Scientist-friendly policies for non-native English-speaking authors: timely and welcome.

That English is the lingua franca of today's science is an indisputable fact. Publication in English in international journals is a pre-requisite for a research paper to gain visibility in academia. However, English proficiency appears to be taken for granted in the scientific community, though this language can be a hurdle for a number of authors, particularly from non-native English-speaking countries. The influence of English proficiency on the publication output of Brazilian authors has never been assessed. We report our preliminary data on the relationship between the English proficiency of 51,223 researchers registered in the CNPq database and their publication output in international journals. We have found that publication rates are higher for those authors with good command of English, particularly written English. Although our research is still underway and our results are preliminary, they suggest that the correlation between written English proficiency and research productivity should not be underestimated. We also present the comments of some Brazilian scientists with high publication records on the relevance of communication skills to the scientific enterprise.

Scientist-friendly policies for non-native English-speaking authors: timely and welcome

That English is the lingua franca of today's science is an indisputable fact. Publication in English in international journals is a pre-requisite for a research paper to gain visibility in academia. However, English proficiency appears to be taken for granted in the scientific community, though this language can be a hurdle for a number of authors, particularly from non-native English-speaking countries. The influence of English proficiency on the publication output of Brazilian authors has never been assessed. We report our preliminary data on the relationship between the English proficiency of 51,223 researchers registered in the CNPq database and their publication output in international journals. We have found that publication rates are higher for those authors with good command of English, particularly written English. Although our research is still underway and our results are preliminary, they suggest that the correlation between written English proficiency and research productivity should not be underestimated. We also present the comments of some Brazilian scientists with high publication records on the relevance of communication skills to the scientific enterprise.

Counteracting effects of urea and methylamines in function and structure of skeletal muscle myosin.

Myosin is an asymmetric protein that comprises two globular heads (S1) and a double-stranded alpha-helical rod. We have investigated the effects of urea and the methylamines trimethylamine oxide (TMA-O) and glycine betaine (betaine) on activity and structure of skeletal muscle myosin. K(+) EDTA ATPase activity of myosin was almost completely inhibited by urea (2M); TMA-O stimulated myosin activity, whereas betaine had no effect. When combined with urea (0-2M), TMA-O or betaine (1 M) effectively protected the ATPase activity of myosin against inhibition. Intrinsic fluorescence measurements showed that in urea or TMA-O (0-2M), there were no shifts in the center of mass of the fluorescence spectrum of myosin, despite a decrease in fluorescence intensity. However, these osmolytes at concentrations above 2M produced a red shift in the emission spectrum. Betaine alone did not alter the center of mass at any concentration tested up to 5.2M. Thus, modifications in ATPase activity induced by low concentrations of solutes (<2M) are not directly correlated with the modifications in myosin structure detected by fluorescence. Both methylamines (>or=1M) were also able to protect myosin structure against urea-induced effects (2-8M). Protection was not observed for S1, supporting the hypothesis that these osmolytes have a biphasic effect on myosin: at lower concentrations there is an effect on the globular portion (S1), and at higher concentrations there is an effect on the coiled-coil (rod) portion of myosin.

Dimethyl sulphoxide enhances the effects of P(i) in myofibrils and inhibits the activity of rabbit skeletal muscle contractile proteins.

In the catalytic cycle of skeletal muscle, myosin alternates between strongly and weakly bound cross-bridges, with the latter contributing little to sustained tension. Here we describe the action of DMSO, an organic solvent that appears to increase the population of weakly bound cross-bridges that accumulate after the binding of ATP, but before P(i) release. DMSO (5-30%, v/v) reversibly inhibits tension and ATP hydrolysis in vertebrate skeletal muscle myofibrils, and decreases the speed of unregulated F-actin in an in vitro motility assay with heavy meromyosin. In solution, controls for enzyme activity and intrinsic tryptophan fluorescence of myosin subfragment 1 (S1) in the presence of different cations indicate that structural changes attributable to DMSO are small and reversible, and do not involve unfolding. Since DMSO depresses S1 and acto-S1 MgATPase activities in the same proportions, without altering acto-S1 affinity, the principal DMSO target apparently lies within the catalytic cycle rather than with actin-myosin binding. Inhibition by DMSO in myofibrils is the same in the presence or the absence of Ca(2+) and regulatory proteins, in contrast with the effects of ethylene glycol, and the Ca(2+) sensitivity of isometric tension is slightly decreased by DMSO. The apparent affinity for P(i) is enhanced markedly by DMSO (and to a lesser extent by ethylene glycol) in skinned fibres, suggesting that DMSO stabilizes cross-bridges that have ADP.P(i) or ATP bound to them.

Biological function and site II Ca2+-induced opening of the regulatory domain of skeletal troponin C are impaired by invariant site I or II Glu mutations.

To investigate the roles of site I and II invariant Glu residues 41 and 77 in the functional properties and calcium-induced structural opening of skeletal muscle troponin C (TnC) regulatory domain, we have replaced them by Ala in intact F29W TnC and in wild-type and F29W N domains (TnC residues 1-90). Reconstitution of intact E41A/F29W and E77A/F29W mutants into TnC-depleted muscle skinned fibers showed that Ca(2+)-induced tension is greatly reduced compared with the F29W control. Circular dichroism measurements of wild-type N domain as a function of pCa (= -log[Ca(2+)]) demonstrated that approximately 90% of the total change in molar ellipticity at 222 nm ([theta](222 nm)) could be assigned to site II Ca(2+) binding. With E41A, E77A, and cardiac TnC N domains this [theta](222 nm) change attributable to site II was reduced to < or =40% of that seen with wild type, consistent with their structures remaining closed in +Ca(2+). Furthermore, the Ca(2+)-induced changes in fluorescence, near UV CD, and UV difference spectra observed with intact F29W are largely abolished with E41A/F29W and E77A/F29W TnCs. Taken together, the data indicate that the major structural change in N domain, including the closed to open transition, is triggered by site II Ca(2+) binding, an interpretation relevant to the energetics of the skeletal muscle TnC and cardiac TnC systems.

Regulation of skeletal muscle tension redevelopment by troponin C constructs with different Ca2+ affinities.

In maximally activated skinned fibers, the rate of tension redevelopment (ktr) following a rapid release and restretch is determined by the maximal rate of cross-bridge cycling. During submaximal Ca2+ activations, however, ktr regulation varies with thin filament dynamics. Thus, decreasing the rate of Ca2+ dissociation from TnC produces a higher ktr value at a given tension level (P), especially in the [Ca2+] range that yields less than 50% of maximal tension (Po). In this study, native rabbit TnC was replaced with chicken recombinant TnC, either wild-type (rTnC) or mutant (NHdel), with decreased Ca2+ affinity and an increased Ca2+ dissociation rate (koff). Despite marked differences in Ca2+ sensitivity (>0.5 DeltapCa50), fibers reconstituted with either of the recombinant proteins exhibited similar ktr versus tension profiles, with ktr low (1-2 s-1) and constant up to approximately 50% Po, then rising sharply to a maximum (16 +/- 0.8 s-1) in fully activated fibers. This behavior is predicted by a four-state model based on coupling between cross-bridge cycling and thin filament regulation, where Ca2+ directly affects only individual thin filament regulatory units. These data and model simulations confirm that the range of ktr values obtained with varying Ca2+ can be regulated by a rate-limiting thin filament process.

Calcium-induced quenching of intrinsic fluorescence in brain myosin V is linked to dissociation of calmodulin light chains.

Myosin V isolated from chick brain (BM V) is a multimeric protein of about 640 kDa consisting of two intertwined heavy chains of 212 kDa and multiple light chains of 10 to 20 kDa. A distinctive feature of the heavy chain is an extended neck region with six consensus IQ sites for the binding of calmodulin (CaM) and myosin light chains. The actin-activated MgATPase has been shown to require >/=1 microM Ca2+ for full activity, and evidence points to a myosin-linked regulatory system where the CaM light chains participate as modulators for the Ca2+ signal. Still, the precise mechanism of Ca2+ regulation remains unknown. In the present study we have used the intrinsic tryptophan fluorescence of native BM V to monitor conformational changes of BM V induced by Ca2+, and we relate these changes to CaM dissociation from the BM V molecule. The fluorescence intensity decreases approximately 17% upon addition of sub-micromolar concentrations of Ca2+ (K0.5 = 0.038 microM). This decrease in fluorescence, which is dominated by a conformational change in the heavy chain, can be reversed by addition of 1, 2-di(2-aminoethoxy)ethane-N,N,N',N'tetraacetic acid (EGTA) followed by an excess of CaM, but not by addition of EGTA alone. Gel filtration of native BM V using HPLC shows that CaM is partially dissociated from the heavy chain in EGTA and dissociates further upon addition of sub-micromolar concentrations of Ca2+. These observations suggest that the affinity of CaM for at least one of the IQ sites on the BM V heavy chain decreases with Ca2+ and that the Ca2+ concentration required for this effect is lower than that needed to activate acto-BM V. Using a cosedimentation assay in the presence of actin, we also observe partial dissociation of CaM when Ca2+ is absent, but now the addition of Ca2+ has a biphasic effect: sub-micromolar Ca2+ concentrations lead to reassociation of CaM with the heavy chain, followed by dissociation when Ca2+ exceeds 5-10 microM. Thus, the binding of CaM to BM V is affected by both actin and Ca2+.

Specificity and kinetic effects of nitrophenol analogues that activate myosin subfragment 1.

2,4-Dinitrophenol (DNP) activates the myosin ATPase of mammalian skeletal muscle in the presence of Ca2+ or Mg2+, and inhibits it when the bivalent cations are replaced by K+ and EDTA. Activation of Mg2+ATPase is abolished by the presence of unregulated actin. 3-Nitrophenol (3-NP) is also an activator, whereas other analogues (2-nitrophenol, 2-NP, and 4-nitrophenol, 4-NP) are much less effective. Concentrations required for their half-maximal effects (K0.5) range from 2 to 15 mM for 3-NP and DNP in the presence of different cations, and the sequence for the analogues is 3-NP<=DNP<<2-NP approximately 4-NP, which is apparently unrelated to either hydrophobicity or pK. DNP and 3-NP have almost identical effects on the ATPase activity of chymotryptic subfragment 1 as they do on myosin, which is an indication that their target is the globular head region rather than the tail, or the 18 kDa (regulatory) light chain. Analysis of the ATP concentration dependence for subfragment- 1 ATPase in the presence of Ca2+ or Mg2+ shows that DNP activates only at high substrate concentrations, becoming increasingly effective with ATP concentrations in the physiological range. At low substrate concentrations, DNP inhibits hydrolysis by increasing the apparent Km for ATP at the catalytic site. In the presence of Mg2+, it mimics the effect of actin, which increases the Km and accelerates the release of products following hydrolysis. At high substrate concentrations, activation by DNP appears to involve a kinetic component with low affinity for ATP that can increase the overall reaction rate by a factor of 2- to 9-fold, depending on the bivalent cation. This low-affinity component is either induced by the drug (in the presence of Mg2+) or shifted by the drug to a lower ATP concentration range (in the presence of Ca2+).

Mimicry of the calcium-induced conformational state of troponin C by low temperature under pressure.

Calcium binding to the N-domain of troponin C initiates a series of conformational changes that lead to muscle contraction. Calcium binding provides the free energy for a hydrophobic region in the core of N-domain to assume a more open configuration. Fluorescence measurements on a tryptophan mutant (F29W) show that a similar conformational change occurs in the absence of Ca2+ when the temperature is lowered under pressure. The conformation induced by subzero temperatures binds the hydrophobic probe bis-aminonaphthalene sulfonate, and the tryptophan has the same fluorescence lifetime (7 ns) as in the Ca2+-bound form. The decrease in volume (delta V = -25.4 ml/mol) corresponds to an increase in surface area. Thermodynamic measurements suggest an enthalpy-driven conformational change that leads to an intermediate with an exposed N-domain core and a high affinity for Ca2+.

Concerted action of the high affinity calcium binding sites in skeletal muscle troponin C.

Mutants of each of the four divalent cation binding sites of chicken skeletal muscle troponin C (TnC) were constructed using site-directed mutagenesis to convert Asp to Ala at the first coordinating position in each site. With a view to evaluating the importance of site-site interactions both within and between the N- and C-terminal domains, in this study the mutants are examined for their ability to associate with other components of the troponin-tropomyosin regulatory complex and to regulate thin filaments. The functional effects of each mutation in reconstitution assays are largely confined to the domain in which it occurs, where the unmutated site is unable to compensate for the defect. Thus the mutants of sites I and II bind to the regulatory complex but are impaired in ability to regulate tension and actomyosin ATPase activity, whereas the mutants of sites III and IV regulate activity but are unable to remain bound to thin filaments unless Ca2+ is present. When all four sites are intact, free Mg2+ causes a 50-60-fold increase in TnC's affinity for the other components of the regulatory complex, allowing it to attach firmly to thin filaments. Calcium can replace Mg2+ at a concentration ratio of 1:5000, and at this ratio the Ca2.TnC complex is more tightly bound to the filaments than the Mg2.TnC form. In the C-terminal mutants, higher concentrations of Ca2+ (above tension threshold) are required to effect this transformation than in the recombinant wild-type protein, suggesting that the mutants reveal an attachment mediated by Ca2+ in the N-domain sites.

The effects of N helix deletion and mutant F29W on the Ca2+ binding and functional properties of chicken skeletal muscle troponin.

To assess the structural and functional significance of the N helix (residues 3-13) of avian recombinant troponin C (rTnC), we have constructed NHdel, in which residues 1-11 have been deleted, both in rTnC and in the spectral probe mutant F29W (Pearlstone, J. R., Borgford, T., Chandra, M., Oikawa, K., Kay, C. M., Herzberg, O., Moult, J., Herklotz, A., Reinach, F. C., and Smillie, L. B. (1992) Biochemistry 31, 6545-6553). Comparison of the far- and near-UV CD spectra (+/- Ca2+) of F29W and F29W/NHdel and titration of the Ca(2+)-induced ellipticity and fluorescence changes indicates that the deletion has little effect on the global fold of the molecule but reduces the Ca2+ affinity of the N domain, but not the C domain, by 1.6-1.8-fold. Comparisons of the mutants NHdel, F29W, and F29W/NHdel with rTnC have been made using several functional assays. In reconstituted troponin-tropomyosin actomyosin subfragment 1 and myofibrillar ATPase systems, both F29W and NHdel have significantly reduced Ca(2+)-activated enzymatic activities. These effects are cumulative in the double mutant F29W/NHdel. On the other hand, maximal isometric tension development in Ca(2+)-activated reconstituted skinned fibers is not affected with F29W and NHdel, although the Ca2+ sensitivity of NHdel in this system is markedly reduced. We conclude that both mutations, NHdel and F29W, are functionally deleterious, possibly affecting interactions of the N domain with troponin I and/or T.

Comparison of calmodulin and troponin C with and without its amino-terminal helix (residues 1-11) in the activation of erythrocyte Ca(2+)-ATPase.

Troponin C can replace calmodulin in the activation of the Ca(2+)-ATPase of pig erythrocytes provided that the reaction medium contains relatively high free Ca2+ concentrations (> 0.5 microM). In the presence of 10 microM free Ca2+, the troponin C-activated ATPase reaches a maximal velocity of approximately 70% of that attained with calmodulin. The half-maximal concentration for troponin C activation is about 200 times greater than for calmodulin. Troponin C displaces the half-maximal concentration for activation by Ca2+ to pCa 5.46 and the cooperativity between the Ca2+ binding sites to nH 1.1, compared with pCa 6.14 and nH 1.72 when calmodulin is used. Both EF-hand proteins also elicit activation by ATP at a nucleotide regulatory site, as well as a Ca(2+)-dependent p-nitrophenyl phosphatase activity. Troponin I prevents activation of the enzyme by troponin C. A mutant of troponin C with the amino-terminal helix deleted (NHdel) activates the Ca(2+)-ATPase to the same extent and with the same Ca2+ dependence as wild-type troponin C (rTnC); the half-maximal concentration for activation by NHdel is 2.5 times smaller than that for rTnC. We conclude that the structural features that distinguish the two EF-hand proteins affect their binding to the target enzyme more than their ability to transform the enzyme's response to Ca2+ or ATP. The differences in the amino-terminal domains of troponin C and calmodulin cannot account for the differences in ability of these proteins to activate the target system used as a model.

ATP regulation of calcium transport in back-inhibited sarcoplasmic reticulum vesicles.

At high concentrations of ATP, ATP hydrolysis and Ca2+ transport by the (Ca2+ + MG2+)-ATPase of intact sarcoplasmic reticulum vesicles exhibit a secondary activation that varies with the extent of back-inhibition by Ca2+ accumulated within the vesicles. When the internal ionized Ca2+ is clamped at low and intermediate levels by the use of Ca-precipitating anions, the apparent Km values for activation by ATP are lower than in fully back-inhibited vesicles (high internal Ca2+). In leaky vesicles unable to accumulate Ca2+, raising Ca2+ in the assay medium from 20-30 microM to 5 mM abolishes the activation of hydrolysis by high concentrations of ATP. The level of [32P]phosphoenzyme formed during ATP hydrolysis from [32P]phosphate added to the medium also varies with the extent of back-inhibition; it is highest when Ca2+ is raised to a level that saturates the internal, low-affinity Ca2+ binding sites. In intact vesicles, increasing the ATP concentration from 10 to 400 microM competitively inhibits the reaction of inorganic phosphate with the enzyme but does not change the rate of hydrolysis. In a previous report (De Meis, L., Gomez-Puyou, M.T. and Gomez-Puyou, A. (1988) Eur. J. Biochem. 171, 343-349), it has been shown that the hydrophobic molecules trifluoperazine and iron bathophenanthroline compete for the catalytic site of the Pi-reactive form of the enzyme. Here it is shown that inhibition of ATP hydrolysis by these compounds is reduced or abolished when Ca2+ binds to the low-affinity Ca2+ binding sites of the enzyme. Since inhibition by these agents is indifferent to activation of hydrolysis by high concentrations of ATP, it is suggested that the second Km for ATP and the inhibition by hydrophobic molecules involve two different Ca-free forms of the enzyme.

Caffeine inhibition of calcium accumulation by the sarcoplasmic reticulum in mammalian skinned fibers.

Oxalate-supported Ca accumulation by the sarcoplasmic reticulum (SR) of chemically skinned mammalian skeletal muscle fibers is activated by MgATP and Ca2+ and partially inhibited by caffeine. Inhibition by caffeine is greatest when Ca2+ exceeds 0.3 to 0.4 microM, when free ATP exceeds 0.8 to 1 mM, and when the inhibitor is present from the beginning of the loading period rather than when it is added after Ca oxalate has already begun to precipitate within the SR. Under the most favorable combination of these conditions, this effect of caffeine is maximal at 2.5 to 5 mM and is half-maximal at approximately 0.5 mM. For a given concentration of caffeine, inhibition decreases to one-half of its maximum value when free ATP is reduced to 0.2 to 0.3 mM. Varying free Mg2+ (0.1 to 2 mM) or MgATP (0.03 to 10 mM) has no effect on inhibition. Average residual uptake rates in the presence of 5 mM caffeine at pCa 6.4 range from 32 to 70% of the control rates in fibers from different animals. The extent of inhibition in whole-muscle homogenates is similar to that observed in skinned fibers, but further purification of SR membranes by differential centrifugation reduces their ability to respond to caffeine. In skinned fibers, caffeine does not alter the Ca2+ concentration dependence of Ca uptake (K0.5, 0.5 to 0.8 microM; Hill n, 1.5 to 2.1). Reductions in rate due to caffeine are accompanied by proportional reductions in maximum capacity of the fibers, and this configuration can be mimicked by treating fibers with the ionophore A23187. Caffeine induces a sustained release of Ca from fibers loaded with Ca oxalate. However, caffeine-induced Ca release is transient when fibers are loaded without oxalate. The effects of caffeine on rate and capacity of Ca uptake as well as the sustained and transient effects on uptake and release observed under different conditions can be accounted for by a single mode of action of caffeine: it increases Ca permeability in a limited population of SR membranes, and these membranes coexist with a population of caffeine-insensitive membranes within the same fiber.

Calcium control of passive permeability to calcium in sarcoplasmic reticulum vesicles.

Calcium efflux from sarcoplasmic reticulum vesicles that have been equilibrated with 1-100 mM CaCl2 in the absence of ATP has two apparently first order components. The initial calcium content of each component increases with the total Ca content of the sarcoplasmic reticulum, which reaches 5, 24, and 80 nmol/mg of protein after equilibration with 1, 10, and 100 mM CaCl2, respectively. Initial rates of Ca efflux into a medium containing 10 mM EGTA increase in proportion to Ca in the loading medium up to 20 mM. Above 20 mM, efflux from the slow component clearly saturates, whereas efflux from the fast component continues to increase. The rate constant for the smaller, faster component to efflux (k congruent to 0.5 min-1) is not affected by changing the concentration of Ca either inside or outside the vesicles. The rate constant of the larger, slower component (k congruent to 0.05 min-1) is also unaffected by changes in internal Ca concentration. However, external [Ca2+] diminishes the rate constant of the slow component 6-10-fold. Inhibition by external [Ca2+] is characterized by cooperative interaction between two sites with an apparent Kd of 5.3 X 10(-6) M. The two components may represent two populations of sarcoplasmic reticulum vesicles that differ 10-fold in passive permeability to Ca when external [Ca2+] is less than 10(-6) M, and 60-100-fold when external [Ca2+] is greater than 10(-5) M. The passive permeability in one of these populations seems to be regulated by external, high affinity Ca binding sites.

Calcium accumulation by the sarcoplasmic reticulum in two populations of chemically skinned human muscle fibers. Effects of calcium and cyclic AMP.

In previous efforts to characterize sarcoplasmic reticulum function in human muscles, it has not been possible to distinguish the relative contributions of fast-twitch and slow-twitch fibers. In this study, we have used light scattering and 45Ca to monitor Ca accumulation by the sarcoplasmic reticulum of isolated, chemically skinned human muscle fibers in the presence and absence of oxalate. Oxalate (5 mM) increased the capacity for Ca accumulation by a factor of 35 and made it possible to assess both rate of Ca uptake and relative sarcoplasmic reticulum volume in individual fibers. At a fixed ionized Ca concentration, the rate and maximal capacity (an index of sarcoplasmic reticulum volume) both varied over a wide range, but fibers fell into two distinct groups (fast and slow). Between the two groups, there was a 2- to 2.5-fold difference in oxalate-supported Ca uptake rates, but no difference in average sarcoplasmic reticulum volumes. Intrinsic differences in sarcoplasmic reticulum function (Vmax, K0.5, and n) were sought to account for the distinction between fast and slow groups. In both groups, rate of Ca accumulation increased sigmoidally as [Ca++] was increased from 0.1 to 1 microM. Apparent affinities for Ca++ (K0.5) were similar in the two groups, but slow fibers had a lower Vmax and larger n values. Slow fibers also differed from fast fibers in responding with enhanced Ca uptake upon addition of cyclic AMP (10(-6) M, alone or with protein kinase). Acceleration by cyclic AMP was adequate to account for adrenaline-induced increases in relaxation rates previously observed in human muscles containing mixtures in fast-twitch and slow-twitch fibers.

Functional heterogeneity of the sarcoplasmic reticulum within sarcomeres of skinned muscle fibers.

Precipitation of Ca oxalate in the sarcoplasmic reticulum of chemically skinned rabbit psoas fibers caused an increase in light scattering which was proportional to the amount of Ca accumulated per unit fiber volume. The increase in scattering was used to measure net accumulation rates and steady-state Ca capacities of the sarcoplasmic reticulum in single fibers. The data obtained were qualitatively and quantitatively similar to those reported for isolated vesicle preparations. Under conditions in which Ca was not depleted from the medium, Ca accumulation was linear with time over much of its course. Steady-state capacities were independent of the Ca concentration; uptake rates were half-maximal at 0.5 microM Ca++ and saturated above about 1.0 microM. Both rate and capacity varied with the oxalate concentration, being maximal at oxalate concentrations greater than or equal to mM and decreasing in proportion to one another at lower concentrations, with a threshold near 0.25 mM. At the lower loads, electron micrographs showed many sarcoplasmic reticulum elements empty of precipitate alongside others that were full, whereas virtually all were filled in maximally loaded fibers. These data indicate that the Ca oxalate capacity of each fiber varies with the number and volume of elements in which Ca oxalate crystals can form at a given oxalate concentration, and that individual regions of the sarcoplasmic reticulum within each sarcomere differ in their ability to support Ca oxalate precipitation. Our working hypothesis is that this range in ability to form Ca oxalate crystals involves differences in ability to accumulate and retain ionized Ca inside the sarcoplasmic reticulum.

Chemically skinned mammalian skeletal muscle. I. The structure of skinned rabbit psoas.

We studied the morphology of rabbit psoas muscle fixed at increasing intervals of time in a chemical skinning solution (Wood et al., 1975), or after skinning and storage for times up to 1 week. The storage solution, in which the chemically skinned muscled fibers were kept at -20 degrees C, had the same ionic composition as the skinning solution but was made with 50% (v/v) glycerol. Progressive structural changes occurred in fibers exposed to skinning solution. The structural changes were essentially complete after 24-48 hr in skinning solution and no further changes were detected in fibers stored for periods up to 1 week. Structural changes were: (i) holes or gaps in the plasma membrane; (ii) swelling of mitochondria and disorganization of their internal structure; (iii) slight swelling of the sarcoplasmic reticulum; (iv) disappearance of sarcoplasmic reticulum (SR) feet from triadic gaps. Other changes included loss of glycogen between fibrils and extraction of myoplasm, or the change of its staining properties. All architectural elements of the SR, except "feet", remained during skinning and storage, and the SR remained able to accumulate calcium. The morphology of the myofilaments during chemical skinning and during storage did not differ from control fibers. We conclude that chemical skinning alters the gross structure of the plasma membrane and mitochondria, but produces minimal changes in the sarcoplasmic reticulum and contractile proteins.

Filament interaction monitored by light scattering in skinned fibers.

The intensity of light scattered by chemically skinned rabbit psoas fibers in relaxed, rigor, and activated states was monitored at 90 degrees to the incident beam. In the relaxed state, scattering varied in proportion to the volume of muscle in the beam. Scattering increased to 2.3 times the resting value when rigor was induced by withdrawal of MgATP or when the myofibrils were activated by the caffeine-induced release of Ca from the sarcoplasmic reticulum. The rigor-induced increase in scattering decreased monotonically when MgATP was reintroduced stepwise (0-100 microM). This decrease in scattering was accompanied by an increase in tension up to an optimum MgATP level of approximately 10 microM, and then tension decreased at higher concentrations (10-100 microM). The increase in scattering during both rigor and activation was dependent upon fiber length. At lengths when thick-thin filament overlap was near zero, the light signal due to rigor and activation fell to within 10% of the signal for the relaxed fiber at that length. The signal during rigor increased only minimally (approximately 10%) when stretch (approximately 1%) was applied. This increase in signal was small despite a measured 5- to 10-fold increase in tension and an estimated twofold increase in stiffness. Thus, the increased light scattering caused by rigor and activation depends on filament overlap and not tension, stiffness, or substrate binding.

Duchenne dystrophy: abnormal generation of tension and Ca++ regulation in single skinned fibers.

Skinned, single-fiber preparations from the quadriceps or gastrocneumius muscles of four ambulatory male children with Duchenne dystrophy were tested for theri ability to generate tension and to regulate CA++. To determine the intrinsic strength (P0) of the contractile material, the maximum Ca++ -activated tensions were normalized to the fiber diameters. Sixty-four percent of the Duchenne fibers had P0 values below 1.0 kg per square centimeter--the lowest value observed in control muscle--and the average P0 values of fibers from each Duchenne biopsy were significantly (p less than 0.01) below the average P0 values for control muscle fibers and for muscle fibers obtained from one obligatory carrier of the Duchenne gene. The low tensions in the Duchenne muscle fibers could not be ascribed to altered Ca++ regulation or to substrate sensitivity of the contractile proteins in the fibers, since these were normal. However, ultrastructural abnormalities of the myofilaments, which might reduce the ability of the contractile system to develop tension, were observed. Furthermore, Ca++ regulation by the sarcoplasmic reticulum (SR) was impaired in most of those muscle fibers, from both carriers and Duchenne patients, that did develop normal tension. These results suggest that in Duchenne muscle a functional disorder in the SR may precede loss of the ability of the contractile proteins to generate tension. However, since muscle fibers from Duchenne-gene carriers developed significantly greater tensions than fibers from Duchenne-patients, while yet having similar defects in Ca++ regulation, the SR disorder may not be exclusively responsible for abnormal contractile protein function.