of an HIV-2-related virus with a smaller sized extracellular envelope glycoprotein.

A new isolate of the human immunodeficiency virus (HIV) related to the HIV-2 strain was isolated from peripheral blood lymphocytes of an Ivory Coast patient with AIDS. This isolate referred to as HIV-2 EHO could be differentiated by its envelope precursor and external glycoprotein which are 20-kDa smaller than those of HIV-2 ROD isolate. Furthermore, the apparent molecular weight of the major core protein of HIV-2 EHO is 27 kDa instead of 26 kDa as in HIV-2 ROD isolate. In addition, the product of the vpx gene which is a characteristic feature of the HIV-2 strain, is 14 kDa in HIV-2 EHO compared with 16 kDa in HIV-2 ROD. In contrast to these, the envelope precursor of HIV-2 EHO forms a transient dimer its maturation as is the case for HIV-2 ROD. In both cases the transmembrane proteins are 36 kDa and exists as homodimers of 80 kDa. Endoglycosidase H digestion experiments indicated that the 20-kDa difference between the two HIV-2 isolates is not due to a difference in the number of N-linked oligosaccharide chains per polypeptide, since deglycosylated envelope precursors of HIV-2 ROD and EHO have an apparent molecular weight of 80 and 60 kDa, respectively. Partial proteolysis of the envelope precursors from the two isolates with Staphylococcus aureus V8 protease gave a distinct pattern of polypeptides. These results suggest that the differences between the external envelope proteins of the two HIV-2 isolates are due to their amino acid composition. Accordingly, polyclonal antibodies raised against HIV-2 ROD envelope do not recognize the corresponding envelope proteins of HIV-2 EHO by immunoblotting and immunoprecipitation assays. These data illustrate that analysis of viral proteins could be useful for a rapid characterization of new viral isolates and show the heterogeneity of HIV-2 isolates in West Africa.

Recovery of antigenically reactive HIV-2 cores.

Negative staining studies of human immunodeficiency virus (HIV) have been hampered by the fragile nature of the particles. Although detergent treatment is capable of releasing cores from HIV-2 particles, these are unstable and do not retain morphological integrity. Addition of glutaraldehyde will stabilise these structures but, if used at too high a concentration, will destroy their antigenicity. This study shows that if both detergent and glutaraldehyde are used in correct proportions, antigenically reactive cores can be recovered from HIV-2 cell cultures. More specifically we show that a mixture of 0.1% Nonidet P40 and 0.1% glutaraldehyde produces preparations of HIV-2 cores that are suitable for immune electron microscopy. These cores reacted positively, that is, formed immune complexes, with both human HIV-2 antisera and a mouse monoclonal antibody that, although directed against p24 (HIV-1), reacts also with p25 (HIV-2).