Ca2+ binding to myosin regulatory light chain affects the conformation of the N-terminus of essential light chain and its binding to actin

We prepared a new type of skeletal myosin subfragment 1 (S1-MLC1F) containing both, the essential and the regulatory light chains, intact, by exchanging the essential light chains of papain S1 with bacterially expressed longer isoform (MLC1F) of this light chain. We then compared the enzymatic and structural properties of chymotryptic S1, papain S1, and S1-MLC1F in the presence and in the absence of Ca(2+) ions bound to the regulatory light chain. In the presence of Ca(2+), subfragment 1 containing both intact light chains exhibited lower V(max) and lower K(m) for actin activation of S1 ATPase. When S1-MLC1F was cross-linked to actin via the N-terminus of the essential light chain, the yield was much higher when Ca(2+) ions saturated the regulatory light chain. Limited proteolysis of the essential light chain in S1-MLC1F was significantly inhibited in the presence of calcium as compared to chymotryptic S1. We conclude that the effect of binding of Ca(2+) to the regulatory light chain is transmitted to the N-terminal extension of the longer isoform of the essential light chain. The resulting structure of the N-terminus is less susceptible to proteolytic digestion, binds tighter to actin, and has an inhibitory effect on actin-activated myosin ATPase. This new conformation of the N-terminus may be responsible for calcium induced myosin-linked modulation of striated muscle contraction.     

Smooth muscle myosin light chain kinase efficiently phosphorylates serine 15 of cardiac myosin regulatory light chain

Specific phosphorylation of the human ventricular cardiac myosin regulatory light chain (MYL2) modifies the protein at S15. This modification affects MYL2 secondary structure and modulates the Ca(2+) sensitivity of contraction in cardiac tissue. Smooth muscle myosin light chain kinase (smMLCK) is a ubiquitous kinase prevalent in uterus and present in other contracting tissues including cardiac muscle. The recombinant 130 kDa (short) smMLCK phosphorylated S15 in MYL2 in vitro. Specific modification of S15 was verified using the direct detection of the phospho group on S15 with mass spectrometry. SmMLCK also specifically phosphorylated myosin regulatory light chain S15 in porcine ventricular myosin and chicken gizzard smooth muscle myosin (S20 in smooth muscle) but failed to phosphorylate the myosin regulatory light chain in rabbit skeletal myosin. Phosphorylation kinetics, measured using a novel fluorescence method eliminating the use of radioactive isotopes, indicates similar Michaelis-Menten V(max) and K(M) for regulatory light chain S15 phosphorylation rates in MYL2, porcine ventricular myosin, and chicken gizzard myosin. These data demonstrate that smMLCK is a specific and efficient kinase for the in vitro phosphorylation of MYL2, cardiac, and smooth muscle myosin. Whether smMLCK plays a role in cardiac muscle regulation or response to a disease causing stimulus is unclear but it should be considered a potentially significant kinase in cardiac tissue on the basis of its specificity, kinetics, and tissue expression.     

Order-disorder structural transitions in synthetic filaments of fast and slow skeletal muscle myosins under relaxing and activating conditions

In the previous study (Podlubnaya et al., 1999, J. Struc. Biol. 127, 1-15) Ca2+-induced reversible structural transitions in synthetic filaments of pure fast skeletal and cardiac muscle myosins were observed under rigor conditions (-Ca2+/+Ca2+). In the present work these studies have been extended to new more order-producing conditions (presence of ATP in the absence of Ca2+) aimed at arresting the relaxed structure in synthetic filaments of both fast and slow skeletal muscle myosin. Filaments were formed from column-purified myosins (rabbit fast skeletal muscle and rabbit slow skeletal semimebranosusproprius muscle). In the presence of 0.1 mM free Ca2+, 3 mM Mg2+ and 2 mM ATP (activating conditions) these filaments had a spread structure with a random arrangement of myosin heads and subfragments 2 protruding from the filament backbone. Such a structure is indistinguishable from the filament structures observed previously for fast skeletal, cardiac (see reference cited above) and smooth (Podlubnaya et al., 1999, J. Muscle Res. Cell Motil. 20, 547-554) muscle myosins in the presence of 0.1 mM free Ca2+. In the absence of Ca2+ and in the presence of ATP (relaxing conditions) the filaments of both studied myosins revealed a compact ordered structure. The fast skeletal muscle myosin filaments exhibited an axial periodicity of about 14.5 nm and which was much more pronounced than under rigor conditions in the absence of Ca2+ (see the first reference cited). The slow skeletal muscle myosin filaments differ slightly in their appearance from those of fast muscle as they exhibit mainly an axial repeat of about 43 nm while the 14.5 nm repeat is visible only in some regions. This may be a result of a slightly different structural properties of slow skeletal muscle myosin. We conclude that, like other filaments of vertebrate myosins, slow skeletal muscle myosin filaments also undergo the Ca2+-induced structural order-disorder transitions. It is very likely that all vertebrate muscle myosins possess such a property.     

Studies on Ca2+-Mg2+ binding sites of frog skeletal muscle myosin.

From skeletal muscle myosin light chains readily dissociate from the myosin oligomer in the absence of divalent cations, and unlike rabbit skeletal muscle myosin light chains, the released light chains of frog skeletal muscle myosin have a high Ca2+ binding affinity. Whereas each Ca2+ binding light chain of frog skeletal muscle myosin, when in association with the heavy chains bound 1 mol of Ca2+, when in the dissociated state bound 0.5 mol of Ca2+; the latter were readily displaced with low Mg2+ concentrations. Whereas 10(-5) M Mg2+ displaced all of the Ca2+ binding sites on the released light chains at Ca2+ concentration ranges of 10(-7) to 10(-4) M, there was negligible displacement of the Ca2+ binding sites with native frog skeletal muscle myosin under these same conditions.     

Signaling to myosin regulatory light chain in sarcomeres

Myosin regulatory light chain (RLC) phosphorylation in skeletal and cardiac muscles modulates Ca(2+)-dependent troponin regulation of contraction. RLC is phosphorylated by a dedicated Ca(2+)-dependent myosin light chain kinase in fast skeletal muscle, where biochemical properties of RLC kinase and phosphatase converge to provide a biochemical memory for RLC phosphorylation and post-activation potentiation of force development. The recent identification of cardiac-specific myosin light chain kinase necessary for basal RLC phosphorylation and another potential RLC kinase (zipper-interacting protein kinase) provides opportunities for new approaches to study signaling pathways related to the physiological function of RLC phosphorylation and its importance in cardiac muscle disease.     

Amino acid sequence of the phosphorylation site of bovine cardiac myosin light chain

Amino acid sequences of peptides containing the phosphorylation site of bovine cardiac myosin light chain (L2) were determined. The site was localized to a serine residue in the tentative amino terminus of the light chain and is homologous to phosphorylation sites in other myosin light chains. Phosphorylation of bovine cardiac light chain by chicken gizzard myosin light chain kinase was Ca2+-calmodulin dependent. Kinetic data gave a Km of 107; microM and a Vmax of 23.6 mumol min-1 mg-1. In contrast to what has been observed with smooth muscle light chains, neither the phosphorylation site fragment of the cardiac light chain nor a synthetic tetradecapeptide containing the phosphorylation site were effectively phosphorylated by the chicken gizzard kinase. Phosphorylation of cardiac myosin light chains by chicken gizzard myosin light chain kinase, therefore, requires other regions of the light chain in addition to a phosphate acceptor site.     

Domain characterization of rabbit skeletal muscle myosin light chain kinase.

Myosin light chain kinase can be divided into three distinct structural domains, an amino-terminal "tail," of unknown function, a central catalytic core and a carboxy-terminal calmodulin-binding regulatory region. We have used a combination of deletion mutagenesis and monoclonal antibody epitope mapping to define these domains more closely. A 2.95-kilobase cDNA has been isolated that includes the entire coding sequence of rabbit skeletal muscle myosin light chain kinase (607 amino acids). This cDNA, expressed in COS cells encoded a Ca2+/calmodulin-dependent myosin light chain kinase with a specific activity similar to that of the enzyme purified from rabbit skeletal muscle. Serial carboxy-terminal deletions of the regulatory and catalytic domains were constructed and expressed in COS cells. The truncated kinases had no detectable myosin light chain kinase activity. Monoclonal antibodies which inhibit the activity of the enzyme competitively with respect to myosin light chain were found to bind between residues 235-319 and 165-173, amino-terminal of the previously defined catalytic core. Thus, residues that are either involved in substrate binding or in close proximity to a light chain binding site may be located more amino-terminal than the previously defined catalytic core.     

Characterization of chicken skeletal muscle myosin light chain kinase. Evidence for muscle-specific isozymes

Myosin light chain kinase purified from chicken white skeletal muscle (Mr = 150,000) was significantly larger than both rabbit skeletal (Mr = 87,000) and chicken gizzard smooth (Mr = 130,000) muscle myosin light chain kinases, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Km and Vmax values with rabbit or chicken skeletal, bovine cardiac, and chicken gizzard smooth muscle myosin P-light chains were very similar for the chicken and rabbit skeletal muscle myosin light chain kinases. In contrast, comparable Km and Vmax data for the chicken gizzard smooth muscle myosin light chain kinase showed that this enzyme was catalytically very different from the two skeletal muscle kinases. Affinity-purified antibodies to rabbit skeletal muscle myosin light chain kinase cross-reacted with chicken skeletal muscle myosin light chain kinase, but the titer of cross-reacting antibodies was approximately 20-fold less than the anti-rabbit skeletal muscle myosin light chain kinase titer. There was no detectable antibody cross-reactivity against chicken gizzard myosin light chain kinase. Proteolytic digestion followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis or high performance liquid chromatography showed that these enzymes are structurally very different with few, if any, overlapping peptides. These data suggest that, although chicken skeletal muscle myosin light chain kinase is catalytically very similar to rabbit skeletal muscle myosin light chain kinase, the two enzymes have different primary sequences. The two skeletal muscle myosin light chain kinases appear to be more similar to each other than either is to chicken gizzard smooth muscle myosin light chain kinase.     

Changes in tropomyosin subunits and myosin light chains during development of chicken and rabbit striated muscles.

We have selected tropomyosin subunits and myosin light chains as representative markers of the myofibrillar proteins of the thin and thick filaments and have studied changes in the type of proteins present during development in chicken and rabbit striated muscles. The β subunit of tropomyosin is the major species found in all embryonic skeletal muscles studied. During development the proportion of the α subunit of tropomyosin gradually increases so that in adult skeletal muscles the α subunit is either the only or the major species present. In contrast, cardiac muscles of both chicken and rabbit contain only the α subunit which remains invariant with development. Two subspecies of the α subunit of tropomyosin which differ in charge only were found in adult and embryonic chicken skeletal muscles. Only one of these subspecies seems to be common to chicken cardiac tropomyosin. With respect to myosin light chains, embryonic skeletal fast muscle myosin of both species resembles the adult fast muscle myosin except that the LC₃ light chain characteristic of the adult skeletal fast muscle is present in smaller amounts. The significance of these isozymic changes in the two myofibrillar proteins is discussed in terms of a model of differential gene expression during development of chicken and rabbit skeletal muscles.     

Characterization of cardiac myosin from rabbit embryos and adult rabbits.

1. Ca2+-ATPase of myosin and electrophoretic pattern of light chains of myosin were investigated in cardiac muscles of 22-day-old rabbit embryos, new-born and adult rabbits. 2. Ca2+-ATPase activity was found to decrease during development and in contrast to that of adult rabbit, cardiac myosin prepared from 22-day-old embryos, is stable on exposure to pH 9.5. 3. Myosin from the cardiac muscle of rabbit embryos reveals light chains of both fast and slow types, that from adult animals, however, reveals light chains of the slow type only. 4. These studies suggest that unlike the cardiac muscle of adult rabbit, cardiac muscle of rabbit embryos contains both fast and slow types of myosin.     

Three-dimensional reconstruction of tarantula myosin filaments suggests how phosphorylation may regulate myosin activity

Muscle contraction involves the interaction of the myosin heads of the thick filaments with actin subunits of the thin filaments. Relaxation occurs when this interaction is blocked by molecular switches on these filaments. In many muscles, myosin-linked regulation involves phosphorylation of the myosin regulatory light chains (RLCs). Electron microscopy of vertebrate smooth muscle myosin molecules (regulated by phosphorylation) has provided insight into the relaxed structure, revealing that myosin is switched off by intramolecular interactions between its two heads, the free head and the blocked head. Three-dimensional reconstruction of frozen-hydrated specimens revealed that this asymmetric head interaction is also present in native thick filaments of tarantula striated muscle. Our goal in this study was to elucidate the structural features of the tarantula filament involved in phosphorylation-based regulation. A new reconstruction revealed intra- and intermolecular myosin interactions in addition to those seen previously. To help interpret the interactions, we sequenced the tarantula RLC and fitted an atomic model of the myosin head that included the predicted RLC atomic structure and an S2 (subfragment 2) crystal structure to the reconstruction. The fitting suggests one intramolecular interaction, between the cardiomyopathy loop of the free head and its own S2, and two intermolecular interactions, between the cardiac loop of the free head and the essential light chain of the blocked head and between the Leu305-Gln327 interaction loop of the free head and the N-terminal fragment of the RLC of the blocked head. These interactions, added to those previously described, would help switch off the thick filament. Molecular dynamics simulations suggest how phosphorylation could increase the helical content of the RLC N-terminus, weakening these interactions, thus releasing both heads and activating the thick filament.     

Calcium regulation of porcine aortic myosin

Calcium regulation of actin-activated porcine aortic myosin MgATPase was studied. The MgATPase of the purified actomyosin was stimulated about 10-fold by 0.1 mM Ca2+. The 20,000 molecular weight light chain subunit (LC20) of myosin was phosphorylated by an endogenous kinase that required Ca2+. Half-maximal activation of both kinase and ATPase occurred at about 0.9 microM Ca2+. Phosphorylated and unphosphorylated myosins, free of actin, kinase, and phosphatase, were purified by gel filtration. The MgATPase of phosphorylated myosin was activated by rabbit skeletal muscle actin; unphosphorylated myosin was actin activated to a much lesser extent. Actin activation was maximal in the presence of Ca2+. Regulation of the aortic myosin MgATPase seems to involve both direct interaction of calcium with phosphorylated myosin and calcium activation of the myosin kinase. The MgATPase of trypsin-treated actomyosin did not require Ca2+ for full activity. The trypsin-treated actomyosin was devoid of LC20. When purified unphosphorylated aortic myosin was treated with trypsin, the LC20, was cleaved and the MgATPase, which was not appreciably actin activated before exposure to protease, was increased and was activated by skeletal muscle actin. After incubation of this light chain-depleted myosin with light chain from rabbit skeletal muscle myosin, the actin activation but not the increased activity, was abolished. Unphosphorylated LC20 seems to inhibit actin activation in this smooth muscle.     

Substrate specificity of myosin light chain kinases.

Skeletal muscle myosin light chain kinase can phosphorylate myosin light chains isolated from skeletal or smooth muscle. In contrast, smooth muscle myosin light chain kinase specifically phosphorylates light chains isolated from smooth muscle. In this study, we have identified residues within the rabbit smooth and skeletal muscle myosin light chain kinases which may interact with the basic residues that are important substrate determinants in the light chains. Mutation of aspartic acid 270 amino-terminal of the catalytic core of the skeletal muscle myosin light chain kinase increased the Km value for both smooth and skeletal muscle light chains. Although deletions of the analogous region of the smooth muscle myosin light chain kinase (residues 663-678) markedly increased the Km value for light chain, mutation of any single acidic residue within this region did not have a similar effect. Mutation of single residues within the catalytic core of the skeletal muscle (E377 and E421) and smooth muscle (E777 and E821) myosin light chain kinases increased Km values for the smooth muscle light chain at least 35- and 100-fold, respectively. It is proposed that these residues may form ionic interactions with the arginine that is 3 residues amino-terminal of the phosphorylatable serine in the smooth muscle light chain.     

Phosphorylation of myosin light chain by a protease-activated kinase from rabbit skeletal muscle

A protease-activated protein kinase that phosphorylates the P light chain of myosin in the absence of Ca2+ and calmodulin has been isolated from rabbit skeletal muscle. The enzyme has properties similar to protease-activated kinase I from rabbit reticulocytes [S. M. Tahara and J. A. Traugh (1981) J. Biol. Chem. 256, 11588-11564], which has been shown to phosphorylate the P light chain of myosin [P. T. Tuazon, J. T. Stull, and J. A. Traugh (1982) Biochem. Biophys. Res. Commun. 108, 910-917]. The protease-activated kinase from skeletal muscle has been partially purified by chromatography on DEAE-cellulose, phosphocellulose and hydroxyapatite. The enzyme phosphorylates histone as well as the P light chain of myosin following activation by proteolysis. Stoichiometric phosphorylation of myosin light chain was observed with the protease-activated kinase and myosin light chain kinase. The sites phosphorylated by the protease-activated kinase and myosin light chain kinase were examined by two-dimensional peptide mapping following chymotryptic digestion. The phosphopeptides observed with the protease-activated kinase were different from those obtained with the Ca2+-dependent myosin light chain kinase, indicating that the two enzymes phosphorylated different sites on the P light chain of skeletal muscle myosin. When actomyosin from skeletal muscle was examined as substrate, the P light chain was phosphorylated following activation of the protease-activated kinase by limited proteolysis.     

Phosphorylation of synthetic peptides by skeletal muscle myosin light chain kinases

Substrate determinants for rabbit and chicken skeletal muscle myosin light chain kinases were examined with synthetic peptides. Both skeletal muscle myosin light chain kinases had similar phosphorylation kinetics with synthetic peptide substrates. Average kinetic constants for skeletal muscle myosin light chain heptadecapeptide, (formula; see text) where S(P) is phosphoserine, were Km, 2.3 microM and Vmax, 0.9 mumol/min/mg of enzyme. Km values were 122 and 162 microM for skeletal muscle peptides containing A-A for basic residues at positions 2-3 and 6-7, respectively. Average kinetic constants for smooth muscle myosin light chain peptide, (formula; see text), were Km, 1.4 microM and Vmax 27 mumol/min/mg of enzyme. Average Km values for the smooth muscle peptide, residues 11-23, were 10 microM which increased 6- and 11-fold with substitutions of alanine at residues 12 and 13, respectively. Vmax values decreased and Km values increased markedly by substitution of residue 16 with glutamate in the 11-23 smooth muscle tridecapeptide. Basic residues located 3 and 6-7 residues toward the NH2 terminus from phosphoserine in smooth muscle myosin light chain and 6-8 and 10-11 residues toward the NH2 terminus from phosphoserine in skeletal muscle myosin light chain appear to be important substrate determinants for skeletal muscle myosin light chain kinases. These properties are different from myosin light chain kinase from smooth muscle.     

Biochemical properties of chimeric skeletal and smooth muscle myosin light chain kinases.

The molecular and biochemical properties of myosin light chain kinases from chicken skeletal and smooth muscle were investigated by recombinant DNA techniques. Deletion of the amino-terminal region of either the smooth or skeletal muscle myosin light chain kinase resulted in a decrease in Vmax with no significant change in Km values for light chain substrates. Skeletal/smooth muscle chimeric kinases were inactive when a 65-residue region amino-terminal of the catalytic core was exchanged between the two forms. Changing alanine 494 to glutamic acid within this region in the chicken skeletal muscle myosin light chain kinase increased the Km values for light chains 10-fold. These results are consistent with the hypothesis that the region amino-terminal of the catalytic core in myosin light chain kinases is involved in light chain recognition. A skeletal muscle kinase which contained the smooth muscle calmodulin binding domain remained regulated by Ca2+/calmodulin. Thus, the calmodulin binding domains of smooth and skeletal muscle myosin light chain kinases share structural elements necessary for regulation.     

Structural transition of the inhibitory region of troponin I within the regulated cardiac thin filament

Contraction and relaxation of cardiac muscle are regulated by the inhibitory and regulatory regions of troponin I (cTnI). Our previous FRET studies showed that the inhibitory region of cTnI in isolated troponin experiences a structural transition from a beta-turn/coil motif to an extended conformation upon Ca(2+) activation. During the relaxation process, the kinetics of the reversal of this conformation is coupled to the closing of the Ca(2+)-induced open conformation of the N-domain of troponin C (cTnC) and an interaction between cTnC and cTnI in their interface. We have since extended the structural kinetic study of the inhibitory region to fully regulated thin filament. Single-tryptophan and single-cysteine mutant cTnI(L129W/S151C) was labeled with 1,5-IAEDANS at Cys151, and the tryptophan-AEDANS pair served as a donor-acceptor pair. Labeled cTnI mutant was used to prepare regulated thin filaments. Ca(2+)-induced conformational changes in the segment of Trp129-Cys151 of cTnI were monitored by FRET sensitized acceptor (AEDANS) emission in Ca(2+) titration and stopped-flow measurements. Control experiments suggested energy transfer from endogenous tryptophan residues of actin and myosin S1 to AEDANS attached to Cys151 of cTnI was very small and Ca(2+) independent. The present results show that the rate of Ca(2+)-induced structural transition and Ca(2+) sensitivity of the inhibitory region of cTnI were modified by (1) thin filament formation, (2) the presence of strongly bound S1, and (3) PKA phosphorylation of the N-terminus of cTnI. Ca(2+) sensitivity was not significantly changed by the presence of cTm and actin. However, the cTn-cTm interaction decreased the cooperativity and kinetics of the structural transition within cTnI, while actin filaments elicited opposite effects. The strongly bound S1 significantly increased the Ca(2+) sensitivity and slowed down the kinetics of structural transition. In contrast, PKA phosphorylation of cTnI decreased the Ca(2+) sensitivity and accelerated the structural transition rate of the inhibitory region of cTnI on thin filaments. These results support the idea of a feedback mechanism by strong cross-bridge interaction with actin and provide insights on the molecular basis for the fine tuning of cardiac function by beta-adrenergic stimulation.     

Structural changes accompanying phosphorylation of tarantula muscle myosin filaments

Electron microscopy has been used to study the structural changes that occur in the myosin filaments of tarantula striated muscle when they are phosphorylated. Myosin filaments in muscle homogenates maintained in relaxing conditions (ATP, EGTA) are found to have nonphosphorylated regulatory light chains as shown by urea/glycerol gel electrophoresis and [32P]phosphate autoradiography. Negative staining reveals an ordered, helical arrangement of crossbridges in these filaments, in which the heads from axially neighboring myosin molecules appear to interact with each other. When the free Ca2+ concentration in a homogenate is raised to 10(-4) M, or when a Ca2+-insensitive myosin light chain kinase is added at low Ca2+ (10(-8) M), the regulatory light chains of myosin become rapidly phosphorylated. Phosphorylation is accompanied by potentiation of the actin activation of the myosin Mg-ATPase activity and by loss of order of the helical crossbridge arrangement characteristic of the relaxed filament. We suggest that in the relaxed state, when the regulatory light chains are not phosphorylated, the myosin heads are held down on the filament backbone by head-head interactions or by interactions of the heads with the filament backbone. Phosphorylation of the light chains may alter these interactions so that the crossbridges become more loosely associated with the filament backbone giving rise to the observed changes and facilitating crossbridge interaction with actin.     

Chimeric myosin regulatory light chains identify the subdomain responsible for regulatory function.

Regulatory light chains, located on the 'motor' head domains of myosin, belong to the family of Ca2+ binding proteins that consist of four 'EF-hand' subdomains. Vertebrate regulatory light chains can be divided into two functional classes: (i) in smooth/non-muscle myosins, phosphorylation of the light chains by a calcium/calmodulin-dependent kinase regulates both interaction of the myosin head with actin and assembly of the myosin into filaments, (ii) the light chains of skeletal muscle myosins are similarly phosphorylated, but they play no apparent role in regulation. To discover the basis for the difference in regulatory properties of these two classes of light chains, we have synthesized in Escherichia coli, chimeric mutants composed of subdomains derived from the regulatory light chains of chicken skeletal and smooth muscle myosins. The regulatory capability of these mutants was analysed by their ability to regulate molluscan myosin. Using this test system, we identified the third subdomain of the regulatory light chain as being responsible for controlling not only the actin-myosin interaction, but also myosin filament assembly.     

Purification and characterization of myosin from bovine retina.

Myosin has been isolated from bovine retinae and characterised by its ATPase (ATP phosphohydrolase, EC 3.6.1.3) activity, its mobility in sodium dodecyl sulphate polyacrylamide gels and by electron microscopy. The purified myosin shows high ATPase activity in the presence of EDTA or Ca2+ and a low activity in the presence of Mg2+. The Mg2+-dependent ATPase activity is stimulated by rabbit skeletal muscle actin. The presumptive retinal myosin possesses a major component which has a mobility in sodium dodecyl sulphate polyacrylamide gel electrophoresis similar to that of the heavy chain of bovine skeletal muscle myosin. Electron microscopy showed retinal myosin to form bipolar filaments in 0.1 M KCl. It is concluded that the retina possesses a protein with enzymic and structural properties similar to those of muscle myosin.