Spallanzani's mouse: a model of restoration and regeneration.

The ability to regenerate is thought to be a lost phenotype in mammals, though there are certainly sporadic examples of mammalian regeneration. Our laboratory has identified a strain of mouse, the MRL mouse, which has a unique capacity to heal complex tissue in an epimorphic fashion, i.e., to restore a damaged limb or organ to its normal structure and function. Initial studies using through-and-through ear punches showed rapid full closure of the ear holes with cartilage growth, new hair follicles, and normal tissue architecture reminiscent of regeneration seen in amphibians as opposed to the scarring usually seen in mammals. Since the ear hole closure phenotype is a quantitative trait, this has been used to show-through extensive breeding and backcrossing--that the trait is heritable. Such analysis reveals that there is a complex genetic basis for this trait with multiple loci. One of the major phenotypes of the MRL mouse is a potent remodeling response with the absence or a reduced level of scarring. MRL healing is associated with the upregulation of the metalloproteinases MMP-2 and MMP-9 and the downregulation of their inhibitors TIMP-2 and TIMP-3, both present in inflammatory cells such as neutrophils and macrophages. This model has more recently been extended to the heart. In this case, a cryoinjury to the right ventricle leads to near complete scarless healing in the MRL mouse whereas scarring is seen in the control mouse. In the MRL heart, bromodeoxyuridine uptake by cardiomyocytes filling the wound site can be seen 60 days after injury. This does not occur in the control mouse. Function in the MRL heart, as measured by echocardiography, returns to normal.

Heart regeneration in adult MRL mice.

The reaction of cardiac tissue to acute injury involves interacting cascades of cellular and molecular responses that encompass inflammation, hormonal signaling, extracellular matrix remodeling, and compensatory adaptation of myocytes. Myocardial regeneration is observed in amphibians, whereas scar formation characterizes cardiac ventricular wound healing in a variety of mammalian injury models. We have previously shown that the MRL mouse strain has an extraordinary capacity to heal surgical wounds, a complex trait that maps to at least seven genetic loci. Here, we extend these studies to cardiac wounds and demonstrate that a severe transmural, cryogenically induced infarction of the right ventricle heals extensively within 60 days, with the restoration of normal myocardium and function. Scarring is markedly reduced in MRL mice compared with C57BL/6 mice, consistent with both the reduced hydroxyproline levels seen after injury and an elevated cardiomyocyte mitotic index of 10-20% for the MRL compared with 1-3% for the C57BL/6. The myocardial response to injury observed in these mice resembles the regenerative process seen in amphibians.

The induction of skeletal muscle hypertrophy by a ski transgene is promoter-dependent.

The chicken c-ski gene expresses at least three alternatively spliced messages. Transgenic mice expressing proteins from cDNA corresponding to two of these messages (FB27 and FB29) under the control of a murine sarcoma virus (MSV) long terminal repeat (LTR) express the transgene in skeletal muscle and develop a muscular phenotype. Both a biologically active form of c-ski and the MSV LTR are required for the development of the muscular phenotype. The normal c-ski gene linked to two other tissue-specific promoters failed to induce muscle growth in transgenic mice, as did an inactive mutant of c-ski expressed under the control of the MSV LTR.

Mice lacking the myotonic dystrophy protein kinase develop a late onset progressive myopathy.

Myotonic dystrophy (DM) is an autosomal dominant disorder resulting from the expansion of a CTG repeat in the 3' untranslated region of a putative protein kinase (DMPK). To elucidate the role of DMPK in DM pathogenesis we have developed Dmpk deficient (Dmpk-/-) mice. Dmpk-/-mice develop a late-onset, progressive skeletal myopathy that shares some pathological features with DM. Muscles from mature mice show variation in fibre size, increased fibre degeneration and fibrosis. Adult Dmpk-/-mice show ultrastructural changes in muscle and a 50% decrease in force generation compared to young mice. Our results indicate that DMPK may be necessary for the maintenance of skeletal muscle structure and function and suggest that a decrease in DMPK levels may contribute to DM pathology.

Selective expression of a ski transgene affects IIb fast muscles and skeletal structure.

The expression of a ski transgene in the bind leg muscles of mice follows a spatial and temporal pattern reminiscent of the pattern of myogenic development. Anterior muscles, which are formed earliest during development, are also the first muscles to express ski mRNA. Muscles derived from the posterior muscle group, formed later during development, exhibit delayed expression of ski mRNA. In addition, there is regional variation in ski mRNA levels within a particular muscle. Superficial regions of fast muscles, which contain a large percentage of type IIb fibers and have a high ATPase activity, express a higher level of ski mRNA than the deep portions of the same muscles. The deep regions contain a lower percentage of type IIb fibers and lower ATPase activity. The soleus, a slow muscle composed predominantly of type I fibers, expresses low ATPase activity and contains much lower levels of ski mRNA. mRNA from the ski transgene is also expressed at high levels in the osteocytes of the leg bones of 15-day and older transgenic mice. High levels of Ski protein is present in the osteocytes of the leg bones. ski expression appears to cause remodeling of the tibia and fibula. The cross-sectional area of the tibia and fibula of ski transgenic mice is significantly decreased compared to controls. X-rays of the skeletons of ski transgenic mice suggest that the bones of the entire skeleton are thinner than the bones in normal mice. Pathological stress fractures were found in several bones in the ski transgenic mice.

Regulation of c-ski transgene expression in developing and mature mice.

The control of c-ski transgene expression and muscle hypertrophy have been investigated in transgenic mice. In adult animals, the level of transgene expression is linked to the specialized phenotype of individual muscles, high levels occur in fast muscles and significantly lower levels in muscles with high metabolic activity (diaphragm, soleus). These findings have led us to propose that a threshold must be passed before ski-induced growth can occur. We now show that within fast muscles, induced hypertrophy uniquely involves IIb fibers. This pattern of expression is under development control; levels of c-ski mRNA are low in all muscles at birth. In the diaphragm, there is a sevenfold increase in c-ski message levels between 5 d and maturity. By contrast, in fast extensor digitorum longus and anterior tibial muscles, there is a 24-fold increase in levels between 5 and 12 d postpartum. Muscle hypertrophy and antibody staining for c-ski protein in myofiber nuclei emerge concurrently. This pattern of c-ski expression parallels the appearance of IIb myosin heavy chain transcripts (Wydert et al., 1987) and differentiation of IIb fibers, suggesting that amplification of c-ski mRNA levels is linked to the development of IIb fiber specialization. Manipulations that are known to perturb IIb fiber development, neonatal denervation, and neonatally induced hypothyroidism inhibit high levels of c-ski expression and hypertrophy. In the adult fast EDL, denervation leads to rapid atrophy of IIb fibers and a significant decline in levels of c-ski mRNA. The results suggest that the environment of differentiated IIb fibers permits the expression of high levels of c-ski mRNA and this, in turn, induces hypertrophy.

The mdx mouse diaphragm reproduces the degenerative changes of Duchenne muscular dystrophy.

Although murine X-linked muscular dystrophy (mdx) and Duchenne muscular dystrophy (DMD) are genetically homologous and both characterized by a complete absence of dystrophin, the limb muscles of adult mdx mice suffer neither the detectable weakness nor the progressive degeneration that are features of DMD. Here we show that the mdx mouse diaphragm exhibits a pattern of degeneration, fibrosis and severe functional deficit comparable to that of DMD limb muscle, although adult mice show no overt respiratory impairment. Progressive functional changes include reductions in strength (to 13.5% of control by two years of age), elasticity, twitch speed and fibre length. The collagen density rises to at least seven times that of control diaphragm and ten times that of mdx hind-limb muscle. By 1.5 years of age, similar but less severe histological changes emerge in the accessory muscles of respiration. On the basis of these findings, we propose that dystrophin deficiency alters the threshold for work-induced injury. Our data provide a quantitative framework for studying the pathogenesis of dystrophy and extend the application of the mdx mouse as an animal model.

Expression of slow and fast myosin heavy chains in overload muscles of the developing rat.

The present study examines the developmental accumulation of slow myosin heavy chain in the extensor digitorum longus, soleus and plantaris muscles of rats after early post-natal imposition of mechanical overload by removal of synergistic muscles. The proportions of slow and fast myosin heavy chain were measured in each muscle by ELISA. Fibres expressing slow myosin were examined immunocytochemically using a monoclonal antibody specific for slow MHC. Between 30 and 60 days of age, MHC increases by 15% (p less than 0.001) in the soleus and by 27% (p less than 0.001) in the plantaris of normally developing, unoperated animals. The effect of overload on the soleus and plantaris is to accelerate the rate of increase in slow MHC accumulation so that levels are respectively 16 and 39% higher than controls by 30 days of age (p less than 0.001). By 60 days, the control soleus and plantaris attain levels of slow MHC roughly equivalent to their overloaded counterparts. In overloaded plantaris the increase in levels of slow myosin does not occur at the expense of fast myosin expression. In the EDL there is a normal developmentally regulated decrease in slow MHC accumulation, reflected by a 40% decrease in levels of slow MHC (p less than 0.0001) and a 50% decrease in the number of slow fibres (p less than 0.001), between 30 days and 20 weeks of age. This elimination of slow myosin accumulation in the EDL is unimpeded by chronic overload. Thus, muscles react to mechanical overload in a tissue specific manner.(ABSTRACT TRUNCATED AT 250 WORDS)

Neuromuscular relationships in the abdomen of the Californian shore crab Pachygrapsus crassipes.

There are two pairs of muscles in each abdominal segment of the crab; one pair of flexors and one pair of extensors. In the early larval stages the muscles have short sarcomeres--a property of fast fibers--and high thin to thick filament ratios--a property of slow fibers. In the adult the abdominal muscles are intermediate and slow, since they have fibers with intermediate and long sarcomeres, high thin to thick filament ratios, low myofibrillar ATPase activity, and high NADH diaphorase activity. The different fiber types are regionally distributed within the flexor muscle. Microelectrode recordings from single flexor muscle fibers in the adult showed that most fibers are supplied by three excitatory motor axons, although some are supplied by as many as five efferents. One axon supplies all of the flexor muscle fibers in its own hemisegment, and the evoked junctional potentials exhibit depression. This feature together with the innervation patterns of the fibers are similar to those reported for the deep flexor muscles of crayfish and lobsters. Therefore, in the adult crab, the abdominal flexor muscles have some features in common with the slow superficial flexors of crayfish and other features in common with the fast deep flexor muscles.

Neuromuscular relationships during claw regeneration in Californian snapping shrimp.

We have examined the innervation patterns of the two excitor axons to the closer muscle in the dimorphic (snapper and pincer) claws of Californian snapping shrimp (Alpheus californiensis). In both claws the fast-closer excitor (FCE) axon supplies all of the closer muscle fibers. The slow-closer excitor (SCE) axon, however, makes functional connections only with fibers on the dorsal and ventral margins, which are composed of slow-type fibers in the large snapper claw and of intermediate-type fibers in the smaller pincer claw. The central band of fast fibers in the pincer closer muscle is not innervated by the SCE. During claw regeneration, the closer muscle is initially composed of a population of fast fibers in the pincer and intermediate-type fibers in the snapper. The innervation patterns of the two excitatory motor axons in regenerating claws at this stage are the same as in fully developed claws. During the first intermolt period some fast-closer muscle fibers in the pincer claw differentiate into intermediate-type fibers, but the axon innervation patterns do not change. If the correlation between SCE axon innervation pattern and the regional distribution of different muscle fiber types is indicative of nerve-muscle interactions, the present data suggest that the trophic influence must proceed from nerve to muscle.