Appearance of contractile activity in muscular dysgenesis (mdgmdg) mouse myotubes during coculture with normal spinal cord cells

Muscular dysgenesis (mdg) in the mouse is an autosomal recessive mutation expressed in the homozygous mutant as lack of skeletal muscle contraction. To test the ability of normal neurons to form neuromuscular contacts with, and/or possibly induce contractions in $\text{mdg}\text{mdg}$ muscle, dispersed cell cultures of normal and dysgenic muscle from newborn mice were cocultured with normal embryonic rat, mouse, and chick dissociated spinal cord cells. Contraction was induced in $\text{mdg}\text{mdg}$ muscle 1 to 10 days (depending upon the species of the neuronal source) following establishment of the cocultures. Control experiments indicated that the dispersed spinal cord preparations were free of myoblasts capable of fusing with $\text{mdg}\text{mdg}$ muscle. The establishment of neuromuscular contacts in the rat neuron cocultures was monitored by cytochemical staining of acetylcholinesterase (AChE), autoradiography of ¹²⁵I-α-bungarotoxin-bound acetylcholine receptors (AChR), and electrophysiological study of muscle membrane activity. Patches of high AChE activity were similar in size and distribution to high-density clusters of AChR on both control and $\text{mdg}\text{mdg}$ myotubes cocultured with rat neurons. The resting membrane potentials of normal myotubes and those of $\text{mdg}\text{mdg}$ myotubes in the presence of neurons were similar (? ?52 mV). The mepp frequency and the mepp amplitude distribution were the same for both control and mutant cocultured muscle. Thus, normal rat spinal cord neurons were capable of forming normal, functional neuromuscular junctions with $\text{mdg}\text{mdg}$ myotubes, and contractions were induced under coculture conditions, in otherwise noncontracting mutant muscle.     

DNA synthesis, mitosis and fusion of myocardial cells

Myocardial cells obtained from embryonic chick ventricles have been used to investigate (1) whether differentiated cells can undergo DNA synthesis and mitosis and, (2) whether heart cells when grown in culture can fuse with each other and with chick skeletal myoblasts to form heterokaryon myotubes. Electron microscopic observations have shown that myocardial cells of day 3 and day 20 chick embryos did contain myofibrils with defined sarcomeres; these cells have been observed in mitosis. Cells obtained by tryptic digestion of day 12 chick ventricles when grown in culture continued to replicate their DNA as shown by thymidine-³H radioautography with DNase controls and were observed in all stages of mitosis. Electron microscopy showed that myofibrils were present in some of the cultured cells. Bi-, tri- and tetranucleate cells were observed in the cultures. Thymidine-³H radioautography showed that these cells were formed by karyokinesis without cytokinesis and by the fusion of uninucleate cells. Since the heart cells could fuse with each other, we tested the possibility that they could fuse with skeletal myoblasts to form heterokaryon myotubes. This was accomplished by co-culturing thymidine-³H labeled ventricular cells and unlabeled skeletal myoblasts. Radioautography with DNase controls showed that some of the myotubes consisted of unlabeled skeletal muscle nuclei and labeled heart nuclei in varied proportions. The factors initiating the formation of these heterokaryons have not been elucidated.     

Laminin α4 and Integrin α6 Are Upregulated in Regenerating dy/dy Skeletal Muscle: Comparative Expression of Laminin and Integrin Isoforms in Muscles Regenerating after Crush Injury

The expression of laminin isoforms and laminin-binding integrin receptors known to occur in muscle was investigated during myogenic regeneration after crush injury. Comparisons were made between dystrophic 129ReJ dy/dy mice, which have reduced laminin α2 expression, and their normal littermates. The overall histological pattern of regeneration after crush injury was similar in dy/dy and control muscle, but proceeded faster in dy/dy mice. In vitro studies revealed a greater yield of mononuclear cells extracted from dy/dy muscle and a reduced proportion of desmin-positive cells upon in vitro cultivation, reflecting the presence of inflammatory cells and “preactivated” myoblasts due to ongoing regenerative processes within the endogenous dystrophic lesions. Laminin α1 was not detectable in skeletal muscle. Laminin α2 was present in basement membranes of mature myofibers and newly formed myotubes in control and dy/dy muscles, albeit weaker in dy/dy. Laminin α2-negative myogenic cells were detected in dy/dy and control muscle, suggesting the involvement of other laminin α chains in early myogenic differentiation, such as laminin α4 and α5 which were both transiently expressed in basement membranes of newly formed myotubes of dy/dy and control mice. Integrin β1 was expressed on endothelial cells, muscle fibers, and peripheral nerves in uninjured muscle and broadened after crush injury to the interstitium where it occurred on myogenic and nonmyogenic cells. Integrin α3 was not expressed in uninjured or regenerating muscle, while integrin α6 was expressed mainly on endothelial cells and peripheral nerves in uninjured muscle. Upon crush injury integrin α6 increased in the interstitium mainly on nonmyogenic cells, including infiltrating leukocytes, endothelial cells, and fibroblasts. In dy/dy muscle, integrin α6 occurred on some newly formed myotubes. Integrin α7 was expressed on muscle fibers at the myotendinous junction and showed weak and irregular expression on muscle fibers. After crush injury, integrin α7 expression extended to the newly formed myotubes and some myoblasts. However, many myoblasts and newly formed myotubes were integrin α7 negative. No marked difference was observed in integrin α7 expression between dy/dy and control muscle, either uninjured or after crush injury. Only laminin α4 and integrin α6 expression patterns were notably different between dy/dy and control muscle. Expression of both molecules was more extensive in dy/dy muscle, especially in the interstitium of regenerating areas and on newly formed myotubes. In view of the faster myogenic regeneration observed in dy/dy mice, the data suggest that laminin α4 and integrin α6 support myogenic regeneration. However, whether these accelerated myogenic effects are a direct consequence of the reduced laminin α2 expression in dy/dy mice, or an accentuation of the ongoing regenerative events in focal lesions in the muscle, requires further investigation.     

Transient neonatal denervation alters the proliferative capacity of myosatellite cells in dystrophic (129ReJdy/dy) muscle

It has been previously shown that transiently denervated, neonatal dystrophic muscle fails to undergo the degeneration–regeneration cycle characteristic of murine dystrophy (Moschella and Ontell, 1987). Thus, the myosatellite cells (myogenic stem cells) in these muscles have been spared the mitotic challenge to which dystrophic myosatellite cells are normally subjected early in the time course of the disease. By in vitro evaluation of the proliferative capacity of myosatellite cells derived from extensor digitorum longus (EDL) muscles of 100-day-old genetically normal (+/+) and genetically dystrophic [dy/dy (129ReJ^dy/dy)] mice and from muscles of age-matched mice that had been neonatally denervated (by sciaticotomy) and allowed to reinnervate, it has been possible to directly determine whether the cessation of spontaneous regeneration in older dy/dy muscles in vivo, is due to an innate defect in the proliferative capacity of the myosatellite cells or exhaustion of the myosatellite cells' mitotic activity during the regenerative phase of the disease. This study demonstrates that transient neonatal denervation of dystrophic muscle (Den.dy/dy) increases the number of muscle colony-forming cells (MCFs) permilligram of wet weight muscle tissue, increases the plating efficiency, and significantly increases the in vitro mitotic activity of dystrophic myosatellite cells toward normal values. The increased mitotic capability of myosatellite cells derived from Den.dy/dy muscle as compared to unoperated dy/dy muscle suggests that there is no innate defect in the proliferative capacity of the myosatellite cells of dy/dy muscles and that the cessation of spontaneous regeneration in the dy/dy muscles is related to the exhaustion of their myosatellite cells' mitotic capability. © 1992 John Wiley & Sons, Inc.     

Development of normal and genetically dystrophic mouse muscle in tissue culture : I. Prefusion and fusion activities of muscle cells: Phase contrast and time lapse study

Dispersed cell cultures, derived from the forelimbs and hindlimbs of genetically dystrophic (dy/dy) and normal (+/+) day mouse embryos were studied with phase contrast microscopy and time lapse cinematography. The composition of the cell populations, and the prefusion and fusion activities of the cells were analysed. Forelimbs of both normal and dystrophic embryos consistently yielded fewer mononucleated cells, more fat cells and fewer myoblasts than hindlimbs, but there was no difference in the population of cells from normal and dystrophic limbs. During prefusion, myoblasts (both normal and dystrophic) exhibited (1) an apparent lack of contact inhibition of locomotion, which was in actuality an extensive movement of one myoblast under another; (2) formation of prefusion aggregates that broke up and realigned into new aggregates before fusion; (3) a special type of post-mitotic association and reassociation, not found among fibroblasts. Onset of rapid cell fusion of myoblasts occurred in a 4 to 8 h period, and was directly dependent upon initial cell concentration. No differences were found between cultures of normal and dystrophic cells in their prefusion activities or in time of onset of rapid cell fusion, when initial concentrations of cells were kept constant. The results of the present study are compared with those of other in vitro studies of dystrophic muscle.     

Intracellular protein degradation in cultures of dystrophic muscle cells and fibroblasts

We have analysed protein degradation in primary cultures of normal and dystrophic chick muscle, in fibroblasts derived from normal and dystrophic chicks, and in human skin fibroblasts from normal donors and from patients with Duchenne muscular dystrophy (DMD). Our results indicate that degradative rates of both short- and long-lived proteins are unaltered in dystrophic muscle cells and in dystrophic fibroblasts. Longer times in culture and co-culturing chick fibroblasts with the chick myotubes do not expose any dystrophy-related abnormalities in protein catabolism. Furthermore, normal and dystrophic muscle cells and fibroblasts are equally able to regulate proteolysis in response to serum and insulin. We conclude that cultures of chick myotubes, chick fibroblasts, and fibroblasts derived from humans afflicted with DMD are not appropriate models for studying the enhanced protein degradation observed in dystrophy.     

DNA synthesis and the cell cycle in cultures of normal and mutant (mdg/mdg) embryonic mouse muscle cells.

The relationship between cell fusion, DNA synthesis and the cell cycle in cultured embryonic normal and dysgenic ($\text{mdg}\text{mdg}$) mouse muscle cells has been determined by autoradiography. The experimental evidence shows that the homozygous mutant myotubes form by a process of cell fusion and that nuclei within the myotubes do not synthesize DNA or undergo mitotic or amitotic division. The duration of the total cell cycle and its component phases was statistically the same in 2-day normal and mutant ($\text{mdg}\text{mdg}$) myogenic cultures with the approximate values: T, 21.5 hr; G₁, 10.5 hr; S, 7.5 hr; and G₂, 2.5 hr. In both kinds of cultures, labeled nuclei appeared in myotubes 15–16 hr after mononucleated cells were exposed to [³H]thymidine, and the rate of incorporation of labeled nuclei into multinucleated muscle cells was comparable in control and dysgenic cultures. Thus, homozygous $\text{mdg}\text{mdg}$ muscle cells in culture are similar to control cells with respect to their mechanism of myotube formation and the coordinate regulation of DNA synthesis and the cell cycle during myogenesis.     

Centrioles are lost as embryonic myoblasts fuse into myotubes in vitro

Embryonic chick myoblasts possess an extensive network of cytoplasmic microtubules which emanate from a single, perinuclear centrosome containing a microtubule-organizing center (MTOC) and the centrioles. However, after myoblasts fuse into myotubes the centrosome is no longer apparent, and instead long parallel arrays of microtubules are seen. From ultrastructural studies on developing muscle tissue, it has been proposed that centrioles are present in myoblasts but are absent from fused muscle fibers. We have examined this hypothesis in vitro in cultures of chick embryonic muscle cells using sera which specifically label centrioles. Almost all (90-97%) mononucleated cells in these cultures, including myoblasts aligned just prior to fusion, contain a pair of centrioles in close proximity to the nucleus. However, in newly fused multinucleated myotubes as well as in older myotubes that had developed myofibrils, centrioles were rarely found (1-10% positive cells). This study thus provides direct evidence for a loss of centrioles from muscle cells soon after they fuse to form myotubes.     

Genetic and physiological evidence concerning the development of chemically sensitive voltage-dependent ionophores in L6 cells

The electrophysiological properties of a tissue culture muscle line, L₆, and a K⁺ resistant mutant (MK₁) derived from L₆ were determined to elucidate certain aspects of membrane differentiation and function. MK₁ was selected as a clone of myoblasts resistant to the toxic effects of 55 mM K⁺. The resting potentials of L₆ and MK₁ myoblasts and myotubes were K⁺ dependent and equal. The amplitudes of the action potentials were equal in normal medium, but 27.7 mM K⁺ interfered with or eliminated the ability of L₆ myotubes to produce action potentials. MK₁ myotubes produced nearly normal action potentials under these conditions. Thus, the K⁺ resistant myoblasts differentiate into myotubes which have an action potential generating mechanism much less sensitive to K⁺ than the normal mechanism. Also, both d-tubocurarine and α-bungarotoxin enhance the amplitude of the action potentials produced by L₆ myotubes in the presence of 27.7 mM K⁺; these compounds do not enhance the amplitude of the action potentials produced by MK₁ myotubes under the same conditions. It is proposed that as a consequence of differentiation a type of ionophore present in myoblasts becomes a voltage-dependent ionophore in myotubes. Furthermore, these voltage-dependent ionophores can be chemically sensitive.     

Isolation and purification of myotube and myoblast nuclei from cultures of embryonic chick skeletal muscle.

Methods are described for the preparation of purified myotubes from embryonic chick skeletal muscle cultures and the preparation of purified nuclei from both myotubes and myoblasts. Myotubes are released from the culture dish by digestion of their collagen substratum with collagenase, and purified by sucrose density gradient sedimentation. Nuclei are prepared from the isolated myotubes by controlled homogenization in Ca²⁺-free medium and sedimentation through 2.1 M sucrose. Nuclei are prepared from cultured myoblasts in a similar fashion, with the inclusion of the non-ionic detergent NP-40 in the homogenization medium and sedimentation through 2.4 M sucrose. Phase contrast microscopic examination showed that the nuclear preparations are free of visible cytoplasmic contamination, and are morphologically similar to nuclei observed in situ. Biochemical assays (protein/DNA and $\text{RNA}\text{DNA}$ ratios) confirm the purity of the nuclear preparations. Both nuclear preparations have been used to prepare purified chromatin which has spectral and chemical properties similar to those reported for chromatin purified directly from several chick tissues.     

Difference in the expression of asymmetric acetylcholinesterase molecular forms during myogenesis in early avian dermomyotomes and limb buds in ovo and in vitro

The A12 (asymmetric) form of acetylcholinesterase (AChE) is generally considered to be synthesized in leg muscle tissues by myotubes under neural influence, but not by myoblasts. We have examined the expression of the different molecular forms of AChE in explants of developing limb buds and dermomyotomes (the myogenic part of the somites) obtained from 3-day-old chick and quail embryos, either directly after removal or during in vitro culture. We describe a muscular differentiation of both territories in vitro, leading to the formation of myotubes which are morphologically similar to the class of early muscle cells described by Bonner and Hauschka (1974). In vivo the A12 form is present in quail dermomyotomes which are almost entirely composed of mononucleated poorly differentiated cells; in contrast, it is absent from similar cells in chick dermomyotomes and from limb buds in both species. This shows that in the case of quail embryos the appearance of the A12 form precedes the fusion of myoblasts into myotubes. In both species, dermomyotome explants express asymmetric and globular forms of the enzyme during muscular differentiation in vitro, whereas limb buds synthesize only globular forms. After surgical removal of neural tube and/or neural crest at 2 days in ovo, the biosynthesis of the A forms in quail dermomyotomes is not suppressed and is consequently not dependent upon prior connection of the dermomyotomes to central neurons or upon the presence of autonomic precursors. Since limb bud muscle cells derive from somites our results raise questions concerning the differentiation of migrating somitic cells in this territory where a neural influence appears necessary to induce the biosynthesis of asymmetric AChE forms.     

Myoblast differentiation in vitro: morphological differentiation of mononucleated myoblasts.

Phospholipase C from Clostridium perfringens has been shown previously to inhibit the fusion of cultured chick myoblasts without affecting recognition or cell cycle parameters. In this paper we report that the mononucleated myoblasts, in phospholipase C, synthesize thick and thin filaments and organize them into myofibrils, and that T-tubules and sarcoplasmic reticulum differentiate and join in morphologically typical junctions. The structurally differentiated myoblasts can then fuse with one another to form myotubes. We conclude that cell fusion is not necessary for muscle differentiation.     

Normal myoblast fusion requires myoferlin

Muscle growth occurs during embryonic development and continues in adult life as regeneration. During embryonic muscle growth and regeneration in mature muscle, singly nucleated myoblasts fuse to each other to form myotubes. In muscle growth, singly nucleated myoblasts can also fuse to existing large, syncytial myofibers as a mechanism of increasing muscle mass without increasing myofiber number. Myoblast fusion requires the alignment and fusion of two apposed lipid bilayers. The repair of muscle plasma membrane disruptions also relies on the fusion of two apposed lipid bilayers. The protein dysferlin, the product of the Limb Girdle Muscular Dystrophy type 2 locus, has been shown to be necessary for efficient, calcium-sensitive, membrane resealing. We now show that the related protein myoferlin is highly expressed in myoblasts undergoing fusion, and is expressed at the site of myoblasts fusing to myotubes. Like dysferlin, we found that myoferlin binds phospholipids in a calcium-sensitive manner that requires the first C2A domain. We generated mice with a null allele of myoferlin. Myoferlin null myoblasts undergo initial fusion events, but they form large myotubes less efficiently in vitro, consistent with a defect in a later stage of myogenesis. In vivo, myoferlin null mice have smaller muscles than controls do, and myoferlin null muscle lacks large diameter myofibers. Additionally, myoferlin null muscle does not regenerate as well as wild-type muscle does, and instead displays a dystrophic phenotype. These data support a role for myoferlin in the maturation of myotubes and the formation of large myotubes that arise from the fusion of myoblasts to multinucleate myotubes.     

Differences in the Developmental Fate of Cultured and Noncultured Myoblasts When Transplanted into Embryonic Limbs

Myoblasts from embryonic, fetal, and adult quail and chick muscles were transplanted into limb buds of chick embryos to determine if myoblasts can form muscle fibers in heterochronic limbs and to define the conditions that affect the ability of transplanted cells to populate newly developing limb musculature. Myoblasts from each developmental stage were either freshly isolated and transplanted or were cultured prior to transplantation into limb buds of 4- to 5-day (ED4-5) chick embryos. Transplanted myoblasts, regardless of the age of the donor from which they were derived, formed muscle fibers within embryonic limb muscles. Transplanted cloned myoblasts formed muscle fibers, although there was little evidence that the number of transplanted myoblasts significantly increased following transplantation or that they migrated any distance from the site of injection. The fibers that formed from transplanted clonal myoblasts often did not persist in the host limb muscles until ED10. Diminished fiber formation from myoblasts transplanted into host limbs was observed whether myoblasts were cloned or cultured at high density. However, when freshly isolated myoblasts were transplanted, the fibers they formed were numerous, widely dispersed within the limb musculature, and persisted in the muscles until at least ED10. These results indicate that transplanted myoblasts of embryonic, fetal, and adult origin are capable of forming fibers during early limb muscle formation. They also indicate that even in an embryonic chick limb where proliferation of endogenous myoblasts and muscle fiber formation is rapidly progressing, myoblasts that are cultured in vitro do not substantially contribute to long-term muscle fiber formation after they are transplanted into developing limbs. However, when the same myoblasts are freshly isolated and transplanted without prior cell culture, substantial numbers of fibers form and persist after transplantation into developing limbs. Thus, these studies demonstrate that the extent to which transplanted myoblasts fuse to form fibers which persist in host musculature depends upon whether donor myoblasts are freshly isolated or maintained in vitro prior to injection.     

Immunological studies of the embryonic muscle cell surface. Antiserum to the prefusion myoblast

Xenogeneic antisera raised in rabbits have been used to detect compositional changes at the cell surfaces of differentiating embryonic chick skeletal muscle. In this report, we present the serological characterization of antiserum (Anti-M-24) against muscle tissue and developmental stage-specific cell surface antigens of the prefusion myoblast. Cells from primary cultures of 12-d-old embryonic chick hindlimb muscle were injected into rabbits, and the resulting antisera were selectively absorbed to obtain immunological specificity. Cytotoxicity and immunohistochemical assays were used to test this antiserum. Absorption with embryonic or adult chick heart, brain, retina, liver, erythrocytes, or skeletal muscle fibroblasts failed to remove all reactivity of Anti-M-24 for myogenic cells at all stages of development. After absorption with embryonic myotubes, however, Anti-M-24 no longer reacted with differentiated myofibers, but did react with prefusion myoblasts. The myoblast surface antigens detected with Anti-M-24 are components of the muscle cell membrane: (a) these macromolecules are free to diffuse laterally within the myoblast membrane; (b) Anti-M-24, in the presence of complement, induced lysis of the muscle cell membrane; and (c) intact monolayers of viable myoblasts completely absorbed reactivity of Anti-M-24 for myoblasts. These antigens are not loosely adsorbed culture medium components or an artifact of tissue culture because: (a) absorption of Anti-M-24 with homogenized embryonic muscle removed all antibodies to cultured myoblasts; (b) Anti-M-24 reacted with myoblast surfaces in vivo; and (c) absorption of Anti-M-24 with culture media did not affect the titer of this antiserum for myoblasts. We conclude that myogenic cells at all stages of development possess externally exposed antigens which are undetected on other embryonic and adult chick tissues. In addition, myoblasts exhibit surface antigenic determinants that are either masked, absent, or present in very low concentrations on skeletal muscle fibroblasts, embryonic myotubes, or adult myofibers. These antigens are free to diffuse laterally within the myoblast membrane and may be modulated in response to appropriate environmental cues during myodifferentiation.     

Roles for the integrin VLA-4 and its counter receptor VCAM-1 in myogenesis.

Mammalian myogenesis is biphasic: primary myoblasts fuse to form primary myotubes, then secondary myoblasts align along the primary myotubes and form secondary myotubes, which comprise most of adult muscle. We provide evidence that an integrin (VLA-4) and its counter receptor (VCAM-1) have a role in secondary myogenesis. Both receptors are synthesized by cultured muscle cells: VLA-4 is induced as myotubes form, whereas VCAM-1 is present on myoblasts and myotubes. In vivo, both molecules are expressed at sites of secondary myogenesis, VLA-4 on primary and secondary myotubes, and VCAM-1 on secondary myoblasts and on regions of secondary myotubes apposed to primary myotubes. These patterns suggest that VLA-4-VCAM-1 interactions influence alignment of secondary myoblasts along primary myotubes and/or the fusion of secondary myoblasts. In support of the latter possibility, antibodies to VLA-4 or VCAM-1 inhibit myotube formation in culture.     

Space shuttle flight (STS-45) of L8 myoblast cells results in the isolation of a nonfusing cell line variant

Myoblast cell cultures have been widely employed in conventional (1g) studies of biological processes because characteristics of intact muscle can be readily observed in these cultured cells. We decided to investigate the effects of spaceflight on muscle by utilizing a well characterized myoblast cell line (L8 rat myoblasts) as cultured in the recently designed Space Tissue Loss Flight Module “A” (STL-A). The STL-A is a “state of the art,” compact, fully contained, automated cell culture apparatus which replaces a single mid-deck locker on the Space Shuttle. The L8 cells were successfully flown in the STL-A on the Space Shuttle STS-45 mission. Upon return to earth, reculturing of these spaceflown L8 cells (L8SF) resulted in their unexpected failure to fuse and differentiate into myotubes. This inability of the L8SF cells to fuse was found to be a permanent phenotypic alteration. Scanning electron microscopic examination of L8SF cells growing at 1g on fibronectin-coated polypropylene fibers exhibited a strikingly different morphology as compared to control cells. In addition to their failure to fuse into myotubes, L8SF cells also piled up on top of each other. When assayed in fusion-promoting soft agar, L8SF cells gave rise to substantially more and larger colonies than did either preflight (L8AT) or ground control (L8GC) cells. All data to this point indicate that flying L8 rat myoblasts on the Space Shuttle for a duration of 7–10 d at subconfluent densities results in several permanent phenotypic alterations in these cells. © 1994 Wiley-Liss, Inc.     

Coordinated development of myofibrils, sarcoplasmic reticulum and transverse tubules in normal and dysgenic mouse skeletal muscle, in vivo and in vitro

We studied the development of transverse (T)-tubules and sarcoplasmic reticulum (SR) in relationship to myofibrillogenesis in normal and dysgenic (mdg/mdg) mouse skeletal muscle by immunofluorescent labeling of specific membrane and myofibrillar proteins. At E16 the development of the myofibrils and membranes in dysgenic and normal diaphragm was indistinguishable, including well developed myofibrils, a delicate network of T-tubules, and a prominent SR which was not yet cross-striated. In diaphragms of E18 dysgenic mice, both the number and size of muscle fibers and myofibrillar organization were deficient in comparison to normal diaphragms, as previously reported. T-tubule labeling was abnormal, showing only scattered tubules and fragments. However, many muscle fibers displayed cross striation of sarcomeric proteins and SR comparable to normal muscle. In cultured myotubes, cross-striated organization of sarcomeric proteins proceeded essentially in two stages: first around the Z-line and later in the A-band. Sarcomeric organization of the SR coincided with the first stage, while the appearance of T-tubules in the mature transverse orientation occurred infrequently, only after A-band maturation. In culture, myofibrillar and membrane organization was equivalent in normal and dysgenic muscle at the earlier stage of development, but half as many dysgenic myotubes reached the later stage as compared to normal. We conclude that the mdg mutation has little effect on the initial stage of membrane and myofibril development and that the deficiencies often seen at later stages result indirectly from the previously described absence of dihydropyridine receptor function in the mutant.     

Human multipotent adipose-derived stem cells restore dystrophin expression of Duchenne skeletal-muscle cells in vitro

Background information. DMD (Duchenne muscular dystrophy) is a devastating X‐linked disorder characterized by progressive muscle degeneration and weakness. The use of cell therapy for the repair of defective muscle is being pursued as a possible treatment for DMD. Mesenchymal stem cells have the potential to differentiate and display a myogenic phenotype in vitro. Since liposuctioned human fat is available in large quantities, it may be an ideal source of stem cells for therapeutic applications. ASCs (adipose‐derived stem cells) are able to restore dystrophin expression in the muscles of mdx (X‐linked muscular dystrophy) mice. However, the outcome when these cells interact with human dystrophic muscle is still unknown. Results. We show here that ASCs participate in myotube formation when cultured together with differentiating human DMD myoblasts, resulting in the restoration of dystrophin expression. Similarly, dystrophin was induced when ASCs were co‐cultivated with DMD myotubes. Experiments with GFP (green fluorescent protein)‐positive ASCs and DAPI (4′,6‐diamidino‐2‐phenylindole)‐stained DMD myoblasts indicated that ASCs participate in human myogenesis through cellular fusion. Conclusions. These results show that ASCs have the potential to interact with dystrophic muscle cells, restoring dystrophin expression of DMD cells in vitro. The possibility of using adipose tissue as a source of stem cell therapies for muscular diseases is extremely exciting.     

Enhanced natural killer (NK) cell activity and NK-sensitive thymic cells in murine muscular dystrophy

Studies have shown that there is an abnormality in the thymus of dystrophic mice with respect to age-dependent thymus weight changes and altered morphology (T. DeKretser and B. Livett, Nature (London), 263, 682, 1976). Recently, others have shown that natural killer (NK) cells can lyse cells of a large, immature, rapidly dividing cell subpopulation within the thymus of normal young (3 weeks of age) mice (M. Hansson, K. Karre, R. Kiessling, J. Roder, B. Anderson, and P. Hayry, J. Immunol., 123, 765, 1979). The NK susceptibility of dystrophic mouse thymocytes as targets was therefore studied. Spleen cells from normal (+/+) and dystrophic ($\text{dy}{}^{\mathrm{2J}}\text{dy}{}^{\mathrm{2J}}$) male C57BL/6J mice 8–10 weeks old were passed over nylon wool and the nonadherent cells were incubated with ⁵¹Cr-labeled YAC-1 lymphoma target cells or thymocytes in a ⁵¹Cr-release assay. Spleen cells from dystrophic mice killed twofold more YAC-1 target cells than did spleen cells from normal mice. Thymocytes from 3- to 4-week-old dystrophic mice were three to four times more susceptible to NK lysis by dystrophic mouse spleen cells as compared with normal mouse spleen cells. Spleen cells from dystrophic mice had the same NK activity against dystrophic and normal mouse thymocytes as targets. Normal mouse spleen cells killed three- to fourfold more dystrophic mouse thymocytes than that of normal mouse thymocytes as targets. Target cellbinding studies revealed that conjugate-forming cells from nylon nonadherent dystrophic mouse spleen cells were found to be two- to fourfold greater than for normal mouse spleen cells using YAC-1 tumor cells as targets. The number of lymphocytes bound per YAC-1 target cell ranged from 2 to 5 for dystrophic mouse spleen cells as compared with 1 to 2 for the normal control group. Using both normal and dystrophic mouse thymocytes as targets, the conjugate-forming cells from dystrophic mouse spleen cells were also found to be twofold greater than in the normal control group. Cold target inhibition studies revealed that the natural killing of dystrophic mouse thymocytes was due to a YAC-1-reactive NK cell. Effector cell depletion studies using monoclonal anti-Thy-1.2 plus complement treatment and plastic petri dish adherence also revealed that the natural killing of dystrophic mouse thymocytes was not due to either T lymphocytes or macrophages. Taken together, these results show an increase in NK-sensitive thymocyte targets in dystrophic mice, in combination with an increase in splenic NK activity.