[Regeneration of the facial nerve in comparison to other peripheral nerves : from bench to bedside]

Despite increasing knowledge of cellular and molecular mechanisms determining the success or failure of peripheral nerve regeneration, no effective treatments for peripheral nerve injury exist. Newly developed and validated approaches for precise numerical assessment of motor deficits have recently allowed testing of novel strategies in experimental animals. One of these approaches is the daily manual stimulation of the denervated musculature. This treatment is effective in cases of cranial nerve lesions with preservation of the sensory input (facial or hypoglossal nerve) and has the potential of direct translation in clinical settings. However, manual stimulation appears to be ineffective for the treatment of mixed peripheral nerve injuries. Generally, no long-term improvement of functional recovery is achieved by electrical stimulation in rodents. While short-term post-traumatic stimulation of the proximal nerve stump has no negative effects, direct electrical stimulation of the muscle during the period of de- and reinnervation appears to hinder muscle fibre reinnervation. Finally, experimental evidence suggests that application of peptides known as glycomimetics, which mimic functional properties of carbohydrate molecules, may provide significant benefits after injuries of mixed peripheral nerves.

Recovery of whisking function promoted by manual stimulation of the vibrissal muscles after facial nerve injury requires insulin-like growth factor 1 (IGF-1)

Recently, we showed that manual stimulation (MS) of denervated vibrissal muscles enhanced functional recovery following facial nerve cut and suture (FFA) by reducing poly-innervation at the neuro-muscular junctions (NMJ). Although the cellular correlates of poly-innervation are established, with terminal Schwann cells (TSC) processes attracting axon sprouts to "bridge" adjacent NMJ, molecular correlates are poorly understood. Since quantitative RT-PCR revealed a rapid increase of IGF-1 mRNA in denervated muscles, we examined the effect of daily MS for 2 months after FFA in IGF-1(+/-) heterozygous mice; controls were wild-type (WT) littermates including intact animals. We quantified vibrissal motor performance and the percentage of NMJ bridged by S100-positive TSC. There were no differences between intact WT and IGF-1(+/-) mice for vibrissal whisking amplitude (48 degrees and 49 degrees ) or the percentage of bridged NMJ (0%). After FFA and handling alone (i.e. no MS) in WT animals, vibrissal whisking amplitude was reduced (60% lower than intact) and the percentage of bridged NMJ increased (42% more than intact). MS improved both the amplitude of vibrissal whisking (not significantly different from intact) and the percentage of bridged NMJ (12% more than intact). After FFA and handling in IGF-1(+/-) mice, the pattern was similar (whisking amplitude 57% lower than intact; proportion of bridged NMJ 42% more than intact). However, MS did not improve outcome (whisking amplitude 47% lower than intact; proportion of bridged NMJ 40% more than intact). We conclude that IGF-I is required to mediate the effects of MS on target muscle reinnervation and recovery of whisking function.

A model system for studying postnatal myogenesis with tetracycline-responsive, genetically engineered clonal myoblasts in vitro and in vivo

The aim of this work was to introduce a tetracycline-responsive (Tet-off) gene expression system into myoblasts in order to regulate a reporter gene not only in vitro but also particularly in muscles implanted with these engineered myoblasts. Mouse myoblasts from a long-term culture (i28 cells) were transfected initially to generate and characterize two stable master clones expressing tetracycline-responsive transactivator protein tTA. Like parental i28 myoblasts, these clones differentiated well in vitro. The second step introduced the firefly (Photinus pyralis) luciferase gene into one of the stable tTA clones producing double transfectants expressing luciferase in the absence of tetracycline. Addition of tetracycline (1 microg ml(-1)) resulted in at least 100-fold decreases in luciferase activity within 8 h in both growing and differentiating myoblast cultures. Enzyme activity was rapidly restored after tetracycline was removed (8 h). After successful implantation of these myoblasts into damaged mouse muscles, luciferase expression in the matured progeny cells could be regulated by oral application of doxycycline for at least 1 month. The tetracycline-responsive master clones are potentially powerful tools for studying the function of various genes in postnatal myogenesis.

A new immunodeficient mouse model for human myoblast transplantation

Design of efficient transplantation strategies for myoblast-based gene therapies in humans requires animal models in which xenografts are tolerated for long periods of time. In addition, such recipients should be able to withstand pretransplantation manipulations for enhancement of graft growth. Here we report that a newly developed immunodeficient mouse carrying two known mutations (the recombinase activating gene 2, RAG2, and the common cytokine receptor gamma, gammac) is a candidate fulfilling these requirements. Skeletal muscles from RAG2(-/-)/gammac(-/-) double mutant mice recover normally after myotoxin application or cryolesion, procedures commonly used to induce regeneration and improve transplantation efficiency. Well-differentiated donor-derived muscle tissue could be detected up to 9 weeks after transplantation of human myoblasts into RAG2(-/-)/gammac(-/-) muscles. These results suggest that the RAG2(-/-)/gammac(-/-) mouse model will provide new opportunities for human muscle research.

Skeletal muscle cell activation by low-energy laser irradiation: a role for the MAPK/ERK pathway

Low-energy laser irradiation (LELI) has been shown to promote skeletal muscle regeneration in vivo and to activate skeletal muscle satellite cells, enhance their proliferation and inhibit differentiation in vitro. In the present study, LELI, as well as the addition of serum to serum-starved myoblasts, restored their proliferation, whereas myogenic differentiation remained low. LELI induced mitogen-activated protein kinase/extracellular signal-regulated protein kinase (MAPK/ERK) phosphorylation with no effect on its expression in serum-starved myoblasts. Moreover, a specific MAPK kinase inhibitor (PD098059) inhibited the LELI- and 10% serummediated ERK1/2 activation. However, LELI did not affect Jun N-terminal kinase (JNK) or p38 MAPK phosphorylation or protein expression. Whereas a 3-sec irradiation induced ERK1/2 phosphorylation, a 12-sec irradiation reduced it, again with no effect on JNK or p38. Moreover, LELI had distinct effects on receptor phosphorylation: it caused phosphorylation of the hepatocyte growth factor (HGF) receptor, previously shown to activate the MAPK/ERK pathway, whereas no effect was observed on tumor suppressor necrosis alpha (TNF-alpha) receptor which activates the p38 and JNK pathways. Therefore, by specifically activating MAPK/ERK, but not JNK and p38 MAPK enzymes, probably by specific receptor phosphorylation, LELI induces the activation and proliferation of quiescent satellite cells and delays their differentiation.

Regenerative capacity and the number of satellite cells in soleus muscles of normal and mdx mice

Satellite cells are potential myogenic cells that participate in repair and growth of muscle fibres. In this investigation, the change in the number of satellite cells following severe muscle damage was monitored in soleus muscle of age-matched mdx and C57Bl/10 mice. Satellite cells were identified immunohistochemically in the light microscope by their association with a recently described marker protein, M-cadherin, and their location between the muscle fibre's sarcolemma and the surrounding basal lamina. In cross-sections of untreated soleus muscle of C57Bl/10 mice at 11-14. 5 months of age, nuclei of M-cadherin positive satellite cells on average amounted to 3.4% of the total number of myonuclei. Surprisingly, significantly higher numbers of satellite cell nuclei, both in absolute numbers (mean 24+/-11 versus 40+/-11 satellite cells per section) and relative to the total number of myonuclei (5. 3%), were found in similarly aged animals in which severe muscle damage had been inflicted 3-6 months before. Cross-sectional area, muscle tissue area and myonuclei counts had recovered to control values. In untreated muscles of age-matched mdx mice satellite cell counts were not different (2.7% of myonuclei) from C57Bl/10 mice. However, regeneration showed marked deficits, as there was a loss of about 36% total cross-sectional area, about 48% total muscle fibre area and about 43% myonuclei per section compared to the untreated mdx muscles. Furthermore, the absolute number of satellite cells decreased from 20+/-11 to 12+/-8 per section. The relative number of satellite cell nuclei remained comparable to, but did not exceed, the undamaged muscles. The poor recovery of muscle and the missing post-regeneration rise in satellite cell numbers may indicate the reproductive limits of the satellite pool.

Function of skeletal muscle tissue formed after myoblast transplantation into irradiated mouse muscles

1. Pretreatment of muscles with ionising radiation enhances tissue formation by transplanted myoblasts but little is known about the effects on muscle function. We implanted myoblasts from an expanded, male-donor-derived, culture (i28) into X-ray irradiated (16 Gy) or irradiated and damaged soleus muscles of female syngeneic mice (Balb/c). Three to 6 months later the isometric contractile properties of the muscles were studied in vitro, and donor nuclei were visualised in muscle sections with a Y chromosome-specific DNA probe. 2. Irradiated sham-injected muscles had smaller masses than untreated solei and produced less twitch and tetanic force (all by about 18 %). Injection of 106 myoblasts abolished these deficiencies and innervation appeared normal. 3. Cryodamage of irradiated solei produced muscle remnants with few (1-50) or no fibres. Additional myoblast implantation led to formation of large muscles (25 % above normal) containing numerous small-diameter fibres. Upon direct electrical stimulation, these muscles produced considerable twitch (53 % of normal) and tetanic forces (35 % of normal) but innervation was insufficient as indicated by weak nerve-evoked contractions and elevated ACh sensitivity. 4. In control experiments on irradiated muscles, reinnervation was found to be less complete after botulinum toxin paralysis than after nerve crush indicating that proliferative arrest of irradiated Schwann cells may account for the observed innervation deficits. 5. Irradiation appears to be an effective pretreatment for improving myoblast transplantation. The injected cells can even produce organised contractile tissue replacing whole muscle. However, impaired nerve regeneration limits the functional performance of the new muscle.

Low-energy laser irradiation affects satellite cell proliferation and differentiation in vitro

Low-energy laser (He-Ne) irradiation was found to promote skeletal muscle regeneration in vivo. In this study, its effect on the proliferation and differentiation of satellite cells in vitro was evaluated. Primary rat satellite cells were irradiated for various time periods immediately after preparation, and thymidine incorporation was determined after 2 days in culture. Laser irradiation affected thymidine incorporation in a bell-shaped manner, with a peak at 3 s of irradiation. Three seconds of irradiation caused an induction of cell-cycle regulatory proteins: cyclin D1, cyclin E and cyclin A in an established line of mouse satellite cells, pmi28, and proliferating cell nuclear antigen (PCNA) in primary rat satellite cells. The induction of cyclins by laser irradiation was compatible with their induction by serum refeeding of the cells. Laser irradiation effect on cell proliferation was dependent on the rat's age. At 3 weeks of age, thymidine incorporation in the irradiated cells was more than twofold higher than that in the controls, while at 6 weeks of age this difference had almost disappeared. Myosin heavy chain (MHC) protein levels were twofold lower in the irradiated than in the control cells, whereas the proliferation of the irradiated cells was twofold higher. Fusion percentage was lower in the irradiated compared to non-irradiated cells. In light of these data, the promoting effect of laser irradiation on skeletal muscle regeneration in vivo may be due to its effect on the activation of early cell-cycle regulatory genes in satellite cells, leading to increased proliferation and to a delay in cell differentiation.

The M-cadherin catenin complex interacts with microtubules in skeletal muscle cells: implications for the fusion of myoblasts

M-cadherin, a calcium-dependent intercellular adhesion molecule, is expressed in skeletal muscle cells. Its pattern of expression, both in vivo and in cell culture as well as functional studies, have implied that M-cadherin is important for skeletal muscle development, in particular the fusion of myoblasts into myotubes. M-cadherin formed complexes with the catenins in skeletal muscle cells similar to E-cadherin in epithelial cells. This suggested that the muscle-specific function of the M-cadherin catenin complex might be mediated by additional interactions with yet unidentified cellular components, especially cytoskeletal elements. These include the microtubules which also have been implicated in the fusion process of myoblasts. Here we present evidence that the M-cadherin catenin complex interacts with microtubules in myogenic cells by using three independent experimental approaches. (1) Analysis by laser scan microscopy revealed that the destruction of microtubules by nocodazole leads to an altered cell surface distribution of M-cadherin in differentiating myogenic cells. In contrast, disruption of actin filaments had little effect on the surface distribution of M-cadherin. (2) M-cadherin antibodies coimmunoprecipitated tubulin from extracts of nocodazole-treated myogenic cells but not of nocodazole-treated epithelial cells ectopically expressing M-cadherin. Vice versa, tubulin antibodies coimmunoprecipitated M-cadherin from extracts of nocodazole-treated myogenic cells but not of nocodazole-treated M-cadherin-expressing epithelial cells. (3) M-cadherin and the catenins, but not a panel of control proteins, were copolymerized with tubulin from myogenic cell extracts even after repeated cycles of assembly and disassemly of tubulin. Moreover, neither M-cadherin nor E-cadherin could be found in a complex with microtubules in epithelial cells ectopically expressing M-cadherin. Our data are consistent with the idea that the interaction of M-cadherin with microtubules might be essential to keep the myoblasts aligned during fusion, a process in which both M-cadherin and microtubules have been implicated.

Ectopic skeletal muscles derived from myoblasts implanted under the skin

We investigated the potential of cultured myoblasts to generate skeletal muscle in an ectopic site. Myoblasts from a clonal cell line or from expanded primary cultures were injected under the skin of the lumbar region of adult syngenic Balb/c mice. One to 7 weeks after injection, distinct muscles, of greater mass in mice injected with clonal myoblasts (6–78 mg, n=37) than in mice injected with primary myoblasts (1–7 mg, n=26), had formed between the subcutaneous panniculus carnosus muscle and the trunk muscles of host animals. These ectopic muscles exhibited spontaneous and/or electrically-evoked contractions after the second week and, when stimulated directly in vitro, isometric contractile properties similar to those of normal muscles. Histological, electron microscopical and tissue culture examination of these muscles revealed their largely mature morphology and phenotype. The fibres, most of which were branched, were contiguous, aligned and capillarised, exhibited normal sarcormeric protein banding patterns, and expressed muscle-specific proteins, including desmin, dystrophin, and isoforms of developmental and adult myosin heavy chain. Enveloping each fibre was a basal lamina, beneath which lay quiescent satellite cells, which could be stimulated to produce new muscle in culture. Presence of endplates (revealed by alpha-bungarotoxin and neurofilament staining), and the eventual loss of expression of neural cell adhesion molecule and extrasynaptic acetylcholine receptors, indicated that some fibres were innervated. That these muscle fibres were of implanted-cell origin was supported by the finding of Y-chromosome and a lack of dystrophin in ectopic muscles formed after subcutaneous injection of, respectively, male myoblasts into female mice and dystrophin-deficient (mdx) myoblasts into normal C57Bl/10 muscle. Our results demonstrate that an organised, functional muscle can be generated de novo from a disorganised mass of myoblasts implanted in an extramuscular subcutaneous site, whereby the host contributes significantly in providing support tissues and innervation. Our observations are also consistent with the idea that myogenic cells behave like tissue-specific stem cells, generating new muscle precursor (satellite) cells as well as mature muscle. Subcutaneous implantation of myoblasts may have a range of useful applications, from the study of myogenesis to the delivery of gene products.

Functional improvement of damaged adult mouse muscle by implantation of primary myoblasts

1. Myoblasts from expanded primary cultures were implanted into cryodamaged soleus muscles of adult BALB/c mice. One to four months later isometric tension recordings were performed in vitro, and the male donor cells implanted into female hosts were traced on histological sections using a Y-chromosome-specific probe. The muscles were either mildly or severely cryodamaged, which led to reductions in tetanic muscle force to 33% (n = 9 muscles, 9 animals) and 70% (n = 11) of normal, respectively. Reduced forces resulted from deficits in regeneration of muscle tissue as judged from the reduced desmin-positive cross-sectional areas (34 and 66% of control, respectively). 2. Implantation of 10(6) myogenic cells into severely cryodamaged muscles more than doubled muscle tetanic force (to 70% of normal, n = 14), as well as specific force (to 66% of normal). Absolute and relative amount of desmin-positive muscle cross-sectional areas were significantly increased indicating improved microarchitecture and less fibrosis. Newly formed muscle tissue was fully innervated since the tetanic forces resulting from direct and indirect (nerve-evoked) stimulation were equal. Endplates were found on numerous Y-positive muscle fibres. 3. As judged from their position under basal laminae of muscle fibres and the expression of M-cadherin, donor-derived cells contributed to the pool of satellite cells on small- and large-diameter muscle fibres. 4. Myoblast implantation after mild cryodamage and in undamaged muscles had little or no functional or structural effects; in both preparations only a few Y-positive muscle nuclei were detected. It is concluded that myoblasts from expanded primary cultures-unlike permanent cell lines-significantly contribute to muscle regeneration only when previous muscle damage is extensive and loss of host satellite cells is severe.

Impaired functional and structural recovery after muscle injury in dystrophic mdx mice

We compared functional and structural recovery from imposed muscle injury in mdx and wild type mice to test their regenerative capacity. Soleus muscle, known to be particularly affected by the disease process, was subjected to most severe damage caused by freeze injury plus 'bystander damage'; the latter causes destruction of host muscle cells in the course of immune rejection of implanted non-histocompatible myogenic cells. Freezing/implantation was performed in mdx and control mice at two ages (4-6 months, "young' and 10-12 months, 'old' age). While recovery of muscle force in the control groups reached 77 and 88% of contralateral by 3 and 6 months, it was 60% and only 43% in mdx mice damaged at young and old age, respectively. Larger force deficits in mdx mice were due to loss of muscle tissue as measured from desmin-positive areas. Worse recovery of dystrophic muscles in general, and old muscles in particular, is interpreted to indicate pronounced exhaustion of the regenerative capacity, possibly caused by previous cycles of degeneration and regeneration.

"Bystander" damage of host muscle caused by implantation of MHC-compatible myogenic cells

Transplantation of normal myoblasts has been considered a potential therapy for muscle dystrophies. While survival of implanted cells has been described in animal experiments and in human trials, functional effects remained unclear. Here we report on survival of progenors of implanted C2nlsBAG cells in regenerating muscles but irreversible net loss in muscle tissue and contractile force. This is caused by immune rejection of implanted myoblasts despite MHC-compatibility and "bystander" damage of host muscle tissue.

Functional effects of myoblast implantation into histoincompatible mice with or without immunosuppression

1. The goals of this study were to evaluate the immunogenicity of myogenic cells (MCs) (1) immediately after implantation into regenerating muscles, and (2) following their maturation under initial immunosuppression. Implanted mouse soleus muscles were evaluated by isometric tension recordings in vitro followed by histological investigations on frozen sections. 2. Implantation of non-histocompatible myoblasts into cryodamaged soleus muscles of CBA/J mice induced immune rejection which caused large and permanent deficits in muscle force: 4-42 weeks postimplantation maximal tetanic tension was 50-60% that of intact or regenerated cryodamaged control muscles without tendency for recovery or histological signs of muscle regeneration. Specific tension (force per unit muscle weight) was also significantly reduced. 3. On frozen sections, only 62 +/- 12% of the total area was desmin-positive, that is, occupied by muscle fibres, versus 90 +/- 4% in regenerated and 92 +/- 3% in intact muscles. Also, the total number of muscle fibre profiles was significantly reduced. 4. Under immune suppression with cyclosporin A (CsA), large muscles developed within 4 weeks. Following CsA withdrawal, muscle weight and force, in addition to desmin-positive areas on cross-sections, gradually declined over several months despite continual regeneration, indicating retarded immune rejection. 5. Initial application of CsA for 8 weeks after implantation, instead of 4 weeks, did not result in better survival of the implants, nor did a higher initial dose of CsA (100 instead of 50 mg kg-1 day-1). Prolonged continuous application of a reduced dose (25 mg kg-1 day-1) did not prevent muscle wasting but caused an additional delay. 6. It is concluded that histoincompatible myoblasts are highly immunogenic and that immune rejection causes large and permanent muscle deficits indicating elimination of host muscle tissue. Initial transient immunosuppression protects the incompatible cells, but after withdrawal, prolonged immune rejection and retarded muscle wasting occur.

Cellular and molecular reactions in mouse muscles after myoblast implantation

Implantation of skeletal muscle precursor cells is a potential means of cell-mediated gene therapy. One unresolved question is the degree of immunogenicity of such myoblasts. We designed the extreme situation of implanting cells of a non-histocompatible myoblast cell line into cryodamaged, but regeneration-capable, muscles of adult mice. Without immunosuppression donor cells are rejected within the first weeks. Immunosuppression with Cyclosporin A prevented invasion of T-lymphocytes and allowed differentiation of implanted myoblasts into myofibres as well as down-regulation of MHC expression. Still, withdrawal of Cyclosporin A after 4 weeks triggered lymphocyte invasion and cytotoxic cell reactions with rejection of donor tissue. Although the vast majority of muscle fibres was MHC-negative 1-4 days after Cyclosporin A withdrawal, single small desmin-positive profiles were weakly positive for donor MHC. Parallel with the increase in the number of lymphocytes, larger numbers of small and large muscle fibres expressed high levels of either donor, host or both, class I--but not class II--molecules. Surprisingly, immune reactions continued over several months, causing gradual loss of muscle tissue. Donor class I molecules persisted for more than 6 months after Cyclosporin A withdrawal, clearly indicating survival of donor muscle fibres despite ongoing rejection. Indirect evidence on the other hand suggests additional loss of host fibres, possibly caused by cytokine release from the immune cells (bystander damage). We conclude that transient treatment with Cyclosporin A induced a kind of tolerance related to the maturation and down-regulation of class I antigens in donor muscle fibres. It is suggested that the start of immune reaction following Cyclosporin A withdrawal is initiated by remaining small amounts of donor MHC molecules, possibly related to the continuous proliferation of the cell-lined-derived donor myoblasts.

Polyclonal antibodies against NCAM and tenascin delay endplate reinnervation

Experiments were performed to block molecules with antibodies which are upregulated in nerve and muscle following denervation. The delay in endplate reinnervation was taken as a measure for their involvement in regeneration. Gluteus maximus muscles of 86 male CBA/J mice were hemidenervated by freezing the caudal gluteal nerve at a defined position. The degree of reinnervation was evaluated in identified endplates by repeated vital staining of ACh receptors with rhodaminated alpha-bungarotoxin and of axons with 4Di-2ASP. Normally, endplates were completely reinnervated by 13-14 days (108 endplates in seven muscles). After daily application of polyclonal antibodies against NCAM or tenascin, reinnervation was significantly delayed. Preimmune serum, rabbit immunoglobulins or saline did not show this effect. Several monoclonal antibodies against NCAM (H-28) and tenascin (576, 578, 630, 633) showed a tendency but no significant effect. It is concluded that both NCAM and tenascin, upregulated after denervation, are involved in axon guidance and/or endplate reinnervation.

Expression pattern of M-cadherin in normal, denervated, and regenerating mouse muscles

Following muscle damage in adult vertebrates, myofibers can be regenerated from muscle precursor cells (satellite cells). During this process, prenatal myogenesis is recapitulated to a large extent, both morphologically and molecularly. A putative morphoregulatory molecule involved in myogenesis is M-cadherin (Mcad), a calcium-dependent cell adhesion protein. The expression of Mcad was studied by immunofluorescence in regenerating, denervated, and normal mouse muscles. Our results demonstrate that Mcad is present in satellite cells in normal muscle. Enhanced staining at sites of contact between satellite cells and the parent muscle fiber suggests an additional, spatially restricted expression of Mcad in muscle fibers. Mcad positive cells in normal and denervated muscles did not incorporate bromodeoxyuridine within 24 hr after injection in vivo, indicating that Mcad is expressed on mitotically quiescent satellite cells. Neural cell adhesion molecule (NCAM) co-localized with Mcad in nearly all satellite cells in denervated muscles but rarely in intact muscles. At early stages of regeneration, Mcad was exclusively and strongly expressed in myoblasts. After fusion of myoblasts into myotubes, Mcad was down-regulated and was barely detectable on more mature myotubes surrounded by distinct basal lamina sheaths. These observations are in line with the idea that Mcad plays a crucial role in myogenesis. In intact muscle, Mcad might function as a molecular link between satellite cell and muscle fiber.

Differential expression of tenascin after denervation, damage or paralysis of mouse soleus muscle

The expression of the extracellular matrix molecule tenascin was studied by immunocytochemistry and Western blotting in soleus muscles of adult mice after nerve damage (denervation), muscle injury (induced by enforced running or freezing) and functional block of synaptic transmission (botulinum toxin). Enhanced expression of tenascin in the extracellular spaces around focally damaged muscle fibres was found already 10 h after onset of running on a motor-driven treadmill which causes muscle injury in soleus muscle. Tenascin expression reached a peak at 2-3 days post-exercise, after which it declined gradually and became undetectable by two weeks after injury. Similarly, cryo-damage of soleus muscles in situ led to upregulation of tenascin. Chronic muscle denervation after sciatic nerve transection caused a persistent (studied up to 31 days) expression of tenascin at denervated endplates and in intramuscular nerve branches but not in other tissue compartments. Local application of botulinum toxin Type A, which results in muscle inactivity but not in tissue degeneration, however, did not induce tenascin expression 12 h to 12 days post-injection. Expression of tenascin after denervation and muscle damage, but its absence after paralysis, were verified by SDS-PAGE and Western blot analysis. Independent of the type of injury (muscle, nerve or both) the known major isoforms of mouse tenascin, as judged by M(r) comparison, were re-expressed, with no preponderance of individual M(r) forms. These results show that tenascin expression in adult muscles is induced by both axon and muscle fibre damage but not by muscle inactivity. In contrast, NCAM, in accordance with previous observations, showed enhanced expression both as a result of inactivity and in association with tissue repair.

Formation of new muscle fibres and tumours after injection of cultured myogenic cells

We examined the effects of implantation of cultured myogenic cells from a permanent cell line into soleus muscles of histocompatible adult mice. Myogenic cells (10(6) or 10(4)) were implanted into intact muscles, muscles frozen with liquid nitrogen, paralysed with botulinum toxin or reinnervated after long-term (seven months) denervation. Formation of numerous muscle fibres in myogenic cell-injected muscles raised the total number of fibres up to ten times above control by four weeks. Larger effects were found in freeze-damaged than in paralysed muscles. The new fibres had small calibers, considerable length (greater than 1.3 mm, maximum distance over which serial sections were made), were multinucleated and were oriented parallel to the large-diameter fibres of the host muscles. In some experiments beta-galactosidase, introduced into myogenic cells via retroviral transfection, was detected in small and large muscle fibres 4-20 weeks after implantation, indicating survival of the grafted cells and formation of mosaic (host-donor) and new fibres of donor origin. Muscle weight increased significantly and, rather surprisingly, a parallel increase was found in isometric tetanic tension of isolated nerve-muscle preparations; thus tension per mg muscle tissue was not different from normal. By eight weeks reduction of acetylcholine sensitivity and down-regulation of neural cell adhesion molecule to normal were observed, indicating that synaptic transmission at the new fibres was mature. After different periods of time (5-20 weeks, depending on the subclone used) tumours developed in most but not all injected limbs (37 out of 39). The tumours were destructive to the muscles and were classified as rhabdomyosarcomas. Prior to tumour formation, neural cell adhesion molecule positive cells reappeared in the muscles; since the myogenic cells initially produced differentiated muscle fibres, it appears that malignant growth is induced by factors in vivo. Thus, at present the outcome of such implantation is unpredictable.

Axonal sprouting and changes in fibre types after running-induced muscle damage

We have recently observed increase in Type I fibres in mouse soleus--but not extensor digitorum longus--muscles as a result of repeated muscle damage induced by voluntary wheel running. The most likely mechanism underlying the changes in fibre type composition is a redistribution of motor units with axonal sprouting and formation of new synapses. To test this hypothesis we exercised mice on a motor-driven treadmill once (3 x 3 h with 30 min rest periods in between, 14 m min-1, slope 6 degrees) or repeatedly (8-10 times at intervals of 3-5 days) and quantified axonal sprouting after staining with zinc iodide-osmium. In the contralateral solei, muscle damage and fibre type changes were evaluated with standard histochemical techniques. Significant numbers of damaged muscle fibers were found 0-15 days after a single exercise as compared to unexercised control animals (range 0.0-0.3% of the fibres in sedentary, n = 5, vs 2.1-14.8% in exercised muscles, n = 10) and repeated damage occurred in repeatedly exercised animals. In muscles of sedentary animals 3.8 +/- 1.4% SD of the examined endplates (n = 880, 5 muscles) had nodal or terminal sprouts. The incidence of sprouting was significantly elevated 3-21 days after a single exercise (7.5 +/- 1.8%, n = 2855, 12 muscles, P less than 0.01 signed-rank test), and more so after repeated running (12.0 +/- 2.5%, n = 1505, 6 muscles, P less than 0.01). Fibre type distributions were not different from controls 3 weeks after a single running episode, but after the 6-7 weeks of repeated running a significant increase in undifferentiated fibres at the cost of Type II fibres was found (9.7 +/- 3.4% versus 1.0 +/- 0.5% in sedentary controls, P less than 0.05, t-test); undifferentiated fibres express both Type I and Type II myofibrillar ATPase and are considered as fibres in the process of changing their types. These observations strongly support the assumption that sprouting and formation of new synapses--followed by motor unit enlargement and redistribution--occur as a result of muscle damage.

Effects of enhanced activity on synaptic transmission in mouse extensor digitorum longus muscle

1. Transmitter release at neuromuscular junctions of extensor digitorum longus (EDL) muscle in mice was studied after 2-8 month periods of unforced running in wheels. 2. Intracellular recordings at 10 Hz stimulation revealed that the quantal content of endplate potentials (EPPs) in Mg(2+)-blocked preparations was larger by 30% in trained (mean number of quanta, m = 1.75 +/- 0.19, n = 7) than in untrained control EDL muscles (m = 1.35 +/- 0.35, n = 7). Similarly the amplitudes of the first, maximum and plateau EPPs during tetanic stimulation (100 Hz for 1 s or 400 ms) in curare-blocked preparations were increased by 28% each; muscle fibre diameters did not differ while other postsynaptic effects were not excluded. 3. Training effects became particularly evident in two pairs of monozygotic twins, in which the time courses of facilitation and depression were changed as well: at 100 Hz stimulation the maximum EPP amplitude was reached on average at 2.6 impulses in controls but at 2.0 impulses in runners, and the following decline below the value of the first EPP at 5.0 and 3.8 impulses respectively. 4. Block resistance, as monitored by isometric tension measurements in different presynaptic (Mg2+) and postsynaptic (curare) blocking solutions, was higher in trained than in control EDL muscles. Depression in a train of four nerve-evoked single twitches at 2 Hz was lower. 5. As expected from the unchanged fibre diameters (see above) isometric tetanic force was similar in trained and control EDL muscles. Muscle fatigue resistance was larger in trained animals and succinic dehydrogenase activity was higher in fibres of trained muscles indicating an endurance training of the EDL muscle. 6. It is concluded that besides changes in muscle fibre properties, prolonged elevated activity causes increased transmitter release in EDL muscles. As a consequence, the safety margin of transmission in trained EDL muscles is markedly elevated.

Effects on recovery of soleus and extensor digitorum longus muscles of prolonged wheel running during a period of repeated nerve damage

The right sciatic nerve in NMRI mice was frozen under anaesthesia 13 times at three-week intervals for a total period of 8.5 months. During this period, but not afterwards, one sub-group of these mice had access to running wheels in which the animals ran several kilometres per night, thereby actively or passively training reinnervated or denervated leg muscles, as well as the intact contralateral muscles. A number of distinct effects persisted for as long as 14-18 weeks after the termination of this "endurance training". In reinnervated soleus muscle, tetanic force was significantly higher (37%) in the trained muscles as was muscle weight (36%); in general, negative effects of the nerve damage persisted. In the reinnervated extensor digitorum longus, tetanic force and muscle weight were significantly smaller in the trained animals (by 11 and 16%, respectively) which are considered typical effects of endurance training. The resistance of the soleus neuromuscular junction to block by both curare and Mg2+ was depressed on the damaged side but this property was not influenced by the training; in extensor digitorum longus the pattern was similar. It is concluded that training during the period of repeated cycles of denervation-reinnervation produced significant effects which impressively outlasted the training period. The possible nature of these effects is discussed.

Muscle injury, cross-sectional area and fibre type distribution in mouse soleus after intermittent wheel-running

1. It was previously noticed that mouse soleus, but not extensor digitorum longus (EDL) muscles, suffer fibre damage at the onset of voluntary wheel-running without further injuries thereafter. 2. In CBA/J mice trained continuously for 5 months and rested for periods of 1, 2, 3, 4 and 5 weeks acute muscle damage was found in soleus 7 days after the resumption of wheel-running. On single cross-sections damage was present on average in 8.7 +/- 3.5% (mean +/- S.D., n = 15) of the fibres, but only in 0.47 +/- 0.21% (n = 9) and 1.3 +/- 1.1% (n = 4) in control animals rested for 0-6 weeks after continuous running or in untrained controls. 3. Repeated muscle damage occurred when mice exercised for 4 days at intervals of 21-25 days, and after thirteen running episodes within 12 months marked changes in soleus, but not EDL muscles, were present. In cross-sections the total number of muscle fibre profiles was significantly larger in soleus of intermittent runners (768 +/- 68, n = 6; P less than 0.05), compared to continuous runners (676 +/- 54, n = 3) and sedentary animals (683 +/- 33, n = 4). This is probably due to incomplete repair which results in 'split fibres'. 4. At the same time total muscle fibre cross-sectional area was significantly elevated in intermittent runners (P less than 0.05), mainly due to increase in fibre diameters. Net cross-sectional areas were 0.59 +/- 0.069 mm2 (n = 6) in intermittent, 0.53 +/- 0.076 mm2 (n = 3) in continuous runners and 0.46 +/- 0.031 mm2 (n = 3) in sedentary controls. 5. Tetanic and twitch force were also significantly elevated in soleus of intermittent runners while the ratio force/area remained the same. 6. There was an increase in the proportion of type I fibres in soleus from 75 +/- 0.9% (n = 4) in untrained controls to 90 +/- 4.4% (n = 6; P less than 0.05) in intermittent runners and 81 +/- 5.6% (n = 3; n.s.) in continuous runners. 7. Resistance to block of synaptic transmission in soleus was significantly higher in intermittent runners for two levels of curare, indicating enhanced safety margins. 8. EDL muscles in intermittent runners were not different from sedentary controls in any of the parameters studied. In particular, muscle fibres with signs of previous damage (split fibres, central nuclei) were rare (on average 0.5-0.6%) and equally frequent in all experimental groups.(ABSTRACT TRUNCATED AT 400 WORDS)

Reinnervation and recovery of mouse soleus muscle after long-term denervation

Reinnervation and recovery of the mouse soleus muscle were studied 2-10 months after denervation periods of about 7 months. To maintain denervation the right sciatic nerve was frozen 14 times at 2-week intervals. Though initially intermittent muscle reinnervation occurred, contractile force of denervated muscles was reduced to less than 10% of the contralateral muscles by the fifth nerve freezing and further declined thereafter. Following reinnervation, recovery of soleus muscle force proceeded slowly to reach plateau values after 5-6 months. Tetanic muscle force reached on average 72% (range 58-86%, n = 12) of contralateral muscles after 5-10 months, (P less than 0.01, t-test for absolute values) and 87% of unoperated animals after 10 months (P less than 0.05, n = 5). Muscle fibre diameters were significantly reduced in reinnervated muscles, but frequency distributions were normal and similarly shaped in reinnervated and control muscles, suggesting complete muscle reinnervation and the absence of denervated fibres even at 2 months of reinnervation. Total numbers of muscle fibres were similar in reinnervated (842 +/- 73 S.D., n = 15), contralateral (854 +/- 104 S.D., n = 15) and control soleus muscles (853 +/- 77 S.D., n = 5). The number of myelinated axons in regenerating soleus nerves reached control values by 3 months after the last freezing, continued to increase till 6 months (150% of control), and declined thereafter (125% at 9-10 months). In the contralateral soleus nerves the number of myelinated axons remained constant during this period. Nerve fibre diameters remained abnormally small; even after 10 months of reinnervation fibre diameters were unimodally distributed with a mean diameter of 3.3 microns in contrast to the bimodal distribution in intact nerves (mean values 3.9 and 9.0 microns, respectively). Total fibre cross-section area per nerve increased with time but reached only 54% +/- 6 S.D., (n = 3) of contralateral nerves by 10 months. The relative thickness of the myelin sheath (g-ratio) returned to normal after 9-10 months. Anatomically, muscle reinnervation appeared to be complete by 7-8 weeks since unusually small muscle fibre profiles were absent.(ABSTRACT TRUNCATED AT 400 WORDS)

Prolonged running does not improve muscle coordination after cross-union of tibial and peroneal nerves in mice

Several months after cross-union of the tibial and peroneal nerves and full muscle reinnervation motor behavior was monitored and was tested by electromyographic recordings from both musculus tibialis anterior (TA) and musculus gastrocnemius medialis (MG). In addition spinal motoneuron pools were labelled by injecting wheat-germ agglutinin-horseradish peroxidase (WGA-HRP) into experimental and control TA muscles. Though the location of TA motoneurons was similar in all 9 mice tested and suggested successful cross-reinnervation, running behavior and EMG patterns varied remarkably. In some animals the alternating activities of TA and MG muscles remained more or less clearly separated from each other but were out of phase with the running cycle. A somewhat better motor behavior was accompanied by simultaneous activity in both muscles. Voluntary running in wheels for several kilometers per day did not visibly improve motor coordination indicating the absence of activity-related synaptic readjustments.

Muscle damage and repair in voluntarily running mice: strain and muscle differences

Soleus, extensor digitorum longus and tibialis anterior muscles of mice voluntarily running in wheels for periods of 5 to 120 days were studied in spaced serial and serial cross-sections. Shortly after the onset of running and during the next 2 weeks, degeneration, necrosis, phagocytosis and regeneration of muscle fibers, satellite cell proliferation and cellular infiltration were found in soleus muscles of mice from all strains investigated (CBA/J, NMRI, C57bl, NIH, SWS and Balb/c). Tibialis anterior but not extensor digitorum longus muscles were also damaged. Predominantly high-oxidative fibers were affected (both slow-oxidative and fast oxidative glycolytic in soleus, fast-oxidative glycolytic in tibialis anterior). Denervated soleus muscles that had been passively stretched during running were not damaged. Evidence was found that, during the early period of running, split fibers form by myogenesis within (regeneration) or outside (satellite cell proliferation) necrotic muscle fiber segments. Split fibers persisted in solei of long-term (2 to 3 months) exercised CBA/J but not NMRI mice. In 6 out of 20 solei of CBA/J runners exercised for 2 months or longer, fiber-type grouping was observed in the areas where extensive damage usually occurred in the early periods. The results show that different muscles are damaged and repaired to varying degrees and that marked interstrain and inter-individual differences are present. It appears that acute muscle injury occurring upon onset of voluntary running is a usual event in the adaptation of muscles to altered use.