Comparison of high-capacity and first-generation adenoviral vector gene delivery to murine muscle in utero.

In utero gene delivery could offer the advantage of treatment at an early stage for genetic disorders such as Duchenne muscular dystrophy (DMD) in which the inevitable process of muscle degeneration is already initiated at birth. Furthermore, treatment of fetal muscle with adenoviral (Ad) vectors is attractive because of a high density of Ad receptors, easy vector accessibility due to immaturity of the basal lamina and the possibility of treating stem cells. Previously, we demonstrated the efficient transduction of fetal muscle by high-capacity Ad (HC-Ad) vectors. In this study, we compared HC-Ad and first-generation Ad (FG-Ad) vectors for longevity of lacZ transgene expression, toxicity and induction of immunity after direct vector-mediated in utero gene delivery to fetal C57BL/6 mice muscle 16 days after conception (E-16). The total amount of beta-galactosidase (betagal) expressed from the HC-Ad vector remained stable for the 5 months of the study, although the concentration of betagal decreased due to muscle growth. Higher survival rates that reflect lower levels of toxicity were observed in those mice transduced with an HC-Ad vector as compared to an FG-Ad vector. The toxicity induced by FG-Ad vector gene delivery was dependent on mouse strain and vector dose. Animals treated with either HC-Ad and FG-Ad vectors developed non-neutralizing antibodies against Ad capsid and antibodies against betagal, but these antibodies did not cause loss of vector genomes from transduced muscle. In a mouse model of DMD, dystrophin gene transfer to muscle in utero using an HC-Ad vector restored the dystrophin-associated glycoproteins. Our results demonstrate that long-term transgene expression can be achieved by HC-Ad vector-mediated gene delivery to fetal muscle, although strategies of vector integration may need to be considered to accommodate muscle growth.

Fetal muscle gene transfer is not enhanced by an RGD capsid modification to high-capacity adenoviral vectors.

High levels of alpha(v) integrin expression by fetal muscle suggested that vector re-targeting to integrins could enhance adenoviral vector-mediated transduction, thereby increasing safety and efficacy of muscle gene transfer in utero. High-capacity adenoviral (HC-Ad) vectors modified by an Arg-Gly-Asp (RGD) peptide motif in the HI loop of the adenoviral fiber (RGD-HC-Ad) have demonstrated efficient gene transfer through binding to alpha(v) integrins. To test integrin targeting of HC-Ad vectors for fetal muscle gene transfer, we compared unmodified and RGD-modified HC-Ad vectors. In vivo, unmodified HC-Ad vector transduced fetal mouse muscle with four-fold higher efficiency compared to RGD-HC-Ad vector. Confirming that the difference was due to muscle cell autonomous factors and not mechanical barriers, transduction of primary myogenic cells isolated from murine fetal muscle in vitro demonstrated a three-fold better transduction by HC-Ad vector than by RGD-HC-Ad vector. We hypothesized that the high expression level of coxsackievirus and adenovirus receptor (CAR), demonstrated in fetal muscle cells both in vitro and in vivo, was the crucial variable influencing the relative transduction efficiencies of HC-Ad and RGD-HC-Ad vectors. To explore this further, we studied transduction by HC-Ad and RGD-HC-Ad vectors in paired cell lines that expressed alpha(v) integrins and differed only by the presence or absence of CAR expression. The results increase our understanding of factors that will be important for retargeting HC-Ad vectors to enhance gene transfer to fetal muscle.

Targeting of high-capacity adenoviral vectors.

High-capacity adenoviral (HC-Ad) vectors contain only the noncoding termini of the viral genome, can deliver large DNA fragments of up to 36 kb into target cells, and feature reduced toxicity and prolonged transgene expression in vivo. To enhance the potential of HC-Ad vectors to transduce specific cell types, we constructed a versatile infectious new helper virus plasmid that can be used readily to introduce peptide ligands into the HI loop of the fiber knob domain of Ad5-based HC-Ad vectors. Helper viruses with a 6x-His epitope or Arg-Gly-Asp (RGD) peptide insertion retained the full infectivity of the wild-type helper virus. The RGD-modified helper virus was used for production of a capsid-modified HC-Ad vector expressing beta-galactosidase. The RGD HC-Ad vector transduced the ovarian carcinoma cell lines SK-OV-3 and OVCAR-3 with 4- to 20-fold higher efficiency, compared to unmodified vectors. Transduction of both primary vascular smooth muscle cells as well as primary human endothelial cells was increased up to 15-fold with the RGD-modified vector. Competition experiments with recombinant knob protein and different RGD peptides indicated that the RGD-mediated transduction was Coxsackie and Adenovirus receptor (CAR)-independent and involved integrin alpha(v)beta(5). The use of fiber-modified helper viruses in the last amplification step of HC-Ad vector production allows for convenient and efficient targeting of these vectors towards different cell types. Targeting strategies will increase the spectrum of applications for HC-Ad vectors and will further add to their safety.