Mutagenesis of the dimer interface residues of tethered and untethered HIV-1 protease result in differential activity and suggest multiple mechanisms of compensation.

As is the case for all retroviruses, the protease of HIV-1 is only functional as a homodimer; dimerization of two protease monomers results in the formation of the enzyme active site. This dimer structure is supported primarily by interactions between the first four amino-terminal and the last four carboxy-terminal amino acids. These eight amino acids form a beta-sheet in which hydrophobic residues are oriented towards the core of the molecule and polar residues are directed towards the solvent. Although the structure of the dimer interface has been determined, the forces that support dimerization have not been fully characterized. Here, we describe a tethered construct in which two protease monomers are joined by a 5 amino acid linker. We evaluate the relative role of each dimer interface residue in functional homo- and heterodimers. Our studies indicate that the hydrophobic residues of the dimer interface are particularly important in maintaining enzyme activity and that enzyme activity is more sensitive to substitutions of the C-terminal amino acids. Further, we demonstrate that the presence of the tether is able to compensate for mutations within the dimer interface that inactivate the enzyme.

The dimer interfaces of protease and extra-protease domains influence the activation of protease and the specificity of GagPol cleavage.

Activation of the human immunodeficiency virus type 1 (HIV-1) protease is an essential step in viral replication. As is the case for all retroviral proteases, enzyme activation requires the formation of protease homodimers. However, little is known about the mechanisms by which retroviral proteases become active within their precursors. Using an in vitro expression system, we have examined the determinants of activation efficiency and the order of cleavage site processing for the protease of HIV-1 within the full-length GagPol precursor. Following activation, initial cleavage occurs between the viral p2 and nucleocapsid proteins. This is followed by cleavage of a novel site located in the transframe domain. Mutational analysis of the dimer interface of the protease produced differential effects on activation and specificity. A subset of mutations produced enhanced cleavage at the amino terminus of the protease, suggesting that, in the wild-type precursor, cleavages that liberate the protease are a relatively late event. Replacement of the proline residue at position 1 of the protease dimer interface resulted in altered cleavage of distal sites and suggests that this residue functions as a cis-directed specificity determinant. In summary, our studies indicate that interactions within the protease dimer interface help determine the order of precursor cleavage and contribute to the formation of extended-protease intermediates. Assembly domains within GagPol outside the protease domain also influence enzyme activation.