The accessibility of the thiol groups on G- and F-actin of rabbit muscle

Bound nucleotide can control the dynamic architecture of monomeric actin

Polymerization of actin into cytoskeletal filaments is coupled to its bound adenine nucleotides. The mechanism by which nucleotide modulates actin functions has not been evident from analyses of ATP- and ADP-bound crystal structures of the actin monomer. We report that NMR chemical shift differences between the two forms are globally distributed. Furthermore, microsecond–millisecond motions are spread throughout the molecule in the ATP form, but largely confined to subdomains 1 and 2, and the nucleotide binding site in the ADP form. Through these motions, the ATP- and ADP-bound forms sample different high-energy conformations. A deafness-causing, fast-nucleating actin mutant populates the high-energy conformer of ATP-actin more than the wild-type protein, suggesting that this conformer may be on the pathway to nucleation. Together, the data suggest a model in which differential sampling of a nucleation-compatible form of the actin monomer may contribute to control of actin filament dynamics by nucleotide.

NMR shows that ATP- and ADP-actin differ globally, including ground and excited state structures and dynamic architecture. Analyses of an actin mutant suggest the high-energy conformer of ATP-actin may be on the pathway to filament nucleation.

Nutrient Intake and Physical Exercise Significantly Impact Physical Performance, Body Composition, Blood Lipids, Oxidative Stress, and Inflammation in Male Rats

BACKGROUND

Humans consuming a purified vegan diet known as the "Daniel Fast" realize favorable changes in blood lipids, oxidative stress, and inflammatory biomarkers, with subjective reports of improved physical capacity.

OBJECTIVE

We sought to determine if this purified vegan diet was synergistic with exercise in male rats.

METHODS

Long⁻Evans rats (n = 56) were assigned to be exercise trained (+E) by running on a treadmill three days per week at a moderate intensity or to act as sedentary controls with normal activity. After the baseline physical performance was evaluated by recording run time to exhaustion, half of the animals in each group were fed ad libitum for three months a purified diet formulated to mimic the Daniel Fast (DF) or a Western Diet (WD). Physical performance was evaluated again at the end of month 3, and body composition was assessed using dual-energy x-ray absorptiometry. Blood was collected for measurements of lipids, oxidative stress, and inflammatory biomarkers.

RESULTS

Physical performance at the end of month 3 was higher compared to baseline for both exercise groups (p < 0.05), with a greater percent increase in the DF + E group (99%) than in the WD + E group (51%). Body fat was lower in DF than in WD groups at the end of month 3 (p < 0.05). Blood triglycerides, cholesterol, malondialdehyde, and advanced oxidation protein products were significantly lower in the DF groups than in the WD groups (p < 0.05). No significant differences were noted in cytokines levels between the groups (p > 0.05), although IL-1β and IL-10 were elevated three-fold and two-fold in the rats fed the WD compared to the DF rats, respectively.

CONCLUSIONS

Compared to a WD, a purified diet that mimics the vegan Daniel Fast provides significant anthropometric and metabolic benefits to rats, while possibly acting synergistically with exercise training to improve physical performance. These findings highlight the importance of macronutrient composition and quality in the presence of ad libitum food intake.

Redox regulation of the actin cytoskeleton and its role in the vascular system

The actin cytoskeleton is critical for form and function of vascular cells, serving mechanical, organizational and signaling roles. Because many cytoskeletal proteins are sensitive to reactive oxygen species, redox regulation has emerged as a pivotal modulator of the actin cytoskeleton and its associated proteins. Here, we summarize work implicating oxidants in altering actin cytoskeletal proteins and focus on how these alterations affect cell migration, proliferation and contraction of vascular cells. Finally, we discuss the role of oxidative modification of the actin cytoskeleton in vivo and highlight its importance for vascular diseases.

Actin filaments-A target for redox regulation

Actin and its ability to polymerize into dynamic filaments is critical for the form and function of cells throughout the body. While multiple proteins have been characterized as affecting actin dynamics through noncovalent means, actin and its protein regulators are also susceptible to covalent modifications of their amino acid residues. In this regard, oxidation-reduction (Redox) intermediates have emerged as key modulators of the actin cytoskeleton with multiple different effects on cellular form and function. Here, we review work implicating Redox intermediates in post-translationally altering actin and discuss what is known regarding how these alterations affect the properties of actin. We also focus on two of the best characterized enzymatic sources of these Redox intermediates-the NADPH oxidase NOX and the flavoprotein monooxygenase MICAL-and detail how they have both been identified as altering actin, but share little similarity and employ different means to regulate actin dynamics. Finally, we discuss the role of these enzymes and redox signaling in regulating the actin cytoskeleton in vivo and highlight their importance for neuronal form and function in health and disease. © 2016 Wiley Periodicals, Inc.

Potential role of oxidative protein modification in energy metabolism in exercise

Exercise leads to the production of reactive oxygen species (ROS) via several sources in the skeletal muscle. In particular, the mitochondrial electron transport chain in the muscle cells produces ROS along with an elevation in the oxygen consumption during exercise. Such ROS generated during exercise can cause oxidative modification of proteins and affect their functionality. Many evidences have been suggested that some muscle proteins, i.e., myofiber proteins, metabolic signaling proteins, and sarcoplasmic reticulum proteins can be a targets modified by ROS generated due to exercise. We detected the modification of carnitine palmitoyltransferase I (CPT I) by Nε-(hexanoyl)lysine (HEL), one of the lipid peroxides, in exercised muscles, while the antioxidant astaxanthin reduced this oxidative stress-induced modification. Exercise-induced ROS may diminish CPT I activity caused by HEL modification, leading to a partly limited lipid utilization in the mitochondria. This oxidative protein modification may be useful as a potential biomarker to examine the oxidative stress levels, antioxidant compounds, and their possible benefits in exercise.

Treatment with the cysteine precursor l-2-oxothiazolidine-4-carboxylate (OTC) implicates taurine deficiency in severity of dystropathology in mdx mice

Oxidative stress has been implicated in the pathology of the lethal skeletal muscle disease Duchenne muscular dystrophy (DMD), and various antioxidants have been investigated as a potential therapy. Recently, treatment of the mdx mouse model for DMD with the antioxidant and cysteine and glutathione (GSH) precursor n-acetylcysteine (NAC) was shown to decrease protein thiol oxidation and improve muscle pathology and ex vivo muscle strength. This study further investigates the mechanism for the benefits of NAC on dystrophic muscle by administering l-2-oxothiazolidine-4-carboxylate (OTC) which also upregulates intracellular cysteine and GSH, but does not directly function as an antioxidant. We observed that OTC, like NAC, decreases protein thiol oxidation, decreases pathology and increases strength, suggesting that the both NAC and OTC function via increasing cysteine and GSH content of dystrophic muscle. We demonstrate that mdx muscle is not deficient in either cysteine or GSH and that these are not increased by OTC treatment. However, we show that dystrophic muscle of 12 week old mdx mice is deficient in taurine, a by-product of disposal of excess cysteine, a deficiency that is ameliorated by OTC treatment. These data suggest that in dystrophic muscles, apart from the strong association of increased oxidative stress and protein thiol oxidation with dystropathology, another major issue is an insufficiency in taurine that can be corrected by increasing the availability of cysteine. This study provides new insight into the molecular mechanism underlying the benefits of NAC in muscular dystrophy and supports the use of OTC as an alternative drug for potential clinical applications to DMD.

Oxidative stress and pathology in muscular dystrophies: focus on protein thiol oxidation and dysferlinopathies

The muscular dystrophies comprise more than 30 clinical disorders that are characterized by progressive skeletal muscle wasting and degeneration. Although the genetic basis for many of these disorders has been identified, the exact mechanism for pathogenesis generally remains unknown. It is considered that disturbed levels of reactive oxygen species (ROS) contribute to the pathology of many muscular dystrophies. Reactive oxygen species and oxidative stress may cause cellular damage by directly and irreversibly damaging macromolecules such as proteins, membrane lipids and DNA; another major cellular consequence of reactive oxygen species is the reversible modification of protein thiol side chains that may affect many aspects of molecular function. Irreversible oxidative damage of protein and lipids has been widely studied in Duchenne muscular dystrophy, and we have recently identified increased protein thiol oxidation in dystrophic muscles of the mdx mouse model for Duchenne muscular dystrophy. This review evaluates the role of elevated oxidative stress in Duchenne muscular dystrophy and other forms of muscular dystrophies, and presents new data that show significantly increased protein thiol oxidation and high levels of lipofuscin (a measure of cumulative oxidative damage) in dysferlin-deficient muscles of A/J mice at various ages. The significance of this elevated oxidative stress and high levels of reversible thiol oxidation, but minimal myofibre necrosis, is discussed in the context of the disease mechanism for dysferlinopathies, and compared with the situation for dystrophin-deficient mdx mice.

ICU-acquired weakness: mechanisms of disability

PURPOSE OF REVIEW

ICU-acquired weakness (ICUAW) is now recognized as a major complication of critical illness. There is no doubt that ICUAW is prevalent - some might argue ubiquitous - after critical illness, but its true role, the interaction with preexisting nerve and muscle lesions as well as its contribution to long-term functional disability, remains to be elucidated.

RECENT FINDINGS

In this article, we review the current state-of-the-art of the basic pathophysiology of nerve and muscle weakness after critical illness and explore the current literature on ICUAW with a special emphasis on the most important mechanisms of weakness.

SUMMARY

Variable contributions of structural and functional changes likely contribute to both early and late myopathy and neuropathy, although the specifics of the temporality of both processes, and the influence patient comorbidities, age, and nature of the ICU insult have on them, remain to be determined.

The natural product cucurbitacin E inhibits depolymerization of actin filaments

Although small molecule actin modulators have been widely used as research tools, only one cell-permeable small molecule inhibitor of actin depolymerization (jasplakinolide) is commercially available. We report that the natural product cucurbitacin E inhibits actin depolymerization and show that its mechanism of action is different from jasplakinolide. In assays using pure fluorescently labeled actin, cucurbitacin E specifically affects depolymerization without affecting polymerization. It inhibits actin depolymerization at substoichiometric concentrations up to 1:6 cucurbitacin E:actin. Cucurbitacin E specifically binds to filamentous actin (F-actin) forming a covalent bond at residue Cys257, but not to monomeric actin (G-actin). On the basis of its compatibility with phalloidin staining, we show that cucurbitacin E occupies a different binding site on actin filaments. Using loss of fluorescence after localized photoactivation, we found that cucurbitacin E inhibits actin depolymerization in live cells. Cucurbitacin E is a widely available plant-derived natural product, making it a useful tool to study actin dynamics in cells and actin-based processes such as cytokinesis.

Beyond atrophy: redox mechanisms of muscle dysfunction in chronic inflammatory disease

Chronic inflammatory diseases such as heart failure, cancer and arthritis have secondary effects on skeletal muscle that cause weakness and exercise intolerance. These symptoms exacerbate illness and make death more likely. Weakness is not simply a matter of muscle atrophy. Functional studies show that contractile dysfunction, i.e. a reduction in specific force, makes an equally important contribution to overall weakness. The most clearly defined mediator of contractile dysfunction is tumour necrosis factor (TNF). TNF serum levels are elevated in chronic disease, correlate with muscle weakness, and are a predictor of morbidity and mortality. Research is beginning to unravel the mechanism by which TNF depresses specific force. TNF acts via the TNFR1 receptor subtype to depress force by increasing cytosolic oxidant activity. Oxidants depress myofibrillar function, decreasing specific force without altering calcium regulation or other aspects of myofibrillar mechanics. Beyond these concepts, the intracellular mechanisms that depress specific force remain undefined. We do not know the pathway by which receptor-ligand interaction stimulates oxidant production. Nor do we know the type(s) of oxidants stimulated by TNF, their intracellular source(s), or their molecular targets. Investigators in the field are pursuing these issues with the long-term goal of preserving muscle function in individuals afflicted by chronic disease.

Effect of resistance training on blood oxidative stress in Parkinson disease

Oxidative stress seems to be involved in the pathogenesis of Parkinson disease (PD). Exercise training can increase endogenous antioxidant protection and decrease the production of reactive oxygen and nitrogen species.

PURPOSE

To investigate the effect of exercise training on oxidative status in persons with PD.

METHODS

Sixteen subjects with PD were match-randomly assigned to resistance exercise (n = 8) or a no-exercise control group (n = 8) on the basis of disease stage (Hoehn and Yahr stages I and II) and sex. Supervised exercise was performed twice weekly for 8 wk, consisting of three sets each of the leg press, leg curl, and calf press. Resting blood samples were taken from subjects before and after the intervention and assayed for markers of oxidative stress [malondialdehyde (MDA) and hydrogen peroxide (H2O2)] and antioxidant capacity (superoxide dismutase, catalase, glutathione peroxidase, and trolox-equivalent antioxidant capacity).

RESULTS

The exercise program was well-tolerated and associated with modest trends toward decreased oxidative stress and increased antioxidant capacity. The two biomarkers of oxidative stress were decreased after exercise training [MDA (15%) and H2O2 (16%)]. With these changes, a postintervention difference was apparent between the resistance exercise training and control groups for H2O2 (P = 0.007), with a trend for difference noted for MDA (P = 0.06). The mean increases in superoxide dismutase (9%) and glutathione peroxidase (15%) noted in the exercise training group were not statistically significant (P > 0.05).

CONCLUSIONS

Short-term resistance training may be associated with reduced oxidative stress in subjects with PD. Future studies with larger samples, inclusive of a higher volume of resistance exercise, are needed to extend these findings.

Effect of exercise on oxidative stress biomarkers

Acute bouts of aerobic and anaerobic exercise can induce a state of oxidative stress, as indicated by an increase in oxidized molecules in a variety of tissues and body fluids. The extent of oxidation is dependent on the exercise mode, intensity, and duration, and is specifically related to the degree of oxidant production. Findings of increased oxidative stress have been reported for both healthy and diseased subjects following single bouts of exercise. While acute exercise has the ability to induce an oxidative stress, this same exercise stimulus appears necessary to allow for an upregulation in endogenous antioxidant defenses. This chapter presents a summary of exercise-induced oxidative stress.

Exercise-induced oxidative stress: cellular mechanisms and impact on muscle force production

The first suggestion that physical exercise results in free radical-mediated damage to tissues appeared in 1978, and the past three decades have resulted in a large growth of knowledge regarding exercise and oxidative stress. Although the sources of oxidant production during exercise continue to be debated, it is now well established that both resting and contracting skeletal muscles produce reactive oxygen species and reactive nitrogen species. Importantly, intense and prolonged exercise can result in oxidative damage to both proteins and lipids in the contracting myocytes. Furthermore, oxidants can modulate a number of cell signaling pathways and regulate the expression of multiple genes in eukaryotic cells. This oxidant-mediated change in gene expression involves changes at transcriptional, mRNA stability, and signal transduction levels. Furthermore, numerous products associated with oxidant-modulated genes have been identified and include antioxidant enzymes, stress proteins, DNA repair proteins, and mitochondrial electron transport proteins. Interestingly, low and physiological levels of reactive oxygen species are required for normal force production in skeletal muscle, but high levels of reactive oxygen species promote contractile dysfunction resulting in muscle weakness and fatigue. Ongoing research continues to probe the mechanisms by which oxidants influence skeletal muscle contractile properties and to explore interventions capable of protecting muscle from oxidant-mediated dysfunction.

Free radicals and muscle fatigue: Of ROS, canaries, and the IOC

Skeletal muscle fibers continually generate reactive oxygen species (ROS) at a slow rate that increases during muscle contraction. This activity-dependent increase in ROS production contributes to fatigue of skeletal muscle during strenuous exercise. Existing data suggest that muscle-derived ROS primarily act on myofibrillar proteins to inhibit calcium sensitivity and depress force. Decrements in calcium sensitivity and force are acutely reversible by dithiothreitol, a thiol-selective reducing agent. These observations suggest that thiol modifications on one or more regulatory proteins are responsible for oxidant-induced losses during fatigue. More intense ROS exposure leads to losses in calcium regulation that mimic pathologic changes and are not reversible. Studies in humans, quadrupeds, and isolated muscle preparations indicate that antioxidant pretreatment can delay muscle fatigue. In humans, this phenomenon is best defined for N-acetylcysteine (NAC), a reduced thiol donor that supports glutathione resynthesis. NAC has been shown to inhibit fatigue in healthy adults during electrical muscle activation, inspiratory resistive loading, handgrip exercise, and intense cycling. These findings identify ROS as endogenous mediators of muscle fatigue and highlight the importance of future research to (a) define the cellular mechanism of ROS action and (b) develop antioxidants as novel therapeutic interventions for treating fatigue.

Reversible glutathionylation regulates actin polymerization in A431 cells

In response to growth factor stimulation, many mammalian cells transiently generate reactive oxygen species (ROS) that lead to the elevation of tyrosine-phosphorylated and glutathionylated proteins. While investigating EGF-induced glutathionylation in A431 cells, paradoxically we found deglutathionylation of a major 42-kDa protein identified as actin. Mass spectrometric analysis revealed that the glutathionylation site is Cys-374. Deglutathionylation of the G-actin leads to about a 6-fold increase in the rate of polymerization. In vivo studies revealed a 12% increase in F-actin content 15 min after EGF treatment, and F-actin was found in the cell periphery suggesting that in response to growth factor, actin polymerization in vivo is regulated by a reversible glutathionylation mechanism. Deglutathionylation is most likely catalyzed by glutaredoxin (thioltranferase), because Cd(II), an inhibitor of glutaredoxin, inhibits intracellular actin deglutathionylation at 2 microM comparable with its IC(50) in vitro. Moreover, mass spectral analysis showed efficient transfer of GSH from immobilized S-glutathionylated actin to glutaredoxin. Overall, this study revealed a novel physiological relevance of actin polymerization regulated by reversible glutathionylation of the penultimate cysteine mediated by growth factor stimulation.

Invited Review: redox modulation of skeletal muscle contraction: what we know and what we don't

Over the past decade, reactive oxygen species (ROS) and nitric oxide (NO) derivatives have been established as physiological modulators of skeletal muscle function. This mini-review addresses the roles of these molecules as endogenous regulators of muscle contraction. The article is organized in two parts. First, established concepts are briefly outlined. This section provides an overview of ROS production by muscle, antioxidant buffers that oppose ROS effects, enzymatic synthesis of NO in muscle, the effects of endogenous ROS on contractile function, and NO as a contractile modulator. Second, a selected group of unresolved topics are highlighted. These more controversial issues include putative source(s) of regulatory ROS, the relative importance of the two NO synthase isoforms constitutively coexpressed by muscle fibers, molecular mechanisms of ROS and NO action, and the physiological relevance of redox regulation. By discussing current questions, as well as the established paradigm, this article is intended to further debate and stimulate research in this area.

Superoxide, hydroxyl radical, and hydrogen peroxide effects on single-diaphragm fiber contractile apparatus

Reactive oxygen species contribute to diaphragm dysfunction in certain pathophysiological conditions (i.e., sepsis and fatigue). However, the precise alterations induced by reactive oxygen species or the specific species that are responsible for the derangements in skeletal muscle function are incompletely understood. In this study, we evaluated the effect of the superoxide anion radical (O(2)(-).), hydroxyl radical (.OH), and hydrogen peroxide (H(2)O(2)) on maximum calcium-activated force (F(max)) and calcium sensitivity of the contractile apparatus in chemically skinned (Triton X-100) single rat diaphragm fibers. O(2)(-). was generated using the xanthine/xanthine oxidase system;.OH was generated using 1 mM FeCl(2), 1 mM ascorbate, and 1 mM H(2)O(2); and H(2)O(2) was added directly to the bathing medium. Exposure to O(2)(-). or.OH significantly decreased F(max) by 14.5% (P < 0.05) and 43.9% (P < 0. 005), respectively.OH had no effect on Ca(2+) sensitivity. Neither 10 nor 1,000 microM H(2)O(2) significantly altered F(max) or Ca(2+) sensitivity. We conclude that the diaphragm is susceptible to alterations induced by a direct effect of.OH and O(2)(-)., but not H(2)O(2), on the contractile proteins, which could, in part, be responsible for prolonged depression in contractility associated with respiratory muscle dysfunction in certain pathophysiological conditions.

Effect of hydrogen peroxide and dithiothreitol on contractile function of single skeletal muscle fibres from the mouse

1. We used intact single fibres from a mouse foot muscle to study the role of oxidation-reduction in the modulation of contractile function. 2. The oxidant hydrogen peroxide (H2O2, 100-300 microM) for brief periods did not change myoplasmic Ca2+ concentrations ([Ca2+]i) during submaximal tetani. However, force increased by 27 % during the same contractions. 3. The effects of H2O2 were time dependent. Prolonged exposures resulted in increased resting and tetanic [Ca2+]i, while force was significantly diminished. The force decline was mainly due to reduced myofibrillar Ca2+ sensitivity. There was also evidence of altered sarcoplasmic reticulum (SR) function: passive Ca2+ leak was increased and Ca2+ uptake was decreased. 4. The reductant dithiothreitol (DTT, 0.5-1 mM) did not change tetanic [Ca2+]i, but decreased force by over 40 %. This was completely reversed by subsequent incubations with H2O2. The force decline induced by prolonged exposure to H2O2 was reversed by subsequent exposure to DTT. 5. These results show that the elements of the contractile machinery are differentially responsive to changes in the oxidation-reduction balance of the muscle fibres. Myofibrillar Ca2+ sensitivity appears to be especially susceptible, while the SR functions (Ca2+ leak and uptake) are less so.

Skeletal muscle force and actomyosin ATPase activity reduced by nitric oxide donor

Nitric oxide (NO) may exert direct effects on actin-myosin cross-bridge cycling by modulating critical thiols on the myosin head. In the present study, the effects of the NO donor sodium nitroprusside (SNP; 100 microM to 10 mM) on mechanical properties and actomyosin adenosinetriphosphatase (ATPase) activity of single permeabilized muscle fibers from the rabbit psoas muscle were determined. The effects of N-ethylmaleimide (NEM; 5-250 microM), a thiol-specific alkylating reagent, on mechanical properties of single fibers were also evaluated. Both NEM (>/=25 microM) and SNP (>/=1 mM) significantly inhibited isometric force and actomyosin ATPase activity. The unloaded shortening velocity of SNP-treated single fibers was decreased, but to a lesser extent, suggesting that SNP effects on isometric force and actomyosin ATPase were largely due to decreased cross-bridge recruitment. The calcium sensitivity of SNP-treated single fibers was also decreased. The effects of SNP, but not NEM, on force and actomyosin ATPase activity were reversed by treatment with 10 mM DL-dithiothreitol, a thiol-reducing agent. We conclude that the NO donor SNP inhibits contractile function caused by reversible oxidation of contractile protein thiols.

Disulphide cross-linking of smooth-muscle and non-muscle caldesmon to the C-terminus of actin in reconstituted and native thin filaments

It was reported that chicken gizzard smooth-muscle caldesmon Cys-580 can be disulphide-cross-linked to the C-terminal pen-ultimate residue (Cys-374) of actin, indicating that these residues are close in the protein complex [Graceffa, P. and Jancso, A. (1991) J. Biol. Chem. 266, 20305-20310]. Since the possibility that the cross-link involves a cysteine residue other than actin Cys-374 was not absolutely excluded, more direct evidence was sought for the identify of the cysteine residues involved in the cross-link. We show here that caldesmon could not be disulphide-cross-linked to actin which had Cys-374 removed by carboxypeptidase A digestion, providing direct support for the participation of actin Cys-374 in the cross-link to caldesmon. In order to assign the caldesmon cysteine residue involved in the cross-link, use was made of caldesmon from porcine stomach muscle, which is shown to contain one cysteine residue close to, or at, position 580, in contrast with chicken gizzard caldesmon, which has an additional cysteine residue at position 153. The porcine stomach caldesmon also formed a disulphide-cross-link to actin, further supporting the original conclusion that Cys-580 of the chicken gizzard caldesmon had been cross-linked to actin. Disulphide-cross-linking with similar yield was also observed in native chicken gizzard muscle thin filaments, indicating that the interaction between actin and the C-terminal domain of caldesmon is the same in native and reconstituted thin filaments. The much smaller non-muscle isoform of caldesmon, from rabbit liver, could be similarly cross-linked to actin, consistent with the sequence similarity between the C-terminal domain of muscle and non-muscle caldesmon. The ability to cross-link caldesmon Cys-580 to actin Cys-374 suggests the possibility that the Cys-580 region of caldesmon and the C-terminus of actin form part of the actin-caldesmon binding interface.

Chemical evidence for the existence of activated G-actin

Globular actin (G-actin) will polymerize to form filamentous actin (F-actin) under physiological ionic conditions, and is known to be regulated by univalent and bivalent cations, such as K+ and Mg2+. The current concept of this process involves four steps: activation, nucleation, elongation and annealing. Evidence for the existence of activated G-protein has been suggested by changes in the resistance to proteolysis [Rich & Estes (1976) J. Mol. Biol. 104, 777-792] and u.v.-light absorption [Rouayrenc & Travers (1981) Eur. J. Biochem. 116, 73-77]. More recently we [Liu et al. (1990) Biochem. J. 266, 453-459] have provided direct chemical evidence for extensive conformational changes during the transformation of G-actin into F-actin. In this study we now present direct chemical evidence for the existence of a short-lived species, an activated form of G-actin, which can be detected by changes in the accessibility of the free thiol groups on the G-actin molecule when modified by a specific thiol-group-targeted reagent, 7-dimethylamino-4-methyl-3-N-maleimidylcoumarin (DACM). The presence of K+ and/or Mg2+ ions caused a large increase in the accessibility of the thiol groups of Cys-217 and Cys-374, but not those of Cys-10 and Cys-257. Mg2+ effected relatively faster changes than did K+ ions. The results suggest that the function of these ions is to convert G-actin into an activated form, and further suggest that the change in conformation is mainly confined to the large domain. Such changes at least involve certain portions of the G-actin molecule that contain Cys-217 and Cys-374. On the other hand, little or no significant change could be observed in the small domain of G-actin as reflected by the accessibility of Cys-10. The bound nucleotide remained as ATP during the activation of G-actin and was hydrolysed to ADP on polymerization. The activated G-actin had a life-time of about 8 min or less depending on the concentration of G-actin. At higher protein concentration, its life-time was much shorter, probably owing to the earlier onset of polymerization, which apparently is governed by the concentration of the activated form. The life-time of this new species can be extended by lowering the temperature and is less affected by actin concentration. This new species is considered to be an activated form of G-actin, since polymerization renders all the thiol groups on actin inaccessible to the reagent DACM.

Effects of sulphydryl modification on skinned rat skeletal muscle fibres using 5,5'-dithiobis(2-nitrobenzoic acid)

1. The sulphydryl groups of skinned skeletal muscle fibres have been reacted with 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) in order to determine whether the effects of modifications to the contractile proteins are reflected in changes in the physiological properties of the contractile apparatus and Ca(2+)-regulatory system. 2. Results obtained from fast-twitch and slow-twitch rat fibres which were treated with DTNB (10 mM, pH 8.6, 5 degrees C) for various periods of time under relaxing conditions showed that a major effect of the modification was to reduce the level of maximally Ca(2+)-activated force and fibre stiffness. Force and fibre stiffness were found to decline in proportion. Treatment with DTNB under these conditions did not cause a rise in force or fibre stiffness in relaxed fibres of either type. 3. The effects induced by DTNB under relaxing conditions were substantially reversed by exposure to the reducing agent dithiothreitol (DTT) (10 mM, pH 7.1, 23 degrees C). Force abolished by 30-35 s treatment with DTNB recovered after subsequent DTT treatment to 67 +/- 3% (mean +/- S.E.M., n = 4) in fast-twitch fibres and to 91 +/- 2% (n = 7) in slow-twitch fibres. These results were significantly different (t test, P less than 0.001) indicating that the level of force recovery depended upon the fibre type. 4. DTNB was found to affect not only the maximal Ca(2+)-activated force, but also the force-pCa (pCa = -log10[Ca2+]) relationships of the fibres in a complex, fibre-type specific way. DTT treatment partially reversed these DTNB effects. 5. The skinned fibre preparations reacted differently with DTNB under rigor conditions than under relaxing conditions, indicating that rigor modifies the reactivity of the functional sulphydryl groups to the thiol-targeted agents. 6. When superprecipitation assays (an in vitro analogue of fibre contraction) were carried out with recombined myofibrillar proteins which had been previously reacted with DTNB it was found that modification of myosin, but not modification of thin filament proteins, led to changes in the superprecipitation reaction. 7. Both the skinned fibre results and the superprecipitation results indicate that the effects of DTNB upon the fibre characteristics are primarily due to modifications of the sulphydryl groups of myosin. Therefore, these results show that myosin is not only involved in determining the ability of the contractile apparatus to develop force but also in determining the Ca(2+)-regulatory characteristics of the muscle fibre.