Cell migration and differentiation during wound healing and regeneration in Microstomum lineare (Turbellaria)

Using transmission electron microscopy and serial sections with light-microscopic autoradiography, I have investigated the ultrastructure of wound healing, the distribution of cells preparing for proliferation, and the fates of cells labelled with exogenous tritiated thymidine ([³H]T) in Microstomum lineare undergoing wound healing and regeneration. Immediately after decapitation the open wound was reduced to a minimum by strong contraction of circular muscle fibers. The wound epidermis was cellular, consisting of thin parts of epidermal cells from the epidermis around the wound. These epidermal cells maintained close adhesive contact with one another through zonulae adherentes and septate junctions. No proliferating cells were found in the old epidermis. The only cells taking up [³H]T were mesenchymal and gastrodermal neoblasts which proliferated and migrated towards the surface. The final epidermis was formed by conjunction of the wound epidermis and newly differentiated epidermal cells. Regeneration in Microstomum, in contrast to that of planarians, occurs mainly by morphallaxis, without the formation of a regeneration blastema, but also through continuous cell proliferation, migration, and differentiation.     

Ultrastructural observations on gastrodermal regeneration in the planarian Dugesia japonica (Turbellaria)

The earliest detectable change during regeneration of the gastrodermis in Dugesia japonica was an aggregation of regenerative cells underneath the gastrodermis remaining at the wound margin. The gastrodermal cells in experimental regenerates retained some of their original characters and presented no indication of cell dedifferentiation. The regenerative cells came into contact with the basal surface of gastrodermal cells, forming stratified cell layers. Differentiation of these cells into gastrodermal cells was initiated by the development of synthetic organelles within their cytoplasm. These differentiating cells gave rise to two different types of gastrodermal cells, namely phagocytic cells and sphere cells. In later stages, there was an apparent movement of differentiated gastrodermal cells towards the parenchyma.     

Quantitative analysis of cell types during growth,degrowth and regeneration in the planarians Dugesia mediterranea and Dugesia tigrina

A method of tissue maceration (dissociation) of planarian tissues into single cells was used to characterize the basic cell types in the planarians Dugesia mediterranea and Dugesia tigrina, and to determine the total cell number and distribution of cell types during growth, degrowth and regeneration.Using this method, 13 basic cell types have been determined for both species. The total number of cells increases with body length and volume whereas the distribution of cell types is only slightly affected. Growth and degrowth occur mainly through changes in total cell number leaving cell distribution only moderately affected. During regeneration, an increase in neoblast density in the blastema followed later on by increases in nerve cells are the more significant changes detected.These results are discussed in relation to mechanisms of cell renewal, blastema formation and maintenance of tissue polarity.Abbreviations nb neoblasts - nv nerve cells - ep epidermal cells - fp fixed parenchyma cells - g gastrodermal cells     

Analysis of the cell kinetics during planarian regeneration by means of SAMBA 200 cell image processor

Summary The relationships between cell kinetics and nuclear transformations in regeneration were investigated in the planarianPolycelis nigra by means of image analysis. A SAMBA 200 cell image processor was used to compute densitometric, textural and morphological parameters on Feulgen-stained nuclei in the blastema and near the cut 2–96 h after decapitation. On the basis of these parameters, the phase of the cell cycle (G₁–G₀, S, G₂ and M) was identified and the variations in the percentage of cells in the various phases as well as the blastema cell number were computed against time after decapitation. It was demonstrated that the transection is followed by the sequential wasting of the M, G₂, S and G₁–G₀ compartments. The depletion of a compartment was interpreted as being responsible for the subsequent recovery observed in the next one. The results show that cell proliferation at the section level is not sufficient to account for the increase of the blastema cell number during the first 48 h of regeneration, since the doubling time is about 12 h while the average cycle time is 48 h. It is thus suggested that G₁–G₀ cells migrate toward the section level, at least during the first 2 days of regeneration. Analysis of the nuclear profiles demonstrated that there are two different classes of G₁–G₀ cells: one corresponding to mature cells with a lot of condensed chromatin distributed in clumps within the nucleus, the other to immature cells with chromatin regularly distributed according to a rather homogeneous pattern. About one G₁–G₀ cell out of five is immature at the section level before decapitation while four cells out of five are immature as early as 8 h after the cut. This early inversion of the ratio between mature and immature cells argues in favour of an immigration of immature G₁–G₀ cells to the young blastema, where they are expected to accomplish only one cell cycle, and thus gives rise to mature cells.     

SDF-1α/CXCR4 signaling mediates digit tip regeneration promoted by BMP-2

Previously we demonstrated that BMP signaling is required for endogenous digit tip regeneration, and that treatment with BMP-2 or -7 induces a regenerative response following amputation at regeneration-incompetent levels (Yu et al., 2010 and Yu et al., 2012). Both endogenous regeneration and BMP-induced regeneration are associated with the transient formation of a blastema, however the formation of a regeneration blastema in mammals is poorly understood. In this study, we focus on how blastema cells respond to BMP signaling during neonatal digit regeneration in mice. First, we show that blastema cells retain regenerative properties after expansion in vitro, and when re-introduced into the amputated digit, these cells display directed migration in response to BMP-2. However, in vitro studies demonstrate that BMP-2 alone does not influence blastema cell migration, suggesting a requirement of another pivotal downstream factor for cell recruitment. We show that blastema cell migration is stimulated by the cytokine, SDF-1α, and that SDF-1α is expressed by the wound epidermis as well as endothelial cells of the blastema. Blastema cells express both SDF-1α receptors, CXCR4 and CXCR7, although the migration response is inhibited by the CXCR4-specific antagonist, AMD3100. Mice treated with AMD3100 display a partial inhibition of skeletal regrowth associated with the regeneration response. We provide evidence that BMP-2 regulates Sdf-1α expression in endothelial cells but not cells of the wound epidermis. Finally, we show that SDF-1α-expressing COS1 cells engrafted into a regeneration-incompetent digit amputation wound resulted in a locally enhanced population of CXCR4 positive cells, and induced a partial regenerative response. Taken together, this study provides evidence that one downstream mechanism of BMP signaling during mammalian digit regeneration involves activation of SDF-1α/CXCR4 signaling by endothelial cells to recruit blastema cells.     

Origin and proliferation of blastema cells during regeneration of Drosophila wing imaginal discs

Following a period of neglect, there has been a resurgence of interest in Drosophila imaginal discs as a model with which to analyze the relationships between growth and pattern formation during regeneration. To broaden our understanding of this process, we used cell lineage techniques to trace the origin of blastema cells and the early and late boundaries of the blastema in regenerating 3/4 wing disc fragments, examined the distribution of S-phase, mitotic and dead cells, and undertook clonal analysis to determine the topology of cell proliferation and its relationship to pattern formation. Using lineage tagging with the JNK phosphatase puckered (puc), we demonstrate that a substantial number of blastema cells arise from cells in which JNK is activated. Furthermore, we show that DNA synthesis and mitosis are activated well before wound healing is completed, in a region where the JNK pathway is activated; later, DNA synthesis and mitosis are observed in scattered cells throughout the blastema. Finally, clonal analysis shows a close relationship between the size and shape of clones and disparities in the positional values of the apposed surfaces.     

Use of the p-nitrophenyl phosphate method for the demonstration of acid phosphatase during starvation and cell autolysis in the planarian Polycelis tenuis Iijima.

Synopsis Acid phosphatase activity is demonstrated employingp-nitrophenyl phosphate as substrate and lead acetate as coupler. The fine structural localization of the enzyme in starved planarian tissues is described. The method is used to pin-point starvation-induced acid phosphatase activity in relation to autophagy and crinophagy in the gland cells; autophagy, autolysis and cell death in parenchymal and gastrodermal cells and basement membrane lysis. Attention is also payed to the demonstration of muscle lysis. The histochemical implications of the method are discussed.     

Cytotoxic effects of 6-mercaptopurine on the limb-bud blastemal cells of rat embryos.

On day 12 of pregnancy Wistar rats were each given a single ip injection of 5, 8, 16, 25, or 50 mg/kg 6-mercaptopurine. The embryos were removed 1, 2, 3, 5, 6, 10, 24, 48, or 72 h after injection or on day 20 and studied by light and electron microscopy. After 25 or 50 mg/kg all embryos showed no mineralization in the lower extremities. By electron microscopy condensation, shrinking, and fragmentation of cells in the limb bud blastema could be seen after 5 h. The fragments were phagocytosed and broken down by neighboring cells or remained in the extracellular space. After 25 or 50 mg/kg the damage was so extensive that the number of undamaged cells and of cells transforming into phagocytes was not sufficient to remove the debris or to compensate for the defect by mitotic activity. Epithelial cells, nerves, and blood vessels, show no morphological signs of damage. The "critical period" was the time cartilage just starts developing, i.e., when the blastema begins to differentiate.     

Mitotic activity in the blastema and stump tissues of regenerating hind limbs of Xenopus laevis larvae after amputation at ankle level. An autoradiographic study

Mitotic activity, as indicated by DNA synthesis, was studied by autoradiographic analysis along the proximodistal axis of regenerating limbs in the early and later larval stages 53 and 57 of Xenopus laevis. Wound-healing, dedifferentiation, blastema formation and growth phases were studied. Most of the various stump tissues, as well as the cell mass of the regeneration blastema, were involved. The study showed an increase in DNA synthesis in the stump tissues during their dedifferentiation as well as during blastema formation. The increase was confined mainly to the distal portion (close to the amputation level), so that a proximodistal gradient was discernible. This could be regarded as valid evidence of contribution of the severed stump tissues to the blastema cells. The mesenchymal blastema cells formed after amputation at stage 53 displayed higher mitotic activity than the fibrocytoid blastema cells formed at stage 57. Although the latter were more differentiated than the former, they still showed DNA replication and mitotic division.     

The phorbol ester TPA dramatically inhibits planarian regeneration

The effect of phorbol ester TPA (12-O-tetradecanoylphorbol-13-acetate) on head regeneration in decapitated planarians (Dugesia lugubris s.1.) has been studied. TPA-treatment soon after head amputation dramatically inhibited the regenerative process. Ultrastructural analysis revealed that the migration of fixed parenchymal cells (FPCs) to the wound area was strongly activated by TPA. FPCs interacted with various types of cells inducing lysis and phagocyting cell debris. The resulting fluid was removed through diaphanous protrusions appearing at the level of the wound zone. Moreover the close association of FPCs with neoblastlike cell clusters in the parenchyma indicated their possible role in the modulation of neoblast migration.     

A stepwise model system for limb regeneration

The amphibian limb is a model that has provided numerous insights into the principles and mechanisms of tissue and organ regeneration. While later stages of limb regeneration share mechanisms of growth control and patterning with limb development, the formation of a regeneration blastema is controlled by early events that are unique to regeneration. In this study, we present a stepwise experimental system based on induction of limb regeneration from skin wounds that will allow the identification and functional analysis of the molecules controlling this early, critical stage of regeneration. If a nerve is deviated to a skin wound on the side of a limb, an ectopic blastema is induced. If a piece of skin is grafted from the contralateral side of the limb to the wound site concomitantly with nerve deviation, the ectopic blastema continues to grow and forms an ectopic limb. Our analysis of dermal cell migration, contribution, and proliferation indicates that ectopic blastemas are equivalent to blastemas that form in response to limb amputation. Signals from nerves are required to induce formation of both ectopic and normal blastemas, and the diversity of positional information provided by blastema cells derived from opposite sides of the limb induces outgrowth and pattern formation. Hence, this novel and convenient stepwise model allows for the discovery of necessary and sufficient signals and conditions that control blastema formation, growth, and pattern formation during limb regeneration.     

Dedifferentiation and redifferentiation of the penis of the freshwater planarian Bdellocephala brunnea

Following decapitation of Bdellocephala brunnea Ijima et Kaburaki and subsequent repeated removal of regenerating head-blastemas, the copulatory apparatus degenerated within 40–60 days. The copulatory apparatus disintegrated into cell clusters that further divided into separate neoblast-like cells that, in turn, eventually transformed into ordinary parenchymal cells by 60 days after decapitation. When the head of worms with a degenerate copulatory apparatus was allowed to regenerate by discontinuing excision of the head blastema, a new copulatory apparatus differentiated, ostensibly from the dedifferentiated cells. The neoblast-like cells appear to participate in the redifferentiation of the penis and of other parts of the copulatory apparatus.     

Ultrastructure of the calcium-sequestering gastrodermal cell in the hydroid Hydractinia symbiolongicarpus (Cnidaria, Hydrozoa)

Large, free-floating crystals of calcium carbonate occur in vacuoles of gastrodermal cells of the hydroid Hydractinia symbiolongicarpus. Here, morphological details about the process by which these cells accumulate and sequester calcium are provided by a cytochemical method designed to demonstrate calcium at the ultrastructural level. Electron-dense material presumably indicative of the presence of calcium was EGTA-sensitive and was shown by parallel electron energy loss spectroscopy (EELS) and energy spectroscopic imaging (ESI) to contain calcium. Calcium occurred in only one cell type, the endodermally derived gastrodermal cell. In these cells, the electron-dense material appeared first as a fine precipitate in the cytosol and nucleus and later as larger deposits and aggregates in the vacuole. During the life cycle, gastrodermal cells of the uninduced planula and the planula during metamorphic induction sequestered calcium. In primary polyps and polyps from established colonies, gastrodermal cells sequestered calcium, but the endodermal secretory cells did not. Our observations support the hypothesis that gastrodermal cells function as a physiological sink for calcium that enters the organism in conjunction with calcium-requiring processes such as motility, secretion, and metamorphosis.     

Nerve-dependent and -independent events in blastema formation during Xenopus froglet limb regeneration

Blastema formation, the initial stage of epimorphic limb regeneration in amphibians, is an essential process to produce regenerates. In our study on nerve dependency of blastema formation, we used forelimb of Xenopus laevis froglets as a system and applied some histological and molecular approaches in order to determine early events during blastema formation. We also investigated the lateral wound healing in comparison to blastema formation in limb regeneration. Our study confirmed at the molecular level that there are nerve-dependent and -independent events during blastema formation after limb amputation, Tbx5 and Prx1, reliable markers of initiation of limb regeneration, that start to be expressed independently of nerve supply, although their expressions cannot be maintained without nerve supply. We also found that cell proliferation activity, cell survival and expression of Fgf8, Fgf10 and Msx1 in the blastema were affected by denervation, suggesting that these events specific for blastema outgrowth are controlled by the nerve supply. Wound healing, which is thought to be categorized into tissue regeneration, shares some nerve-independent events with epimorphic limb regeneration, although the healing process results in simple restoration of wounded tissue. Overall, our results demonstrate that dedifferentiated blastemal cells formed at the initial phase of limb regeneration must enter the nerve-dependent epimorphic phase for further processes, including blastema outgrowth, and that failure of entry results in a simple redifferentiation as tissue regeneration.     

Glucose-6-phosphatase distribution in isolated and cultured adult rat hepatocytes

The cytochemical localization of glucose-6-phosphatase (G6Pase) and its biochemical quantification were studied in isolated and cultured adult rat parenchymal cells. Appropriate technical conditions were chosen to assume adequate ultrastructural preservation and retention of enzyme activity. Isolated hepatocytes separated by collagenase perfusion were shortly fixed in glutaraldehyde and entrapped in a pellet of fibrin. Frozen sections, 50 microns in thickness were incubated for cytochemical demonstration of G6Pase, in a slightly modified Wachstein-Meisel medium. Hepatocytes in culture, fixed for 1 min in glutaraldehyde, were impregnated in a 10% cryoprotective glycerol solution and quickly frozen in liquid nitrogen at -170 degrees C in order to induce penetration of the substrate. In these conditions, a homogeneous distribution of the enzyme was observed in both isolated and cultured cells. The cytochemical reaction appears continuous in the smooth and rough endoplasmic cisternae and in the nuclear envelope. Lead phosphate deposits, although evenly distributed, are reduced in intensity after 48 h culture. Biochemical determinations reveal the presence of a high specific enzymatic activity in isolated cells (108 nmolP/min/mg proteins), which decreases in culture, respectively to 70 and 50% of the original value, after 24 and 48 h culture. G6Pase induction by glucagon was obtained after 48 and 72 h in culture.     

Bromodeoxyuridine labeling reveals a class of satellite-Like cells within the electric organ

When the electric organ (EO) of weakly electric fish is amputated, a blastema forms from which new EO and muscle cells arise. However, the progenitor cells that contribute to the blastema are unknown. We studied regeneration of the electric organ in Sternopygus to answer this question. The EO of this species is composed of electrocyte cells surrounded by peripheral bundles of muscle fibers. Fish were injected with 5′-bromodeoxyuridine (BrdU) 24 h after amputating the terminal portion of the EO. At this time, a population of small cells were labeled in the extracellular matrix between electrocytes and muscle fibers. These cells did not label in control fish injected with saline or in nonamputated BrdU-injected fish. For the first 6 days postamputation, increasing numbers of BrdU-labeled cells appeared at the wound margin. A blastema formed 6 days after amputation and contained numerous BrdU-labeled cells. At 10 days postamputation, clusters of BrdU-positive cells were seen throughout the wound margin and proximal blastema. At 14 days, BrdU-labeled nuclei were present within developing electrocytes. Labeling alternate sections with MF20 antimyosin and AE1 anticytokeratin antibodies confirmed that BrdU-positive multinucleate cells coexpress myosin and cytokeratin epitopes, diagnostic of newly regenerated electrocytes. Electron micrographs reveal that the small cells surrounding muscles and electrocytes are similar; they contain an elongate nucleus, are largely devoid of cytoplasm, and possess few organelles. This morphology and evidence of myogenic potential suggests that these cells are satellite cells. © 1993 John Wiley & Sons, Inc.     

Plasticity of photoreceptor-generating retinal progenitors revealed by prolonged retinoic acid exposure

Background

Epimorphic regeneration results in the restoration of lost tissues and structures from an aggregation of proliferating cells known as a blastema. Among amniotes the most striking example of epimorphic regeneration comes from tail regenerating lizards. Although tail regeneration is often studied in the context of ecological costs and benefits, details of the sequence of tissue-level events are lacking. Here we investigate the anatomical and histological events that characterize tail regeneration in the leopard gecko, Eublepharis macularius.

Results

Tail structure and tissue composition were examined at multiple days following tail loss, revealing a conserved pattern of regeneration. Removal of the tail results in a consistent series of morphological and histological events. Tail loss is followed by a latent period of wound healing with no visible signs of regenerative outgrowth. During this latent period basal cells of the epidermis proliferate and gradually cover the wound. An additional aggregation of proliferating cells accumulates adjacent to the distal tip of the severed spinal cord marking the first appearance of the blastema. Continued growth of the blastema is matched by the initiation of angiogenesis, followed by the re-development of peripheral axons and the ependymal tube of the spinal cord. Skeletal tissue differentiation, corresponding with the expression of Sox9, and muscle re-development are delayed until tail outgrowth is well underway.

Conclusions

We demonstrate that tail regeneration in lizards involves a highly conserved sequence of events permitting the establishment of a staging table. We show that tail loss is followed by a latent period of scar-free healing of the wound site, and that regeneration is blastema-mediated. We conclude that the major events of epimorphic regeneration are highly conserved across vertebrates and that a comparative approach is an invaluable biomedical tool for ongoing regenerative research.     

Nerve-induced ectopic limb blastemas in the Axolotl are equivalent to amputation-induced blastemas

Adult urodeles (salamanders) are unique in their ability to regenerate complex organs perfectly. The recently developed Accessory Limb Model (ALM) in the axolotl provides an opportunity to identify and characterize the essential signaling events that control the early steps in limb regeneration. The ALM demonstrates that limb regeneration progresses in a stepwise fashion that is dependent on signals from the wound epidermis, nerves and dermal fibroblasts from opposite sides of the limb. When all the signals are present, a limb is formed de novo. The ALM thus provides an opportunity to identify and characterize the signaling pathways that control blastema morphogenesis and limb regeneration. Our previous study provided data on cell contribution, cell migration and nerve dependency indicating that an ectopic blastema is equivalent to an amputation-induced blastema. In the present study, we have determined that formation of both ectopic blastemas and amputation-induced blastemas is regulated by the same molecular mechanisms, and that both types of blastema cells exhibit the same functions in controlling growth and pattern formation. We have identified and validated five marker genes for the early stages of wound healing, dedifferentiation and blastema formation, and have discovered that the expression of each of these markers is the same for both ectopic and amputation-induced blastemas. In addition, ectopic blastema cells interact coordinately with amputation-induced blastema cells to form a regenerated limb. Therefore, the ALM is appropriate for identifying the signaling pathways regulating the early events of tetrapod limb regeneration.