Cell entry and trafficking of human adenovirus bound to blood factor X is determined by the fiber serotype and not hexon:heparan sulfate interaction.

Human adenovirus serotype 5 (HAdV5)-based vectors administered intravenously accumulate in the liver as the result of their direct binding to blood coagulation factor X (FX) and subsequent interaction of the FX-HAdV5 complex with heparan sulfate proteoglycan (HSPG) at the surface of liver cells. Intriguingly, the serotype 35 fiber-pseudotyped vector HAdV5F35 has liver transduction efficiencies 4-logs lower than HAdV5, even though both vectors carry the same hexon capsomeres. In order to reconcile this apparent paradox, we investigated the possible role of other viral capsid proteins on the FX/HSPG-mediated cellular uptake of HAdV5-based vectors.

Influence of chimeric human-bovine fibers on adenoviral uptake by liver cells and the antiviral immune response.

Human adenoviruses (HAdV) are widely used for in vitro and in vivo gene transfer. Viral hepatotropism, inflammatory responses and neutralization by pre-existing antibodies (NAbs) are obstacles for clinical applications of HAdV vectors. Although the multifactorial events leading to innate HAdV toxicity are far from being elucidated, there is a consensus that the majority of intravenously injected-HAdV vectors is sequestered by Kuppfer cells, probably independently of coagulation factors.

Capsomer-specific fluorescent labeling of adenoviral vector particles allows for detailed analysis of intracellular particle trafficking and the performance of bioresponsive bonds for vector capsid modifications.

Adenoviral (Ad) vectors are widely used for gene therapy approaches. Because of the high abundance of the natural adenoviral receptors (coxsackievirus-adenovirus receptor and integrins) on a wide variety of cells, numerous methods have been developed to redirect the virions to specific receptors on target cell surfaces. Importantly, an increasing number of publications have shown that the success of targeting not only depends on receptor binding and cellular uptake, but also on intracellular trafficking processes.

Improved adenovirus type 5 vector-mediated transduction of resistant cells by piggybacking on coxsackie B-adenovirus receptor-pseudotyped baculovirus.

Taking advantage of the wide tropism of baculoviruses (BVs), we constructed a recombinant BV (BV(CAR)) pseudotyped with human coxsackie B-adenovirus receptor (CAR), the high-affinity attachment receptor for adenovirus type 5 (Ad5), and used the strategy of piggybacking Ad5-green fluorescent protein (Ad5GFP) vector on BV(CAR) to transduce various cells refractory to Ad5 infection. We found that transduction of all cells tested, including human primary cells and cancer cell lines, was significantly improved using the BV(CAR)-Ad5GFP biviral complex compared to that obtained with Ad5GFP or BV(CAR)GFP alone. We determined the optimal conditions for the formation of the complex and found that a high level of BV(CAR)-Ad5GFP-mediated transduction occurred at relatively low adenovirus vector doses, compared with transduction by Ad5GFP alone.

Reductive amination as a strategy to reduce adenovirus vector promiscuity by chemical capsid modification with large polysaccharides.

Background: Chemical capsid modification of adenovirus vectors with synthetic polymers has been shown to aid in overcoming typical barriers for adenovirus vector-mediated gene transfer. Carbohydrate-based polymers for covalent modification of adenovirus vectors have been largely neglected so far. We utilized a reductive amination strategy to generate a novel class of adenovirus-based glycovectors with a mannan derivative.