Computer-assisted analysis of envelope protein sequences of seven human immunodeficiency virus isolates: prediction of antigenic epitopes in conserved and variable regions.

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J Virol. 1987 February; 61(2): 570-578

Computer-assisted analysis of envelope protein sequences of seven human immunodeficiency virus isolates: prediction of antigenic epitopes in conserved and variable regions.

S Modrow, B H Hahn, G M Shaw, R C Gallo, F Wong-Staal and H Wolf

ABSTRACT

Independent isolates of human immunodeficiency virus (HIV) exhibita striking genomic diversity, most of which is located in theviral envelope gene. Since this property of the HIV group ofviruses may play an important role in the pathobiology of thevirus, we analyzed the predicted amino acid sequences of theenvelope proteins of seven different HIV strains, three of whichrepresent sequential isolates from a single patient. By usinga computer program that predicts the secondary protein structureand superimposes values for hydrophilicity, surface probability,and flexibility, we identified several potential antigenic epitopesin the envelope proteins of the seven different viruses. Interestingly,the majority of the predicted epitopes in the exterior envelopeprotein (gp120) were found in regions of high sequence variabilitywhich are interspersed with highly conserved regions among theindependent viral isolates. A comparison of the sequential viralisolates revealed that changes concerning the secondary structureof the protein occurred only in regions which were predictedto be antigenic, predominantly in highly variable regions. Themembrane-associated protein gp41 contains no highly variableregions; about 80% of the amino acids were found to be conserved,and only one hydrophilic area was identified as likely to beaccessible to antibody recognition. These findings give insightinto the secondary and possible tertiary structure of variantHIV envelope proteins and should facilitate experimental approachesdirected toward the identification and fine mapping of HIV envelopeproteins.

J Virol. 1987 February; 61(2): 570-578

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