Bruce F. Smith

A Single Intravenous Injection of Adeno-associated Virus Serotype-9 Leads to Whole Body Skeletal Muscle Transduction in Dogs

The success of many gene therapy applications hinges on efficient whole body transduction. In the case of muscular dystrophies, a therapeutic vector has to reach every muscle in the body. Recent studies suggest that vectors based on adeno-associated virus (AAV) are capable of body-wide transduction in rodents. However, translating this finding to large animals remains a challenge. Here we explored systemic gene delivery with AAV serotype-9 (AAV-9) in neonatal dogs. Previous attempts to directly deliver AAV to adult canine muscle have yielded minimal transduction due to a strong cellular immune response. However, in neonatal dogs we observed robust skeletal muscle transduction throughout the body after a single intravenous injection. Importantly, systemic transduction was achieved in the absence of pharmacological intervention or immune suppression and it lasted for at least 6 months (the duration of study). We also observed several unique features not predicted by murine studies. In particular, cardiac muscle was barely transduced in dogs. Many muscular dystrophy patients can be identified by neonatal screening. The technology described here may lead to an effective early intervention in these patients.

Elucidation of muscle-binding peptides by phage display screening.

Muscle makes up the largest tissue volume of the body, yet its size makes muscle‐specific therapy difficult. This becomes particularly relevant when approaches to gene therapy for inherited myopathies are evaluated. Thus, a mechanism to target constructs or pharmaceuticals to muscle following intravenous injection would be advantageous. By screening a random phage display library we have identified a heptapeptide sequence, ASSLNIA, with enhanced in vivo skeletal and cardiac muscle binding. Phage carrying this peptide showed a 9‐ to 20‐fold (depending on control tissue) increase in muscle selectivity compared with phage with no insert. When the injected individual phage clone was localized by immunohistochemistry, it was found within focal areas of the membrane of myofibers. Thus, the peptide identified represents a ligand that is capable of accessing skeletal and cardiac muscle from the lumen of blood vessels and could therefore readily be exploited for targeted delivery to muscle cells.

A canine conditionally replicating adenovirus for evaluating oncolytic virotherapy in a syngeneic animal model

Oncolytic adenoviruses, which selectively replicate in and subsequently kill cancer cells, have emerged as a promising approach for treatment of tumors resistant to other modalities. Although preclinical results have been exciting, single-agent clinical efficacy has been less impressive heretofore. The immunogenicity of adenoviruses, and consequent premature abrogation of replication, may have been a partial reason. Improving the oncolytic potency of agents has been hampered by the inability to study host-vector interactions in immune-competent systems, since human serotype adenoviruses do not productively replicate in animal tissues. Therefore, approaches such as immunomodulation, which could result in sustained replication and subsequently increased oncolysis, have not been studied. Utilizing the osteocalcin promoter for restricting the replication of a canine adenovirus to dog osteosarcoma cells, we generated and tested the first nonhuman oncolytic adenovirus. This virus effectively killed canine osteosarcoma cells in vitro and yielded a therapeutic benefit in vivo. Canine osteosarcoma is the most frequent malignant disease in large dogs, with over 8000 cases in the United States annually, and there is no curative treatment. Therefore, immunomodulation for increased oncolytic potency could be studied with clinical trials in this population. This could eventually translate into human trials.

Protective immunity induced by DNA vaccination of channel catfish with early and late transcripts of the channel catfish herpesvirus (IHV-1)

Seven full-length transcripts encoding four early and three late genes of the channel catfish virus (CCV), ictalurid herpesvirus I (IHV-1), have been cloned following rt-PCR amplification and DNA sequencing. Transcripts were selected based on their predicted association with membrane structures, identification as an envelope glycoprotein, or as a viral capsid protein. The transcripts derived from ORF 6, ORF 7, ORF 8a, ORF 10, ORF 51, ORF 53, and ORF 59 were all shown to be complete and unspliced. Each of the seven ORFs was cloned into a vaccine expression vector designed to support high levels of expression of the inserted sequence in catfish tissues. Solutions of DNA containing one each of the seven CCV ORFs, vector alone or PBS were injected intramuscularly into 4-8 cm catfish. Four to 6 weeks after injection each experimental group was challenged with one LD(50) of CCV. Single injections of DNA expression constructs containing ORF 59, encoding the envelope glycoprotein, or ORF 6, encoding a presumptive membrane protein, were found to elicit the strongest resistance to challenge compared to uninjected, PBS injected or vector injected groups. Even more effective was a combination vaccine pair in which both ORF 59 and ORF 6 expression constructs were injected. Other ORFs did not provide consistent protection to challenge above that observed in control fish. Both percent survival and kinetics of cumulative deaths were improved using the combination DNA vaccine encoding ORF 6 and ORF 59. Both ORF 6 and ORF 59 were able to elicit virus neutralizing antibodies capable of an anamnestic response on viral challenge. We believe this evidence provides adequate proof of principle for the use of DNA vaccines in channel catfish and the effectiveness of the resistance to viral infection they elicit.

An intronic LINE-1 element insertion in the dystrophin gene aborts dystrophin expression and results in Duchenne-like muscular dystrophy in the corgi breed

Duchenne muscular dystrophy (DMD) is a dystrophin-deficient lethal muscle disease. To date, the catastrophic muscle wasting phenotype has only been seen in dystrophin-deficient humans and dogs. Although Duchenne-like symptoms have been observed in more than a dozen dog breeds, the mutation is often not known and research colonies are rarely established. Here, we report an independent canine DMD model originally derived from the Pembroke Welsh corgi breed. The affected dogs presented clinical signs of muscular dystrophy. Immunostaining revealed the absence of dystrophin and upregulation of utrophin. Histopathologic examination showed variable fiber size, central nucleation, calcification, fibrosis, neutrophil and macrophage infiltration and cardiac focal vacuolar degeneration. Carrier dogs also displayed mild myopathy. The mutation was identified as a long interspersed repetitive element-1 (LINE-1) insertion in intron 13, which introduced a new exon containing an in-frame stop codon. Similar mutations have been seen in human patients. A colony was generated by crossing carrier females with normal males. Affected puppies had a normal birth weight but they experienced a striking growth delay in the first 5 days. In summary, the new corgi DMD model offers an excellent opportunity to study DMD pathogenesis and to develop novel therapies.

CpG oligodeoxynucleotides stimulate canine and feline immune cell proliferation

Oligodeoxynucleotides (ODNs) with unmethylated CpG dinucleotide motifs may be useful as non-specific immune system stimulants and adjuvants for protein or nucleic acid vaccines in humans and other primates. They may also be useful in cancer immunotherapy and in the modulation of allergic responses or mucosal immunity. To begin to determine the potential utility of CpG ODN technology in small animal veterinary medicine, we developed procedures to analyze the effects of CpG ODN on canine and feline blood, spleen and lymph node (LN) cells. We find that certain CpG ODN cause good lymphocyte proliferation (as monitored by [(3)H]-thymidine incorporation) in both canine and feline spleen and LN cells, but not in blood. This overall stimulatory effect of CpG ODN on spleen and LN cells is CpG dependent. The reverse sequences, GpC ODNs, do not cause significant lymphocyte proliferation in the cat; however, dogs are more sensitive to stimulation by the non-specific immune effects of the phosphorothioate backbone. We conclude that unmethylated CpG ODNs may also have potential uses as immune stimulants for vaccines and other antimicrobial agents in veterinary medicine for companion animals.

Mucosal Immunization with Helicobacter, CpG DNA, and Cholera Toxin Is Protective

ABSTRACT The mucosal delivery of antigens requires an effective adjuvant to induce mucosal immunity. Current mucosal adjuvants include cholera toxin (CT) and Escherichia coli heat-labile toxin. Unmethylated CpG immunostimulatory oligodeoxynucleotides (ODNs) have been proposed as novel mucosal adjuvants. In this study, mice were immunized with sonicated Helicobacter felis with CT and/or CpG ODN adjuvants. All groups receiving either adjuvant singly or in combination developed increased serum anti-H. felis immunoglobulin G (IgG). The addition of either CpG or CT, or both, produced a specific fecal anti-H. felis IgA response, with the highest IgA levels occurring in animals immunized intranasally with sonicated H. felis with CT and CpG. Following H. felis challenge, addition of the adjuvant CpG ODN provided no significant protection, while groups given CT showed a high degree of protection, although not complete. When CpG ODN was combined with CT and the vaccine combination was delivered intranasally, no bacterial colonization was detected by quantitative PCR, providing “sterile immunity” and demonstrating synergy between CpG ODN and CT.

Nucleic acid immunization protects dogs against challenge with virulent canine parvovirus.

Nucleic acid vaccines (NAVs) use expression vectors encoding one or more antigen genes to transfect host cells inducing both humoral and cellular immunity against the expressed antigen. NAV offers major advantages over conventional vaccines for the protection of humans and animals. This study shows that a plasmid DNA (pGT36VP1) encoding the full length VP1 region of canine parvovirus (CPV) induces immunity that protects dogs against challenge with virulent virus. Five dogs without anti-CPV antibodies were injected at 9 months of age with increasing doses of pGT36VP1 or saline. NAV vaccinated dogs showed an increase of serum IgG titer starting 1 week post-injection which peaked at week 2 and remained detectable for at least 14 weeks. A second dose of NAV resulted in an anamnestic response within 1 week. IgG titers peaked at week 3 and 4 after the second injection. All pGT36VP1 vaccinated dogs were protected against infection after virulent CPV challenge regardless of dose and the unvaccinated control dog was fully susceptible. This study demonstrated for the first time that a NAV can protect dogs against an infectious disease.

A Genetically Engineered Adenovirus Vector Targeted to CD40 Mediates Transduction of Canine Dendritic Cells and Promotes Antigen-Specific Immune Responses In Vivo

Targeting viral vectors encoding tumor-associated antigens to dendritic cells (DCs) in vivo is likely to enhance the effectiveness of immunotherapeutic cancer vaccines. We have previously shown that genetic modification of adenovirus (Ad) 5 to incorporate CD40 ligand (CD40L) rather than native fiber allows selective transduction and activation of DCs in vitro. Here, we examine the capacity of this targeted vector to induce immune responses to the tumor antigen CEA in a stringent in vivo canine model. CD40-targeted Ad5 transduced canine DCs via the CD40-CD40L pathway in vitro, and following vaccination of healthy dogs, CD40-targeted Ad5 induced strong anti-CEA cellular and humoral responses. These data validate the canine model for future translational studies and suggest targeting of Ad5 vectors to CD40 for in vivo delivery of tumor antigens to DCs is a feasible approach for successful cancer therapy.

Infectivity enhancement for adenoviral transduction of canine osteosarcoma cells

The full realization of conditionally replicative adenoviruses (CRAds) for cancer therapy has been hampered by the limited knowledge of CRAd function in vivo and particularly in an immunocompetent host. To address this issue, we previously proposed a canine adenovirus type 2 (CAV2)-based CRAd for clinical evaluation in canine patients with osteosarcoma (OS). In this study, we evaluated infectivity-enhancement strategies to establish the foundation for designing a potent CAV2 CRAd with effective transduction capacity in dog osteosarcoma cells. The results indicate that the native CAV2 fiber–knob can mediate increased binding, and consequently gene transfer, in both canine osteosarcoma immortalized and primary cell lines relative to previously reported Ad5 infectivity-enhancement strategies. Gene delivery was further enhanced by incorporating a polylysine polypeptide onto the carboxy terminus of the CAV2 knob. This vector demonstrated improved gene delivery in osteosarcoma xenograft tumors. These data provide the rationale for generation of infectivity-enhanced syngeneic CAV2 CRAds for clinical evaluation in a dog osteosarcoma model.