Antitumor and antibacterial properties of virally encoded cationic sequences

The objective of this study was to test our Viral Quinta Columna Strategy (VQCS), a new biological hypothesis predicting that specific multifunctional virally encoded cationic domains may have the capacity to penetrate human cells and interact with PP2A proteins to deregulate important human intracellular pathways, and may display LL37 cathelicidin-like antagonistic effects against multiple pathogens such as bacteria or viruses. We comparatively analyzed the host defense properties of adenodiaphorins and of some specific cationic sequences encoded by different viruses using two distinct biological models: U87G, a well-characterized cell tumor model; and a group B NEM316 ΔdltA, highly sensitive to LL37 cathelicidin. We found that the adenovirus type 2 E4orf4 is a cell-permeable protein containing a new E4orf4 protein transduction domain, named large adenodiaphorin or LadD . Interestingly, the host defense LL37 peptide is the unique cathelicidin in humans. In this context, we also demonstrated that similarly to LL37 LadD , several virally encoded cationic sequences including the C-terminus HIV-1 89.6 Vpr , shorter adenodiaphorins AdD /AdD/ /AdD , as well as HIV-2 Tat and JC polyomavirus small t , displayed similar toxicity against Gram-positive NEM316 ΔdltA strain. Finally, LadD , adenodiaphorin AdD , AdD , and LL37 and LL cathelicidin peptides also inhibited the survival of human U87G glioblastoma cells. In this study, we demonstrated that specific cationic sequences encoded by four different viruses displayed antibacterial activities against NEM316 ΔdltA strain. In addition, HIV-1 Vpr and adenovirus 2 E4orf4 two cationic penetrating sequences that bind PP2A, inhibited the survival of U87G glioblastoma cells. These results illustrate the host defense properties of virally encoded sequences and could represent an initial step for future complete validation of the VQCS hypothesis.