Robert A. Cross

Expression of the N‐terminal domain of dystrophin in E. coli and demonstration of binding to F‐actin

The N‐terminal head domain of human dystrophin has been expressed in soluble form and high yield in E. coli, allowing us to test the previously unconfirmed assumption that dystrophin binds actin. DMD246, the first 246 amino acid residues of dystrophin, binds F‐actin in a strongly co‐operative manner with a Hill constant of 3.5, but does not bind G‐actin. Dystrophin heads are thus functionally competent actin‐binding proteins. This result opens the way to identifying critical residues in the actin‐binding site and encourages us that the other domains of dystrophin might also be treated as functionally autonomous modules, accessible to a similar approach.

Active site trapping of nucleotide by smooth and non-muscle myosins

The folded 10 S monomer conformation of smooth muscle myosin traps the hydrolysis products ADP and Pi in its active sites. To test the significance of this, we have searched for equivalent trapping in other conformational and assembly states of avian gizzard and brush border myosins, using formycin triphosphate (FTP) as an ATP analogue. When myosin monomers were in the straight-tail 6 S conformation, the hydrolysis products were released at about 0.03 s-1. Adoption of the folded 10 S monomer conformation reduced this rate by more than 100-fold, effectively trapping the products FDP and Pi in the active sites. This profound inhibition of product release occurred only on formation of the looped tail monomer conformation. In vitro-assembled myosin filaments released products at a comparable rate to free straight-tail 6 S monomers, and smooth muscle heavy meromyosin, which lacks the C-terminal two-thirds of the myosin tail, also did not trap the products in this way. Phosphorylation of the myosin regulatory light chain had no effect on the rate of product release from straight-tail 6 S myosin monomers or from myosin filaments. Rather, it allowed actin to accelerate product release. Phosphorylation acted also to destabilize the folded monomer conformation, causing the recruitment of molecules from the pool of folded monomers into the myosin filaments. The two processes of contraction and filament assembly are thus both controlled in vitro by light-chain phosphorylation. A similar linked control in vivo would allow the organization of myosin in the cell to adapt itself continuously to the pattern of contractile activity.

A folded (10 S) conformer of myosin from a striated muscle and its implications for regulation of ATPase activity

Myosin from the striated adductor muscle of the scallop Pecten maximus is shown to fold into a compact 10 S conformer under relaxing conditions, as has been characterized for smooth and non-muscle myosins. The folding transition is accompanied by the trapping of nucleotide at the active site to give a species with a half-life of about an hour at 20 degrees C. Ca2+ binding to the specific, regulatory sites on a myosin head promotes unfolding to the extended 6 S conformer and activates product release by 60-fold. The unfolding transition, however, remains much slower than the contraction-relaxation cycle of scallop striated muscle and could not play a role in the regulation of these events. The dissociation of products from myosin heads in native thick filaments is Ca2(+)-regulated, but under relaxing conditions the nucleotide is released at least an order of magnitude faster than from the 10 S monomeric myosin, at a rate similar to that observed with heavy meromyosin. Thus, there is no evidence for any intermolecular interaction between neighbouring molecules in the filament analogous to the head-neck intramolecular interaction in the 10 S conformer. It is possible that the 10 S myosin state represents an inert form involved in the control of filament assembly during muscle growth and development. Removal of regulatory light chains or labelling the reactive heavy chain thiol of myosin prevents, or at least disfavours, formation of the folded 10 S conformer and allows separation of the modified protein from the native molecules.

What is 10S myosin for

Myosin filaments in smooth muscle and in non-muscle cells exchange molecules with a pool of free monomers. Regulatory light chain phosphorylation, which regulates the force-generating interaction of these filaments with actin, also regulates the transition of the free monomers into a functionally inert, folded (10S) conformation. It seems likely that the regulated formation of 10S in these systems is a means of coupling force generation to myosin filament assembly.