Rhea J. C. Levine

Myosin light chain phosphorylation affects the structure of rabbit skeletal muscle thick filaments

To identify the structural basis for the observed physiological effects of myosin regulatory light chain phosphorylation in skinned rabbit skeletal muscle fibers (potentiation of force development at low calcium), thick filaments separated from the muscle in the relaxed state, with unphoshorylated light chains, were incubated with specific, intact, myosin light chain kinase at moderate (pCa 5.0) and low (pCa 5.8) calcium and with calcium-independent enzyme in the absence of calcium, then examined as negatively stained preparations, by electron microscopy and optical diffraction. All such experimental filaments became disordered (lost the near-helical array of surface myosin heads typical of the relaxed state). Filaments incubated in control media, including intact enzyme in the absence of calcium, moderate calcium (pCa 5.0) without enzyme, and bovine serum albumin substituting for calcium-independent myosin light chain kinase, all retained their relaxed structure. Finally, filaments disordered by phosphorylation regained their relaxed structure after incubation with a protein phosphatase catalytic subunit. We suggest that the observed disorder is due to phosphorylation-induced increased mobility and/or changed conformation of myosin heads, which places an increased population of them close to thin filaments, thereby potentiating actin-myosin interaction at low calcium levels.

Structure of Limulus telson muscle thick filaments

Abstract Computer analysis of electron micrographs of negatively stained thick filaments isolated from the telson levator muscle of the horseshoe crab ( Limulus polyphemus ) has shown that they have a four-stranded helical structure. The repeating units along each helix have a bent extended shape (measuring approximately 20 nm × 8 nm × 8 nm) and are inclined at an angle of about 30 ° to the helical path. At the resolution of this study, it was difficult to establish the exact size of the surface subunits, but our results are probably more consistent with each unit representing the two heads of a single myosin molecule rather than larger aggregates.

Multiple structures of thick filaments in resting cardiac muscle and their influence on cross-bridge interactions.

Based on two criteria, the tightness of packing of myosin rods within the backbone of the filament and the degree of order of the myosin heads, thick filaments isolated from a control group of rat hearts had three different structures. Two of the structures of thick filaments had ordered myosin heads and were distinguishable from each other by the difference in tightness of packing of the myosin rods. Depending on the packing, their structure has been called loose or tight. The third structure had narrow shafts and disordered myosin heads extending at different angles from the backbone. This structure has been called disordered. After phosphorylation of myosin-binding protein C (MyBP-C) with protein kinase A (PKA), almost all thick filaments exhibited the loose structure. Transitions from one structure to another in quiescent muscles were produced by changing the concentration of extracellular Ca. The probability of interaction between isolated thick and thin filaments in control, PKA-treated preparations, and preparations exposed to different Ca concentrations was estimated by electron microscopy. Interactions were more frequent with phosphorylated thick filaments having the loose structure than with either the tight or disordered structure. In view of the presence of MgATP and the absence of Ca, the interaction between the myosin heads and the thin filaments was most likely the weak attachment that precedes the force-generating steps in the cross-bridge cycle. These results suggest that phosphorylation of MyBP-C in cardiac thick filaments increases the probability of cross-bridges forming weak attachments to thin filaments in the absence of activation. This mechanism may modulate the number of cross-bridges generating force during activation.

Determination of the handedness of the crossbridge helix ofLimulus thick filaments

SummaryThick filaments, isolated in their long conformation from unstimulatedLimulus telson muscles, were shadowed with platinum or platinum-carbon and examined using electron microscopy and optical diffraction techniques. All filaments showed evidence of a right-handed surface helix, which had a major repeat at approx. 43 nm. In fortuitously oriented specimens the subunits, presumably crossbridges, which comprised the helical strands were clearly delineated. Optical transforms obtained from images of shadowed filaments confirmed the helical repeat at approx. 43 nm and could be readily interpreted as patterns expected from a one-surface view of the four-stranded filament structure we have previously reported.The striking resemblance between optically filtered images of shadowed filaments and the computed reconstruction of the one-surface filament further confirm our model for the myosin lattice of theLimulus thick filament.

Multiple Forms of Cardiac Myosin-binding Protein C Exist and Can Regulate Thick Filament Stability

Although absence or abnormality of cardiac myosin binding protein C (cMyBP-C) produces serious structural and functional abnormalities of the heart, function of the protein itself is not clearly understood, and the cause of the abnormalities, unidentified. Here we report that a major function of cMyBP-C may be regulating the stability of the myosin-containing contractile filaments through phosphorylation of cMyBP-C. Antibodies were raised against three different regions of cMyBP-C to detect changes in structure within the molecule, and loss of myosin heavy chain was used to monitor degradation of the thick filament. Results from Western blotting and polyacrylamide gel electrophoresis indicate that cMyBP-C can exist in two different forms that produce, respectively, stable and unstable thick filaments. The stable form has well-ordered myosin heads and requires phosphorylation of the cMyBP-C. The unstable form has disordered myosin heads. In tissue with intact cardiac cells, the unstable unphosphorylated cMyBP-C is more easily proteolyzed, causing thick filaments first to release cMyBP-C and/or its proteolytic peptides and then myosin. Filaments deficient in cMyBP-C are fragmented by shear force well tolerated by the stable form. We hypothesize that modulation of filament stability can be coupled at the molecular level with the strength of contraction by the sensitivity of each to the concentration of calcium ions.

Anti-actin-peroxidase staining of the helical wall-free prokaryoteSpiroplasma citri

An antiserum made against sodium dodecyl sulfate-denatured actin from invertebrates and coupled to horseradish peroxidase specifically stains the wall-free prokaryoteSpiroplasma citri. The results of experiments with spiroplasmas reported here, coupled with the report of the extraction from them of an actin-like protein, suggest that these highly motile organisms possess an actin-like mediated mechanism of motility.

[16] Preparation and assay of paramyosin

Publisher Summary This chapter presents the procedure for preparation and assay of paramyosin. Techniques for isolation of paramyosin from invertebrate muscles take advantage of the proteins resistance to denaturation by organic solvents and its unique solubility properties. For highest yields, it is useful to use muscles that have higher paramyosin : myosin ratios. Some of these tissues also contain intrinsic proteases or those from bacterial parasites, so appropriate precautions should be taken to avoid proteolysis of paramyosin. There are three general methods to assay for the presence of paramyosin. These include (a) formation and electron microscopic examination of the paracrystalline precipitates of the protein; (b) identification of the polypeptide chains by SDSpolyacrylamide gel electrophoresis; and, alone or in combination with these; (c) positive staining of paramyosin chain bands on SDSpolyacrylamide gels and/or paracrystals with labeled antibody specific for paramyosin.

Fibre types in Limulus telson muscles: morphology and histochemistry

SummaryUsing a variety of techniques, we have demonstrated the presence of at least two fibre types inLimulus median telson levator muscle. By light and electron microscopy, large (21 56 μm2 mean cross-sectional area) fibres have A-bands of 4.1 μm, one-half I bands of 2.15 μm and Z lines ⩽ 0.5 μm in width. Few mitochondria are found in these fibres, which comprise 54% of those present in a given microscope field and which occupy 82% of the total cross-sectional area. Small fibres (484 μm2 mean cross-sectional area) have A bands of 6.3 μm, one-half I bands of 3.1 μm and Z lines between 0.5 and 1.0 μm in width and are rich in mitochondria. Although small fibres comprise nearly one-half (46%) of the fibres in a field, they occupy only 18% of the total cross-sectional area.Histochemical staining for alkaline-stable myofibrillar ATPase activity and mitochondrial reduced β-nicotinamide adenine nucleotide (β-NADH) tetrazolium reductase activity confirms the presence of two fibre types. The large fibres react positively for the myofibrillar ATPase activity and negatively for the mitochondrial enzyme activity. The reverse is seen with the small fibres. Some fibres of intermediate size, having intermediate staining characteristics, were also observed. Native gel electrophoresis of both myofibrillar and purified myosin preparations supports the observed differences in myofibrillar ATPase activity in that two myosin isozymes are resolved on pyrophosphate gels. Although the thick filaments isolated from unstimulated small fibres are longer (>6.0 μm) than those isolated from unstimulated large fibres (4.26 μm), all have a similar appearance with respect to the arrangement of myosin heads on their surfaces, and similar diameters. The implications of the observed heterogeneity of fibre types is discussed with reference to previously reported phenomena inLimulus telson muscle, including changes in length of thick filaments on fibre stimulation and the shape of the length-tension curve obtained from fibre bundles.

Structure of short thick filaments from Limulus muscle.

Shortened Limulus thick filaments, isolated from stimulated muscle, are structurally similar to long filaments, isolated from unstimulated muscle, except for length. Both have 3-fold screw symmetry with a helical repeat at approximately 43 nm, axial spacing of 14.5 nm between successive crowns of crossbridges and 4-fold rotational symmetry as estimated from the Bessel argument, by analysis of optical transforms of electron micrograph negatives of negatively stained samples. Both short and long filaments also have similar radii for the location of their crossbridges, thus similar diameters. Equal numbers of subunits/helical strand are also apparent on images of metal-shadowed long and short filaments. Since these data argue against molecular reorganization during filament shortening, it is suggested that the change in length of Limulus thick filaments may occur by reversible disaggregation of constituent protein molecules.

STRUCTURE OF LIMULUS AND OTHER INVERTEBRATE THICK FILAMENTS

We have demonstrated remarkable similarity among the skeletal muscles of chelicerate arthropods with respect to the cross-bridge arrangement on the surface of their thick filaments. The latter, gently isolated from the muscles of three representative species (Limulus telson , tarantula leg and scorpion leg and tail) have been examined by electron microscopy and optical diffraction using both negatively stained and unidirectionally metal shadowed preparations. The filaments are highly periodic and produce clear and detailed diffraction patterns. The cross-bridge projections form integral surface helices, with an axial spacing of 14.5 nm between adjacent crowns and a major axial repeat every 43.5 nm. We have demonstrated previously that Limulus filaments are four-stranded and analysis of both electron micrographs and their transforms, as well as optical reconstructions of the arachnid filaments is consistent with their also having a four-start surface helix, which is right-handed in all cases. Of all those examined, thus far, only Limulus thick filaments have been demonstrated to change length under various conditions. Shortened Limulus filaments isolated from K+-stimulated fibers retain the 43.5 nm axial repeat periodicity and 14.5 nm axial spacing between crowns. In preliminary analysis of negatively stained and metal shadowed preparations, we see no systematic change with respect to screw or rotational symmetry in short as compared with long filaments. A few of the former have a very slightly increased diameter (3-4 nm) in the middle of each filament arm. This region often shows disorder on optical transforms. From our results we cannot rule out the possibility that disaggregation and reaggregation of thick filament proteins accompany the changes in length of Limulus thick filaments.