Effect of Calcium Activated Factor on Properties of Actin and Myosin of Rabbit Skeletal Muscle

The effect of calcium activated factor (CAF) on enzymatic properties of actin and myosin was investigated. SDS polyacrylamide gel electrophoresis revealed that CAF did not degrade actin, but a slight degradation was found in myosin during CAF digestion, which might have been due to contaminated protease (s) in CAF preparation. No influence was found in EDTA ATPase of myosin and polymerization of G-actin during CAF digestion. However, heavy meromyosin (HMM) ATPase activating ability of actin was slightly decreased during CAF digestion. Although CAF digestion slightly decreased the biological activity of myofibrillar proteins, a single sarcomere prepared by CAF digestion is a useful model for studying muscle contraction because of its almost intact contractility.     

Overextended sarcomeres regain filament overlap following stretch

Sarcomere overextension has been widely implicated in stretch-induced muscle injury. Yet, sarcomere overextensions are typically inferred based on indirect evidence obtained in muscle and fibre preparations, where individual sarcomeres cannot be observed during dynamic contractions. Therefore, it remains unclear whether sarcomere overextensions are permanent following injury-inducing stretch-shortening cycles, and thus, if they can explain stretch-induced force loss. We tested the hypothesis that overextended sarcomeres can regain filament overlap in isolated myofibrils from rabbit psoas muscles. Maximally activated myofibrils (n=13) were stretched from an average sarcomere length of 2.6±0.04μm by 0.9μm sarcomere(-1) at a speed of 0.1μm sarcomere(-1)s(-1) and immediately returned to the starting lengths at the same speed (sarcomere strain=34.1±2.3%). Myofibrils were then allowed to contract isometrically at the starting lengths (2.6μm) for ～30s before relaxing. Force and individual sarcomere lengths were measured continuously. Out of the 182 sarcomeres, 35 sarcomeres were overextended at the peak of stretch, out of which 26 regained filament overlap in the shortening phase while 9 (～5%) remained overextended. About 35% of the sarcomeres with initial lengths on the descending limb of the force-length relationship and ～2% of the sarcomeres with shorter initial lengths were overextended. These findings provide first ever direct evidence that overextended sarcomeres can regain filament overlap in the shortening phase following stretch, and that the likelihood of overextension is higher for sarcomeres residing initially on the descending limb.     

Mechanical characterization of skeletal muscle myofibrils.

A new instrument, based on a technique described previously, is presented for studying mechanics of micron-scale preparations of two to three myofibrils or single myofibrils from muscle. Forces in the nanonewton to micronewton range are measurable with 0.5-ms time resolution. Programmed quick (200-microseconds) steps or ramp length changes are applied to contracting myofibrils to test their mechanical properties. Individual striations can be monitored during force production and shortening. The active isometric force, force-velocity relationship, and force transients after rapid length steps were obtained from bundles of two to three myofibrils from rabbit psoas muscle. Contrary to some earlier reports on myofibrillar mechanics, these properties are generally similar to expectations from studies on intact and skinned muscle fibers. Our experiments provide strong evidence that the mechanical properties of a fiber result from a simple summation of the myofibrillar force and shortening of independently contracting sarcomeres.     

The use of cryomethods for research on the sarcomere ultrastructure of rabbit skeletal muscles

The ultrastructure of sarcomeres of glycerinated rabbit psoas muscle was studied using freeze-fracture-etching, freeze-drying and optical diffraction techniques in comparison with the investigation of this muscle by plastic sections and negative staining methods. In frozen and dried myofibrils isolated from the above muscle the stripes of minor proteins location in A- and I-disks were clearly seen. The pivot structure in thick filaments was revealed in longitudinal fractures of the muscle. The ordered arrangement of myosin heads (crossbridges) associated with actin filaments was preserved in frozen longitudinal fractures as evidenced by optical diffraction. Freeze etching technique allowed to revealed some details of Z-line structure: alpha-actinin bridges connecting the ends of actin filaments of neighbouring sarcomeres and to preserve the lateral struts between actin filaments in I-disks.     

Half-sarcomere dynamics in myofibrils during activation and relaxation studied by tracking fluorescent markers

To study the dynamics of individual half-sarcomeres in striated muscle contraction, myofibrils prepared from rabbit psoas muscle and left ventricles of guinea pig were immunostained with two conjugated antibody complexes consisting of a primary antibody against either alpha-actinin or myomesin and a secondary fluorescently labeled Fab-fragment. We simultaneously measured force kinetics and determined the positions of the Z-line and M-band signals by fluorescence video microscopy and sophisticated computer vision (tracking) algorithms. Upon calcium activation, sarcomeres and half-sarcomeres shortened nonuniformly. Shortening occurred first rapidly and exponentially during the force rise and then slowly during the force plateau. In psoas myofibrils, time-resolved displacements of the A-band in sarcomeres were observed, i.e., the two halves of individual sarcomeres behaved nonuniformly. Nonuniformity in length changes between the two halves of sarcomeres was comparable to that between two adjacent half-sarcomeres of neighboring sarcomeres. Sequential lengthening of half-sarcomeres was observed in cardiac myofibrils during the rapid phase of force relaxation. The independent dynamics of the halves in a sarcomere reveals the half-sarcomere as the functional unit rather than the structural unit, the sarcomere. The technique will facilitate the study of filament sliding within individual half-sarcomeres and the mechanics of intersegmental chemomechanical coupling in multisegmental striated muscles.     

Kettin, a major source of myofibrillar stiffness in Drosophila indirect flight muscle

Kettin is a high molecular mass protein of insect muscle that in the sarcomeres binds to actin and alpha-actinin. To investigate kettin's functional role, we combined immunolabeling experiments with mechanical and biochemical studies on indirect flight muscle (IFM) myofibrils of Drosophila melanogaster. Micrographs of stretched IFM sarcomeres labeled with kettin antibodies revealed staining of the Z-disc periphery. After extraction of the kettin-associated actin, the A-band edges were also stained. In contrast, the staining pattern of projectin, another IFM-I-band protein, was not altered by actin removal. Force measurements were performed on single IFM myofibrils to establish the passive length-tension relationship and record passive stiffness. Stiffness decreased within seconds during gelsolin incubation and to a similar degree upon kettin digestion with mu-calpain. Immunoblotting demonstrated the presence of kettin isoforms in normal Drosophila IFM myofibrils and in myofibrils from an actin-null mutant. Dotblot analysis revealed binding of COOH-terminal kettin domains to myosin. We conclude that kettin is attached not only to actin but also to the end of the thick filament. Kettin along with projectin may constitute the elastic filament system of insect IFM and determine the muscle's high stiffness necessary for stretch activation. Possibly, the two proteins modulate myofibrillar stiffness by expressing different size isoforms.     

Extraction of Thick Filaments in Individual Sarcomeres Affects Force Production by Single Myofibrils

It has been accepted that the force produced by a skeletal muscle myofibril depends on its cross-sectional area but not on the number of active sarcomeres because they are arranged in series. However, a previous study performed by our group showed that blocking actomyosin interactions within an activated myofibril and depleting the thick filaments in one sarcomere unexpectedly reduced force production. In this study, we examined in detail how consecutive depletion of thick filaments in individual sarcomeres within a myofibril affects force production. Myofibrils isolated from rabbit psoas were activated and relaxed using a perfusion system. An extra microperfusion needle filled with a high-ionic strength solution was used to erase thick filaments in individual sarcomeres in real time before myofibril activation. The isometric forces were measured upon activation. The force produced by myofibrils with intact sarcomeres was significantly higher than the force produced by myofibrils with one or more sarcomeres lacking thick filaments (p < 0.0001) irrespective of the number of contractions imposed on the myofibrils and their initial sarcomere length. Our results suggest that the myofibril force is affected by intersarcomere dynamics and the number of active sarcomeres in series.     

Force produced by isolated sarcomeres and half-sarcomeres after an imposed stretch

When a stretch is imposed to activated muscles, there is a residual force enhancement that persists after the stretch; the force is higher than that produced during an isometric contraction in the corresponding length. The mechanisms behind the force enhancement remain elusive, and there is disagreement if it represents a sarcomeric property, or if it is associated with length nonuniformities among sarcomeres and half-sarcomeres. The purpose of this study was to investigate the effects of stretch on single sarcomeres and myofibrils with predetermined numbers of sarcomeres (n = 2, 3. . . , 8) isolated from the rabbit psoas muscle. Sarcomeres were attached between two precalibrated microneedles for force measurements, and images of the preparations were projected onto a linear photodiode array for measurements of half-sarcomere length (SL). Fully activated sarcomeres were subjected to a stretch (5-10% of initial SL, at a speed of 0.3 μm·s(-1)·SL(-1)) after which they were maintained isometric for at least 5 s before deactivation. Single sarcomeres showed two patterns: 31 sarcomeres showed a small level of force enhancement after stretch (10.46 ± 0.78%), and 28 sarcomeres did not show force enhancement (-0.54 ± 0.17%). In these preparations, there was not a strong correlation between the force enhancement and half-sarcomere length nonuniformities. When three or more sarcomeres arranged in series were stretched, force enhancement was always observed, and it increased linearly with the degree of half-sarcomere length nonuniformities. The results show that the residual force enhancement has two mechanisms: 1) stretch-induced changes in sarcomeric structure(s); we suggest that titin is responsible for this component, and 2) stretch-induced nonuniformities of half-sarcomere lengths, which significantly increases the level of force enhancement.     

Chicken breast muscle connectin: passive tension and I-band region primary structure

We performed cDNA cloning of chicken breast muscle connectin. Together with previous results, our analysis elucidated a 24.2 kb sequence encoding the amino terminus of the protein. This corresponded to the I-band region of the skeletal muscle sarcomere, which is involved in extension and contraction between the Z-line and the A-I junction. There were fewer middle immunoglobulin domains and amino acid residues in the PEVK segment of chicken breast muscle connectin than in human skeletal muscle connectin, but more than in human cardiac muscle connectin. We measured passive tension generation by stretching mechanically skinned myofibril bundles. This revealed that appreciable tension development in chicken breast muscle began at longer sarcomere spacings than in rabbit cardiac muscle, but at shorter spacings than in rabbit psoas and soleus muscles. We suggest that the chicken breast muscle sarcomere remains in a relatively extended state even in unstrained sarcomeres. This would explain why chicken breast muscle does not extend under force to the same degree as rabbit psoas and soleus muscles.     

A Ca2+-activated protease possibly involved in myofibrillar protein turnover. Purification from porcine muscle.

Ca2+-activated Z-disk-removing activity in the P0-40 crude muscle extracts described by Busch et al. (Busch, W. A., Stromer, M. H., Goll, D. E., and Suzuki, A. (1972), J. Cell Biol. 52, 367) was purified from porcine skeletal muscle extracts by using five column chromatographic procedures in succession: (1) 6% agarose; (2) DEAE-cellulose; (3) Sephadex G-200; (4) DEAE-cellulose with a very shallow gradient; (5) Sephadex G-150. All Z-disk-removing activity eluted in a single peak off each column. Z-disk-removing activity always coeluted with Ca2+-activated proteolytic activity, so Z-disk-removing activity in the P0-40 crude muscle extract is due to a single Ca2+-activated protease (CAF). The five column chromatographic procedures produced a 140-fold increase in specific activity of the Ca2+-activated proteolytic enzymic activity; because preparation of the P0-40 crude CAF fraction before chromatography produced a 127-fold increase in specific activity, the entire procedure described here produces a 17 800-fold increase in specific activity of CAF. This increase in specific activity suggests that muscle contains 3.4 mug of CAF per g of muscle fresh weight; this content is in reasonably good agreement with our yields of 0.25-0.76 mug of purified CAF per g of muscle. Purified CAF migrated as a single band during polyacrylamide gel electrophoresis in pH 7.5 Tris-HC1 buffer but migrated as two bands with molecular weights of 80 000 and 30 000 during polyacrylamide gel electrophoresis in sodium dodecyl sulfate. Densitometric scans of sodium dodecyl sulfate-polyacrylamide gels show that the 80 000- and 30 000-dalton subunits make up 85 to 90% of the protein in purified CAF preparations and that these subunits are present in equimolar ratios.     

Passive force generation and titin isoforms in mammalian skeletal muscle.

When relaxed striated muscle cells are stretched, a resting tension is produced which is thought to arise from stretching long, elastic filaments composed of titin (also called connectin). Here, I show that single skinned rabbit soleus muscle fibers produce resting tension that is several-fold lower than that found in rabbit psoas fibers. At sarcomere lengths where the slope of the resting tension-sarcomere length relation is low, electron microscopy of skinned fibers indicates that thick filaments move from the center to the side of the sarcomere during prolonged activation. As sarcomeres are stretched and the resting tension sarcomere length relation becomes steeper, this movement is decreased. The sarcomere length range over which thick filament movement decreases is higher in soleus than in psoas fibers, paralleling the different lengths at which the slope of the resting tension-sarcomere length relations increase. These results indicate that the large differences in resting tension between single psoas and soleus fibers are due to different tensions exerted by the elastic elements linking the end of each thick filament to the nearest Z-disc, i.e., the titin filaments. Quantitative gel electrophoresis of proteins from single muscle fibers excludes the possibility that resting tension is less in soleus than in psoas fibers simply because they have fewer titin filaments. A small difference in the electrophoretic mobility of titin between psoas and soleus fibers suggests the alternate possibility that mammalian muscle cells use at least two titin isoforms with differing elastic properties to produce variations in resting tension.     

The effect of rate, paired pacing and calcium on the length-tension relations in the rabbit papillary muscle

The effect of sustained paired pacing, extracellular Ca2+ concentration and of the rate of steady-state single pacing on the length-tension relations in the isolated papillary muscles of right ventricles of rabbit hearts was investigated. We found that full range change of contractile force (CF, from close to zero to maximal) may be obtained by means of the change of the resting muscle length by 10-15% of Lmax (the length at which CF is maximal). This change brings about the shift of the thin filaments of the sarcomeres along the thick ones by one sixth of their length. The only effect of all the applied interventions could be reproduced by multiplying CF at each length step by some coefficient. Neither of them did change the basic pattern of length-tension relations. These results are compatible with the hypothesis that the basic mechanism of length-tension relations is the change of sensitivity of contractile system to the sarcoplasmic Ca2+ concentration.     

Synthesis of a "free" form of hyaluronic acid by articular chondrocytes in monolayer culture

Primary and first passage rabbit chondrocyte cultures synthesized a "free" form of hyaluronic acid (HA-f) previously characterized in rabbit cartilage. HA-f was isolated from the [3H] glcN/35SO4-labelled cell-associated-fraction (CAF) and from the culture medium by successive equilibrium centrifugations in Cs2SO4/CsCl/Cs2SO4 under low salt conditions. The culture medium HA-f appeared in the void volume of Sepharose CL-2B eluted with low salt, (0.5M sodium acetate), and was susceptible to digestion with Streptomyces hyaluronidase. HA-f aggregated purified rabbit cartilage proteoglycan monomer. These results indicated that HA-f probably subserves hyaluronic acid already complexed with proteoglycan monomer. Newly synthesized HA-f may be required for the continual formation of proteoglycan aggregates.     

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.     

Subunit structure of AMP-deaminase from chicken and rabbit skeletal muscle.

The AMP-deaminases from chicken and rabbit muscle have been investigated by techniques which include sedimentation equilibrium, sodium dodecyl sulfate gel electrophoresis, amino acid analysis, NH2- and COOH-terminal analyses, and tryptic peptide mapping. The molecular weights of the native chicken (276,000) and rabbit (271,000) enzymes obtained by sedimentation equilibrium studies are in good agreement with values of 276,000 (chicken) and 275,000 (rabbit) calculated from amino acid analyses. The enzymes were reduced, carboxymethylated, and treated with either maleic or succinic anhydride in the presence of 6 M guanidine hydrochloride. Sodium dodecyl sulfate gel electrophoresis of the chemically modified enzymes resulted in a single electrophoretic species having an apparent molecular weight of 85,000. This observation is consistent with previous studies on the nonacylated enzymes and suggests that the muscle AMP-deaminases from chicken and rabbit do not contain noncovalent linkages which are readily disrupted by a large increase in negative charge. NH2-terminal analyses by the method of Stark and Amyth as well as the dansyl technique, indicate that the NH2-terminal positions of these enzymes are blocked. The enzymes are also resistant to digestion with carboxypeptidases A or B (or both) in the presence of sodium dodecyl sulfate. The most distinctive feature of the amino acid compositions of both the chicken and rabbit AMP-deaminases is the presende of eight half-cystine residues per 69,000 g of protein. Tryptic digests of the S-14C-carboxymethylated proteins were fractionated by ion exchange chromatography and high voltage electrophoresis. Six and five radioactiviely labeled peptides were detected in the electrophoretograms of the chicken and rabbit enzymes, respectively. This observation and the number of ninhydrinposition spots, together with the physical data on the molecular weights of the native enzymes and their subunits, suggest that the AMP-deaminases from chidken and rabbit muscle consist of four identical or very similar polypeptide chains.     

Sarcomere overextension reduces stretch-induced tension loss in myofibrils of rabbit psoas

Stretch-induced damage to skeletal muscles results in loss of isometric tension. Although there is no direct evidence, loss of tension has been implicitly assumed to be the consequence of permanent loss of myofilament overlap in some sarcomeres ('sarcomere overextension'). Using isolated myofibrils of rabbit psoas muscle (n=38; 6 control and 32 test specimens) at 12-15°C, we directly tested the idea that loss of tension following stretch is caused by sarcomere overextension. Experimental myofibrils were maximally activated at the edge of the descending limb (sarcomere length ～ 2.9 μm) of the sarcomere length-tension relationship and then stretched by 1 μm sarcomere(-1) at a constant speed of 0.1 μms(-1)sarcomere(-1) to result in an average strain of 33.6 ± 0.9% (mean ± 1 SE). Myofibrils were immediately returned to the original lengths and relaxed. Isometric tension measured in a subsequent re-activation 3-5 min later was reduced by 24.6 ± 1.5% from its original value. In 22 out of the 32 test specimens, all sarcomeres maintained myofilament overlap, while in 10 myofibrils one or two sarcomeres were stretched permanently beyond myofilament overlap (>4.0 μm), and thus exhibited overextended sarcomeres. Loss of tension following stretch was significantly smaller in myofibrils with overextended sarcomeres compared to myofibrils with no overextended sarcomeres (19.5 ± 2.3% and 27.1 ± 1.8%, respectively; p=0.017). Combined, these results suggest that the loss of tension associated with stretch-induced damage can occur in the absence of sarcomere overextension and that sarcomere overextension limits rather than causes stretch-induced tension loss.     

Hydrolysis by horse muscle acylphosphatase of (Ca2+ + Mg2+)-ATPase phosphorylated intermediate

Horse muscle acylphosphatase (EC 3.6.1.7) was found to hydrolyze the labeled phosphorylated intermediate of (Ca²⁺ + Mg²⁺)-ATPase from rabbit muscle. In addition, the phosphorylated peptides obtained by pepsin digestion of the labeled phosphorylated microsomes were completely hydrolyzed by acylphosphatase. These findings suggest a possible regulatory role of this enzyme in vivo on the calcium transport process by sarcoplasmic reticulum.     

A quantitative model of intersarcomere dynamics during fixed-end contractions of single frog muscle fibers.

A numerical model of a muscle fiber as 400 sarcomeres, identical except for their initial lengths, was used to simulate fixed-end tetanic contractions of frog single fibers at sarcomere lengths above the optimum. The sarcomeres were represented by a lumped model, constructed from the passive and active sarcomere length-tension curves, the force-velocity curve, and the observed active elasticity of a single frog muscle fiber. An intersarcomere force was included to prevent large disparities in lengths of neighboring sarcomeres. The model duplicated the fast rise, slow creep rise, peak, and slow decline of tension seen in tetanic contractions of stretched living fibers. Decreasing the initial non-uniformity of sarcomere length reduced the rate of rise of tension during the creep phase, but did not decrease the peak tension reached. Limitations of the model, and other processes that might contribute to the shape of the fixed end tetanic tension record are discussed. Taking account of model and experimental results, it is concluded that the distinctive features of the tension records of fixed end tetanic contraction at lengths beyond optimum can be explained by internal motion within the fiber.     

Sarcomere reorganization in mite muscle.

The number of sarcomeres in a given muscle of the mite Tarsonemus randsi was constant in both larval and adult stages, with the exception of the two medial dorsal metapodosomal muscles in males. These muscles have three sarcomeres in larvae and one sarcomere in adults. This change in sarcomere number within a muscle was observed in the living animal by polarized light microscopy using parthenogenetically derived male larvae. Initially the transforming muscles shortened slowly (hours) and the appearance of the sarcomeres was comparable to that seen during normal contraction. With continued shortening there was apposition of adjacent A bands and disappearance of clearly visible Z lines, but no loss of birefringence. Over the next 12 hr there was further shortening of the muscle and loss of birefringence. This was apparent as shortening of the three apposed A regions to the length of a single A band with a small increase in muscle width and no increase in the peak retardation of the birefringent region. The observations are discussed in terms of differential loss of the A filaments of the two terminal sarcomeres.     

Localized deposition of lead phosphate precipitate in glycerinated rabbit psoas muscle during ATP-induced contraction

The location of ATP-ase sites within sarcomeres was studied by allowing glycerinated rabbit psoas muscle to shorten under load in a solution containing ATP and lead nitrate. The lead phosphate precipitate formed during the contraction is located mainly within the A-band of shortened sarcomeres. In fibers glycerinated at rest length, the heaviest precipitate deposits are located at the center of the A-band, roughly corresponding to the double overlap zone, with lesser precipitate concentrations at the A-l boundary contraction bands. In fibers glycerinated at stretched length, shortened sarcomeres with heavy contraction bands at the A-l boundary and patent H-bands have heavy precipitate deposits over the contraction bands and no localization to the center of the A-band. The precipitate is thus seen to be most concentrated at those regions where one would expect to find the best contact between thick and thin filaments. Physiological experiments were performed. Evidence is presented that lead ions can substitute for calcium in the contraction process, altering the time course of contraction.