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While the axolotl's ability to completely regenerate amputated limbs is well known and studied, the mechanism of axolotl bone fracture healing remains poorly understood. One reason might be the lack of a standardized fracture fixation in axolotl. We present a surgical technique to stabilize the osteotomized axolotl femur with a fixator plate and compare it to a non-stabilized osteotomy and to limb amputation. The healing outcome was evaluated 3 weeks, 3, 6 and 9 months post-surgery by microcomputer tomography, histology and immunohistochemistry. Plate-fixated femurs regained bone integrity more efficiently in comparison to the non-fixated osteotomized bone, where larger callus formed, possibly to compensate for the bone fragment misalignment. The healing of a non-critical osteotomy in axolotl was incomplete after 9 months, while amputated limbs efficiently restored bone length and structure. In axolotl amputated limbs, plate-fixated and non-fixated fractures, we observed accumulation of PCNA+ proliferating cells at 3 weeks post-injury similar to mouse. Additionally, as in mouse, SOX9-expressing cells appeared in the early phase of fracture healing and amputated limb regeneration in axolotl, preceding cartilage formation. This implicates endochondral ossification to be the probable mechanism of bone healing in axolotls. Altogether, the surgery with a standardized fixation technique demonstrated here allows for controlled axolotl bone healing experiments, facilitating their comparison to mammals (mice).

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The axolotl Ambystoma mexicanum is one of the most commonly used model organisms in developmental and regenerative studies because it can reconstitute what is believed to be a completely normal anatomical and functional forelimb/hindlimb after amputation. However, to date it has not been confirmed whether each regenerated forelimb muscle is really a "perfect" copy of the original muscle. This study describes the regeneration of the arm, forearm, hand, and some pectoral muscles (e.g., coracoradialis) in transgenic axolotls that express green fluorescent protein (GFP) in muscle fibers. The observations found that: (1) there were muscle anomalies in 43% of the regenerated forelimbs; (2) however, on average in each regenerated forelimb there are anomalies in only 2.5% of the total number of muscles examined, and there were no significant differences observed in the specific insertion and origin of the other muscles analyzed; (3) one of the most notable and common anomalies (seen in 35% of the regenerated forelimbs) was the presence of a fleshy coracoradialis at the level of the arm; this is a particularly outstanding configuration because in axolotls and in urodeles in general this muscle only has a thin tendon at the level of the arm, and the additional fleshy belly in the regenerated arms is strikingly similar to the fleshy biceps brachii of amniotes, suggesting a remarkable parallel between a regeneration defect and a major phenotypic change that occurred during tetrapod limb evolution; (4) during forelimb muscle regeneration there was a clear proximo-distal and radio-ulnar morphogenetic gradient, as seen in normal development, but also a ventro-dorsal gradient in the order of regeneration, which was not previously described in the literature. These results have broader implications for regenerative, evolutionary, developmental and morphogenetic studies.

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The axolotl Ambystoma mexicanum is one of the most used model organisms in developmental and regenerative studies because it is commonly said that it can reconstitute a normal and fully functional forelimb/hindlimb after amputation. However, there is not a publication that has described in detail the regeneration of the axolotl hindlimb muscles. Here we describe and illustrate, for the first time, the regeneration of the thigh, leg and foot muscles in transgenic axolotls that express green fluorescent protein in muscle fibers and compare our results with data obtained by us and by other authors about axolotl forelimb regeneration and about fore- and hindlimb ontogeny in axolotls, frogs and other tetrapods. Our observations and comparisons point out that: (1) there are no muscle anomalies in any regenerated axolotl hindlimbs, in clear contrast to our previous study of axolotl forelimb regeneration, where we found muscle anomalies in 43% of the regenerated forelimbs; (2) during axolotl hindlimb regeneration there is a proximo-distal and a tibio-fibular morphogenetic gradient in the order of muscle regeneration and differentiation, but not a ventro-dorsal gradient, whereas our previous studies showed that in axolotl forelimb muscle regeneration there are proximo-distal, radio-ulnar and ventro-dorsal morphogenetic gradients. We discuss the broader implications of these observations for regenerative, evolutionary, developmental and morphogenetic studies.

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The axolotl Ambystoma mexicanum is one of the most used model organisms in evolutionary, developmental and regenerative studies, particularly because it can reconstitute a fully functional and complete forelimb/hindlimb. Surprisingly, there is no publication that describes all the pectoral and forelimb muscles of this species or provides a comparative framework between these muscles and those of other model organisms and of modern humans. In the present paper we describe and illustrate all these muscles in A. mexicanum and provide the first report about the myology of adults of a model organism that is based on analyses and dissections of both wildtype animals and transgenic animals that express green fluorescent protein (GFP) in muscle fibers. On the one hand, the inclusion of GFP-transgenic animals allows us to show the muscles as more commonly seen, and thus easier to understand, by current developmental and regenerative biologists. On the other hand, by including wildtype and GFP-transgenic animals and by visualizing these latter animals with and without a simultaneous transmission laser light, we were able to obtain a more complete and clearer understanding of the exact limit of the fleshy and tendinous parts of the muscles and their specific connections with the skeletal elements. This in turn allowed us to settle some controversies in previous anatomical and comparative studies. As most developmental, regenerative and evolutionary biologists are interested in comparing their observations of A. mexicanum with observations in other model organisms, and ultimately in using this information to increase the understanding of human evolution and medicine, we also provide tables showing the homologies between the pectoral and forelimb muscles of axolotls, of model organisms such as mice, frogs and chicken, and of Homo sapiens. An example illustrating the outcomes of using our methodology and of our observations is that they revealed that, contrary to what is often stated in the literature, A. mexicanum has a muscle coracoradialis that has both a well developed proximal fleshy belly and a distal long and thin tendon, supporting the idea that this muscle very likely corresponds to at least part of the amniote biceps brachii. Our observations also: (i) confirmed that the flexores digitorum minimi, interphalangeus digiti 3, pronator quadratus and palmaris profundus 1 are present as distinct muscles in A. mexicanum, supporting the idea that the latter muscle does not correspond to the pronator accessorius of reptiles; (ii) confirmed that the so-called extensor antebrachii radialis is present as a distinct muscle in this species and, importantly, indicated that this muscle corresponds to the supinator of other tetrapods; (iii) showed that, contrary to some other urodeles, including some other Ambystoma species, there is no distinct muscle epitrochleoanconeus in A. mexicanum and; (iv) showed that the ulnar and radial bundles of the abductor et extensor digiti 1 correspond to the abductor pollicis longus and extensor pollicis longus of other tetrapods, respectively.

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The ability of diverse metazoans to regenerate whole-body structures was first described systematically by Spallanzani in 1768 and continues to fascinate biologists today. Given the current interest in stem cell biology and its therapeutic potential, examples of vertebrate regeneration garner strong interest. Among regeneration-competent vertebrates such as the fish, frog, and salamander, the salamander is particularly impressive because it can regenerate the entire limb and tail as well as various internal organs as an adult (Goss 1969). This spectacular natural phenomenon leads us to ask what cellular properties allow regeneration and what prevents this phenomenon in other vertebrates. From this perspective, it is imperative to know whether the stem cells in regenerating limbs harbor particularly special traits such as a higher plasticity in cell fate compared to tissue stem cells in other organisms. Flexibility in cell fate needs to be considered with respect not only to tissue identity, but also to patterning because limb amputation causes cells in a particular limb segment to form more distal limb elements. How positional identity is encoded in stem cells and how it is controlled to produce only the missing portion of the limb are also questions of fundamental importance.

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Tailed amphibians such as axolotls and newts have the unique ability to fully regenerate a functional spinal cord throughout life. Where the cells come from and how they form the new structure is still poorly understood. Here, we describe the development of a technique that allows the visualization of cells in the living animal during spinal cord regeneration. A microelectrode needle is inserted into the lumen of the spinal cord and short rapid pulses are applied to transfer the plasmids encoding the green or red fluorescent proteins into ependymal cells close to the plane of amputation. The use of small, transparent axolotls permits imaging with epifluorescence and differential interference contrast microscopy to track the transfected cells as they contribute to the spinal cord. This technique promises to be useful in understanding how neural progenitors are recruited to the regenerating spinal cord and opens up the possibility of testing gene function during this process.

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In vitro antimicrobial susceptibility of strains of Pseudomonas aeruginosa by standard diffusion disk test and a modified method, by the addition Tris-EDTA, was evaluated. Increase in sensitivity of agent using modified method was observed mainly in aminoglycosides (amikacin, gentamicin, tobramycin), quinolones (ofloxacin and norfloxacin) and cephalosporins (cefoperazone and ceftazidime) groups. by standard diffusion disk test and a modified method, by the addition Tris-EDTA, was evaluated. Increase in sensitivity of agent using modified method was observed mainly in aminoglycosides (amikacin, gentamicin, tobramycin), quinolones (ofloxacin and norfloxacin) and cephalosporins (cefoperazone and ceftazidime) groups

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During tail regeneration in urodele amphibians such as axolotls, all of the tissue types, including muscle, dermis, spinal cord, and cartilage, are regenerated. It is not known how this diversity of cell types is reformed with such precision. In particular, the number and variety of mature cell types in the remaining stump that contribute to the blastema is unclear. Using Nomarski imaging, we followed the process of regeneration in the larval axolotl tail. Combining this with in vivo fluorescent labeling of single muscle fibers, we show that mature muscle dedifferentiates. Muscle dedifferentiation occurs by the synchronous fragmentation of the multinucleate muscle fiber into mononucleate cells followed by rapid cell proliferation and the extension of cell processes. We further show that direct clipping of the muscle fiber and severe tissue damage around the fiber are both required to initiate dedifferentiation. Our observations also make it possible to estimate for the first time how many of the blastema cells arise specifically from muscle dedifferentiation. Calculations based on our data suggest that up to 29% of nondermal-derived cells in the blastema come from dedifferentiation of mature muscle fibers. Overall, these results show that endogenous multinucleate muscle fibers can dedifferentiate into mononucleate cells and contribute significantly to the blastema.

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

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BACKGROUND: Adult urodele amphibians such as the newt have remarkable regenerative ability, and a critical aspect of this is the ability of differentiated cells to re-enter the cell cycle and lose their differentiated characteristics. Unlike mammalian myotubes, cultured newt myotubes are able to enter and traverse S phase, following serum stimulation, by a pathway leading to phosphorylation of the retinoblastoma protein. The extracellular regulation of this pathway is unknown. RESULTS: Like their mammalian counterparts, newt myotubes were refractory to mitogenic growth factors such as the platelet-derived growth factor (PDGF), which act on their mononucleate precursor cells. Cultured newt myotubes were activated to enter S phase by purified thrombin in the presence of subthreshold amounts of serum. The activation proceeded by an indirect mechanism in which thrombin cleaved components in serum to generate a ligand that acted directly on the myotubes. The ligand was identified as a second activity present in preparations of crude thrombin and that was active after removal of all thrombin activity. It induced newt myotubes to enter S phase in serum-free medium, and it acted on myotubes but not on the mononucleate precursor cells. Cultured mouse myotubes were refractory to this indirect mechanism of S-phase re-entry. CONCLUSIONS: These results provide a link between reversal of differentiation and the acute events of wound healing. The urodele myotube responds to a ligand generated downstream of thrombin activation and re-enters the cell cycle. Although this ligand can be generated in mammalian sera, the mammalian myotube is unresponsive. These results provide a model at the cellular level for the difference in regenerative ability between urodeles and mammals.

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A key early event of newt limb regeneration is the local dedifferentiation of cells to form dividing progenitor cells. This involves the plasticity of differentiation and the ability to re-enter the cell cycle. In culture, differentiated newt myotubes are able to re-enter S-phase in response to serum stimulation. Here, we analyzed the intracellular and extracellular requirements for this process. Cell cycle re-entry depends on the phosphorylation of the retinoblastoma protein, which is a key regulator of the G1-S transition. This is in contrast to mammalian myotubes, which are refractory to serum stimulation and cannot phosphorylate retinoblastoma protein in response to serum. The serum factor responsible for this phosphorylation appears to be distinct from common polypeptide growth factors and is enriched in crude preparations of bovine thrombin. Fractionation and analysis of this preparation indicate that the factor is regulated by thrombin and plasmin proteolysis. These results indicate that factors involved in acute responses to wounding such as clotting may be important initiators of the regenerative response.

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Withdrawal from the cell cycle is an essential aspect of vertebrate muscle differentiation and requires the retinoblastoma (Rb) protein that inhibits expression of genes needed for cell cycle entry. It was shown recently that cultured myotubes derived from the Rb-/- mouse reenter the cell cycle after serum stimulation (Schneider, J.W., W. Gu, L. Zhu, V. Mahdavi, and B. Nadal-Ginard. 1994. Science (Wash. DC). 264:1467-1471). In contrast with other vertebrates, adult urodele amphibians such as the newt can regenerate their limbs, a process involving cell cycle reentry and local reversal of differentiation. Here we show that myotubes formed in culture from newt limb cells are refractory to several growth factors, but they undergo S phase after serum stimulation and accumulate 4N nuclei. This response to serum is inhibited by contact with mononucleate cells. Despite the phenotypic parallel with Rb-/- mouse myotubes, Rb is expressed in the newt myotubes, and its phosphorylation via cyclin-dependent kinase 4/6 is required for cell cycle reentry. Thus, the postmitotic arrest of urodele myotubes, although intact in certain respects, can be undermined by a pathway that is inactive in other vertebrates. This may be important for the regenerative ability of these animals.

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The controlled extension of neurites is essential not only for nervous system development, but also for effective nerve regeneration after injury. This process is critically dependent on microtubule assembly since axons fail to elongate in the presence of drugs which disrupt normal assembly dynamics. For this reason, neurite outgrowth is potentially controllable by manipulation of the assembly state of the intracellular array of microtubules. Therefore, understanding how microtubule assembly dynamics and neurite outgrowth are coupled, in the absence of drugs, can lend valuable insight into the control and guidance of the outgrowth process. In the present study we characterized the stochastic dynamics of neurite outgrowth and its corresponding microtubule array, which advances concomitantly with the advance of the nerve growth cone, the highly motile structure at the terminus of the growing neurite, using reported fluorescent microscopic image sequences (Tanaka and Kirschner, 1991, J. Cell Biol. 115:345-363). Although previously modeled as an uncorrelated random walk, the stochastic advance of the growth cone was found to be anticorrelated over a time scale of approximately 4 min, meaning that growth cone advances tended to be followed by growth cone retractions approximately 4 min later. The observed anticorrelation most likely reflects the periodic stops and starts of neurite outgrowth that have been reported anecdotally. A strikingly similar pattern of anticorrelation was also identified in the advance of the growth cone's microtubule array. Cross-correlation analysis showed that growth cone dynamics tended to precede microtubule dynamics on a time scale of approximately 0-2 min, while microtubules tended to precede growth cone dynamics on a approximately 0-20-s time scale, indicating a close temporal coupling between microtubule and growth cone dynamics. Finally, the scaling of the mean-squared displacements with time for both the growth cone and microtubules suggested a fractional Brownian motion model which accounts for the observed anticorrelation of growth cone and microtubule advance. (c) 1996 John Wiley & Sons, Inc.

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Implantation of beads soaked in fibroblast growth factor into the flank of a chick embryo causes extra limbs to be formed, suggesting that FGF is important in initiating limb buds.

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To understand how microtubules are generated in the growth cone, we have imaged fluorescently tagged microtubules in living frog embryonic neurons. The neurons were labeled by injecting rhodamine-labeled tubulin into the fertilized egg and explanting the neurons from the neural tube. Microtubules extend deep into the growth cone periphery and adopt three characteristic distributions: (a) dispersed and splayed throughout much of the growth cone; (b) looped and apparently contorted by compression; and (c) bundled into tight arrays. These distributions interconvert on a time scale of several minutes and these interconversions are correlated with the behavior of the growth cone. We observed microtubule growth and shrinkage in growth cones, but are unable to determine their contribution to net assembly. However, translocation of polymer form the axon appears to be a major mechanism of generating new polymer in the growth cone, while bundling of microtubules in the growth cone appears to be the critical step in generating new axon. Neurons that were about to turn spontaneously generated microtubules in the future direction of growth, suggesting that orientation of microtubules might be an important early step in neuronal pathfinding.

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