Control of the blastemal cell cycle by the peripheral nervous system during newt limb regeneration; continuous labeling analysis

Forty-eight and 96 hr 3H-thymidine continuous labeling was analyzed on denervated mid-bud limb blastemas of Pleurodeles waltlii M. In innervated blastemas, 92 to 95% of mesenchymal cells are cycling; denervation provokes an early exiting from the cycle in G0-1(+ 15% of non-cycling cells for a 6-day denervation, + 20% for an 8 day denervation) and an elongation of the G1 phase. For epidermis only 25% (48 hr labeling) to 53% (96 hr labeling) of cells are cycling in innervated blastemas; denervation strongly decreases this percentage (+ 40% of non-cycling cells for a 6-day denervation, + 60% for an 8-day denervation). As for mesenchyme, denervation also lengthens the G1 phase of epidermal cells. So our results contradict the conclusion of other authors claiming a G2 blockage. They account for the fall in proliferation indices and the arrest of regeneration after denervation. Finally, they show that the cell cycle of regeneration cells is controlled by the neurotrophic factor.     

Influence of denervation on the regeneration of Pleurodele limbs

Abstract. A cytophotometric study of Feulgen-stained mesenchymal cell nuclei from regeneration blastemas of both innervated and denervated limbs over the 1st 7 days following the midbud stage showed a diminution of the percentage of cells in the S + G₂ phases and a corresponding augmentation of the percentage of cells in the G₀+ G₁ phases. This change, which was temporally correlated with the redifferentiation of the innervated blastemas, was greater in denervated blastemas, even though they do not redifferentiate. From these results, it is concluded that the denervation of midbud blastemas brings about either an extension of the G₁ phase or an exiting from the cell cycle to G₁ (G_0–1), or both phenomena.     

Ganglia implantation as a means of supplying neurotrophic stimulation to the newt regeneration blastema: cell-cycle effects in innervated and denervated limbs.

Regulation of blastema cell proliferation during amphibian limb regeneration is poorly understood. One unexplained phenomenon is the relatively low level of active cell cycling in the adult newt blastema compared to that of larval axolotls. In the present study, we used ganglia implantation as a means of "superinnervating" normally innervated adult newt blastemas to test whether blastema cell subpopulations are responsive to nerve augmentation. The effectiveness of implanted ganglia to provide neurotrophic stimulation was demonstrated in denervated blastemas. Blastemas implanted with 2 dorsal root ganglia and simultaneously denervated 14 days after amputation exhibited control levels of cell cycle activity 6 days later, as measured by 3H-thymidine pulse labeling. Denervated blastemas that were sham-operated or implanted with pituitary glands exhibited cell-cycle declines similar to those of denervated blastemas without implanted ganglia. Thus, 2 implanted ganglia provide neurotrophic stimulation equivalent to that of the normal nerve supply. Dorsal root ganglia implanted into normally innervated blastemas, which should effectively double neurotrophic activity to the blastema, had no effect on cell-cycle activity, innervated blastemas implanted with ganglia for 6 days exhibited pulse labeling indices similar to those of normally innervated blastemas. These data indicate that neurotrophic stimulation is not normally limiting in innervated limbs, and that some other factor, whether extrinsic or intrinsic to blastema cells, accounts for the relatively low level of active cell cycling in the adult newt blastema.     

The effects of partial and complete denervation on adult newt forelimb blastema cell-cycle parameters

Abstract. The adult newt blastema cell-cycle time (cct) was measured by the percentage of labeled mitoses (PLM) method at the early-bud and mid-bud stages and was found to be 42.9 and 42.7 h, respectively. At both stages, the DNA synthetic phase (S) occupied the majority (75%) of the cct. However, the blastema labeling index (LI) after a 2-h pulse of ³H-thymidine was less than 30% i.e., considerably less than predicted from the ratio of the duration of S over the cct. Compared to that of controls, the PLM plot for partially denervated blastemas exhibited a coincident and equal-sized first peak of labeled mitoses and a coincident but smaller second peak of labeled mitoses. After 24 h of continuous labeling, the LI of control blastemas reached 53%, whereas the LIs of partially denervated and completely denervated blastemas reached only 33% and 20%, respectively. These results are consistent with the view that many cells of adult newt blastemas are not actively progressing through the cell cycle and that the number of noncycling cells is increased by partial or complete denervation. The noncycling cells are probably in the G₁ phase of the cell cycle.     

Rôle du Système Nerveux Sur la Prolifération Cellulaire des Blastèmes de Régénération de Membre de Triton (Pleurodeles Waltlii Michah)

Cellular proliferation of both epidermal and mesenchymal cells of denerved cone stage limb blastemas ( Pleurodeles waltlii Michah) was studied in vivo. The mitotic index and thymidine ³H incorporation (autoradiography following short term (1 hr) incubation and scintigraphy) show that denervation causes a significant decrease in the cellular proliferation (about 70% 4 days after denervation). Denervation affects first the mesenchymal cells, the proliferation of epidermal cells declines later. These results are discussed in term of cellular cycle.     

Generation of mononucleate cells from post-mitotic myotubes proceeds in the absence of cell cycle progression

The remarkable regenerative ability of adult urodele amphibians depends in part of the plasticity of differentiated cells at the site of injury. Limb regeneration proceeds by formation of a mesenchymal growth zone or blastema under the wound epidermis at the end of the stump. Previous work has shown that when cultured post-mitotic newt myotubes are introduced into the blastema, they re-enter the cell cycle and undergo conversion to mononucleate cells which divide and contribute to the regenerate [11, 13]. In order to investigate the interdependence of these two aspects of plasticity, we have blocked cell cycle progression of the myotubes either by X-irradiation or by transfection of the CDK4/6 inhibitor p16. In each case, the efficacy of the block was evaluated in culture after activation of S phase re-entry by serum stimulation. The experimental myotubes were implanted into limb blastemas along with a differentially labelled control population of myotubes containing an equivalent number of nuclei. X-irradiated myotubes gave rise to mononucleate cells in the limb blastema, and the progeny were blocked in respect of S phase entry. Comparable results were obtained with the p16-expressing myotubes. We conclude that progression through S or M phase is not required for generation of mononucleate cells and suggest that such cells may arise by budding from the muscle syncytium.     

Nerve-independence of limb regeneration in larval Xenopus laevis is related to the presence of mitogenic factors in early limb tissues.

Early limbs of larval Xenopus laevis can form a regeneration blastema in the absence of nerves. The nerve-independence could be due to the synthesis of neurotrophic-like factors by the limb bud cells. To test this hypothesis, two series of experiments were performed. Series A: the right hindlimbs of stage 57 larvae (acc. to Nieuwkoop and Faber. 1956. Normal table of Xenopus laevis [Daudin]. Amsterdam: North-Holland Pub. Co.), which are nerve-dependent for regeneration, were amputated through the tarsalia. The regenerating limbs were submitted to: sham denervation; denervation; denervation and implantation of a fragment of an early limb, or a late limb, or a spinal cord. Series B: froglets were subjected to amputation of both forelimbs. The cone blastemas were transplanted into denervated hindlimbs of stage 57 larvae, together with a fragment of an early or a late limb. The results in series A showed that the implantation of early limb tissue into the denervated blastema maintained cell proliferation at levels similar to those observed after the implantation of a spinal cord fragment or in sham denervated blastemas. However, the implantation of late limb tissues were ineffective. The results of series B showed that the implantation of early limb tissue, but not of late limb tissue prevented the inhibition of cell proliferation and the regression of denervated limb blastemas of juveniles. These results indicate that the nerve-independence is related to the synthesis of diffusible mitogenic neurotrophic-like factors in early limb tissues, and that nerve-dependence is established when differentiated cells of late limb tissues stop producing these factors.     

A monoclonal antibody detects a difference in the cellular composition of developing and regenerating limbs of newts

We have previously described a monoclonal antibody (called 22/18) that reacts with the early blastemal cells of the regenerating limb of the newt (Notophthalmus viridescens). In embryos of two newt species the antibody reacts with the epidermis, glial cells in the neural tube, the lens and cells in a restricted region of the aorta. In the developing limb bud less than 1% of the mesenchymal cells were reactive with 22/18, although most cells stained brightly with an antibody to another cytoskeletal component. When limbs were amputated prior to the arrival of nerves (axons and Schwann cells) at the amputation plane there was no extra reactivity with 22/18 as compared to the contralateral unamputated control, even though the amputated buds regenerated satisfactorily. Limbs amputated after nerves are present at the plane of amputation respond by forming a 22/18-positive blastema. The appearance of the 22/18 responses is a function of the stage of limb development as shown by amputation of forelimb and hindlimb buds at a larval stage where development of the forelimb is greatly advanced relative to the hindlimb. The distribution of the 22/18-positive cells in larval blastemas showed them to be closely associated with axons as detected by double staining with an antiserum to a neurofilament subunit. The clear antigenic difference between development and regeneration may be related to the relationship between embryonic regulation and epimorphic regeneration, and also to the acquisition of nerve-dependent proliferation of blastemal cells.     

In vivo relationship between morphonuclear parameters and hormone sensitivity of the murine MXT mammary tumor

The initially hormonosensitive (HS) MXT mouse mammary tumor spontaneously evolved to hormonoin-dependence (HI). Using a SAMBA 200 cell image processor, we compared the DNA content and the chromatin structure of HS and HI tumor cells squashed onto histologic slides; the nuclei were colored by the Feulgen reaction. We compared HI and HS nuclei by a discriminant analysis using the 15 parameters obtained on each nucleus. We show that the percentage of well-classified granulocytes (2n DNA content control) versus HS or HI nuclei exceeded 99. On the other hand, this percentage did not reach 70 when we compared HS and HI. The cell cycle analysis revealed that the percentage of cells in S and G2 + M phases were significantly higher in HI tumors than in the HS. Hence, HI and HS MXT tumor nuclei seem to be morphologically identical, but are significantly different if we refer to cell proliferation rates.     

Expression and biological effect of urodele fibroblast growth factor 1: relationship to limb regeneration

Fibroblast growth factors (FGFs) have been previously implicated in urodele limb regeneration. Here, we examined expression of FGF-1 by blastema cells and neurons and investigated its involvement in wound epithelial formation and function and in the trophic effect of nerves. Neurons innervating the limb and blastema cells in vivo and in vitro expressed the FGF-1 gene. The peptide was present in blastemas in vivo. Wound epithelium thickened when recombinant newt FGF-1 was provided on heparin-coated beads, demonstrating that the FGF-1 was biologically active and that the wound epithelium is a possible target tissue of FGF. FGF-1 did not stimulate accessory limb formation. FGF-1 was as effective as 10% fetal bovine serum in maintaining proliferative activity of blastema cells in vitro but was unable to maintain growth of denervated, nerve-dependent stage blastemas when provided on beads or by injection. FGF-1 had a strong stimulating effect on blastema cell accumulation and proliferation of limbs inserted into the body cavity that were devoid of an apical epithelial cap (AEC). These results show that FGF-1 can signal wound epithelium cap formation and/or function and can stimulate mesenchyme accumulation/proliferation in the absence of the AEC but that FGF-1 is not directly involved in the neural effect on blastema growth.     

In vitro and in vivo characterization of blastemal cells from regenerating newt limbs.

To better characterize the cells involved in newt limb regeneration, blastemal cells from accumulation and differentiation phase blastemas were grown in dissociated cell culture, and their morphology and antigenic phenotype determined using a variety of antibodies directed against intermediate filaments, cell adhesion molecules, and extracellular matrix molecules. In addition to previously described blastemal cell morphologies, many of the cells in these cultures had a round cell body, with an eccentrically placed nucleus and a cytoplasm filled with autofluorescent granules. The majority of accumulation phase blastemal cells labeled with antibodies against GFAP, vimentin, 22/18 as well as with antibodies against NCAM, L-1, laminin, and fibronectin. The majority of differentiation phase blastemal cells had a similar phenotype but lacked expression of vimentin and fibronectin. Comparison of the blastemal phenotype in vitro and in vivo showed similar expression characteristics. However, in differentiation phase blastemas, laminin immunoreactivity was concentrated in specific locations. In addition, the proliferation of cultured blastemal cells is stimulated by the addition of a crude brain extract, consistent with previous studies in vivo and in vitro. Taken together, these observations suggest that dissociated cultures of newt limb blastemal cells provide a suitable model for the analysis of the cell and molecular mechanisms involved in limb regeneration.     

Visualizing spatiotemporal dynamics of multicellular cell-cycle progression

The cell-cycle transition from G1 to S phase has been difficult to visualize. We have harnessed antiphase oscillating proteins that mark cell-cycle transitions in order to develop genetically encoded fluorescent probes for this purpose. These probes effectively label individual G1 phase nuclei red and those in S/G2/M phases green. We were able to generate cultured cells and transgenic mice constitutively expressing the cell-cycle probes, in which every cell nucleus exhibits either red or green fluorescence. We performed time-lapse imaging to explore the spatiotemporal patterns of cell-cycle dynamics during the epithelial-mesenchymal transition of cultured cells, the migration and differentiation of neural progenitors in brain slices, and the development of tumors across blood vessels in live mice. These mice and cell lines will serve as model systems permitting unprecedented spatial and temporal resolution to help us better understand how the cell cycle is coordinated with various biological events.     

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.     

Blastema cell proliferation in vitro: effects of limb amputation on the mitogenic activity of spinal cord extracts

Primary cultures of mesenchymal cells of axolotl limb blastemas provide a very sensitive in vitro bioassay for studying nerve dependence of newt regeneration. These cells can be stimulated by crude spinal cord extracts of non-amputated animals in a dose-dependent manner up to 60 micrograms protein/ml of culture medium; at this concentration the mitotic index is increased 4-fold. Spinal cord extracts of axolotls 14 days after forelimb amputation (i.e., late bud stage) are more efficient in stimulating blastema cell proliferation (+50%) than extracts of axolotls 7 days after forelimb amputation (i.e., early bud stage) or of axolotls without amputation. In a similar manner, spinal cord extracts of young axolotls 14 days after forelimb amputation, are more stimulatory than older axolotls 14 d after forelimb amputation which regenerate only a very small blastema during the same time. It appears that spinal cord mitogenic activity is enhanced after limb amputation, probably in correlation with blastema cell requirements for limb regeneration.     

Cell-cycle studies by multiparametric automatic scanning of topographically preserved cells in culture

The authors have developed a new methodology for characterizing in situ the cell cycle of human mammary epithelial cell lines. Using a SAMBA 200 cell image processor (scanning cytometry), 15 densitometric and textural parameters were computed on each Feulgen-stained nucleus. Parameters computed from the grey level cooccurrence and run-length section matrices allowed assessment of the chromatin pattern. Multiparametric analysis of data defined: 1) the relative position of each cell; 2) the relative positions of groups of cells, each group corresponding to a definite phase of the cell cycle; and 3) the function of these parameters best separating these phases. Files then were constructed for each phase: G0/G1, S, G2/ and M. Using these three files as a reference to classify cells, it was possible to ascertain the phase of the cell cycle for each cell of a population. The MDA AG human cell line synchronized by mitotic selection was used as a model to develop this method. The criteria used to assign cells to G0/G1, S, or G2 was DNA content. Classification in M phase was achieved by visual identification of mitotic cells. This method was checked on unsynchronized MDA AG and then applied to other human cell lines (MDA MB231, MCF-7, T47D C111). Comparison of results obtained by scanning cytometry and flow cytometry showed the proportion of cells assigned to G0/G1, S, and G2/M by the two methods to be similar. This new method removes some of the limitations of flow cytometry by 1) allowing visual verification of each cell analyzed; 2) lowering the number of cells required for study; 3) discriminating between G2 and M; and 4) preserving cell topography.     

Cloning and neuronal expression of a type III newt neuregulin and rescue of denervated, nerve-dependent newt limb blastemas by rhGGF2

Urodele amphibians are the only vertebrates that can regenerate their limbs throughout their life. The critical feature of limb regeneration is the formation of a blastema, a process that requires an intact nerve supply. Nerves appear to provide an unidentified factor, known as the neurotrophic factor (NTF), which stimulates cycling of blastema cells. One candidate NTF is glial growth factor (GGF), a member of the neuregulin (NRG) growth factor family. NRGs are both survival factors and mitogens to glial cells, including Schwann cells. All forms of NRGs contain an EGF-like domain that is sufficient to activate NRG receptors erbB2, erbB3, and erbB4. To investigate the involvement of neuregulin in newt limb regeneration, we cloned and characterized one neuregulin isoform, a neuregulin with a cysteine-rich domain (CRD-NRG), from newt (Notophthalmus viridescens) spinal cord. Results of in situ hybridization showed that the newt CRD-NRG is highly expressed in dorsal root ganglia and spinal cord neurons that innervate the limbs. We also demonstrated the biological activity of recombinant human GGF2 (rhGGF2) in urodele limb regeneration. When rhGGF2 was injected into denervated, nerve-dependent axolotl blastemas, the labeling index (LI) of blastema cells was maintained at a level near to that of control, innervated blastemas, whereas without rhGGF2 the LI decreased significantly. In another experiment, rhGGF2 was delivered into denervated, nerve-dependent blastemas either by direct infusion into blastemas or by injection into the intraperitoneal cavity. The denervated blastemas were rescued into a regeneration response.     

Epigenetic characteristics of bovine donor cells for nuclear transfer: levels of histone acetylation

Donor cell type, cell-cycle stage, and passage number of cultured cells all affect the developmental potential of cloned embryos. Because acetylation of the histones on nuclear chromatin is an important aspect of gene activation, the present study investigated the differences in histone acetylation of bovine fibroblast and cumulus cells at various passages and cell-cycle stages. The acetylation was qualitatively analyzed by epifluorescent confocal microscopy and quantitatively by immunofluorescent flow cytometry. Specifically, we studied levels of histone H4 acetylated at lysine 8 and histone H3 acetylated at lysine 18; acetylation at these lysine residues is among the most common for these histone molecules. We also studied levels of linker histone H1 in donor cells. Our results show that stage of cell cycle, cell type, and number of cell passages all had an effect on histone content. Histone H1 and acetyl histone H3 increased with cell passage (passages 5-15) in G0/G1- and G2/M-stage cumulus and fibroblast cells. We also found that acetyl histone H4 was lower in early versus late cell passages (passage 5 vs. 15) for G0/G1-stage cumulus cells. In both cell types examined, acetyl histones increased with cell-cycle progression from G0/G1 into the S and G2/M phases. These results indicate that histone acetylation status is remodeled by in vitro cell culture, and this may have implications for nuclear transfer.     

Glial growth factor and nerve-dependent proliferation in the regeneration blastema of Urodele amphibians

After amputation of a limb from Urodele amphibians, division of the blastemal cells (the progenitor cells of the regenerate) depends on one or more unidentified growth factors provided by the nerve supply. Here we show that glial growth factor (GGF), a mitogenic protein previously purified from the bovine pituitary, is present in newt nervous system extracts. It is also detectable in extracts of the forelimb regeneration blastema, and its level there decreases after denervation. We have previously shown that blastemal cells dependent on the nerve for division are marked by a monoclonal antibody called 22/18. When denervated blastemas are cultured in the presence of partially purified GGF from newt brain, or pure GGF from the bovine pituitary, the thymidine labeling index of blastemal cells that are 22/18-positive is increased as much as sevenfold. These data indicate that GGF plays a role in nerve-dependent proliferation in the blastema.