Activation of protein phosphatase-2A1 by HIV-1 Vpr cell death causing peptide in intact CD(4+) T cells and in vitro.

HIV-1, the etiologic agent of human AIDS, causes cell death in host and non-host cells via HIV-1 Vpr, one of its auxiliary gene product. HIV-1 Vpr can also cause cell cycle arrest in several cell types. The cellular processes that link HIV-1 Vpr to the cell death machinery are not well characterized. Here, we show that the C terminal portion of HIV-1 Vpr which encompasses amino acid residues 71-96 (HIV-1 Vpr(71-96)), also termed HIV-1 Vpr cell death causing peptide, is an activator of protein phosphatase-2A(1) when applied extracellularly to CD(4+) T cells. HIV-1 Vpr(71-96) is a direct activator of protein phosphatase-2A(1) that has been purified from CD(4+) T cells. Full length HIV-1 Vpr by itself does not cause the activation of protein phosphatase-2A(1) in vitro. HIV-1 Vpr(71-96) also causes the activation of protein phosphatase-2A(0) and protein phosphatase-2A(1) from brain, liver, and adipose tissues. These results indicate that HIV-1 can cause cell death of infected cells and non-infected host and non-host cells via HIV-1 Vpr derived C terminal peptide(s) which act(s) by cell penetration and targeting of a key controller of the cell death machinery, namely, protein phosphatase-2A(1). The activation of other members of the protein phosphatase-2A subfamily of enzymes which are involved in the control of several metabolic pathways in brain, liver, and adipose tissues by HIV-1 Vpr derived C terminal peptide(s) may underlie various metabolic disturbances that are associated with HIV-1 infection.

Rapamycin causes activation of protein phosphatase-2A1 and nuclear translocation of PCNA in CD4+ T cells.

Rapamycin is a powerful immunosuppressant that causes cell cycle arrest in T cells and several other cell types. Despite its important clinical role, the mechanism of action of rapamycin is not fully understood. Here, we show that rapamycin causes the activation of protein phosphatase-2A1 which forms a complex with proliferation cell nuclear antigen (PCNA) in a CD4+ T cell line. Rapamycin also induces PCNA translocation from the cytoplasm to the nucleus, an effect which is antagonized by okadaic acid, an inhibitor of type 2A protein phosphatases. These findings provide evidence for the existence of a signal transduction pathway that links a rapamycin-activated type 2A protein phosphatase to the control of DNA synthesis, DNA repair, cell cycle, and cell death via PCNA.