Purification and biochemical characterization of myomesin, a myosin-binding and titin-binding protein, from bovine skeletal muscle.

We report a method for isolating homogeneous myomesin from mammalian skeletal muscle. The identity of the purified bovine protein was confirmed by its reactivity with myomesin-specific monoclonal antibodies and with polyclonal antibodies raised against peptides derived from the amino-terminal and carboxy-terminal ends of the sequence predicted by the human myomesin cDNA. All partial sequences obtained from bovine myomesin can be aligned along the human sequence predicted by its cloned cDNA. Electron microscopy of myomesin revealed short flexible rods with a molecular length of about 50 nm. Circular dichroism spectra showed a high degree of beta structure as expected for a member of the immunoglobulin superfamily of proteins. Alignment of the sequences of the class I and II domains of myomesin with the sequences of domains of known three-dimensional structure provides a more detailed model of myomesin. In agreement with this view, the cleavage sites observed by limited proteolysis locate primarily between individual domains. In a solid-phase overlay assay myomesin specifically bound to the myosin rod and to light meromyosin (LMM), but not to the carboxy-terminal 30-kDa fragment of LMM. The myosin-binding site seemed to be confined to the amino-terminal 240 residues of the molecule. The cross-reactivity of myomesin with the phosphorylation-dependent monoclonal neurofilament antibody NE14 [Shaw, G.E., Debus, E. & Weber, K. (1984) Eur. J. Cell Biol. 34, 130-136] was analyzed. NE14 reactivity of myomesin was abolished by alkaline phosphatase. Reactivity of the antibody on stable proteolytic fragments of myomesin showed that the phosphorylation site must reside within the carboxy-terminal 60 residues.