Transgenic overexpression of ADAM12 suppresses muscle regeneration and aggravates dystrophy in aged mdx mice

Muscular dystrophies are characterized by insufficient restoration and gradual replacement of the skeletal muscle by fat and connective tissue. ADAM12 has previously been shown to alleviate the pathology of young dystrophin-deficient mdx mice, a model for Duchenne muscular dystrophy. The observed effect of ADAM12 was suggested to be mediated via a membrane-stabilizing up-regulation of utrophin, alpha7B integrin, and dystroglycans. Ectopic ADAM12 expression in normal mouse skeletal muscle also improved regeneration after freeze injury, presumably by the same mechanism. Hence, it was suggested that ADAM12 could be a candidate for nonreplacement gene therapy of Duchenne muscular dystrophy. We therefore evaluated the long-term effect of ADAM12 overexpression in muscle. Surprisingly, we observed loss of skeletal muscle and accelerated fibrosis and adipogenesis in 1-year-old mdx mice transgenically overexpressing ADAM12 (ADAM12(+)/mdx mice), even though their utrophin levels were mildly elevated compared with age-matched controls. Thus, membrane stabilization was not sufficient to provide protection during prolonged disease. Consequently, we reinvestigated skeletal muscle regeneration in ADAM12 transgenic mice (ADAM12(+)) after a knife cut lesion and observed that the regeneration process was significantly impaired. ADAM12 seemed to inhibit the satellite cell response and delay myoblast differentiation. These results discourage long-term therapeutic use of ADAM12. They also point to impaired regeneration as a possible factor in development of muscular dystrophy.     

脂肪干细胞移植对Duchenne型肌营养不良症鼠神经肌肉再生单位的影响

背景：目前,Duchenne型肌营养不良症尚无有效治疗方法,之前的研究表明基因治疗和干细胞移植治疗是可能的“治愈”方法。实验拟将两者结合起来,在动物模型上观察其疗效,并验证之前提出的神经肌肉再生单位的假说。 目的：探讨脂肪干细胞移植治疗Duchenne型肌营养不良症的有效性和可行性,观察细胞移植对肌纤维、新生血管及神经末梢的影响。 方法：体外分离培养mdx鼠脂肪干细胞,经杆状病毒基因载体进行基因修饰,用于移植治疗Duchenne型肌营养不良症模型鼠。移植后检测实验动物的血清肌酸激酶水平、肌肉病理改变及肌肉内dystrophin表达;免疫荧光检测细胞移植后血管、肌肉和神经再生情况。 结果与结论：细胞移植后,能够重建模型鼠的dystrophin表达,一定程度上减轻并逆转肌肉的病理损害,进而降低血清激酸激酶水平;此外,细胞移植后能够形成干细胞来源的肌纤维、血管内皮细胞和神经末梢。这些证据表明,脂肪干细胞移植是有希望治疗Duchenne型肌营养不良症的方法之一。     

HISTOLOGICAL STUDY OF MUSCULAR CHANGES IN PROGRESSIVE MUSCULAR DYSTROPHY

Changes of skeletal muscle of 28 patients with progressive muscular dystrophy were studied light microscopically. Slowly progressive muscular atrophy with various forms of degeneration and more acute necrosis with incomplete regeneration were the principal changes. Fatty tissue infiltration and fibrosis of the interstitial tissue seemed to occur relatively late in the course of the disease. Incidence of necrosis and regeneration of muscle fibers are significantly higher in the Duchenne-type dystrophy and in an early stage, thus giving some quantitative difference concerning the genetic clinical types and duration of the disease, though no definite specific change is found for each type of muscular dystrophy.
Significance of these changes are discussed from a morphological standpoint and under consideration of biological speciality of muscle fiber. Regenerative substitution of necrotic muscle fiber performed by survived nuclei of the necrotic fiber itself in close association of myophago-cytosis appeared to be a peculiar process exhibited by skeletal muscle as a syncytial cell.     

Long-term survival of transplanted stem cells in immunocompetent mice with muscular dystrophy

Satellite cells refer to resident stem cells in muscle that are activated in response to damage or disease for the regeneration and repair of muscle fibers. The use of stem cell transplantation to treat muscular diseases has been limited by impaired donor cell survival attributed to rejection and an unavailable stem cell niche. We isolated a population of adult muscle mononuclear cells (AMMCs) from normal, strain-matched muscle and transplanted these cells into δ-sarcoglycan-null dystrophic mice. Distinct from other transplant studies, the recipient mice were immunocompetent with an intact endogenous satellite cell pool. We found that AMMCs were 35 times more efficient at restoring sarcoglycan compared with cultured myoblasts. Unlike cultured myoblasts, AMMC-derived muscle fibers expressed sarcoglycan protein throughout their entire length, consistent with enhanced migratory ability. We examined the capacity of single injections of AMMCs to provide long-term benefit for muscular dystrophy and found persistent regeneration after 6 months, consistent with augmentation of the endogenous stem cell pool. Interestingly, AMMCs were more effectively engrafted into aged dystrophic mice for the regeneration of large clusters of sarcoglycan-positive muscle fibers, which were protected from damage, suggesting that the stem cell niche in older muscle remains permissive.     

Activation of caspase 3, 9, 12, and Bax in masseter muscle of mdx mice during necrosis

The mdx mouse, a model of muscular dystrophy, lacks dystrophin, a cell membrane protein. It is known that the lack of dystrophin causes muscle fiber necrosis from 2 weeks after birth, and the majority of necrotic muscle fibers are replaced by regenerated muscle fibers by 4 weeks after birth. A recent study indicated the possibility that mitochondria-mediated intracellular stress, a phenomenon similar to apoptosis, may be produced during muscle fiber necrosis, but did not analyze endoplasmic reticulum-mediated intracellular stress. Therefore, we examined the expression of the caspase-12 gene involved in the endoplasmic reticulum stress pathway and the Bax, caspase-9, and caspase-3 genes involved in the mitochondrial stress pathway in the mdx masseter muscle. We found over-expression of caspase-12 in cells at 2–3 weeks after birth when muscle fiber necrosis was not prominent. This suggests that stress occurs in the endoplasmic reticulum to maintain cell morphology in the absence of dystrophin. In addition, Bax was abundantly expressed in the mdx masseter muscle at 3 weeks after birth, and the expression of caspase-9 and -3 was prominent at 3–4 weeks after birth when necrosis and regeneration were marked. These results indicate that endoplasmic reticulum and mitochondrial stresses are produced during necrosis of the mdx masseter muscle, and suggest that these events are a phenomenon similar to apoptosis.     

Flk-1+ adipose-derived mesenchymal stem cells differentiate into skeletal muscle satellite cells and ameliorate muscular dystrophy in mdx mice

Duchenne muscular dystrophy (DMD) is a severe hereditary disease characterized by the absence of dystrophin on the sarcolemma of muscle fiber. This absence results in widespread muscle damage and satellite cell activation. After depletion of the satellite cell pool, skeletal muscle is then invariably replaced by connective tissue, leading to progressive muscle weakness. Herein, we isolated Flk-1(+) mesenchymal stem cells (MSCs) from adult adipose tissue and induced them to differentiate into skeletal muscle cells in culture. Within mdx mice, an animal model of DMD, adipose tissue-derived Flk-1(+) MSCs (AD-MSCs) homed to and differentiated into cells that repaired injured muscle tissue. This repair correlated with reconstitution of dystrophin expression on the damaged fibers. Flk-1(+) AD-MSCs also differentiated into muscle satellite cells. This differentiation may have accounted for long-term reconstitution. These cells also differentiated into endothelial cells, thereby possibly improving fiber regeneration as a result of the induced angiogenesis. Therefore, Flk-1(+) AD-MSC transplants may repair muscular dystrophy.     

Expression of transforming growth factor-beta 1 and its relation to endomysial fibrosis in progressive muscular dystrophy.

Progressive muscular dystrophy is characterized by muscle fiber necrosis, regeneration, and endomysial fibrosis. Although absence of dystrophin has been known as the cause of muscle fiber degeneration, pathogenesis of interstitial fibrosis is still unknown. Transforming growth factor-beta 1 (TGF-beta 1) induces accumulation of extracellular matrix in various diseases, such as liver cirrhosis and interstitial pneumonitis. To investigate its function on the pathogenesis of progressive muscular dystrophy, it was necessary to determine the degree of TGF-beta 1 expression and the site of TGF-beta 1 immunoreactivity. In Duchenne muscular dystrophy and most of Becker muscular dystrophy, high TGF-beta 1 immunoreactivity expressed on muscle fibers and extracellular space. In other myopathies with endomysial fibrosis, however, TGF-beta 1 was seldom observed. We also examined the immunoreactivity of the latent TGF-beta binding protein, which is bound to the TGF-beta precursors. In all Duchenne muscular dystrophy and half of Becker muscular dystrophy cases, high latent TGF-beta 1 binding protein immunoreactivity was seen, but in other myopathies its immunoreactivity was seldom seen on muscle fibers or extracellular space. Therefore TGF-beta 1 may play an important role in synthesis and accumulation of extracellular matrix in progressive muscular dystrophy.     

Muscular dystrophy and muscle regeneration

An animal model of muscular dystrophy, the dystrophic (129ReJ dy/dy) mutant mouse, was used to evaluate the regenerative phenomenon in dystrophic muscle. The effect of age on "spontaneous" regeneration (i.e., regeneration in the absence of secondary trauma) was assessed by quantitative morphometric analysis and evaluation of myosatellite cell dynamics (i.e., myosatellite cell frequency, proliferative activity, and fusion capability). Spontaneous regeneration ceased by the time the mice were 8 weeks old. The findings suggested that the small "regenerating" myofibers found in older dystrophic muscle had been formed earlier in the time course of the disease and were growth-inhibited. To determine the cause of the cessation of regeneration, dystrophic muscle was subjected to the severe trauma of whole-muscle transplantation, a trauma that results in total myofiber necrosis followed by de novo myotube formation. When young dystrophic muscle (from 4- to 6-week-old dystrophic mice) was orthotopically transplanted, the time course of degeneration-regeneration was similar to that seen in age-matched normal muscle. Moreover, the regenerated dystrophic myofibers were capable of long-term survival (200 days or longer after transplantation), and they failed to show evidence of histologic changes consistent with murine dystrophy. When older dystrophic muscle (from 17-week-old dystrophic mice), muscle that failed to display spontaneous regeneration, was transplanted, it displayed remarkable regenerative capacity. It was suggested that the cessation of spontaneous regeneration in older dystrophic murine muscle is due not to exhaustion of myosatellite cell proliferative capacity, but rather to age-related loss of the mitogenic effect of dystrophy on the myosatellite cells of dystrophic muscle.     

解整合素-金属蛋白酶1 2基因在骨巨细胞瘤组织中的表达及意义

目的 检测解整合素-金属蛋白酶12（ADAM12）基因在骨巨细胞瘤组织中的表达和定位,探讨其对骨巨细胞瘤中多核巨细胞形成的作用。方法 用逆转录-聚合酶链反应（RT-PCR）检测18例、用RNA原位杂交检测12例骨巨细胞瘤患者的瘤组织、6倍体外培养骨巨细胞瘤瘤细胞、2例胚胎横纹肌和5例成人横纹肌组织的ADAM12mRNA。结果 RT-PCR显示,18例骨巨细胞瘤组织中,12例（67%）有ADAM12mRNA表达;RNA原位杂交则显示12例骨巨细胞瘤组织全部呈ADAM12阳性反应,并且位于几乎所有的多核巨细胞和单核基质细胞质中。随着骨巨细胞瘤培养细胞传代次数的增多和多核巨细胞的消失,ADAM12mRNA的表达也逐渐消失。结论 骨巨细胞瘤中的多核巨细胞可能是由单核基质细胞融合而成,ADAM12基因参与这一融合过程。     

ADAM 12 protease induces adipogenesis in transgenic mice

ADAM 12 (meltrin-alpha) is a member of the ADAM (a disintegrin and metalloprotease) family. ADAM 12 functions as an active metalloprotease, supports cell adhesion, and has been implicated in myoblast differentiation and fusion. Human ADAM 12 exists in two forms: the prototype membrane-anchored protein, ADAM 12-L, and a shorter secreted form, ADAM 12-S. Here we report the occurrence of adipocytes in the skeletal muscle of transgenic mice in which overexpression of either form is driven by the muscle creatine kinase promoter. Cells expressing a marker of early adipogenesis were apparent in the perivascular space in muscle tissue of 1- to 2-week-old transgenic mice whereas mature lipid-laden adipocytes were seen at 3 to 4 weeks. Moreover, female transgenics expressing ADAM 12-S exhibited increases in body weight, total body fat mass, abdominal fat mass, and herniation, but were normoglycemic and did not exhibit increased serum insulin, cholesterol, or triglycerides. Male transgenics were slightly overweight and also developed herniation but did not become obese. Transgenic mice expressing a truncated form of ADAM 12-S lacking the prodomain and the metalloprotease domain did not develop this adipogenic phenotype, suggesting a requirement for ADAM 12 protease activity. This is the first in vivo demonstration that an ADAM protease is involved in adipogenesis.     

Muscle regeneration in dystrophic mdx mice is enhanced by isosorbide dinitrate

Activation of muscle satellite cells, a fundamental step in the success of muscle regeneration is mediated by nitric oxide (NO). In this study, we investigated whether isosorbide dinitrate (ISD), an NO donor, could improve muscle regeneration in dystrophic mdx mice. The right tibialis anterior muscle of mdx and C57Bl/10 mice was injected with bupivacaine (0.3 ml, 33 mg/kg), a myotoxic agent, to induce muscle fiber regeneration. After bupivacaine injection, mice were treated with ISD (30 mg/kg; i.p.), verapamil (a non-NO donor vasodilator, 15 mg/kg, i.p.) or saline solution (vehicle, 0.3 ml, i.p.) for 20 days. Some bupivacaine-injected mice received no pharmacological treatment (control group). Muscle regeneration was evaluated by counting the total number of muscle fibers and measuring myofiber cross-sectional area. ISD significantly improved bupivacaine-induced muscle regeneration in mdx by increasing by 20% the total number of muscle fibers compared to the other groups. Spontaneous muscle regeneration, evaluated in the contralateral non-injected muscle, was not affected. ISD treatment did not affect myofiber cross-sectional area. Verapamil and saline had no effect on muscle regeneration. These results suggested that NO derived from ISD stimulated and/or recruited satellite cells. Pharmacological treatment with ISD could be clinically useful for improving muscle regeneration in Duchenne muscular dystrophy.     

Skeletal muscle regeneration associated with the stroma reaction during tumor invasion in the rat tongue

This study was aimed to demonstrate the regeneration of skeletal muscle fibers in the stroma reaction during tumor invasion, using the rat model of tongue carcinoma. By oral administration of 4-nitroquinoline N-oxide, squamous cell carcinoma (SCC) appeared in the epithelium, and deeply invaded the muscular layer, inducing the stroma reaction around the tumor. Regenerating muscle fibers, characterized by the immature profiles of sparse myofibrils, centrally disposed multi-nuclei, and abundant mitochondria, were extended from the surrounding normal muscles into the stroma. By immunohistochemistry, some of them expressed BF-45, a marker for an early stage of myodifferentiation, similar to the regenerating muscle fibers in the bupivacaine hydrochloride-induced injury. They were closely associated with the stromal components such as ED-1-positive macrophages, alpha-smooth muscle actin-positive myofibroblasts, and factor VIII-related antigen-positive vascular endothelial cells, suggesting the roles of their interactions in muscle regeneration. Immature muscle fibers were usually devoid of acetylcholinesterase-positive endplates on them, but some were reinnervated by the terminal axons. The present results indicate that skeletal muscle regeneration is induced in association with the stroma reaction during SCC invasion in the tongue.     

Myogenic Akt signaling upregulates the utrophin-glycoprotein complex and promotes sarcolemma stability in muscular dystrophy

Duchenne muscular dystrophy is caused by dystrophin mutations that lead to structural instability of the sarcolemma membrane, myofiber degeneration/regeneration and progressive muscle wasting. Here we show that myogenic Akt signaling in mouse models of dystrophy promotes increased expression of utrophin, which replaces the function of dystrophin thereby preventing sarcolemma damage and muscle wasting. In contrast to previous suggestions that increased Akt in dystrophy was a secondary consequence of pathology, our findings demonstrate a pivotal role for this signaling pathway such that modulation of Akt can significantly affect disease outcome by amplification of existing, physiological compensatory mechanisms.     

Electron microscopic and autoradiographic characterization of hindlimb muscle regeneration in the mdx mouse

The pattern of postnatal growth and development of skeletal muscle in mdx mice was studied by light and transmission electron microscopy and by autoradiography and was compared with that in their normal age-matched controls at 4 and 32 weeks of age. The muscle weights of both the extensor digitorum longus (EDL) and soleus muscles of mdx mice were significantly greater than those in control mice at both ages. Body weights of male and female mdx mice were also increased over controls up to 12 weeks of age. At 4 weeks, both the EDL and soleus muscles exhibited focal areas of degeneration, necrosis, and regeneration of centrally nucleated extrafusal fibers resulting in a wide range of fiber sizes. By 32 weeks, the majority of fibers in both muscles were centrally nucleated, and focal areas of recent regeneration were observed. By electron microscopy, the course of macrophage infiltration into areas of degenerating fibers and the ongoing regeneration of myofibers within redundant cylinders of external lamina were noted. This pattern was frequent in 4-week-old mdx muscles and was present to a lesser degree at 32 weeks. A notable lack of both adipose tissue infiltration and fibrotic change in the endomysium were observed in muscles at both ages. Autoradiograms of muscles from 4-week-old mdx mice injected with tritiated thymidine showed an increased proportion of labeled sublaminal nuclei at 24 and 48 hours after injection compared to controls. At 32 weeks of age, labeling of nuclei in muscles of mdx mice was also greater than in controls, but was reduced compared to muscle labeling in 4-week-old mdx mice. The observed features of mdx muscle tissue suggest that this animal model is more applicable to the study of regeneration dynamics than to Duchenne-type human muscular dystrophy.     

Histopathologic features of masseter muscle in the distrophic hamster (UM-X7.1 Syrian hamster)

Dystrophic hamster has been regarded as the useful model animal for Severe childhood autosomal recessive muscular dystrophy (SCARMD). Although, many studies on Dystrophic hamster have utilized the muscular tissue of the trunk, however no study have been analyzed for the masticatory muscle. For this study, we used a Dystrophic hamster (UM-X7.1 Syrian hamster) to histochemically investigate the effect of muscular dystrophy on the masseter muscle. Large and small regenerated muscle fibers, and necrotic fibers were detected almost in all areas. Opaque fiber, hypertrophic fiber with fiber splitting structure and necrotic fiber filled up by mononuclear phagocytes were recognized. The region, in which the mononuclear phagocytic cells infiltrated, showed strong positivity to acid phosphatase, and lysosome enzyme. There were many muscle fibers with reduced levels of succinate dehydrogenase (SDH) activities in the muscle fiber. Some TUNEL-positive cells were confirmed in both necrotic and non-necrotic areas. It was suggested that a part of TUNEL-positive cells are the cells originated from the connective tissue or immunocytes. In this result, histopathologic changes of the masseter muscle of the UM-X7.1 Syrian hamster was similar to muscle of the body trunk in the past reports. As the result, it was suggested that jaw closing movements may be negatively affected caused by the decline of the masseter muscle twitch. And, the point of view by which apoptosis is the trigger for the muscle fiber collapse were not seen in the Dystrophic hamster masseter muscle. We suggest that apoptosis is a one step in the process of regeneration of muscle fibers.     

肌桥与其桥接神经再生间变化的形态学观察

为探知缝接神经缺损的肌条（肌桥）与其缝接神经再生间的变化关系,从而为改善肌桥神经再生效果提供形态学依据。采用５０只兔的１００条肌条和３０条狗的６０条肌条为研究材料,分Ａ、Ｂ、Ｃ三组,用不同形态结构的肌肉,分别与正中神经缺损３ｃｍ处缝接和不与神经相缝接而将肌条两端固定在桥接神经缺损邻近处。术后不同时间,取材常规制成光、电镜标本,镜下观察和图像分析仪测定。结果：术后不同肌桥,几乎均显示肌条中央存留肌纤维较周边的少,再生神经纤维较周边的多,而不与神经连接的肌条,没有明显肌条中央与周边存留肌纤维的不同,一条变性肌纤维内可同时看到再生神经纤维和肌原纤维存在。结果提示：肌桥肌纤维变性可促进神经纤维再生,神经纤维再生可加速肌纤维变性,再生神经纤维可伴随肌纤维变性而长入。长红肌纤维为肌桥的神经再生效果好。     

Studies on isolated human skeletal muscle fibers, including a proposed pattern of nuclear distribution and a concept of nuclear territories

Studies of human skeletal muscle fibers from tissue specimens isolated by supersonic cavitation, employing a Willens Polytron, show that the number of nuclei per millimeter, the surface area of fiber per nucleus, and the cytoplasmic volume per nucleus increase with fiber diameter, for fibers from the same muscle, from muscle to muscle, and from patient to patient. Skeletal muscle fibers from patients with Pompe's disease, muscular dystrophy (both autosomal and sex linked recessive juvenile forms), Riley-Day central autonomic dysfunction, and cardiomyopathy with skeletal muscle weakness show increased N/mm. and decreased A/N and V/N values, whereas fibers from patients with the Down syndrome show low N/mm. and high A/N and V/N values. Possibly abnormal fiber values were also observed in familial cerebellar atrophy with mental retardation, in 18 trisomy, Jansky-Bielschowsky disease, and ataxia-telangiectasia. Skeletal muscle fibers from autosomal recessive (“limb girdle”) muscular dystrophy show segmental, and those from Duchenne's dystrophy diffuse, hypernucleation. In Pompe's disease, acid mucopolysaccharide occurs in discrete “packages” in skeletal muscle, muscles of respiration showing less acid mucopolysaccharide than others.Evidence that the nuclei of skeletal muscle fibers are arranged in a pattern based on a hexagonal array, such that the fibers are covered by nuclear territories of relatively uniform size and shape, is presented, models of such architecture are presented, and possible biochemical implications of nuclear territories are discussed. Evidence that division of fiber nuclei is amitotic is presented. The concept that nuclear rows or chains in skeletal muscle fibers are nuclear clones is proposed, and possible biochemical implications of this arrangement are also discussed.