Extracellular matrix organization in developing muscle: correlation with acetylcholine receptor aggregates.

Abstract

Monoclonal antibodies recognizing laminin, heparan sulfate proteoglycan, fibronectin and 2 apparently novel connective tissue components were used to examine the organization of extracellular matrix of skeletal muscle in vivo and in vitro. Four of the 5 monoclonal antibodies are described for the first time here. Immunocytochemical experiments with frozen-sectioned muscle demonstrated that both the heparan sulfate proteoglycan and laminin exhibited staining patterns identical to that expected for components of the basal lamina. The remaining matrix constituents were detected in all regions of muscle connective tissue: the endomysium, perimysium and epimysium. Embryonic muscle cells developing in culture elaborated an extracellular matrix, each antigen exhibiting a unique distribution. Of particular interest was the organization of extracellular matrix on myotubes: the build-up of matrix components was most apparent in plaque overlying clusters of an integral membrane protein, the acetylcholine receptor (AChR). The heparan sulfate proteoglycan was concentrated at virtually all AChR clusters and showed a remarkable level of congruence with receptor organization; laminin was detected at 70-95% of AChR clusters but often was not completely co-distributed wth AChR within the cluster; fibronectin and the 2 other extracellular matrix antigens occurred at .apprx. 20, 8 and 2% of the AChR clusters, respectively, and showed little or no congruence with AChR. From observations on the distribution of extracellular matrix components in tissue cultured fibroblasts and myogenic cells, several ideas about the organization of extracellular matrix are suggested. Congruence between AChR clusters and heparan sulfate proteoglycan suggests the existence of some linkage between the 2 molecules, possibly important for regulation of AChR distribution within the muscle membrane. The qualitatively different patterns of extracellular matrix organization over myotubes and fibroblasts suggest that each of these cell types uses somewhat different means to regulate the assembly of extracellular matrix components within its domain. The limited co-distribution of different components within the extracellular matrix in vitro and the selective immune precipitation of each antigen from conditioned medium suggest that each extracellular matrix component is secreted in a form that is not complexed with other matrix constituents.