Activation of protein kinase C during newt limb regeneration: effect of denervation.

Blastema cell proliferation during newt limb regeneration is a nerve-dependent process. The present study was undertaken to determine whether or not that process is mediated by protein kinase C (PKC) activation during limb regeneration in Pleurodeles walt. Analysis included evaluation of PKC activity and its subcellular localization at various stages of regeneration, both in vivo and in vitro. The data reveal an increase in PKC activity in both the cytosol and particulate fractions of whole blastemas reaching a maximum at the mid-bud stage, which correlates with blastema cell proliferation rate. Denervation significantly reduces blastema cell proliferation and also causes a reduction in membrane-associated PKC activity. The effect of PKC activity appears to be restricted to the blastemal mesenchyme, which exhibits a dramatic reduction in activity 96 h after denervation. In contrast, PKC activity in the epidermal cap did not change. Cultured whole blastemas likewise express a decrease in particulate PKC activity and therefore mimic denervated blastemas in this parameter. Co-culture of blastemas with spinal ganglia partially reduces the decline in PKC activity, and the phorbol ester 12-O-tetradecanoylphorbol 13-acetate, a direct activator of PKC, also prevents the fall in membrane-bound PKC activity while stimulating blastema cell proliferation, in vitro. These data indicate that blastema cell (mesenchyme) proliferation is related to increased PKC activity and that PKC may therefore be involved in the nerve-dependent signalling pathway regulating the early phase of urodele limb regeneration.

Experimental evidence for FGF-1 control of blastema cell proliferation during limb regeneration of the amphibian Pleurodeles waltl.

During regeneration, blastema cell proliferation depends on several different factors which are, as yet, not fully understood. Previous studies showing the presence of FGF-1 and FGF receptors in the limb blastema make FGF-1 a potentially important molecule for limb regeneration but they do not demonstrate that this factor is active during the process. In the present study, we have first of all confirmed the presence of FGF-1 in limb blastemas of the amphibian Pleurodeles waltl using immunochemistry. Second, we provide evidence in vivo that FGF-1 controls blastema cell proliferation by using different reagents which interfere with FGF activity. Sulfated polysaccharides which bind FGFs, such as heparin, iota-carrageenan and pentosan polysulfate, are able to decrease both 3H-thymidine incorporation and the mitotic index in regeneration blastemas. In addition, suramin which inhibits the binding of growth factors to their receptors, induces the same effect. The presence of receptors in blastema cells is also demonstrated by using the FGF-saporin complex which is known to bind to FGF receptors and to kill cells bearing these receptors. This complex decreases the mitotic index in mesenchyme, while saporin alone did not influence cell proliferation. Finally, results obtained using a neutralizing monoclonal antibody against FGF-1 which was able to specifically reduce blastema cell proliferation, suggests that FGF-1 plays an important function in limb regeneration.

Nerve dependent sulphated glycosaminoglycan synthesis in limb regeneration of the newt Pleurodeles waltl.

Denervation of the amputated limb of newts stops the regeneration process by decreasing blastema cell proliferation. We investigated the effect of the denervation on each of the two compartments (epidermal cap, mesenchyme) in mid-bud blastemas on the level of sulphated glycosaminoglycans (GAGS). Denervation resulted in an increase of about threefold in the incorporation of [35S] sulphate into mesenchyme GAGs but had no effect on the epidermal cap. The increase of GAG synthesis in the mesenchymal part of the blastema involved both heparan sulphates and chondroitin-dermatan sulphates. Gel filtration showed no change in GAGs size after denervation. These results confirm that the mesenchymal part of the mid-bud blastema is the main target of nerves and, as heparan sulphates are known to store acidic fibroblast growth factor (aFGF), a polypeptide found in the blastema (Boilly et al.. 1991), this suggest that the nerves' effect on glycosaminoglycans turnover could be implicated in the control of bioavailability of this growth factor in the blastema.