Cellular distribution of proteolytic enzymes in the skeletal muscle of sarcoid myopathy.

To clarify the mechanism of muscle fiber destruction in sarcoid myopathy, muscle biopsy specimens were examined from patients with sarcoid myopathy, polymyositis, or dermatomyositis. In sarcoid myopathy, noncaseating granulomatous lesions were located in the perimysium or endomysium or both. Little fiber atrophy, caused by mechanical compression of the granuloma, was seen, and there was no evidence of ischemia-induced changes (i.e., perifascicular atrophy) due to microangiopathy in muscles. Immunoreactivity for membrane-associated cytoskeletal proteins such as dystrophin and merosin was detected homogeneously along the surface of many small granulomas in intrafascicular lesions. These granulomas showed a characteristic phenotypic cellular distribution: CD68(+) and CD4(+) cells were present in the center, and some CD8(+) cells were found at the periphery, indicating typical sarcoid granuloma formation in each muscle fiber. Strong expression of proteases such as cathepsin B, calpain II and ubiquitin-proteasome was observed in macrophages and epithelioid cells but not in lymphocytes in granulomas within muscle fibers or those in the endomysium or perimysium. The expression intensity was stronger in premature-stage granulomas than in late-stage granulomas. Weak expression of these proteases was detected mainly in some muscle fibers invaded by epithelioid cells and macrophages and in a few atrophic or necrotic fibers adjacent to inflammatory foci but not in fibers of fascicles without granuloma formation or in fibers in perifascicular areas. Our results suggest that muscle fiber destruction in sarcoid myopathy is caused mainly by direct invasion of granulomatous inflammatory cells into muscle fibers during the process of granuloma formation rather than by mechanical compression or ischemia. Furthermore, the proteases derived from epithelioid cells and macrophages may play an important role in muscle fiber destruction.

Adhesion molecule expression in experimental myositis.

Experimental allergic myositis (EAM) in Lewis rats, induced with partially purified myosin, is regarded as a model of human polymyositis. To clarify the role of adhesion molecules in the pathogenesis of EAM in Lewis rats, we investigated intramysial expressions of the intercellular adhesion molecule (ICAM)-1 and vascular cell adhesion molecule (VCAM)-1, and the serum level of soluble ICAM-1 in EAM rats. All the EAM rat muscles had scattered inflammatory foci, as well as cell infiltration and necrosis, by week 4 after the initial immunization (i.e., day 0 after the last immunization). As compared with the control muscles, ICAM-1 and VCAM-1 were strongly expressed immunohistochemically in the endothelium of vessels in the endomysium and perimysium, and to lesser extents in the inflammatory infiltrates and on the sarcolemma of nonnecrotic muscle fibers adjacent to the inflammatory infiltrates or invaded muscle fibers. ICAM-1 in the muscle extracts and sera from EAM rats increased on each test day, as compared with extracts from the normal controls. The values peaked on day 0 after the last immunization, then gradually decreased with time. ICAM-1 elevations in the muscle extracts were correlated with the percent of sections that had inflammatory lesions (P = 0.032) and the histological scores (P = 0.005) on day 0, whereas there was no significance on days 3 and 7. These findings suggest that the adhesion molecules ICAM-1 and VCAM-1 increase in the early stage of EAM, and function in the initiation of the inflammatory process of myositis.