Jean-Jacques Robert

Specific and efficient gene transfer strategy offers new potentialities for the treatment of motor neurone diseases.

Several growth factors are candidates for the therapy of motor neurone diseases. However, there is no efficient, safe, and practicable administration route which hampers the clinical use of these potentially therapeutic agents. We show that specific and high yield gene transfer into motor neurones can be obtained by peripheral intramuscular injections of recombinant adenoviruses. These vectors are retrogradely transported from muscular motor units to motor neurone cell bodies. Gene transfer can thus be specifically targeted to particular regions of the spinal cord by appropriate choice of the injected muscle. The efficiency of gene transfer is high, with 58–100% of the motor neurones afferent to the injected muscle expressing the transgene. This new therapeutic protocol allows specific targeting of motor neurones without lesioning the spinal cord, and should avoid undesirable side effects associated with systemic administration of therapeutic factors.

Cells of the neuronal lineage play a major role in the generation of amyloid precursor fragments in gelsolin-related amyloidosis.

Gelsolin-related amyloidosis or familial amyloidosis, Finnish type (FAF) (OMIM No105120) is a hereditary amyloid disease caused by a mutation in a precursor protein for amyloid (gelsolin) and characterized by corneal dystrophy and polyneuropathy.In vitro expression of the FAF-mutant (Asp187→ Asn/Tyr) secretory gelsolin in COS cells leads to generation of an aberrant polypeptide presumably representing the precursor for tissue amyloid. Here, we provide evidence that this abnormal processing results from defective initial folding of the secreted FAF gelsolin due to the lack of the Cys188-Cys201 disulfide bond, normally formed next to the FAF mutation site. We compared cells of different tissue origin and discovered a dramatic difference between the amount of cleavage of FAF gelsolin to the amyloid precursor in neuronal and non-neuronal cells. More than half of the mutant gelsolin was cleaved in PC12 and in vitro differentiated human neuronal progenitor cells. In contrast, human fibroblasts and Schwannoma cell cultures showed only a limited capacity to cleave FAF gelsolin, although the cleavage mechanism per se seems to be similar in the various cell types. The present findings of processing and distribution of secreted FAF gelsolin in the neuronal cells emphasize the role of neurons in the tissue pathogenesis of this amyloid polyneuropathy.

An adenovirus encoding CuZnSOD protects cultured striatal neurones against glutamate toxicity.

Superoxide dismutase (SOD), a key enzyme in the detoxification of free radicals, catalyses the dismutation of superoxide O2* to oxygen and hydrogen peroxide (H2O2). It is therefore a promising candidate for gene transfer therapy of neurological diseases in which free radicals are thought to be involved. We have constructed a recombinant adenoviral vector containing the human copper-zinc SOD cDNA. Using this vector we were able to drive the production of an active human copper-zinc SOD protein (hCuZnSOD) in various cell lines and primary cultures. Infection of striatal cells with a recombinant adenovirus expressing hCuZnSOD protected these cells from glutamate-induced cell death.

Gene transfer in situ and in cells for intracerebral transplantation

The therapeutic potential of gene transfer into somatic cells is increasingly considered in human diseases. Strategies are conceived to treat some diseases in which the delivery of a gene product can counteract a pathological process. There are three types of disease that form the target of these new potential treatments. In the first place, inherited gene defects; secondly, cell deficiencies leading to a lack of a gene product controlling a life-critical physiological function and thirdly, acquired diseases of tumour and/or viral origin. Such therapeutic tools must be evaluated in terms of efficacy and safety. They also have to be improved with respect to their effects in the perspective of a viable therapy for patients. This goal requires a strategy based on progressive steps toward efficient and safe clinical applications. This review will first survey the history of gene transfer technology and then describe the tools which are mainly being studied at present and how they are being developed to obtain a significant improvement of function.