Frédéric Revah

PREVENTION OF MOTONEURON DEATH BY ADENOVIRUS-MEDIATED NEUROTROPHIC FACTORS

Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disease characterized by progressive loss of motoneurons, and has no effective treatment. Experimental studies in rodents have shown that motoneurons respond to a variety of molecules including brain‐derived neurotrophic factor (BDNF), and the glial‐cell line‐derived neurotrophic factor (GDNF). Here we investigated the neuroprotective effect of these growth factors, encoded by an adenovirus, on the death of axotomized facial motoneurons in newborn rats. We used a new gene therapy strategy that involves gene transfer to motoneurons by intramuscular injection of an adenoviral vector, which is retrogradely transported from injected target muscle (Finiels et al.,: NeuroReport 7:373–378, 1995). A significant increased survival of motoneurons was observed in animals pretreated with adenovirus encoding BDNF (34.5%, P < 0.05) or GDNF (41.9%, P < 0.05) 1 week after axotomy.

IMMUNOHISTOCHEMICAL ANALYSIS OF PRESENILIN-1 EXPRESSION IN THE MOUSE BRAIN

At least 22 different mutations associated with early‐onset familial Alzheimers disease (AD) in various kindreds have been reported to occur in a recently identified gene on chromosome 14, presenilin 1 (PS‐1) (Sherrington et al. (1995) Nature 375, 754–760 [1] and reviewed by Van Broeckhoven (1995) Nat. Genet. 11, 230–231 [2]). In order to study the localization of PS‐1 in the brain, we raised a polyclonal antiserum specific to a fragment of the predicted protein sequence of PS‐1. PS‐1 immunostaining was found intracellularly, in the perikaria of discrete cells, mostly neurons, appearing as thick granules, resembling large‐size vesicles. These granules were located in the periphery of cell bodies and extended into dendrites and neurites. PS‐1 expression was found to be broadly distributed throughout the mouse brain, not only in structures involved in AD pathology, but also in structures unaltered by this disease.

Induction of Neuronal Apoptosis by Excitotoxins Associated with Long-Lasting Increase of 12-O-Tetradecanoylphorbol 13-Acetate-Responsive Element-Binding Activity

Abstract: We show that excitotoxic cell death, which is associated with pathological neurodegenerative processes, can display morphological and biochemical features characteristic of apoptosis, a mode of cell death typical of physiological neuronal elimination during development. Cortical neurons cultured in the absence of serum, stimulated with NMDA, glutamate, or quisqualate after 3–5 days in vitro, showed significant degeneration. This death was blocked by 1 µM MK‐801, indicating that it was mediated by the activation of NMDA receptors. Dying cells displayed an apoptotic morphology, characterized by cytoplasm and chromatin condensation. No internucleosomal DNA degradation was observed, confirming that morphological changes of apoptosis can be dissociated from DNA laddering. Inhibitors of protein or RNA synthesis abolished cell death, and the protective effect of cycloheximide was similar when the drug was applied 2 h before or 8 h after glutamate. These experiments suggest the participation of active gene transcription in the mechanism of death. We thus analyzed the modulation of transcription factors in dying cells using electrophoretic mobility shift assays. The level of factors binding to the 12‐O‐tetradecanoylphorbol 13‐acetate‐responsive element (TRE) displayed a late and sustained increase preceding neuronal death, which was not found for factors complexing the Sp1 P, Oct, and USF binding sites. These results raise the possibility that apoptosis is one of the mechanisms of death in the pathologies linked to excitotoxicity and that activation of TRE‐binding factors could play a role in these processes.

Immunohistochemical analysis of presenilin 2 expression in the mouse brain: distribution pattern and co-localization with presenilin 1 protein

Missense mutations of presenilin 1 (PS-1) and presenilin 2 (PS-2) genes cause the majority of early-onset familial forms of Alzheimers disease (AD). We previously characterized the distribution of the PS-1 protein in the mouse brain by immunohistochemistry using an antibody directed against an epitope located in the large hydrophilic loop [Moussaoui, S., Czech, C., Pradier, L., Blanchard, V., Bonici, B., Gohin, M., Imperato, A. and Revah, F., Immunohistochemical analysis of presenilin 1 expression in the mouse brain, FEBS Lett., 383 (1996) 219-222]. Similarly, we now report the distribution pattern of PS-2 protein in the mouse brain. For these experiments we used a polyclonal antibody raised against a synthetic peptide corresponding to the amino-acid sequence 7-24 of the predicted human PS-2 protein. The specificity of the antibody was evidenced by its ability to recognize PS-2 protein in immunoprecipitation studies and by antigen-peptide competition. In the mouse brain, PS-2 protein was present in numerous cerebral structures, but its distribution in these structures did not correlate with their susceptibility to AD pathology. In all examined structures of the gray matter, PS-2 protein was concentrated in neuronal cell bodies but it was not detected in the glial cells of the white matter. The regional distribution pattern of PS-2 protein was almost identical to that of PS-1 protein. Moreover, PS-2 protein co-localized with PS-1 protein in a large number of neuronal cell bodies. In terms of subcellular localization, PS-2 immunostaining was present almost exclusively in neuronal cell bodies while PS-1 immunostaining was also present in dendrites. This could be explained by the different epitopes of the antibodies and the known proteolytic processing of both presenilins in vivo [Tanzi, R.E., Kovacs, D.M., Kim, T.-W., Moir, R.D., Guenette, S.Y. and Wasco, W., The presenilin genes and their role in early-onset familial Alzheimers disease, Alzheimers disease Rev., 1 (1996) 91-98]. Within neuronal cell bodies, the immunostaining of PS-2 protein, as well as that of PS-1 protein, had a reticular and granular appearance. This suggests in agreement with previous observations on PS-1 and PS-2 in COS and H4 cells [Kovacs, D.M., Fausett, H.J., Page, K.J., Kim, T.-W., Moir, R.D., Merriam, D.E., Hollister, R.D., Hallmark, O.G., Mancini, R., Felsenstein, K.M., Hyman, B.T., Tanzi, R.E., Wasco, W., Alzheimer-associated presenilins 1 and 2: neuronal expression in brain and localization to intracellular membranes in mammalian cells, Nature Med., 2 (1996) 224-229] that these proteins are situated in intracytoplasmic organelles, possibly the endoplasmic reticulum and the Golgi complex.

In vivo adenovirus-mediated gene transfer to newborn rat retinal pigment epithelial cells

A successful surgical access to the subretinal space is critical for achieving adenovirus-mediated gene transfer to the retinal pigment epithelial (RPE) cells or photoreceptor cells. We report a novel surgical approach allowing an efficient delivery of recombinant replication-deficient adenoviral vectors into the subretinal space of newborn rats. Our data suggest that this method may be useful for infecting reproducibly large area of the RPE cell layer of normal newborn rats and should be applicable to RCS pups. We also show the feasibility of infecting ex vivo RPE cells in culture using the same recombinant adenoviral vector.