Direct x-ray observation of a single hexagonal myofilament lattice in native myofibrils of striated muscle

A striated muscle fiber consists of thousands of myofibrils with crystalline hexagonal myofilament lattices. Because the lattices are randomly oriented, the fiber gives rise to an equatorial x-ray diffraction pattern, which is essentially a rotary-averaged "powder diffraction," carrying only information about the distance between the lattice planes. We were able to record an x-ray diffraction pattern from a single myofilament lattice, very likely originating from a single myofibril from the flight muscle of a bumblebee, by orienting the incident x-ray microbeam along the myofibrillar axis (end-on diffraction). The pattern consisted of a number of hexagonally symmetrical diffraction spots whose originating lattice planes were readily identified. This also held true for some of the weak higher order reflections. The spot-like appearance of reflections implies that the lattice order is extremely well maintained for a distance of millimeters, covering up to a thousand of approximately 2.5-microm-long sarcomeres connected in series. The results open the possibility of applying the x-ray microdiffraction technique to study many other micrometer-sized assemblies of functional biomolecules in the cell.     

The effect of inorganic phosphate on force generation in single myofibrils from rabbit skeletal muscle

In striated muscle, force generation and phosphate (P(i)) release are closely related. Alterations in the [P(i)] bathing skinned fibers have been used to probe key transitions of the mechanochemical coupling. Accuracy in this kind of studies is reduced, however, by diffusional barriers. A new perfusion technique is used to study the effect of [P(i)] in single or very thin bundles (1-3 microM in diameter; 5 degrees C) of rabbit psoas myofibrils. With this technique, it is possible to rapidly jump [P(i)] during contraction and observe the transient and steady-state effects on force of both an increase and a decrease in [P(i)]. Steady-state isometric force decreases linearly with an increase in log[P(i)] in the range 500 microM to 10 mM (slope -0.4/decade). Between 5 and 200 microM P(i), the slope of the relation is smaller ( approximately -0.07/decade). The rate constant of force development (k(TR)) increases with an increase in [P(i)] over the same concentration range. After rapid jumps in [P(i)], the kinetics of both the force decrease with an increase in [P(i)] (k(Pi(+))) and the force increase with a decrease in [P(i)] (k(Pi(-))) were measured. As observed in skinned fibers with caged P(i), k(Pi(+)) is about three to four times higher than k(TR), strongly dependent on final [P(i)], and scarcely modulated by the activation level. Unexpectedly, the kinetics of force increase after jumps from high to low [P(i)] is slower: k(Pi(-)) is indistinguishable from k(TR) measured at the same [P(i)] and has the same calcium sensitivity.     

Binding and location of AMP deaminase in rabbit psoas muscle myofibrils

It is shown that an interaction exists between AMP deaminase (EC 3.5.4.6) and myofibrils that is sufficiently strong (Kd congruent to 10(-10) M) for more than 99% of the binding sites for the enzyme to be filled in vivo. The binding is not strong enough, however, to stop removal of the enzyme during the extensive washing normally used in the preparation of myofibrils. Fluorescent antibodies to the enzyme label myofibrils close to the junction of the A- and I-bands. The invariance of the position of the antibody stripes at this site, over a range of sarcomere lengths, indicates that the enzyme is attached to the A-band. The intensity of the fluorescence declines in parallel with dissociation of the enzyme. In this muscle, the number of AMP deaminase binding sites per thick filament is approximately six, suggesting that the enzyme is located at a single axial position in each half A-band. Electron microscopy of negatively stained, antibody-labelled myofibrils reveals the distance between the AMP deaminase sites at opposite ends of an A-band to be 1.69(+/- 0.02 micron). Since the length of the A-band is 1.57 micron, the binding site for the enzyme must be significantly beyond where thick filaments have previously been thought to end.     

Binding of ADP and 5'-adenylyl imidodiphosphate to rabbit muscle myofibrils

The binding of [3H]ADP and [3H]adenyl-5'-yl-imidodiphosphate ([3H]AMP-PNP) to rabbit skeletal myofibrils was measured at 25 and 7 degrees C, mu = 0.12 M, using [14C]mannitol as a volume marker. We found that ADP bound to myosin heads in overlap with a binding constant of about 10(4) M-1, similar to the value we previously obtained in vitro with acto.S-1. The binding of AMP-PNP to myosin heads was measured both in and out of overlap. The affinity of AMP-PNP to the heads out of overlap was similar to that obtained in vitro with S-1 alone. The binding of AMP-PNP to the myosin heads in overlap was much weaker. We could fit these data with a binding constant of about 1 x 10(3) M-1, assuming a single population of cross-bridges and 1 mol of AMP-PNP bound per mol of myosin head. This value was reduced by a factor of 2 when we corrected for nonspecific binding. It was also possible to fit the data assuming two equal populations of cross-bridges with one of the populations binding AMP-PNP about 5-fold more strongly than the other population. Therefore, for at least half of the cross-bridges in overlap, the binding of AMP-PNP is almost as weak as the value of 3 x 10(2) M-1 we previously measured for the acto.S-1 complex in vitro (Biosca, J. A., Greene, L. E., and Eisenberg, E. (1986) J. Biol. Chem. 261, 9793-9800).     

Nucleotide turnover rate measured in fully relaxed rabbit skeletal muscle myofibrils

Steady state measurements of the ATP turnover rate of myosin crossbridges in relaxed living mammalian muscle or in in vitro systems are complicated by other more rapid ATPase activities. To surmount these problems we have developed a technique to measure the nucleotide turnover rate of fully relaxed myosin heads in myofibrils using a fluorescent analogue of ATP (mant-ATP). Rabbit myofibrils, relaxed in 1.6 mM ATP, were rapidly mixed with an equal volume of solution containing 80 microM mant-ATP and injected into a fluorimeter. As bound ADP is released, a fraction of the myosin active sites bind mant-ATP and fluorescence emission rises exponentially, defining a rate of nucleotide turnover of 0.03 +/- 0.001 s-1 at 25 degrees C (n = 17). This rate was approximately equal to one half that of purified myosin. The turnover rates for myosin and myofibrils increased between 5 degrees and 42 degrees C, reaching 0.16 +/- 0.04 s-1 and 0.06 +/- 0.005 s-1, respectively, at 39 degrees C, the body temperature of the rabbit. If the rate observed for purified myosin occurred in vivo, it would generate more heat than is observed for resting living muscle. When myosin is incorporated into the myofilament lattice, its ATPase activity is inhibited, providing at least a partial explanation for the low rate of heat production by living resting muscle.     

Properties of phosphorylated myofibrils from gizzard smooth muscle

Phosphorylation of chicken gizzard myosin light chain in myofibril and its effect on myofibrillar ATPase activity were investigated in the contracted state of myofibrils. When myofibrils were incubated for two hours at 30 degreeds C with ATP, magnesium and calcium, the myosin light chain was phosphorylated by endogenous light-chain kinase. Standing overnight, the phosphorylated light chain was dephosphorylated by endogenous light-chain phosphatase. Control myofibril had much higher ATPase activity than phosphorylated and phosphorylated-dephosphorylated myofibrils. It was very interesting that the phosphorylated and phosphorylated-dephosphorylated myofibrils were quite similar in ATPase activity. However, phosphorylated myofibril differed from phosphorylated-dephosphorylated myofibril in Ca2+ dependency of Mg2+-ATPase activity. The phosphorylated-dephosphorylated myofibril was not affected by the presence or absence of Ca2+. In contrast, phosphorylated myofibril apparently showed a negative Ca2+-sensitivity. On the other hand, the results indicating that the superprecipitation gel formed by phosphorylated-dephosphorylated myosin could not be dissolved in 0.6 M NaCl, suggest that the phosphorylation-dephosphorylation process of the actomyosin system in gizzard myofibril results in stronger actin-myosin interaction.     

Effect of calcium ion on the interaction of aldolase with rabbit muscle myofibrils

A partition equilibrium study has shown calcium ion to be a noncompetitive inhibitor of aldolase adsorption by rabbit muscle myofibrils. This inhibition is interpreted quantitatively in terms of a 10-fold decrease in the intrinsic association constant for the aldolase-myofibril interaction upon Ca2+ binding to either or both of the low-affinity troponin sites associated with regulation of muscle contraction.     

Transverse elasticity of myofibrils of rabbit skeletal muscle studied by atomic force microscopy

Surface structure of myofibrils of rabbit skeletal muscle and their transverse elasticity were studied by atomic force microscopy. Images of myofibrils had a periodic structure characteristic of sarcomeres of skeletal muscle fibers. The transverse elasticity distribution in the sarcomere was determined based on force-distance curves measured at various loci of single myofibrils. The Z-line in rigor myofibrils was the most rigid in all the loci of myofibrils studied under various physiological conditions. The overall transverse elasticity of myofibrils decreased in the order in rigor solution > +AMPPNP solution > relaxing solution. The "apparent" transverse Young's modulus of myofibrils estimated at the overlap region between thin and thick filaments was 84.0 +/- 18.1, 37.5 +/- 14.0, and 11.5 +/- 3.5 kPa in rigor, +AMPPNP, and relaxing solution respectively.     

Effect of calcium on extraction of Z-band proteins from I-Z-I brushes of rabbit striated muscle.

1. When rabbit striated muscle I-Z-I brushes were subjected to eleven extractions with three different extracting solutions, relatively more amount of proteins was extracted in the presence of 1 nM CaCl2 than in the presence of 5 mM EDTA or 5 mM ethyleneglycol-bisp(beta-aminoethylether)-N,N,N1,N1-tetra-acetic acid (EGTA). Among proteins extracted in the presence of 1 mM CaCl2, the protein components with molecular weights of 85,000, 95,000 and 220,000 were included, whereas these were not extracted in the other two. 2. Co-electrophoreses of 220,000 dalton protein and myosin heavy chain showed that these two protein components were distinct from each other. 3. Roles of Ca2+ are discussed on disintegration processes of I-Z-I brushes in special reference to its co-operative action with calcium-activated factor enzyme.     

Kinetic studies of glyceraldehyde-3-phosphate dehydrogenase from rabbit muscle

Initial rate studies at pH 7.6 with three aldehydes, product inhibition patterns with NADH and dead-end inhibition with adenosine diphosphoribose show that the kinetic mechanism of glyceraldehyde-3-phosphate dehydrogenase from rabbit muscle cannot be ordered, and support an enzyme-substitution mechanism. Deviations from Michaelis-Menten behaviour are consistent with negative interactions in the binding of NAD+ and instability of the species E(NAD)3 and E(NAD)4. Inhibition with large concentrations of phosphate and arsenate indicates competition for a binding site for glyceraldehyde 3-phosphate, and is not found with glyceraldehyde as substrate.     

Characterization of sarcolemma from rabbit skeletal muscle: developmental studies

Sarcolemmal membranes were obtained from skeletal muscle of rabbits at different developmental stages. Lipid and protein composition, as well as enzymatic activities, were compared in sarcolemma prepared in vesicular form. During the developmental period no distinct changes in lipid content and composition were found. Some changes in protein pattern and activities of marker enzymes (5′-nucleotidase and ouabain-sensitive Na⁺,K⁺-ATPase) were detected. Also, changes in Mg²⁺-ATPase and Mg²⁺, Ca²⁺-ATPase activities during development were found.