Effects on adult newt limb regeneration of partial and complete skin flaps over the amputation surface

Expression of Mmp-9 and related matrix metalloproteinase genes during axolotl limb regeneration

One of the earliest events in limb regeneration is the extensive remodeling of the extracellular matrix (ECM). Matrix metalloproteinases (MMPs) are a family of matrix degrading enzymes that have been identified in both normal and disease states. Using RT-PCR and cDNA library screening, we have isolated sequences homologous to four different Mmp genes. The spatial and temporal expression of one of these, Mmp-9, has been analyzed during axolotl limb regeneration. Northern blot analysis identifies a 3.8 kb transcript that is abundantly expressed during regeneration, and whole-mount in situ hybridization has uncovered an unusual bi-phasic expression pattern. The first phase begins at 2 hours after amputation, and expression is confined to the healed wound epithelium. This phase continues for 2 days, showing peak expression at 14 hours after amputation. This early phase may be needed to retard reformation of the basal lamina of the epidermis, and thereby facilitate the epidermal-mesenchymal interactions required for successful regeneration. The second phase begins a few days later when a small blastema has formed. During this phase, expression is in the mesenchyme, localized to cells around the tips of the cut skeletal elements. This expression is maintained through several stages until redifferentiation begins. The timing and position of the second phase of expression is consistent with a role for Mmp-9 in the removal of damaged cartilage matrix. We have also discovered that the time of onset of Mmp-9 expression is sensitive to denervation, which causes a delay of several hours. Finally, retinoids, known for their dramatic effects on the pattern of regenerating limbs, can cause a down regulation of Mmp-9 expression. Dev Dyn 1999;216:2-9.

Expression of Msx-2 during development, regeneration, and wound healing in axolotl limbs

Msx genes are transcription factors that are expressed during embryogenesis of developing appendages in regions of epithelial-mesenchymal interactions. Various lines of evidence indicate that these genes function to maintain embryonic tissues in an undifferentiated, proliferative state. We have identified the axolotl homolog of Msx-2, and investigated its expression during limb development, limb regeneration, and wound healing. As in limb buds of higher vertebrates, axolotl Msx-2 is expressed in the apical epidermis and mesenchyme; however, its expression domain is more extensive, reflecting the broader region of the apical epidermal cap in amphibians. Msx-2 expression is downregulated at late stages of limb development, but is reexpressed within one hour after limb amputation. Msx-2 is also reexpressed during wound healing, and may be essential in the early stages of initiation of the limb regeneration cascade.

Expression of type XII collagen by wound epithelial, mesenchymal, and ependymal cells during blastema formation in regenerating newt (Notophthalmus viridescens) tails

Previously we showed that type XII collagen (col XII) is highly upregulated in the regenerating newt (Notophthalmus viridescens) forelimb. Here, using immunohistochemistry and in situ hybridization, we studied the pattern of expression of col XII during early stages of adult newt tail regeneration. The results show that immunoreactivity of col XII is first seen as a thin layer beneath the wound epithelium (WE) at 3 days after amputation. Reactivity associated with the mesenchyme becomes obvious at day 4 and increases considerably between days 6 and 7 after amputation. In situ hybridization indicates that the early WE-associated reactivity and later mesenchymal reactivity are due to increased col XII gene expression by the WE and mesenchyme, respectively. At 7 days after tail amputation both wound epithelial and mesenchymal cells exhibit a strong riboprobe signal. Interestingly, a distinct riboprobe signal is also seen in the cells of the outgrowing ependymal tube at day 7 but little if any col XII immunoreactivity is present. The spatial pattern of col XII gene expression changes by day 14 after amputation in that transcription in mesenchyme is maintained at a high level, in the WE it is reduced, and in ependyma it ceases to be detectable. Local deprivation of the spinal cord significantly lowers the level of col XII message in the mesenchyme. Much of this decrease in transcription is due to minimal mesenchymal cell accumulation secondary to spinal cord ablation. The temporal and spatial patterns of expression of the col XII gene in the WE, mesenchyme, and ependyma during tail regeneration strongly suggest a role for col XII in regulating both spinal cord outgrowth and spinal cord-dependent tail regeneration.

Perspective: a suggested role for basement membrane structures during newt limb regeneration

BACKGROUND

Interactions between epithelium and mesenchyme, which occur across a basement membrane (BM) zone, are essential to generate a growth bud, or blastema, from which a new limb regenerates. An intact BM at that interface is believed to inhibit regeneration, but that mechanism of inhibition is not understood.

METHODS

Interference contrast microscopy and antibodies to laminin have been used to describe reformation of the BM and the basal lamina (BL) and their relationships to wound epithelium and mesenchyme in successive stages of blastema formation.

RESULTS

The BL is initially absent from the amputation surface and is reestablished to continuity by the late bud stage of regeneration. It forms generally from base to apex, precedes reticular lamina (RL) formation, and is absent beneath most of the wound epithelium. Our inability to correlate mesenchymal cell accumulation exclusively with the area lacking BL apically and postaxially prompted rethinking of the significance of the BL.

CONCLUSIONS

Consistent with these and other observations, we suggest that the BL, when it forms during blastema formation, appears to function as in other developing systems to stabilize the phenotype of adjacent cells. Thus, epithelium becomes epidermis and adjacent mesenchyme synthesizes RL and becomes dermis. Accordingly, the feature that distinguishes regenerating from nonregenerating appendages is the ability of regenerating appendages to delay BL closure until after a critical mass of mesenchymal cells has accumulated.

Stabilizing role of the basement membrane and dermal fibers during newt limb regeneration

BACKGROUND

Following amputation of a newt limb, tissues at the amputation site undergo histolysis to give rise to a growth bud, or blastema, but they also provide a base on which the regenerate is constructed. Studies suggest that dermal tissues may differentially resist histolysis.

METHODS AND RESULTS

To examine stability of tissues at the amputation site, more than 80 preblastemal staged regenerating limbs were examined histologically. Initially, all soft tissues not attached to bone retracted and were covered by migrating epithelium. The dermis was seen to be stable during the first week postamputation. Muscle dedifferentiated and was heavily stained with anti-tenascin antibodies, but the intact overlying dermis was unstained. Fiber bundles, revealed by staining with phosphotungstic acid hematoxylin, isolated the dermis from dedifferentiating deeper tissues during the first week postamputation, but partially broke down during the second week. However, the basement membrane (BM) remained as the distalmost intact structure at the amputation site in all limbs examined. The BM was the foundation for new BM synthesis which preceded dermis synthesis in the base of the blastema during the second week, even while undifferentiated cells were accumulating centrally.

CONCLUSIONS

We suggest that the dermis resists histolysis long enough for new BM to form in continuity with that of the stump. Dermis formation (dermogenesis) distal to the amputation plane begins early as in mammalian healing but is not completed until after blastema formation. Thus, factors that inhibit dermal closure appear to distinguish regenerating from non-regenerating appendages.

Examination of fibronectin distribution and its sources in the regenerating newt limb by immunocytochemistry and in situ hybridization

Using monoclonal antibodies (mAbs) reactive to newt limb regenerates, we hope to gain insight into the identity and function of regeneration significant molecules. mAb MT4 (matrix 4) identifies an extracellular matrix (ECM) protein that is strongly up-regulated first in the distal stump and then in the blastema during regeneration. Within the first 24 hr after amputation the MT4 antigen is localized to an acellular space beneath the wound epithelium, and first appears in the basal cells of the wound epithelium between days 5 and 7. At mid-bud blastema stages, the MT4 antigen is homogeneously distributed as thin fibers in the blastema ECM, and is later largely restricted to the distal tip of the blastema and the areas of cartilage condensation. After extraction and immunoblotting, the MT4 antigen was observed as three reduced species of M(r) 225, 250, and 260. Taken together, the immunoblot and immunocytochemistry results suggested that mAb MT4 recognized newt fibronectin (FN). Sequence from a cDNA (NvFN.10) obtained by screening a newt blastema cDNA expression library with mAb MT4 conclusively identified the MT4 antigen as FN. To further investigate the expression of FN in regeneration, cDNA NvFN.10 was used to construct a riboprobe and in situ hybridization was done. In the unamputated limb only a few scattered cells expressed the FN gene. Within the first 3 days after amputation strong hybridization signal was observed in the basal cells of the wound epithelium. Most of the stump cells that dedifferentiated and accumulated beneath the wound epithelium at 7 days expressed the FN gene, while the basal cells of the wound epithelium maintained their expression. At mid- and late-bud blastema stages the vast majority of the blastema cells were strongly expressing the FN gene, but the wound epithelial cells now showed only weak FN transcription. Thus initially FN comes from the plasma. Then FN is synthesized by both the wound epithelium and mesenchyme. Finally, at blastema stages FN is produced primarily by the mesenchyme. The expression pattern of FN throughout regeneration suggests that this glycoprotein has roles in wound epithelial and mesenchymal cell migration and mesenchymal cell proliferation and differentiation.

The wound epithelium of regenerating limbs of Pleurodeles waltl and Notophthalmus viridescens: studies with mAbs WE3 and WE4, phalloidin, and DNase 1

The wound epithelium of regenerating limbs of the American newt, Notophthalmus viridescens (Nv), up-regulates a number of antigens, including those recognized by mAbs WE3 and WE4. In the present study, we show that the WE3 antigen is up-regulated in a similar fashion in the wound epithelium of the European newt, Pleurodeles waltl (Pw). mAb WE3 and WE4 reactivities to secretory/transport body cell types, including integumentary glands, perineurium, endothelium, and conjunctiva, are also similar in these two species of newt. However, mAb WE4 reacts to both the epidermis and wound epithelium in Pw, whereas in Nv, mAb WE4 reacts only to the wound epithelium. Because the WE3 antigen is cytoskeleton-associated and Western blots reveal a 43 kDa species, we compared mAb WE3 reactivity with that of rhodamine-labeled phalloidin, a known actin-binding compound. Phalloidin did not react preferentially to the wound epithelium, conjunctiva, or other cell types strongly reactive to mAb WE3. Pretreatment of sections and tissue extracts with DNAse 1, a protein known to bind to actin, nearly abolished mAb WE3 reactivity in tissue sections and both WE3 and WE4 reactivity in ELISA assays, respectively. The results lead to the hypothesis that the WE3 and WE4 antigens are actin-binding proteins unique to the wound epithelium and other secretory/transport cell types.

Monoclonal antibody ST1 identifies an antigen that is abundant in the axolotl and newt limb stump but is absent from the undifferentiated regenerate

Monoclonal antibodies (mAb) utilized in regeneration studies to date identify antigens that are up-regulated in the blastema. We obtained a monoclonal antibody, designated ST1 (Stump 1), that is reactive to an extracellular matrix (ECM) antigen exhibiting the opposite distribution; ST1 is an abundant antigen of the limb stump soft tissues but is absent from within the blastema. The border between abundance and absence of mAb ST1 reactivity was sharp and extended as a concavity into the stump. This distinct dichotomy led to further studies relevant to understanding how this extracellular matrix antigen is modulated during regeneration. mAb ST1 reactivity decreased in the internal tissues at the distal end of the limb prior to blastema formation and remained absent until the onset of differentiation. The initial decrease in mAb ST1 reactivity was dependent on the combined effects of injury and the wound epithelium but was nerve independent. At blastema stages of regeneration, the distribution of tenascin, ascertained by mAb MT1 reactivity, closely matched the area without reactivity to mAb ST1. The spatial and temporal distribution of the ST1 antigen in unamputated limbs and during regeneration did not correspond to any previously described ECM component.

The mutant axolotl Short toes exhibits impaired limb regeneration and abnormal basement membrane formation

The mutant axolotl Short toes develops with abnormal kidneys, Mullerian ducts, and limbs and provides one of the few experimental systems for developmental studies in amphibia. The present paper describes another deviation from this animal's normal physiology, which is very characteristic of the wild type: amputated limbs of Short toes fail to regenerate. A blastema is formed but differentiation does not occur. Detailed histological analysis provides evidence of abnormal formation of the basement membrane and accumulation of extracellular matrix within the blastema, which could be attributed to an imbalance of extracellular matrix and basement membrane proteins. The basement membrane develops much thicker and is convoluted in the arrested blastema of mutant animals. In contrast to the limbs, the tails of Short toes regenerated normally with no apparent abnormalities. No gross genomic aberrations have been detected between normal and mutant DNA, indicating that a large deletion or insertion is not likely to be the cause of this mutation.

Acidic fibroblast growth factor is present in regenerating limb blastemas of axolotls and binds specifically to blastema tissues

The growth of regenerating limbs of amphibians depends upon proliferation of the blastema cells that accumulate beneath the epidermal cap. The epidermal cap is known to be mitogenic for the blastema cells. We have extracted a mitogenic activity from both the mesenchymal and epidermal (epidermal cap) components of cone stage blastemas which is retained on heparin-Sepharose and elutes with 1.15 M NaCl. This fraction stimulates neurite outgrowth of PC12 cells and [3H]thymidine incorporation into CCL 39 cells and is potentiated by heparin. The 2 M fraction was inactive. The heparin-Sepharose-purified growth factor cross-reacts with bovine acidic FGF polyclonal antibodies and shows a Mr of 16,000 on Western blots. Blastema membranes contain specific high affinity binding sites (Kd = 25 pM; capacity = 30 fmole/mg protein) and low affinity binding sites (Kd = 18 nM; capacity = 30 pmole/mg protein) for aFGF as revealed by Scatchard analysis. 125I-aFGF which is bound specifically by both the epidermal cap and mesenchyme of blastema frozen sections is displaced by an excess of unlabeled factor and inhibited by heparin. Heparinase treatment and 2 M NaCl washing which decreased the binding was fourfold more efficient for epidermal cap than for mesenchyme suggesting the presence of high affinity receptors in the latter tissue. The presence of aFGF (or a closely related molecule) in blastemas is consistent with our earlier results that showed stimulation of proliferation of cultured blastema cells by acidic or basic FGF or heparin alone. These results suggest the possibility that aFGF is stored in the epidermal cap during limb regeneration and that it stimulates the proliferation of the underlaying mesenchyme.

Expression of the 9G1 antigen in the apical cap of axolotl regenerates requires nerves and mesenchyme

Monoclonal antibody 9G1 (mAb 9G1) is reactive to the wound epithelium of axolotl larvae and therefore provided the opportunity to examine the interaction between the wound epithelium, nerves, and blastemal mesenchyme during axolotl limb regeneration. In unamputated limbs, mAb 9G1 is reactive to most or all cells of the dermis, skeletal elements, blood vessels, and nerves, to a few unidentified cells in muscle, and to none in epidermis. During regeneration of axolotl limbs, mAb 9G1 reacts strongly to an intracellular antigen of the blastemal mesenchyme and of the distal-most portion of the wound epithelium, the so-called apical epithelial cap (AEC). Because this thickened wound epithelium of regenerating amphibian limbs has been suggested as functioning in a manner similar to the apical ectodermal ridge (AER) of embryonic limb buds, it was of interest to further examine the reactivity of mAb 9G1 during various stages of regeneration. Whether mAb 9G1 reactivity in the AEC depended on mesenchyme and/or nerves was also tested. Monoclonal antibody 9G1 reactivity appears in the AEC of regenerating limbs prior to outgrowth of the blastema and persists throughout blastemal stages. Apical epithelial cap reactivity to mAb 9G1 is nerve dependent during early stages of blastema development and becomes nerve-independent at later stages. When epithelium-free blastemal mesenchyme is grafted onto injured flank musculature, ectopic limb regeneration occurs and the AEC derived from flank epidermis exhibits mAb 9G1 reactivity. These results show that a mAb 9G1 reactive AEC is characteristic of regenerating limbs and that expression of the 9G1 antigen by the AEC is dependent upon underlying blastemal mesenchyme and nerves.

In vitro control of blastema cell proliferation by extracts from epidermal cap and mesenchyme of regenerating limbs of axolotls

The presence of a mitogenic activity in limb blastemas of axolotls was detected in crude extracts of blastemas at the mid-bud stage. The mitogenicity of the extracts was estimated from the mitotic index of blastema cells grown for 6 days in the presence of limb blastema extracts, with colchicine present for the last 2 days. All the extracts tested (whole blastema, blastemal mesenchyme, epidermal cap) significantly enhanced proliferation of blastema cells. The highest stimulation factors we observed were 7 × with 7 μg protein/ml whole blastema extracts, 5.2 × with 14 μg/ml blastemal mesenchyme extracts, and 11 x with 3.5 μg/ml epidermal cap extracts. Hence the epidermal cap extracts appeared to be the most mitogenic. Extracts from the blastemal mesenchyme, although less mitogenic than the epidermal cap extracts, were more potent than nerve extracts [Albert P, Boilly B (1986) Biol Cell 58:251-262]. These results are discussed with regard to the production of growth factors during limb regeneration.

The role of cells versus matrix in bone induction

Earlier observations indicated that epithelial cells of urinary bladder, and transformed epithelial cells from human amnion (FL), epidermal carcinoma (HeLa), etc. can induce ectopic endochondral bone formation when implanted into the skeletal muscle of immunosuppressed or autologous animals. Such epithelial cells are associated with little matrix. Bone-inducing activity was also demonstrated in cultured osteosarcoma cells of murine and human origin or extracts thereof, and it is notable that these bone-inducing osteosarcoma cells grow in vitro with little matrix production. Finally, electron microscopy of in vitro cartilage induction showed that decalcified rodent bone that had been extensively extracted to remove cells still contained devitalized cells and cell fragments some of which made contact with inducible, cartilage-forming mesenchymal cells that had migrated in from cocultured muscle. Suggestions: These observations suggest that: 1) the bone-inducing agent(s) of both epithelial and mesenchymal cells may reside mostly in cells rather than matrix. Thus it may be premature to assume that bone "matrix" is the major source of bone-inducing agent in decalcified bone until the osteoinductive activity of residual bone cells has been assessed; and 2) that the osteoinductive agent, whether residing in epithelial cells or bone cells, may be the same or a similar factor operating through the same mechanism.

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.

Appearance and regulation of an antigen associated with limb regeneration in Notophthalmus viridescens

Previous reports from this laboratory have documented a cellular antigen, 22/18, associated with regeneration of forelimbs in the newt Notophthalmus viridescens (Kintner and Brockes: Nature 308:67-69, 1984; Journal of Embryology and Experimental Morphology 89:37-55, 1985; Brockes: Science 225:1280-1287, 1984; Kintner et al.: Molecular Basis of Neural Development, 1985). The antigen is expressed at various stages of regeneration in several types of cells including Schwann cells and muscle cells. We report here that, in addition to the previous results, the expression of 22/18 occurs very early in the regeneration process and is initially confined to an apparently nonmuscle, non-neural population of cells. The well-defined context of the antigen's first appearance has allowed us to investigate the regulation of its expression. In particular, injury is sufficient to elicit the appearance of 22/18. It can appear prior to mitosis and despite denervation. In circumstances where regeneration is inhibited, expression of 22/18 can persist.

The role of cartilage and fibronectin during respecification of pattern induced in the regenerating amphibian limb by retinoic acid

When retinoic acid (RA) is applied to the regenerating limb the positional information of blastemal cells is respecified and extra limb segments develop. We are trying to elucidate the molecular basis of the action of RA and report here experiments focused on the role that fibronectin (FN) might play in the process. The FN distribution in stump tissues, regeneration blastemas and RA-treated blastemas was investigated by immunocytochemistry. Two effects of RA were observed. Firstly, excessive dedifferentiation of the severed cartilage at the amputation plane, resulting in lumps of FN-positive matrix being released into the blastema; secondly, blastemal cells tend to aggregate together into FN-positive accumulations. Excessive dedifferentiation of the cartilage plays no role in the RA-induced respecification of pattern, because we show that extra segments are still produced in RA-treated limbs from which all the cartilage has been removed. The effect on blastemal cell FN distribution was investigated in several ways. Axolotl plasma FN and cellular FN were characterised on immunoblots, and no obvious change was observed after RA treatment; neither were there changes in amounts of FN detected by ELISA. Levels of FN synthesis were measured by [35S]-methionine labelling and again no change observed after RA treatment. We conclude that the change in FN distribution observed by immunocytochemistry after RA treatment may be due to the retention of FN on the surface of the blastemal cells rather than to any effect on the levels of synthesis of this molecule.

Regenerate epithelium and skin glands of the adult newt react to the same monoclonal antibody

A search for specific proteins involved in newt limb regeneration, using monoclonal antibodies against forelimb blastemas, led to the detection of an antigen in the regenerate epithelium. Fluorescent-antibody-labeled cells first appeared just prior to blastema outgrowth. From bud through early digit stages this antibody reacted with nearly all of the regenerate epithelial cells. Other tissues also reacted, including nerve, blood vessels, and gastrointestinal tract. The behavior of the reactive cells in the regenerate epithelium, and their close association with immediately adjacent skin glands, raises several new possibilities for the origin of the regenerate epithelium.

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.

Are limb development and limb regeneration both initiated by an integumentary wounding? A hypothesis

It is proposed that, whereas an actual wound to a salamander limb may initiate limb regeneration, a local and developmentally programmed integumentary wound may initiate limb development. The electrophysiological changes induced by these lesions of the skin may be a common denominator linking limb regeneration and limb development. Such early electrical events are considered to initiate or guide the early accumulation of cells, and to help to produce the local environment in which a limb will arise. This scheme provides a self-limiting positive-feedback mechanism for the production of a localized area where other developmental mechanisms act in concert with endogenous electrical fields (or in their complete absence), thereby leading to limb differentiation. This hypothesis may not be restricted to limb formation; it may be of more general significance, i.e. in the process of organogenesis in embryos. One might reasonably suggest that, by such a mechanism, any developing placode (for example, auditory or olfactory placodes) might form and localize.

Injury, nerve, and wound epidermis related electrophoretic and fluorographic protein patterns in forelimbs of adult newts

Polyacrylamide slab gel electrophoresis and [35S]methionine fluorography were used to examine proteins in regenerating newt limbs, amputated denervated limbs, unamputated denervated limbs, and separated blastema mesodermal core and wound epidermis. A total of 27 protein electrophoretic bands were obtained from amputated limbs and 24 bands from unamputated limbs. Amputation resulted in the appearance of 4 new bands and the loss of 1 band as compared to unamputated limbs. These 5 banding differences were apparent on stained gels 3 days postamputation and were maintained through 10 weeks postamputation (complete regenerate stage). Only one band in unamputated limbs was always detectable on fluorographs, whereas virtually all of the stainable bands of amputated limbs were visible on fluorographs. Amputation clearly stimulated a marked, generalized increase in the synthesis of limb proteins. The 5 amputation induced changes were equally evident in stained gels of both innervated and denervated limbs. Amputated denervated limbs possessed a full set of fluorographic bands (including the 5 differences) through 18 days postamputation. However, denervation without amputation was not sufficient to alter the stainable banding pattern. Wound epidermis and mesodermal core both displayed the 5 banding differences and had identical banding patterns with the exception of one epidermal specific band. This band was also present in whole limb skin but was absent in unamputated mesodermal limb tissue. This was the only band of unamputated limbs that was consistently detectable by fluorography. It is concluded that amputation induces nerve independent changes in protein synthesis that are common to both mesodermal core and wound epidermis. These changes may represent preparation for cellular proliferation.

Injury to nerves and the initiation of amphibian limb regeneration

The possibility has been investigated that nerves, which promote mitotic activity during the growth phase of limb regeneration, may also release factors upon injury to stimulate the cellular events during the initiation of regeneration. These events have been compared in control, innervated limb stumps and in limbs denervated for various periods before amputation. Wound closure occurred in an essentially normal manner in limbs denervated at the time of amputation but frequently occurred at reduced rates or not at all in limb stumps denervated 5 days before amputation. Tissue loss and various degrees of morphological regression were seen in many of the predenervated limb stumps, including all of those denervated for 6 days or more before amputation. Evidence is presented which suggests that regression may result from a combination of the denervated state and disturbance to the limb's vascular system. Limbs predenervated 2-10 days before amputation were fixed 7 days after amputation and examined histologically. All limb stumps, including those involved in regression, showed tissue dissociation and cellular dedifferentiation. Autoradiography revealed that the dedifferentiation involved DNA synthesis in both denervated and innervated limbs. Seven days after amputation, DNA-labeling indices in limb stumps predenervated 2 or 4 days were similar to those of control limbs, but labeling indices were significantly reduced in limbs predenervated 6 or more days. The results are assessed in light of the state of nerve degeneration in the limbs at the time of amputation and are discussed in terms of what is known regarding nerve-derived growth-promoting substances.

Cell cycle and histological effects of reinnervation in denervated forelimb stumps of larval Ambystoma

Although nerves are a requirement for regeneration of a salamander limb, denervation of an amputated larval Ambystoma forelimb does not permanently prevent the limb from regenerating. When nerves grow back into the distal stump in sufficient numbers, regeneration occurs. In this study we examined histological and cell cycle events in denervated limb stumps of Ambystoma as they became reinnervated and began to regenerate. Prior to reinnervation and regeneration, dedifferentiated cells are present in the distal stump but are rarely synthesizing DNA or undergoing mitosis and are densely packed. About 2 days after the distal tip of the stump becomes reinnervated, the limb tip appears to "expand" as cells become less densely packed, and cell cycle activity begins. Mitotic index (MI) and labeling index (LI) increase slowly compared to MI and LI in control amputated limbs. Evidence for the localization of cycling activity is presented. In reinnervated stumps, the increase in LI precedes the increase in MI, suggesting that most of the cells are initiating cycling from the G1 phase.

Higher vertebrates do not regenerate digits and legs because the wound epidermis is not functional. A hypothesis

The necessity of injury, nerves, and wound epidermis for urodele limb regeneration is well accepted. Whether one or more of these three factors is limiting in amputated nonregenerating limbs of other vertebrates is a problem area in need of resolution. One view, that higher vertebrates possess inadequate innervation for limb regeneration to occur, is not strongly supported by experimental results. Superinnervation of lizard and mammalian limbs fails to elicit limb regeneration. Furthermore, in the well-known cases of mammalian regeneration, deer antlers and rabbit ears, a nerve requirement has not been demonstrated. In urodeles, the wound epidermis has recently been shown to have the role of maintaining dedifferentiated cells of the amputated limb stump in the cell cycle. The result of this wound epidermal stimulus is a sufficient number of cell divisions such that blastema formation occurs. We postulate that in amputated limbs of higher vertebrates, the wound epidermis is nonfunctional. Dedifferentiated or undifferentiated cells are not maintained in the cell cycle and blastema formation therefore does not occur. Instead, tissue regeneration occurs precociously due to lack of a cycling stimulus. The scar tissue which forms at the limb tips of nonregenerating vertebrates is the result of a nonfunctional wound epidermis.

Mice regrow the tips of their foretoes

Mice will replace the tip of a foretoe when it is amputated distal to the last interphalangeal joint. Amputation of the digit more proximal to the joint does not result in regrowth of the foretoe. Though this growth shares certain similarities with the epimorphic regeneration of amphibian limbs, the two processes are not the same. The regrowth reported here in mice is probably similar to the scattered clinical reports of fingertips regeneration in children, and presents a model system with which to explore the controls of wound healing and tissue reconstruction in mammals.

Cellular proliferation in the skin of X-rayed newt limbs (with a note on x-ray-induced limb regression)

Left hind limbs, including the pelvis, of adult newts (Notophthalmus viridescens) were locally irradiated with a dose of x-rays that inhibited regeneration (2,000 R). This x-ray dose and other doses (700-2,000 R) capable of inhibiting limb regeneration also cause limb regression prior to amputation. Before limb regression occurred, there was a latent period of 3 to 6 weeks. Limb regression was characterized by necrotic wasting and resorption of distal elements. The degree of loss was variable and dependent upon dosage. After this further degenerative changes were not noted. Proliferation of epidermal cells was examined 4 days after irradiation prior to limb regression or after x-ray-induced degeneration of the limbs had ended. Proliferative activity in x-rayed limbs was also compared at various stages of contralateral control limb regeneration. Limbs examined after x-ray-induced limb regression had ended showed levels of [3H]-thymidine incorporation into DNA comparable to normal epidermis. In contrast, limbs examined 4 days after irradiation had lower levels of DNA synthesis (P much less than 0.01). Amputation of limbs in both groups caused an increase in DNA synthesis (P much less than 0.01). Histological examination showed that cellular proliferation was associated primarily with the epidermis. These results indicate that epidermal cell proliferation was not resistant to x-rays. However, levels of normal cell division were observed after amputation of after cessation of x-ray-induced limb regression.

Newt forelimb regeneration blastemas in vitro: cellular response to explanation and effects of various growth-promoting substances

Macromolecular synthesis was studied in cultured newt forelimb blastemas. Late bud stage blastemas were explanted into organ culture and thus denervated. When the response of the blastemas to explantation was examined, it was found that a peak in 3H-leucine incorporation occurred at 2 hr of incubation, and a similar peak in 3H-thymidine incorporation occurred at 3-4 hr. After these initial increases, both parameters declined to levels lower than those determined at the time of explantation. The peaks in macromolecular synthesis reported here in vitro are similar to those observed in blastemas in vivo after denervation (Singer, '74). In the second part of the study, the ability of various growth-promoting substances to stimulate DNA synthesis in cultured blastemas was investigated. Increasing concentrations of fetal bovine serum caused increased levels of 3H-thymidine incorporation, with maximal stimulation at 30% serum. Newt brain extract (NBVE) was as effective as additional serum, with optimal stimulation at 100 micrograms total NBE protein per ml culture medium. Fibroblast growth factor (FGF), derived from brain tissue, at a concentration of 10 ng/ml was as effective as both 30% serum and the optimal concentration of NBE. Epidermal growth factor (EGF) produced a maximal effect at 1 ng/ml. Neither nerve growth factor nor the platelet-derived growth factor were stimulatory. Bovine insulin was highly active in stimulating DNA synthesis at concentrations from 1-10 micrograms/ml. The requirement of nerves for blastemal development, as well as the possible roles of the various growth-promoting substances in this process, are discussed.

Morphogenetic effect of rotated skin cuffs on tail regeneration in Plethodon cinereus

As an epimorphic system, the urodele tail has much in common with the urodele limb, relative to tissue components. In an effort to elucidate potentially similar functions of the skin during regeneration, two procedures which have been shown to be highly disruptive of limb morphogenesis were performed on the tail. In the first, cuffs of tail skin were rotated 180 degrees about the long axis of tails in Plethodon cinereus. Subsequent amputation through the rotated cuffs produced regenerates at a normal rate which were also normal in both internal architecture and skin gland distribution. In a second series, cuffs of tail skin were rotated 90 degrees about the dorso-ventral axis of the tail, such that the dorsal red stripe encircled the tail. Upon amputation through the middle of the cuff, the stump skin presented an exclusively dorsal surface which, nevertheless, had no effect upon the morphogenetic success of the regenerate. These data therefore indicate that a tissue, such as skin, may be inconsistent in its morphogenetic influence among epimorphic fields within the same organism. It is not clear whether these results reflect differences in field behavior or in absolute tissue potential determined by the field of origin. A tissue hierarchy of morphogenetic influence within and among epimorphic fields is suggested as a preliminary framework within which to coordinate such information.

Responses of denervated adult newt limb stumps to reinnervation and reinjury

It is well known that denervated adults newt limbs do not regenerate. Not understood is why denervated newt limb stumps fail to initiate regeneration upon reinnervation. In an effort to define the regeneration limiting factors, we examined the histology of long-term denervated newt limb stumps and tested the effects of various kinds of reinjury. In 5-week denervated limb stumps there were present dedifferentiated cells, differentiated cartilage, and densely packed layered cells. The epidermis covering the limb tip resembled skin epidermis rather than wound epidermis. The kinds of reinjury that were successful in restoring the regeneration capabilities to 5-week denervated limb stumps included; reamputation (100%), a single razor incision (60%), and removal of the healed tissues from the distal limb tip (70%). The results of the study emphasize the importance of both injury and wound epidermis in initiating regeneration.

DNA synthesis and mitosis in adult newt limbs following amputation and insertion into the body cavity

Experiments were designed to investigate the roles of injury, nerves, and wound epidermis in regeneration. By immediate insertion of amputated limbs into the body cavity, the wound epidermis was prevented from forming. Through 3 weeks post amputation, these inserted limbs showed lower 3H-thymidine labeling indices and mitotic indices than control normally regenerating limbs. No blastema formed and regeneration did not occur. When denervation preceded insertion, some labeling with 3H-thymidine was seen but essentially no mitoses were observed. When insertion of innervated limbs was delayed for 48 hr to allow the wound epidermis to form, regeneration occurred in a normal fashion. These results emphasize the importance of injury, nerves, and wound epidermis in controlling cell cycle events during regeneration.

Reduction of sodium dependent stump currents disturbs urodele limb regeneration

We have asked the question whether the natural electric currents which leave urodele limb stumps are in any way needed for their regeneration. As an initial test, we have greatly reduced such currents in the tiger salamander, Ambystoma tigrinum, by applying 0.5 mM amiloride to the stump skin or by immersion of the animals in sodium depleted media. We have also reduced such currents in the red spotted newt, Notophthalmus viridescens, by such immersion. Limb regeneration in half of the amiloride-treated animals was either entirely blocked or grossly deficient, while the others regenerated normally. Limb regeneration in sodium depleted media was consistently inhibited for some weeks but then recovered. These results are consistent with the hypothesis that stump currents are in some way needed for normal regeneration.

Regenerative responses in larval axolotl limbs with skin grafts over the amputation surface

Complete flaps of whole skin over the amputation surface of larval axolotl limbs did not prevent dedifferentiation, DNA synthesis, and mitosis. However, even by two weeks, insufficient cell division had occurred for blastema formation. In about 50% of the cases, small areas of wound epidermis formed over the amputated tip of the radius or ulna. At two weeks after amputation, mitotic figures and dedifferentiated cells which incorporated H3-thymidine were predominantly located in the vicinity of the small area of wound epidermis. Although delayed in relation to controls, these limbs regenerated. The results are consistent with the view that the wound epidermis is necessary to maintain dedifferentiated cells in the cell cycle.