PP2A1 binding, cell transducing and apoptotic properties of Vpr77-92: A new functional domain of HIV-1 Vpr proteins

Background: The hallmark of HIV-1 pathogenesis is the progressive CD4(+) T cell depletion and high propensity of CD4(+) T cells to apoptosis. HIV-1 viral protein R (Vpr) is a major pro-apoptotic gene product. A first Vpr-mediated apoptotic mechanism that requires a physical interaction of HIV-1 Vpr(71-82) mitochondriotoxic domain containing the conserved sequence (71-)HFRIGCRHSRIG(-82) with the Adenine Nucleotide Translocator (ANT) has been characterized. The family of Ser/Thr protein phosphatase PP2A interacts with several viral proteins to regulate cell growth and apoptotic pathways. Previous studies based on yeast two hybrid assays and mutational experiments indicated that PP2A(1) is involved in the induction of G2 arrest by HIV-1 Vpr. [br/] Principal Findings: Experiments combining pull-down, cell penetration and apoptosis analyses in distinct human cells indicate that the PP2A(1) binding sequence from Vpr(77-92) is a new cell penetrating apoptotic sequence. We also found that the I84P mutation or the IIQ/VTR83-85 and T89A substitutions in the Vpr(77-92) sequence prevent PP2A(1) binding, cell penetration and apoptosis. In addition the double R77A and R80A mutation known to inactivate the mitochondriotoxic Vpr(71-82) domain, has no effect on the biological properties of the Vpr(77-92) domain. [br/] Conclusion: Together our data provide evidence for the first time that the Vpr(77-92) sequence delineates a biological active domain of Vpr with PP2A(1) binding and pro-apopototic capacities and, it is conceivable that this cell penetrating sequence may account for the Vpr internalization in uninfected cells. Finally, our data also implicate the existence of two partially overlapping pro-apoptotic domains in the Vpr C-terminal part, a redundancy that represents a new approach to address the question of biological relevance of HIV-1 Vpr. In this context, future studies will be required to determine the functional relevance of the Vpr(77-92) domain in full length Vpr protein and also in entire HIV provirus

Transducing properties of a pre-structured α-helical DPT-peptide containing a short canine adenovirus type 2 E4orf4 PP2A1-binding sequence

Induction of the death pathway resulting from the specific interaction of the PP2A1 phosphatase with adenoviral E4orf4 protein is a promising approach for cancer therapy. With the aim of deregulating tumor pathways, and mimicking E4orf4 anti-cancer signal, we have previously proposed the DPT technology concept, based on design of specific PP1/PP2A interacting penetrating peptides. Using biochemical, structural and cell survival experiments, we have characterized new DPT-peptides containing short PP2A binding sequences. We identified overlapping sequences, located within the N-terminal domain E4orf423-46 of canine adenoviral E4orf4 protein, that interact with the PP2A-Bα subunit of PP2A1 holoenzyme. We characterized DPT-E4orf44 and TAT-E4orf44, two bi-partite cell penetrating peptides containing the 12 PP2A1 binding residues of the canine type 2 E4orf427-38 sequence, respectively fused to the DPT-sh1 and TAT shuttle sequences. Surprisingly DPT-E4orf44, in contrast to inactive TAT-E4orf44, adopted a well defined α-helical structure and co-precipitated PP2A1 from HeLa cell extracts. DPT-E4orf44 also internalized streptavidin-HRP and inhibited survival of HeLa cells more efficiently than TAT, TAT-E4orf44 or the previously published anti-tumor TAT-derived peptide shepherdin. DPT-E4orf44 also efficiently inhibited the survival of human adherent transformed cells, including wild type and p53 mutated colonic HCT116 cells, without affecting survival of human non-transformed fibroblasts. Our results suggest that α-helical structured DPT peptides specifically interacting with PP2A could be a valuable anti-cancer drug design scaffold