Background: The gene therapeutic Cal-1 comprises the anti-HIV agents: (i) sh5, a short hairpin RNA to CCR5 that down-regulates CCR5 expression and (ii) maC46 (C46), a peptide that inhibits viral fusion with the cell membrane. These constructs were assessed for inhibition of viral replication and selective cell expansion in a number of settings.
Methods: HIV replication, selective outgrowth and cell surface viral binding were analysed with a single cycle infection assay of six pseudotyped HIV strains and a static and longitudinal passaging of MOLT4/CCR5 cells with HIV. Pronase digestion of surface virus and fluorescence microscopy assessed interactions between HIV virions and transduced cells.
Results: Cal-1 reduced CCR5 expression in peripheral blood mononuclear cells to CCR5Δ32 heterozygote levels. Even low level transduction resulted in significant preferential expansion in MOLT4/CCR5 gene-containing cells over a 3-week HIV challenge regardless of viral suppression [12.5% to 47.0% (C46), 46.7% (sh5), 62.2% (Dual), respectively]. The sh5 and Dual constructs at > 95% transduction also significantly suppressed virus to day 12 in the passage assay and all constructs, at varying percentage transduction inhibited virus in static culture. No escape mutations were present through 9 weeks of challenge. The Dual construct significantly suppressed infection by a panel of CCR5-using viruses, with its efficacy being independently determined from the single constructs. Dual and sh5 inhibited virion internalisation, as determined via pronase digestion of surface bound virus, by 70% compared to 13% for C46.
Conclusions: The use of two anti-HIV genes allows optimal preferential survival and inhibition of HIV replication, with the impact on viral load being dependent on the percentage of gene marked cells.
Keywords: C46; CCR5; HIV; gene therapy; lentivirus; shRNA.
Copyright © 2018 John Wiley & Sons, Ltd.