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.

A developmentally regulated wound epithelial antigen of the newt limb regenerate is also present in a variety of secretory/transport cell types.

The role of the wound epithelium in amphibian limb regeneration is not understood. We showed previously that monoclonal antibody (mAb) WE3 stains the wound epithelium but not skin epidermis, suggesting that the WE3 antigen may be a marker for, or be important in, the function of the wound epithelium. In the present study, we conducted an extensive immunohistochemical survey of adult newt tissues to define the distribution of the WE3 antigen. The results show that the antigen is most commonly found in tissues specialized in macromolecular secretion and/or ion transport. Since the enzyme, carbonic anhydrase, serves as a useful marker for a variety of specialized transporting cell types, we examined whether this enzyme was present in WE3-reactive cells. Of the tissues examined, a striking degree of colocalization of carbonic anhydrase and the WE3 antigen was observed, further strengthening the view that the WE3 antigen is an important constituent of specialized transporting cells. A preliminary biochemical characterization suggests that the antigen is probably a glycoprotein, which elutes during gel filtration as a species of over 660 kDa. Possible implications for the function of the wound epithelium are discussed.

Cell cycle controls and the role of nerves and the regenerate epithelium in urodele forelimb regeneration: possible modifications of basic concepts.

Data from pulse and continuous labeling with [3H]thymidine and from studies with monoclonal antibody WE3 have led to the modification of existing models and established concepts pertinent to understanding limb regeneration. Not all cells of the adult newt blastema are randomly distributed and actively progressing through the cell cycle. Instead, many cells are in a position that we have designated transient quiescence (TQ) and are not actively cycling. We postulate that cells regularly leave the TQ population and enter the actively cycling population and vice versa. The size of the TQ population may be at least partly determined by the quantity of limb innervation. Larval Ambystoma may have only a small or nonexisting TQ, thus accounting for their rapid rate of regeneration. Examination of reactivity of monoclonal antibody WE3 suggests that the early wound epithelium, which is derived from skin epidermis, is later replaced by cells from skin glands concomitant with blastema formation. WE3 provides a useful tool to further investigate the regenerate epithelium.

Dorsal root ganglia grafts stimulate regeneration of denervated urodele forelimbs: timing of graft implantation with respect to denervation.

Amphibian forelimb regeneration is a nerve-dependent process; nerves presumably release one or more neurotrophic factors that stimulate blastema cell division. To date several candidate molecules/factors have been shown to stimulate macromolecular synthesis and/or mitosis but sustained cell cycle activity and blastema development have not been achieved. Because dorsal root ganglia (DRG) implants are capable of promoting regeneration of denervated adult newt limbs (Kamrin & Singer, 1959), we have evaluated the DRG stimulation of regeneration in denervated limbs of adult newts and larval axolotls; two alternative timing strategies were tested as a step toward defining bioassay parameters that best reflect neurotrophic activity. The frequency of regeneration in denervated adult newt limbs was compared after providing DRG before or at the time of denervation (to maintain neurotrophic and cell cycle activity) versus DRG implantation at various postdenervation times (to resupply neurotrophic activity and restimulate suppressed cell cycle activity). The results show that denervated adult newt limbs regenerated most frequently using the maintenance strategy, but as the denervation interval was extended in the restimulation strategy, the frequency of regeneration declined. Larval axolotl limbs responded positively in both maintenance and restimulation DRG-grafting protocols. These results suggest that the efficacy of DRG stimulation of regeneration in adult newts was related to the relative number of blastema cells present at the time of denervation and the proliferative status of the blastema cells; bioassays with denervated adult newt limbs should be designed with these constraints in mind. Because such constraints are not as problematic with the larval axolotl, this species may provide the best opportunity for further defining bioassay parameters related to the neurotrophic stimulation of regeneration.

A test of the punctuated-cycling hypothesis in Ambystoma forelimb regenerates: the roles of animal size, limb innervation, and the aneurogenic condition.

The punctuated-cycling (PC) hypothesis [39] predicts that the proportion of actively cycling (AC) cells within the blastema influences the rate of limb regeneration in urodele amphibians. To test this, we compared the rate of regeneration and the parameters of the PC hypothesis in small and large Ambystoma mexicanum larvae and in aneurogenic limbs of Ambystoma maculatum. Aneurogenic limbs regenerated more slowly than limbs of small axolotls, but considerably faster than limbs of large axolotls. Regardless of regeneration rates, virtually all blastema cells were in the proliferative fraction (Pf) (ranging from 92.3% +/- 4.2% to 96.2% +/- 3.4%). As predicted, in the blastemata of more rapidly regenerating small axolotls, 86% of the proliferative fraction was actively cycling, but as regeneration slowed, the proportion of the proliferative fraction that was actively cycling decreased (the AC of aneurogenic limbs being 69.5%, and that of large axolotl limbs being 57.3%) and the proportion of transiently quiescent cells increased. The parameters of the PC hypothesis were also examined in small axolotls at two different times during regeneration. During dedifferentiation and initial blastema formation, 61% of the cells in the proliferative fraction were actively cycling and 34% were transiently quiescent. During the rapid-growth phase of the blastema, 88% of the cells in the proliferative fraction were actively cycling and only 7% of the cells were transiently quiescent. It therefore appears that dedifferentiated cells do not immediately begin active cycling and that the transiently quiescent population is relatively large; however, during the period of rapid growth the proportion of transiently quiescent cells is small. In amputated/denervated limbs of small axolotls, the size of the proliferative fraction decreased as the length of the denervation interval increased. Furthermore, with prolonged denervation the total proportion of actively cycling blastema cells also declined (to about 15%). The failure of denervated limbs to regenerate was correlated with an increased nonproliferative fraction and a reduced proportion of actively cycling cells.

Pattern-deficient forelimb regeneration in adult bullfrogs.

This study was designed to test the ability of adult bullfrogs (Rana catesbeiana) to regenerate forelimbs, both with and without various experimental treatments. Distal humerus-level forelimb amputations provided with additional deviated (sciatic) nerve and/or repeated soft-tissue injury exhibited considerable outgrowth. However, control sham-operated forelimbs also produced regenerates with comparable frequency, size, and morphological complexity. The lengths of the regenerates ranged from 0.4 to 2.6 cm, representing an outgrowth of 10-65% of the portion removed by the distal humerus amputation plane; some regenerates exhibited an external morphology indicative of digitlike structures. Some outgrowths were flexible but only one was capable of independent movement. Victoria Blue staining of whole regenerates revealed a variety of internal cartilage elements. Staining showed a single solid mass of cartilage in some regenerates while others had several individual and variably shaped cartilages projecting distally. Histological analysis also revealed the presence of connective tissue, striated muscle, and abundant nerve fibers in addition to the individual cartilage elements. We have tentatively termed these responses pattern-deficient regeneration.

In vitro effects of insulin on macromolecular events in newt limb regeneration blastemata.

This work provides data demonstrating a stimulatory effect of insulin on macromolecular events occurring in cultured regeneration blastemata and demonstrates a synergistic interdependence between nerves and insulin in newt limb regeneration. The current experiments provide evidence for the following: (1) Insulin is paramount for expression of the mitogenic effect of nerves on cultures blastemata. (2) Insulin stimulates the incorporation of (3H)uridine into the acid-insoluble fraction of blastemal homogenates, but it does not alter the turnover rate of incorporated labeled uridine. (3) Insulin also stimulates the incorporation of 35SO4 and (3H)leucine into both chondroitinase-sensitive and chondroitinase-resistant blastemal proteoglycans. (4) Insulin increases the uptake of radiolabeled precursors by the blastemata, namely, (3H)leucine, (3H)uridine, 35SO4, (3H)alpha-aminoisobutyrate, and (3H)2-deoxy-D-glucose. The importance of insulin in the regulation of newt limb regeneration is discussed.

Studies of mitosis in excised limb regenerates of the newt, Notophthalmus viridescens.

Subsequent to excision and explantation of the limb blastema into culture medium, there is an abrupt reduction in mitotic index lasting several hours. Coincident with the disappearance of mitosis, abnormal mitotic figures (AMFs), lacking the condensed chromosomal nature of normal figures, are seen. These persist until normal levels of mitotic activity are restored approximately 6 hr later. The transient loss of mitotic activity is observed in both ganglionated and nonganglionated explants. The large number of prophase figures observed at time zero were sharply reduced within minutes, without concomitant increases in the later phases. The possibility that some cells, without completing mitosis, become temporarily indistinguishable as mitotic figures, is discussed in terms of chromosomal decondensation and recondensation.

Promotion of mitosis in cultured newt limb regenerates by a diffusible nerve factor.

Regeneration blastemata of adult newt forelimbs were cultured transfilter to dorsal root ganglia on extremely low porosity (0.05 mu m) filters. Mitotic index profiles in these blastemata were compared with those obtained using filters of greater porosity (0.45 mu m). In the above experiments nerves and blastema tissue were separated by 5 or 25 mu m, i.e., the thickness of the respective filters. The results show that the transfilter mitogenic effect of the nerves was retained when the lower pore size filters were used. In addition, sensory ganglia grown at the bottom of a culture well, separated from the blastema explants by a distance of approximately 2 mm, were nevertheless able to promote blastema cell proliferation. The ganglia can thus be considered to be providing a "sustained conditioning" of the medium with neuromitogenic factor(s). This study also shows that nerves can promote blastema cell mitosis, although cell-to-cell contact between nerves and responding cells was precluded.