Temporal distribution of 5BrdU-labelled cells suggests that most injured tissues contribute proliferating cells for the regeneration of the tail and limb in lizard

After tail and limb amputation in lizard, injection of 5BrdU for 6 days produces immunolabelled cells in most tissues of tail and limb stumps. After further 8 and 16 days, and 14 and 22 days of regeneration, numerous 5BrdU-labelled cells are detected in regenerating tail and limb, derived from most stump tissues. In tail blastema cone at 14 days, sparse-labelled cells remain in proximal dermis, muscles, cartilaginous tube and external layers of wound epidermis but are numerous in the blastema. In apical regions at 22 days of regeneration, labelled mesenchymal cells are sparse, while the apical wound epidermis contains numerous labelled cells in suprabasal and external layers, indicating cell accumulation from more proximal epidermis. Cell proliferation dilutes the label, and keratinocytes take 8 days to migrate into corneous layers. In healing limbs, labelled cells remain sparse from 14 to 22 days of regeneration in wound epidermis and repairing tissues and little labelling dilution occurs indicating low cell proliferation for local tissue repair but not distal growth. Labelled cells are present in epidermis, intermuscle and peri-nerve connectives, bone periosteum, cartilaginous callus and sparse fibroblasts, leading to the formation of a scarring outgrowth. Resident stem cells and dedifferentiation occur when stump tissues are damaged.     

Immunolocalization of a p53/p63‐like protein in the regenerating tail of the wall lizard (Podarcis muralis) suggests it is involved in the differentiation of the epidermis

During tail regeneration in lizards, the epidermis forms new scales comprising a hard beta‐layer and a softer alpha‐layer. Regenerated scales derive from a controlled folding process of the wound epidermis that gives rise to epidermal pegs where keratinocytes do not invade the dermis. Basal keratinocytes of pegs give rise to suprabasal cells that initially differentiate into a corneous wound epidermis and later in corneous layers of the regenerated scales. The immunodetection of a putative p53/63 protein in the regenerating tail of lizards shows that immunoreactivity is present in the nuclei of basal cells of the epidermis but becomes mainly cytoplasmic in suprabasal and in differentiating keratinocytes. Sparse labelled cells are present in the regenerating blastema, muscles, cartilage, ependyma and nerves of the growing tail. Ultrastructural observations on basal and suprabasal keratinocytes show that the labelling is mainly present in the euchromatin and nucleolus while labelling is more diffuse in the cytoplasm. These observations indicate that the nuclear protein in basal keratinocytes might control their proliferation avoiding an uncontrolled spreading into other tissues of the regenerating tail but that in suprabasal keratinocytes the protein moves from the nucleus to the cytoplasm, a process that might be associated to keratinocyte differentiation.     

Regeneration of adhesive tail pad scales in the New Zealand gecko (Hoplodactylus maculatus) (Reptilia;Squamata;Lacertilia) can serve as an experimental model to analyze setal formation in lizards generally

During the regeneration of the tail in the arboreal New Zealand gecko (Hoplodactylus maculatus) a new set of tail scales,modified into pads bearing setae 5-20 μm long,is also regenerated.Stages of the formation of these specialized scales from epidermal pegs that invaginate the dermis of the regenerating tail are described on the basis of light and electron microscopic images.Within the pegs a differentiating clear layer interfaces with the spinulae and setae of the Oberh(a)utchen according to a process similar to that described for the digital pads.A layer of clear cytoplasm surrounds the growing tiny setae and eventually comifies around them and their spatular ends,later leaving the new setae free-standing on the epidermal surface.The fresh adhesive pads help the gecko to maintain the prehensile function of its regenerated tail as together with the axial skeleton (made of a cylinder of elastic cartilage) the pads allow the regenerated tail to curl aroundtwigs and small branches just like the original tail.The regeneration of caudal adhesive pads represents an ideal system to study the cellular processes that determine setal formation under normal or experimental manipulation as the progressive phases of the formation of the setae can be sequentially analyzed.     

Immunohistochemical localization of a proto-cadherin fat tumour-suppressor homolog in the regenerating tail of lizard suggests a role in apical growth control

The present immunohistochemical and western blotting study evaluates the localization of a proto-cadherin which gene is overexpressed in the regenerating blastema of the lizard Podarcis muralis. Bioinformatic analysis suggests that the antibody recognizes FAT1/2 proteins. Western blot indicates a main band around 50 kDa, a likely fragment derived from the original membrane-bound large protein. Immunofluorescence shows main labelling in differentiating wound keratinocytes, lower in ependyma, mesenchyme and extracellular matrix of the blastema. The apical epidermal peg contains keratinocytes with labelled peripheral cytoplasm, as confirmed using ultrastructural immunogold that also reveals most labelling located along the cell surface of mesenchymal cells. Myoblasts and differentiating myotubes of regenerating muscles are less intensely labelled. The regenerating cartilaginous tube contains sparse labelled chondroblasts, especially in external and internal perichondria. In regenerating scales, differentiating beta-cells appear immunofluorescent mainly along the cell perimeter. In more differentiated muscle, cartilage and connective tissues of the new tail, the labelling lowers or disappears. The observations indicate that FAT1/2 proto-cadherins are present in the apical blastema where an intense remodelling takes place for the growth of the new tail but where also a tight control of cell division and migration is active and may regulate potential tumorigenic process.     

Comparative fine structure of the axial skeleton inside the regenerated tail of some lizard species and the tuatara (Sphenodon punctatus)

The regenerated tail of the New Zealand gecko Hoplodactylus maculatus is equipped with an elastic cartilaginous tube as skeletal axis. Other lizard species and Sphenodon punctatus possess variably developed hyaline cartilaginous tubes. Moreover, H. maculatus enhances the functional performance of its tail by long elastic fibres, which are arranged all around the central regenerated spinal cord. The different characteristics of the regenerated skeleton could be related to the different environments that the species studied occupy in nature.     

Microscopical observations on the regenerating tail in the tuatara Sphenodon punctatus indicate a tendency to scarring,but also influence from somatic growth

The process of tail regeneration in the tuatara (Sphenodon punctatus) is not entirely known. Similarity to and differences from lizard tail regenerations are indicated in the present histological and ultrastructural study. Regeneration is influenced by the animal's age and ambient temperature, but in comparison to that of lizards it is very slow and tends to produce outgrowths that do not reach the length of the original tail. Although microscopically similar to lizard blastemas, the mesenchyme rapidly gives rise to a dense connective tissue that contains few muscle bundles, nerves, and fat cells. The unsegmented cartilaginous tube forming the axial skeleton is not calcified after 5 months of regeneration, but calcification in the inner region of the cartilage, present after 10 months, increases thereafter. Amyelinic and myelinic peripheral nerves are seen within the regenerating tails of 2–3 mm in length and the spinal cord forms an ependymal tube inside a cartilaginous casing. Tissues of the original tail, like muscles, vertebrae and the adipose mass, are largely replaced by dense connective tissue that occupies most of the volume of the new tail at 5 and 10 months of regeneration. It is unknown whether the differentiation of the dense connective tissue is caused by the relatively low temperature that this species lives under or stems from a genetic predisposition toward scarring as with most other amniotes. Increases of muscle and adipose tissues seen in older regenerated tails derive from somatic growth of the new tail in the years following tail loss and not from a rapid regeneration process like that in lizards.     

Msx1‐2 immunolocalization in the regenerating tail of a lizard but not in the scarring limb suggests its involvement in the process of regeneration

The immunolocalization of the muscle segmental homoeobox protein Msx1‐2 of 27–34 kDa in the regenerating tail blastema of a lizard shows prevalent localization in the apical ependyma of the regenerating spinal cord and less intense labelling in the wound epidermis, in the apical epidermal peg (AEP), and in the regenerating segmental muscles. The AEP is a micro‐region of the regenerating epidermis located at the tail tip of the blastema, likely corresponding to the AEC of the amphibian blastema. No immunolabelling is present in the wound epidermis and scarring blastema of the limb at 18–21 days of regeneration, except for sparse repairing muscles. The presence of a proximal–distal gradient of Msx1‐2 protein, generated from the apical ependyma, is suggested by the intensity of immunolabelling. The AEP and the ependyma are believed to induce and maintain tail regeneration, and this study suggests that Msx1‐2 proteins are components of the signalling system that maintains active growth of the tail blastema. The lack of activation and production of Msx1‐2 protein in the limb are likely due to the intense inflammatory reaction following amputation. This study confirms that, like during regeneration in fishes and amphibians, also the blastema of lizards utilizes common signalling pathways for maintaining regeneration.     

Low‐cysteine alpha‐keratins and corneous beta‐proteins are initially formed in the regenerating tail epidermis of lizard

During tail regeneration in lizards, the stratified regenerating epidermis progressively gives rise to neogenic scales that form a new epidermal generation. Initially, a soft, un‐scaled, pliable, and extensible epidermis is formed that is progressively replaced by a resistant but non‐extensible scaled epidermis. This suggests that the initial corneous proteins are later replaced with harder corneous proteins. Using PCR and immunocytochemistry, the present study shows an upregulation in the synthesis of low‐cysteine type I and II alpha‐keratins and of corneous beta‐proteins with a medium cysteine content and a low content in glycine (formerly termed beta‐keratins) produced at the beginning of epidermal regeneration. Quantitative PCR indicates upregulation in the production of alpha‐keratin mRNAs, particularly of type I, between normal and the thicker regenerating epidermis. PCR‐data also indicate a higher upregulation for cysteine‐rich corneous beta‐proteins and a high but less intense upregulation of low glycine corneous protein mRNAs at the beginning of scale regeneration. Immunolabeling confirms the localization of these proteins, and in particular of beta‐proteins with a medium content in cysteine initially formed in the wound epidermis and later in the differentiating corneous layers of regenerating scales. It is concluded that the wound epidermis initially contains alpha‐keratins and corneous beta‐proteins with a lower cysteine content than more specialized beta‐proteins later formed in the mature scales. These initial corneous proteins are likely related to the pliability of the wound epidermis while more specialized alpha‐keratins and beta‐proteins richer in glycine and cysteine are synthesized later in the mature and inflexible scales. J. Morphol. 278:119–130, 2017. ©© 2016 Wiley Periodicals,Inc.     

Epidermal Growth Factor and EGF Receptors are mainly expressed in the wound epidermis and proliferating ependyma of the regenerating tail of lizards

The presence of EGF and its receptor during tail regeneration in lizard has been assessed by immunoblotting and immunofluorescence to test whether this growth factor may be involved in the process. Immunolabelled bands at 8 and 42–46 kDa for EGF are detected in the regenerating tail. A main band at 45–50 kDa and other weaker bands at lower or higher molecular weight for the EGF receptor are also present. The results indicate that degraded forms of the protein are present although the specific nature of the different bands could not be determined. Immunofluorescence indicates that EGF-labelled cells and EGF receptor are especially seen in the wound epidermis and in the cytoplasm of ependymal cells. Numerous basal keratinocytes of the wound epidermis and apical epidermal peg contain labelled nuclei for EGFR, suggesting that activated receptor stimulates intense cell proliferation of the wound epidermis. Blastema and labelled myoblasts are occasionally detected in early differentiating muscles, but almost no labelled chondroblasts are present in the differentiating cartilaginous tube. The study indicates that EGF and its receptor are mainly present in epithelial cells in a form that allows them to regulate proliferation during tail regeneration.     

Epidermal fine structure of the toe tips of Sphaerodactylus cinereus (Reptilia, Gekkonidae)

This paper deals with epidermal structures of the sphaerodactyline gecko Sphaerodactylus cinereus : adhesive pads, cutaneous sensilla and intraepidermal axon terminals.
The adhesive pad is restricted to a single terminal scale and bears approximately 6,000 setae. The setae are complex, hair-like structures which branch and sub-branch up to five times. The terminal ends are shaped like inverted cones. They provide the friction which enables the gecko to walk even on vertical glass-plates.
Cutaneous sensilla of supposed mechanoreceptive function are found in groups of three or four at the anterior free edge of all dorsal and distal scales of the digit. The sensillum consists of a circular platelet in an epidermal depression bordered by an annular furrow and two or three bristles in a central position.
Discoid axon terminals in the digital scales are located between relatively stiff structures: the corneous layers of the epidermis and a layer of tonofibrillar bundles. The axon terminals are hypothesized to be sensitive to the internal pressure depending on hyperextension of the toe.     

Differential mRNA and tissue expression of lymphangiogenic growth factors (VEGF-C and -D) and their receptor (VEGFR-3) during tail regeneration in a gecko

Lymphangiogenesis, the growth of new lymph vessels, has important roles in both normal and pathological lymphatic function. Despite recent advances, the precise molecular mechanisms behind the lymphangiogenic process remain unclear. The Australian marbled gecko, Christinus marmoratus, voluntarily drops its tail (autotomy) as a predator avoidance strategy. Following autotomy a new tail is regenerated including lymphatic drainage pathways. We examined the molecular control of lymphangiogenesis within the unique model of the regenerating gecko tail. Partial sequences were obtained of the gecko lymphangiogenic growth factors, vascular endothelial growth factor C (VEGF-C) and VEGF-D along with their receptor VEGFR-3. These were highly homologous to other vertebrates. Quantitative real-time polymerase chain reaction (PCR) demonstrated up-regulation of VEGF-C, VEGF-D and VEGFR-3 mRNA expression during the early and middle stages of tail regeneration (between 4 and 9 weeks following autotomy), in late regeneration (12 weeks) and during mid-regeneration (7 and 9 weeks), respectively. VEGF-C and VEGF-D immunostaining was observed lining some lymphatic-like and blood vessels in early–mid tail regeneration, indicating possible associations of the proteins with VEGFRs on endothelia. Keratinocytes and fibroblasts also showed positive staining of VEGF-C and VEGF-D in early–mid tail regeneration. Additionally, VEGF-C was localised in adipose tissue in all tail states examined. This work suggests that specific timings exist for the expression of the lymphangiogenic growth factors, VEGF-C and VEGF-D, and their receptor, VEGF-R3, throughout the regeneration of a functional lymphatic network. Along with localisation data, this suggests potential functions for the growth factors in lymphangiogenesis and angiogenesis throughout tail regeneration.     

The regenerated tail of juvenile leopard geckos (Gekkota: Eublepharidae: Eublepharis macularius) preferentially stores more fat than the original

The tail of many species of lizard is used as a site of fat storage, and caudal autotomy is a widespread phenomenon among lizards. This means that caudal fat stores are at risk of being lost if the tail is autotomized. For fat-tailed species, such as the leopard gecko, this may be particularly costly. Previous work has shown that tail regeneration in juveniles of this species is rapid and that it receives priority for energy allocation, even when dietary resources are markedly reduced. We found that the regenerated tails of juvenile leopard geckos are more massive than their original counterparts, regardless of dietary intake, and that they exhibit greater amounts of skeleton, inner fat, muscle and subcutaneous fat than original tails (as assessed through cross-sectional area measurements of positionally equivalent stations along the tail). Autotomy and regeneration result in changes in tail shape, mass and the pattern of tissue distribution within the tail. The regenerated tail exhibits enhanced fat storage capacity, even in the face of a diet that results in significant slowing of body growth. Body growth is thus sacrificed at the expense of rapid tail growth. Fat stores laid down rapidly in the regenerating tail may later be used to fuel body growth or reproductive investment. The regenerated tail thus seems to have adaptive roles of its own, and provides a potential vehicle for studying trade-offs that relate to life history strategy.     

Immunolocalization of large corneous beta‐proteins in the green anole lizard (Anolis carolinensis) suggests that they form filaments that associate to the smaller beta‐proteins in the beta‐layer of the epidermis

The distribution of large corneous beta‐proteins of 18–43 kDa (Ac37, 39, and 40) in the epidermis of the lizard Anolis carolinensis is unknown. This study analyses the localization of these beta‐proteins in different body scales during regeneration. Western blot analysis indicates most protein bands at 40–50 kDa suggesting they mix with alpha‐keratin of intermediate filament keratin proteins. Ac37 is present in mature alpha‐layers of most scales and in beta‐cells of the outer scale surface in some scales but is absent in the Oberhäutchen, in the setae and beta‐layer of adhesive pads and in mesos cells. In differentiating beta‐keratinocytes Ac37 is present over 3–4 nm thick filaments located around the amorphous beta‐packets and in alpha‐cells, but is scarce in precorneous and corneous layers of the claw. Ac37 forms long filaments and, therefore, resembles alpha‐keratins to which it probably associates. Ac39 is seen in the beta‐layer of tail and digital scales, in beta‐cells of regenerating scales but not in the Oberhäutchen (and adhesive setae) or in beta‐ and alpha‐layers of the other scales. Ac40 is present in the mature beta‐layer of most scales and dewlap, in differentiating beta‐cells of regenerating scales, but is absent in all the other epidermal layers. The large beta‐proteins are accumulated among forming beta‐packets of beta‐cells and are packed in the beta‐corneous material of mature beta‐layer. Together alpha‐keratins, large beta‐proteins form the denser areas of mature beta‐layer that may have a different consistence that the electron‐paler areas. J. Morphol. 276:1244–1257, 2015. © 2015 Wiley Periodicals, Inc.     

Immunolabelling for RhoV and actin in early regenerating tail of the lizard Podarcis muralis suggests involvement in epithelial and mesenchymal cell motility

Immunolabelling for RhoV and actin in early regenerating tail of the lizard Podarcis muralis suggests involvement in epithelial and mesenchymal cell motility. Acta Zoologica, Stockolm. Immunolabelling for RhoV and α‐smooth muscle actin, genes that are highly expressed in the regenerating tail of lizards, shows that a main protein band immunolabelled for RhoV is seen at 65–70 kDa and only a weak band at 22–24 kDa. This suggests that alteration occurred during extraction or is due to biochemical processing of the protein. RhoV immunolabelled cells are present in apical and proximal regenerating epidermis during scale neogenesis. The apical ependyma is labelled but labelling fades and disappears in medial‐proximal regions, near the original spinal cord. Differentiating muscles and cartilage show low labelling. Ultrastructural immunolocalization of RhoV in wound keratinocytes shows labelling in regions containing actin filaments that associate with tonofilaments and desmosomes while a low labelling is present in mesenchymal cells. Filamentous regions of the nucleus, nuclear membrane and the nucleolus are immune‐labelled for RhoV. Similar localization is seen for actin that is present along the perimeters of keratinocytes associated with tonofilaments, in elongations of mesenchymal cells, in muscle satellite cells, endothelial and pericytes of blood vessels. It is suggested that RhoV and actin are associated in the dynamic cytoskeleton needed for the movements of epidermal and mesenchymal cells and in endothelial cells forming new blood vessels.     

Blood vessel formation during tail regeneration in the leopard gecko (Eublepharis macularius): The blastema is not avascular

Unique among amniotes, many lizards are able to self‐detach (autotomize) their tail and then regenerate a replacement. Tail regeneration involves the formation of a blastema, an accumulation of proliferating cells at the site of autotomy. Over time, cells of the blastema give rise to most of the tissues in the replacement tail. In non‐amniotes capable of regenerating (such as urodeles and some teleost fish), the blastema is reported to be essentially avascular until tissue differentiation takes place. For tail regenerating lizards less is known. Here, we investigate neovascularization during tail regeneration in the leopard gecko (Eublepharis macularius ). We demonstrate that the gecko tail blastema is not an avascular structure. Beginning with the onset of regenerative outgrowth, structurally mature (mural cell supported) blood vessels are found within the blastema. Although the pattern of blood vessel distribution in the regenerate tail differs from that of the original, a hierarchical network is established, with vessels of varying luminal diameters and wall thicknesses. Using immunostaining, we determine that blastema outgrowth and tissue differentiation is characterized by a dynamic interplay between the pro‐angiogenic protein vascular endothelial growth factor (VEGF) and the anti‐angiogenic protein thrombospondin‐1 (TSP‐1). VEGF‐expression is initially widespread, but diminishes as tissues differentiate. In contrast, TSP‐1 expression is initially restricted but becomes more abundant as VEGF‐expression wanes. We predict that variation in the neovascular response observed between different regeneration‐competent species likely relates to the volume of the blastema. J. Morphol. 278:380–389, 2017. © 2017 Wiley Periodicals, Inc.     

Hindlimb suspension reduces muscle regeneration

Exposure of juvenile skeletal muscle to a weightless environment reduces growth and satellite cell mitotic activity. However, the effect of a weightless environment on the satellite cell population during muscle repair remains unknown. Muscle injury was induced in rat soleus muscles using the myotoxic snake venom, notexin. Rats were placed into hindlimb-suspended or weightbearing groups for 10 days following injury. Cellular proliferation during regeneration was evaluated using 5-bromo-2′-deoxyuridine (BrdU) immunohistochemistry and image analysis. Hindlimb suspension reduced (P<0.05) regenerated muscle mass, regenerated myofiber diameter, uninjured muscle mass, and uninjured myofiber diameter compared to weightbearing rats. Hindlimb suspension reduced (P<0.05) BrdU labeling in uninjured soleus muscles compared to weightbearing muscles. However, hindlimb suspension did not abolish muscle regeneration because myofibers formed in the injured soleus muscles of hindlimb-suspended rats, and BrdU labeling was equivalent (P>0.10) on myofiber segments isolated from the soleus muscles of hindlimb-suspended and weightbearing rats following injury. Thus, hindlimb suspension (weightlessness) does not suppress satellite cell mitotic activity in regenerating muscles before myofiber formation, but reduces growth of the newly formed myofibers. Accepted: 11 December 1997     

Immunolocalization of Wnts in the lizard blastema supports a key role of these signaling proteins for tail regeneration

A highly upregulated gene during tail regeneration in lizards is Wnt2b, a gene broadly expressed during development. The present study examines the distribution of Wnt proteins, most likely wnt2b, by western blotting and immunofluorescence in the blastema-cone of lizards using a specific antibody produced against a lizard Wnt2b protein. Immunopositive bands at 48–50 and 18 kDa are present in the regenerative blastema, the latter likely as a degradation product. Immunofluorescence is mainly observed in the wound epidermis, including in the Apical Epidermal Peg where the protein appears localized in intermediate and differentiating keratinocytes. Labeling is more intense along the perimeter of keratinocytes, possibly as a secretory product, and indicates that the high epidermal proliferation of the regenerating epidermis is sustained by Wnt proteins. The regenerating spinal cord forms an ependymal tube within the blastema and shows immunolabeling especially in the cytoplasm of ependymal cells contacting the central canal where some secretion might occur. Also, regenerating nerves and proximal spinal ganglia innervating the regenerating blastema contain this signaling protein. In contrast, the blastema mesenchyme, muscles and cartilage show weak immunolabeling that tends to disappear in tissues located in more proximal regions, close to the original tail. However, a distal to proximal gradient of Wnt proteins was not detected. The present study supports the hypothesis that Wnt proteins, in particular Wnt2b, are secreted by the apical epidermis covering the blastema and released into the mesenchyme where they stimulate cell multiplication.     

Tissue regeneration during lower jaw restoration in zebrafish shows some features of epimorphic regeneration

Zebrafish have the ability to regenerate skeletal structures, including the fin, skull roof, and jaw. Although fin regeneration proceeds by epimorphic regeneration, it remains unclear whether this process is involved in other skeletal regeneration in zebrafish. Initially in epimorphic regeneration, the wound epidermis covers the wound surface. Subsequently, the blastema, an undifferentiated mesenchymal mass, forms beneath the epidermis. In the present study, we re-examined the regeneration of the zebrafish lower jaw in detail, and investigated whether epimorphic regeneration is involved in this process. We performed amputation of the lower jaw at two different positions; the proximal level (presence of Meckel's cartilage) and the distal level (absence of Meckel's cartilage). In both manipulations, a blastema-like cellular mass was initially formed. Subsequently, cartilaginous aggregates were formed in this mass. In the proximal amputation, the cartilaginous aggregates were then fused with Meckel's cartilage and remained as a skeletal component of the regenerated jaw, whereas in the distal amputation, the cartilaginous aggregates disappeared as regeneration progressed. Two molecules that were observed during epimorphic regeneration, Laminin and msxb, were expressed in the regenerating lower jaw, although the domain of msxb expression was out of the main plain of the aggregate formation. Administration of an inhibitor of Wnt/β-catenin signaling, a pathway associated with epimorphic regeneration, showed few effects on lower jaw regeneration. Our finding suggests that skeletal regeneration of the lower jaw mainly progresses through tissue regeneration that is dependent on the position in the jaw, and epimorphic regeneration plays an adjunctive role in this regeneration.