13. Functional Role of Adenovirus Penton in Modulating In Vivo Properties of Liver-Targeted and Liver-Detargeted Adenovirus Variants

Pharmacokinetic studies of adenovirus (Ad) vectors after intravascular delivery demonstrate that the majority of an administered virus dose is rapidly sequestered from the circulation by the liver. The molecular determinants that target Ad to the liver have been found on each of the virus capsid proteins, including hexon, penton, and fiber. The penton protein in the majority of Ad serotypes comprises a hypervariable loop containing an RGD motif that has been shown to interact with a number of cellular integrins upon virus entry into the cell. The binding of penton to integrins triggers virus internalization and relaxes the virus structure for subsequent endosomal disassembly. However, RGD motif interaction with integrins on tissue macrophages leads to production of inflammatory cytokines and significantly contributes to systemic Ad toxicity. Despite its importance for the virus entry into the cell, the penton is not well employed in the development of therapeutic Ad vectors. Therefore, in this study we evaluated strategies for modulating Ad penton interactions with cellular integrins. Ad vectors were created bearing substitutions of the RGD motif with mimetic non-RGD-containing peptides derived from extracellular proteins laminin 1 and laminin 3. These peptides are interacting with a different subset of integrins compared to those binging penton RGD motif. Unlike wild type (WT) Ad5, these penton-modified vectors were able to utilize β4 integrin for cell entry. The in vivo studies demonstrated that penton-modified Ads cannot activate a full inflammatory cascade and their in vivo toxicity, therefore, is dramatically reduced. Although the penton-mutated vectors were infecting a set of cancer cell lines in vitro and hepatocytes in vivo with a similar efficacy as the WT Ad5, interactions of virus with Kupffer cells and virus accumulation in the liver after intravascular vector delivery remain similar for penton-mutated and WT Ad vector. We also developed Ad vectors containing mutations abrogating virus interactions with all types of liver cells. Additionally to penton modifications, we introduced a T425A mutation in the hexon hyper variable loop HVR7 to completely abrogate virus interaction with blood coagulation FX and prevent transduction of hepatocytes. Furthermore, a set of mutations in the hexon HVR1 region were introduced to prevent Ad uptake by Kupffer cells. Due to penton modifications these vectors had very low toxicity and combinations of three mutations diverted the vector away from the liver. These data demonstrate that RGD loop modification represents a useful approach for introducing beneficial properties to the Ad vectors for greatly reducing their systemic toxicity and enable liver de-targeting. CryoEM analyses are currently underway to identify the structural differences in the capsid between the penton mutants and the wild type Ad.