The stability of HIV-2 Vpx and Vpr proteins is regulated by the presence or absence of zinc-binding sites and poly-proline motifs with distinct roles.

The Vpx and Vpr proteins of human immunodeficiency virus type 2 (HIV-2) are important for virus replication. Although these proteins are homologous, Vpx is expressed at much higher levels than Vpr. Previous studies demonstrated that this difference results from the presence of an HHCC zinc-binding site in Vpx that is absent in Vpr. Vpx has another unique region, a poly-proline motif (PPM) of seven consecutive prolines at the C-terminus. Using PPM point mutants of Vpx, this study demonstrated that these seven consecutive prolines are critical for suppressing proteasome degradation of Vpx in the absence of Gag. Both the PPM and the zinc-binding site stabilize Vpx but do so via different mechanisms. PPM and zinc-binding site mutants overexpressed in Escherichia coli aggregated readily, indicating that these motifs normally prevent exposure of the hydrophobic region outside the structure. Furthermore, introduction of the zinc-binding site and the PPM into Vpr increased the level of Vpr expression so that it was as high as that of Vpx. Intriguingly, HIV-2 has evolved to express Vpx at high levels and Vpr at low levels based on the presence and absence of these two motifs with distinct roles.

Zinc-binding site of human immunodeficiency virus 2 Vpx prevents instability and dysfunction of the protein.

Human immunodeficiency virus 2 Vpx coordinates zinc through residues H39, H82, C87 and C89. We reported previously that H39, H82 and C87 mutants maintain Vpx activity to facilitate the degradation of SAMHD1. Herein, the expression of Vpx mutants in cells was examined in detail. We demonstrated that the zinc-binding site stabilizes the protein to keep its function in virus growth when low levels of Vpx are expressed. At higher levels of expression, Vpx aggregation could occur, and zinc binding would suppress such aggregation. Among the amino acids involved in zinc coordination, H39 plays the most critical role. In summary, zinc binding appears to mitigate flexibility of the three-helix fold of Vpx, thereby preventing dysfunction.

Poly-proline motif in HIV-2 Vpx is critical for its efficient translation.

Human immunodeficiency virus type 2 (HIV-2) carries an accessory protein Vpx that is important for viral replication in natural target cells. In its C-terminal region, there is a highly conserved poly-proline motif (PPM) consisting of seven consecutive prolines, encoded in a poly-pyrimidine tract. We have previously shown that PPM is critical for Vpx expression and viral infectivity. To elucidate the molecular basis underlying this observation, we analysed the expression of Vpx proteins with various PPM mutations by in vivo and in vitro systems. We found that the number and position of consecutive prolines in PPM are important for Vpx expression, and demonstrated that PPM is essential for efficient Vpx translation. Furthermore, mutational analysis to synonymously disrupt the poly-pyrimidine tract suggested that the context of PPM amino acid sequences is required for efficient translation of Vpx. We similarly analysed HIV-1 and HIV-2 Vpr proteins structurally related to HIV-2 Vpx. Expression level of the two Vpr proteins lacking PPM was shown to be much lower relative to that of Vpx, and not meaningfully enhanced by introduction of PPM at the C terminus. Finally, we examined the Vpx of simian immunodeficiency virus from rhesus monkeys (SIVmac), which also has seven consecutive prolines, for PPM-dependent expression. A multi-substitution mutation in the PPM markedly reduced the expression level of SIVmac Vpx. Taken together, it can be concluded that the notable PPM sequence enhances the expression of Vpx proteins from viruses of the HIV-2/SIVmac group at the translational level.

Mutational analysis of HIV-2 Vpx shows that proline residue 109 in the poly-proline motif regulates degradation of SAMHD1.

In this study, we performed a mutational analysis to determine whether the mechanism by which HIV-2 Vpx confers the capacity for infectivity and viral replication in macrophages is solely dependent on its ability to degrade the host antiviral factor SAMHD1. Contrary to expectations, we demonstrated that P(109) in the C-terminal poly-proline motif of HIV-2 Vpx has two unique roles: to facilitate the specific degradation of SAMHD1 in macrophages, and to facilitate multimerization of Vpx, therefore preventing SAMHD1 degradation in the presence of high levels of Vpx.