J P Lecocq

Bio: J P Lecocq is an academic researcher from Transgene SA. The author has contributed to research in topics: Virus & Gene. The author has an hindex of 19, co-authored 35 publications receiving 4070 citations.

Expression of rabies virus glycoprotein from a recombinant vaccinia virus

Abstract: Rabies is one of the oldest diseases know to man, but its successful control has remained elusive. Although effective vaccines of tissue culture origin against rabies do exist, such preparations are expensive. Live vaccinia virus (VV) recombinants expressing influenza or hepatitis B antigens have recently been used to immunize against these diseases. We have now used this approach to produce a novel rabies vaccine. We first altered the rabies glycoprotein cDNA by site-directed mutagenesis and removed the poly(dG) tail. We then aligned the modified cDNA with an early VV promoter sequence inserted within a cloned copy of the vaccinia thymidine kinase gene and transfected this plasmid into VV-infected cells. Recombination between the virus and the plasmid resulted in a recombinant virus harbouring the rabies glycoprotein cDNA. Inoculation of rabbits with the live recombinant virus induced high titres of rabies virus-neutralizing antibodies, and scarification with the recombinant VV protected mice against challenge with street rabies virus.

Protection from rabies by a vaccinia virus recombinant containing the rabies virus glycoprotein gene

Abstract: Inoculation of rabbits and mice with a vaccinia-rabies glycoprotein recombinant (V-RG) virus resulted in rapid induction of high concentrations of rabies virus-neutralizing antibodies and protection from severe intracerebral challenge with several strains of rabies virus. Protection from virus challenge also was achieved against the rabies-related Duvenhage virus but not against the Mokola virus. Effective immunization by V-RG depended on the expression of a rabies glycoprotein that registered proline rather than leucine as the eighth amino acid from its NH2 terminus (V-RGpro8). A minimum dose required for effective immunization of mice was 10(4) plaque-forming units of V-RGpro8 virus. beta-propiolactone-inactivated preparations of V-RGpro8 virus also induced high levels of rabies virus-neutralizing antibody and protected mice against intracerebral challenge with street rabies virus. V-RGpro8 virus was highly effective in priming mice to generate a secondary rabies virus-specific cytotoxic T-lymphocyte response following culture of lymphocytes with either ERA or PM strains of rabies virus.

Diversity of airway epithelial cell targets for in vivo recombinant adenovirus-mediated gene transfer.

Abstract: A variety of pulmonary disorders, including cystic fibrosis, are potentially amenable to treatment in which a therapeutic gene is directly transferred to the bronchial epithelium. This is difficult to accomplish because the majority of airway epithelial cells replicate slowly and/or are terminally differentiated. Adenovirus vectors may circumvent this problem, since they do not require target cell proliferation to express exogenous genes. To evaluate the diversity of airway epithelial cell targets for in vivo adenovirus-directed gene transfer, a replication deficient recombinant adenovirus containing the Escherichia coli lacZ (beta-galactosidase [beta-gal]) gene (Ad.RSV beta gal) was used to infect lungs of cotton rats. In contrast to uninfected animals, intratracheal Ad.RSV beta gal administration resulted in beta-gal activity in lung lysate and cytochemical staining in all cell types forming the airway epithelium. The expression of the exogenous gene was dose-dependent, and the distribution of the beta-gal positive airway epithelial cells in Ad.RSV beta gal-infected animals was similar to the normal cell differential of the control animals. Thus, a replication deficient recombinant adenovirus can transfer an exogenous gene to all major categories of airway epithelial cells in vivo, suggesting that adenovirus vectors may be an efficient strategy for in vivo gene transfer in airway disorders such as cystic fibrosis.

Oral vaccination of the fox against rabies using a live recombinant vaccinia virus.

Abstract: Rabies, a viral disease affecting all warm-blooded animals, is prevalent in most parts of the world1, where it propagates amongst wild animals, particularly the fox and dog. The public health and economic consequences of infection in man and livestock are well known. Attempts to control the disease by vaccinating wild carnivores with inactivated or attenuated rabies virus remain controversial, and we have instead evaluated here the potential of a recombinant vaccinia virus to protect foxes against the disease. We have found that the administration of vaccinia virus (VV) or a recombinant harbouring the rabies surface antigen gene (VVTGgRAB) is innocuous to foxes. The recombinant virus can elicit the production of titres of rabies-neutralizing antibodies equal or superior to those obtained with conventional vaccine, and 108 plaque-forming units (PFU) of VVTGIgRAB administered subcutaneously, intradermally or orally confers complete protection to severe challenge infection with street rabies virus.

Searching for Peptide Ligands With an Epitope Library

Abstract: Tens of millions of short peptides can be easily surveyed for tight binding to an antibody, receptor or other binding protein using an "epitope library." The library is a vast mixture of filamentous phage clones, each displaying one peptide sequence on the virion surface. The survey is accomplished by using the binding protein to affinity-purify phage that display tight-binding peptides and propagating the purified phage in Escherichia coli. The amino acid sequences of the peptides displayed on the phage are then determined by sequencing the corresponding coding region in the viral DNA's. Potential applications of the epitope library include investigation of the specificity of antibodies and discovery of mimetic drug candidates.

The Basic Science of Gene Therapy

Abstract: The development over the past decade of methods for delivering genes to mammalian cells has stimulated great interest in the possibility of treating human disease by gene-based therapies. However, despite substantial progress, a number of key technical issues need to be resolved before gene therapy can be safely and effectively applied in the clinic. Future technological developments, particularly in the areas of gene delivery and cell transplantation, will be critical for the successful practice of gene therapy.