Daniel Raulais

Characterization of acidic and basic fibroblast growth factors in brain, retina and vitreous chick embryo

We have purified acidic and basic fibroblast growth factors (c-aFGF, c-bFGF) from 11 day-old chick embryo brain, retina and vitreous by heparin-Sepharose chromatography and reverse phase HPLC. The analysis of their biological activity as well as their molecular weight indicates that they were analogous to basic or acidic human and bovine FGF. The ratio of c-aFGF to c-bFGF activity depended of the tissue. In brain c-aFGF represented 66% of the total mitogenic activity retained on the heparin-sepharose column and c-bFGF 34% while retina contained 16% of c-aFGF and 84% of c-bFGF; vitreous 78% of c-aFGF and 22% of c-bFGF. Like human aFGF, Heparin stimulated purified c-aFGF mitogenic activity in the absence of serum but inhibited the activity of the retina acid soluble extract, in the presence of foetal calf serum (FCS). Thus, chick embryo and adult human acidic and basic FGF respectively share the same biochemical properties. Since there are no blood vessels in chick retina or vitreous, their presence in these tissues suggests that angiogenesis is not the only role of these growth factors.

A new heparin binding protein regulated by retinoic acid from chick embryo

A 19 KDa heparin binding protein was previously purified from chicken embryos. Essentially localized within basement membranes in early embryonic tissues, this protein is very rich in basic and cystein residues. Its N-terminal fragment is similar to corresponding fragment of two other proteins expressed during embryogenesis and postnatal period. Its synthesis and secretion are induced by retinoic acid in chicken myoblasts and fibroblasts. This new retinoic acid induced heparin binding protein (RI-HB) does stimulate neurite outgrowth and proliferation on PC12 cells. These results suggest that retinoic acid could regulate some aspect of differentiation and development by inducing the synthesis of a new family of growth and neurotrophic factors.

Acidic Fibroblast Growth Factor (aFGF) in Developing Normal and Dystrophic (mdx) Mouse Muscles. Distribution in Degenerating and Regenerating mdx Myofibres

Affinity purified polyclonal antibodies directed against human recombinant acidic FGF (aFGF), were used in immunofluorescence studies to localize this growth factor in several normal and dystrophic (mdx) mouse skeletal muscles. The expression of aFGF was detected throughout the life of both the control and mdx mice. In striated muscles, examined up to 3 weeks postnatal, aFGF was localized around the myofibres and this pattern was consistent in both mdx and the normal counterpart strain. However, the intensity of the signal was much stronger in the mdx strain. In mdx mouse skeletal muscles, examined during the acute phase of degeneration and regeneration (3-14 weeks) aFGF was localized around the myofibres, in approximately 60% of the nuclei of newly formed or regenerated myofibres and also in the pockets of necrosis which represented actively degenerating myofibres. In normal mouse skeletal muscles, studied over the same period, the antibodies localized aFGF mainly to the periphery of the muscle fibres. The augmentation of aFGF observed by immunofluorescence in mdx mouse muscles was confirmed by enzyme immunoassay (EIA) analysis of the same muscles over the same period of time. The data from the EIA indicated a 3.5-fold increase in aFGF in mdx as compared to normal muscles at 3 weeks, and an approximate 26-fold increase during the period of active degeneration-regeneration. This increased concentration of aFGF noted in the mdx muscles suggests that this endogenous aFGF may participate in the high level of regenerative activity observed in mdx mouse.

Localization of acidic fibroblast growth factor in proliferative vitreoretinopathy membranes

The pathogenesis of proliferative vitreoretinopathy (PVR) membranes remains poorly understood. We have studied the presence of acidic fibroblast growth factor (aFGF), a potent mitogen for many cells, within these membranes. We have used affinity purified monospecific anti-aFGF polyclonal antibodies, in conjunction with highly sensitive immunofluorescence techniques. The labelling was exclusively localized to cell bodies and was absent from the extracellular matrix. Double labelling techniques revealed that all cytokeratin positive cells (probably pigmented epithelial cells) and macrophages contained aFGF-like immunoreactivity, whilst glial cells were unlabelled. Appropriate controls indicated the specificity of the antibodies. Hence, the presence of this mitogenic molecule within certain cell types constituting PVR membranes may contribute to the pathogenesis.

HB-GAM/Pleiotrophin and Midkine are Differently Expressed and Distributed During Retinoic Acid-induced Neural Differentiation of P19 Cells

HB-GAM/Pleiotrophin and Midkine (MK) are developmentally-regulated proteins with putative functions during cell growth and differentiation. Using the P19 cell which is a model to study the events associated with early development, we examined the expression and cellular localization of HB-GAM and MK during neural differentiation of P19 cells induced by retinoic acid (RA). The temporal expressions of HB-GAM and MK transcripts and both the levels and cellular localizations of the corresponding proteins appeared dramatically different. MK mRNA, already expressed in untreated P19 cells, was transiently increased by exposure to RA and then largely down regulated. More interestingly, HB-GAM which was not detected in untreated P19 cells was strongly expressed after 2 days of RA treatment and this expression persists throughout the duration of the culture suggesting that it could be involved in different aspects of this differentiation process.