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5. Ca2+ and force during dynamic contractions in mouse intact skeletal muscle fibers.

Author

Fukutani, Atsuki, Westerblad, Håkan, Jardemark, Kent, and Bruton, Joseph

Subjects
MUSCLE contraction, FIBERS, SKELETAL muscle, ECCENTRICS (Machinery), MICE, ACTOMYOSIN
Abstract

Muscle fiber force production is determined by the excitation frequency of motor nerves, which induce transient increases in cytoplasmic free Ca2+ concentration ([Ca2+]i) and the force-generating capacity of the actomyosin cross-bridges. Previous studies suggest that, in addition to altered cross-bridge properties, force changes during dynamic (concentric or eccentric) contraction might be affected by Ca2+-dependent components. Here we investigated this by measuring [Ca2+]i and force in mouse muscle fibers undergoing isometric, concentric, and eccentric contractions. Intact single muscle fibers were dissected from the flexor digitorum brevis muscle of mice. Fibers were electrically activated isometrically at 30–100 Hz and after reaching the isometric force plateau, they were actively shortened or stretched. We calculated the ratio (relative changes) in force and [Ca2+]i attained in submaximal (30 Hz) and near-maximal (100 Hz) contractions under isometric or dynamic conditions. Tetanic [Ca2+]i was similar during isometric, concentric and eccentric phases of contraction at given stimulation frequencies while the forces were clearly different depending on the contraction types. The 30/100 Hz force ratio was significantly lower in the concentric (44.1 ± 20.3%) than in the isometric (50.3 ± 20.4%) condition (p = 0.005), whereas this ratio did not differ between eccentric and isometric conditions (p = 0.186). We conclude that the larger force decrease by decreasing the stimulation frequency during concentric than during isometric contraction is caused by decreased myofibrillar Ca2+ sensitivity, not by the decreased [Ca2+]i. [ABSTRACT FROM AUTHOR]

Published
2024
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7. Ryanodine receptor fragmentation and sarcoplasmic reticulum Ca²⁺ leak after one session of high-intensity interval exercise

Author

Place, Nicolas, Ivarsson, Niklas, Venckunas, Tomas, Neyroud, Daria, Brazaitis, Marius, Cheng, Arthur J., Ochala, Julien, Kamandulis, Sigitas, Girard, Sebastien, Volungevičius, Gintautas, Paužas, Henrikas, Mekideche, Abdelhafid, Kayser, Bengt, Martinez-Redondo, Vicente, Ruas, Jorge L., Bruton, Joseph, Truffert, Andre, Lanner, Johanna T., Skurvydas, Albertas, and Westerblad, Håkan

Published
2015

8. Sphingomyelinase activity promotes atrophy and attenuates force in human muscle fibres and is elevated in heart failure patients

Author

Olsson, Karl, primary, Cheng, Arthur J., additional, Al‐Ameri, Mamdoh, additional, Tardif, Nicolas, additional, Melin, Michael, additional, Rooyackers, Olav, additional, Lanner, Johanna T., additional, Westerblad, Håkan, additional, Gustafsson, Thomas, additional, Bruton, Joseph D., additional, and Rullman, Eric, additional

Published
2022
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11. Rational antibody design for undruggable targets using kinetically controlled biomolecular probes

Author

Trkulja, Carolina L., primary, Jungholm, Oscar, additional, Davidson, Max, additional, Jardemark, Kent, additional, Marcus, Monica M., additional, Hägglund, Jessica, additional, Karlsson, Anders, additional, Karlsson, Roger, additional, Bruton, Joseph, additional, Ivarsson, Niklas, additional, Srinivasa, Sreesha P., additional, Cavallin, Alexandra, additional, Svensson, Peder, additional, Jeffries, Gavin D. M., additional, Christakopoulou, Maria-Nefeli, additional, Reymer, Anna, additional, Ashok, Anaswara, additional, Willman, Gabriella, additional, Papadia, Daniela, additional, Johnsson, Emma, additional, and Orwar, Owe, additional

Published
2021
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19. Insulin increases near-membrane but not global Ca2+ in isolated skeletal muscle

Author

Bruton, joseph D., Katz, Abram, and Westerblad, Hakan

Subjects
Insulin -- Research, Calcium ions -- Research, Muscles -- Research, Glucose metabolism -- Research, Science and technology
Abstract

It has long been debated whether changes in [Ca.sup.2+] are involved in insulin-stimulated glucose uptake in skeletal muscle. We have now investigated the effect of insulin on the global free myoplasmic [Ca.sup.2+] concentration and the near-membrane free [Ca.sup.2+] concentration ([[[Ca.sup.2+]].sub.mem]) in intact, single skeletal muscle fibers from mice by using fluorescent [Ca.sup.2+] indicators. Insulin has no effect on the global free myoplasmic [Ca.sup.2+] concentration. However, insulin increases [[[Ca.sup.2+]].sub.mem] by [approximately equal to] 70% and the half-maximal increase in [[[Ca.sup.2+]].sub.mem] occurs at an insulin concentration of 110 microunits per ml. The increase in [[[Ca.sup.2+]].sub.mem] by insulin persists when sarcoplasmic reticulum [Ca.sup.2+] release is inhibited but is lost by perfusing the fiber with a low [Ca.sup.2+] medium or by addition of L-type [Ca.sup.2+] channel inhibitors. Thus, insulin appears to stimulate [Ca.sup.2+] entry into muscle cells via L-type [Ca.sup.2+] channels. Wortmannin, which inhibits insulin-mediated activation of glucose transport in isolated skeletal muscle, also inhibits the insulin-mediated increase in [[[Ca.sup.2+]].sub.mem]. These data demonstrate a new facet of insulin signaling and indicate that insulin-mediated increases in [[[Ca.sup.2+]].sub.mem] in skeletal muscle may underlie important actions of the hormone.

Published
1999

31. SR Ca2+ leak in skeletal muscle fibers acts as an intracellular signal to increase fatigue resistance.

Author

Ivarsson, Niklas, Mattsson, C. Mikael, Cheng, Arthur J, Bruton, Joseph D, Ekblom, Björn, Lanner, Johanna T, Westerblad, Håkan, Ivarsson, Niklas, Mattsson, C. Mikael, Cheng, Arthur J, Bruton, Joseph D, Ekblom, Björn, Lanner, Johanna T, and Westerblad, Håkan

Abstract

Effective practices to improve skeletal muscle fatigue resistance are crucial for athletes as well as patients with dysfunctional muscles. To this end, it is important to identify the cellular signaling pathway that triggers mitochondrial biogenesis and thereby increases oxidative capacity and fatigue resistance in skeletal muscle fibers. Here, we test the hypothesis that the stress induced in skeletal muscle fibers by endurance exercise causes a reduction in the association of FK506-binding protein 12 (FKBP12) with ryanodine receptor 1 (RYR1). This will result in a mild Ca2+ leak from the sarcoplasmic reticulum (SR), which could trigger mitochondrial biogenesis and improved fatigue resistance. After giving mice access to an in-cage running wheel for three weeks, we observed decreased FKBP12 association to RYR1, increased baseline [Ca2+]i, and signaling associated with greater mitochondrial biogenesis in muscle, including PGC1α1. After six weeks of voluntary running, FKBP12 association is normalized, baseline [Ca2+]i returned to values below that of nonrunning controls, and signaling for increased mitochondrial biogenesis was no longer present. The adaptations toward improved endurance exercise performance that were observed with training could be mimicked by pharmacological agents that destabilize RYR1 and thereby induce a modest Ca2+ leak. We conclude that a mild RYR1 SR Ca2+ leak is a key trigger for the signaling pathway that increases muscle fatigue resistance.

Published
2019
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35. Muscle fatigue: from observations in humans to underlying mechanisms studied in intact single muscle fibres

Author

Place, Nicolas, Yamada, Takashi, Bruton, Joseph, Westerblad, Håkan, Place, Nicolas, Yamada, Takashi, Bruton, Joseph, and Westerblad, Håkan

Abstract

Prolonged dynamic exercise and sustained isometric contractions induce muscle fatigue, as manifested by decreased performance and a reduction in the maximum voluntary contraction force. Studies with non-invasive measurements in exercising humans show that mechanisms located beyond the sarcolemma are important in the fatigue process. In this review, we describe probable cellular mechanisms underlying fatigue-induced changes in excitation-contraction (E-C) coupling occurring in human muscle fibres during strenuous exercise. We use fatigue-induced changes observed in intact single muscle fibres, where force and cellular Ca2+ handling can be directly measured, to explain changes in E-C coupling observed in human muscle during exercise

Published
2018

36. Impaired sarcoplasmic reticulum Ca2+ release is the major cause of fatigue‐induced force loss in intact single fibres from human intercostal muscle.

Author

Olsson, Karl, Cheng, Arthur J., Al‐Ameri, Mamdoh, Wyckelsma, Victoria L., Rullman, Eric, Westerblad, Håkan, Lanner, Johanna T., Gustafsson, Thomas, and Bruton, Joseph D.

Subjects
SARCOPLASMIC reticulum, FIBERS, MUSCLE mass, MUSCLES, SKELETAL muscle
Abstract

Key points: Changes in intramuscular Ca2+ handling contribute to development of fatigue and disease‐related loss of muscle mass and function. To date, no data on human intact living muscle fibres have been described.We manually dissected intact single fibres from human intercostal muscle and simultaneously measured force and myoplasmic free [Ca2+] at physiological temperature.Based on their fatigue resistance, two distinct groups of fibres were distinguished: fatigue sensitive and fatigue resistant. Force depression in fatigue and during recovery was due to impaired sarcoplasmic reticulum Ca2+ release in both groups of fibres.Acidification did not affect force production in unfatigued fibres and did not affect fatigue development in fatigue‐resistant fibres.The current study provides novel insight into the mechanisms of fatigue in human intercostal muscle. Changes in intracellular Ca2+ handling of individual skeletal muscle fibres cause a force depression following physical activity and are also implicated in disease‐related loss of function. The relation of intracellular Ca2+ handling with muscle force production and fatigue tolerance is best studied in intact living single fibres that allow continuous measurements of force and myoplasmic free [Ca2+] during repeated contractions. To this end, manual dissections of human intercostal muscle biopsies were performed to isolate intact single fibres. Based on the ability to maintain tetanic force at >40% of the initial value during 500 fatiguing contractions, fibres were classified as either fatigue sensitive or fatigue resistant. Following fatigue all fibres demonstrated a marked reduction in sarcoplasmic reticulum Ca2+ release, while myofibrillar Ca2+ sensitivity was either unaltered or increased. In unfatigued fibres, acidosis caused a reduction in myofibrillar Ca2+ sensitivity that was offset by increased tetanic myoplasmic free [Ca2+] so that force remained unaffected. Acidification did not affect the fatigue tolerance of fatigue‐resistant fibres, whereas uncertainties remain whether or not fatigue‐sensitive fibres were affected. Following fatigue, a prolonged force depression at preferentially low‐frequency stimulation was evident in fatigue‐sensitive fibres and this was caused exclusively by an impaired sarcoplasmic reticulum Ca2+ release. We conclude that impaired sarcoplasmic reticulum Ca2+ release is the predominant mechanism of force depression both in the development of, and recovery from, fatigue in human intercostal muscle. Key points: Changes in intramuscular Ca2+ handling contribute to development of fatigue and disease‐related loss of muscle mass and function. To date, no data on human intact living muscle fibres have been described.We manually dissected intact single fibres from human intercostal muscle and simultaneously measured force and myoplasmic free [Ca2+] at physiological temperature.Based on their fatigue resistance, two distinct groups of fibres were distinguished: fatigue sensitive and fatigue resistant. Force depression in fatigue and during recovery was due to impaired sarcoplasmic reticulum Ca2+ release in both groups of fibres.Acidification did not affect force production in unfatigued fibres and did not affect fatigue development in fatigue‐resistant fibres.The current study provides novel insight into the mechanisms of fatigue in human intercostal muscle. [ABSTRACT FROM AUTHOR]

Published
2020
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37. Additional file 2: Figure S2. of Impaired Ca2+ release contributes to muscle weakness in a rat model of critical illness myopathy

Author

Llano-Diez, Monica, Cheng, Arthur, Jonsson, William, Ivarsson, Niklas, HĂĽkan Westerblad, Sun, Vic, Cacciani, Nicola, Larsson, Lars, and Bruton, Joseph

Subjects
nervous system, fungi, cardiovascular system, musculoskeletal system, tissues
Abstract

Typical examples of the negative controls obtained for Na+ channels, DHPR, RyR and SERCA1 immunohistochemical staining (PDF 871 kb)

Published
2016
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38. Additional file 1: Figure S1. of Impaired Ca2+ release contributes to muscle weakness in a rat model of critical illness myopathy

Author

Llano-Diez, Monica, Cheng, Arthur, Jonsson, William, Ivarsson, Niklas, HĂĽkan Westerblad, Sun, Vic, Cacciani, Nicola, Larsson, Lars, and Bruton, Joseph

Abstract

Coomassie protein staining. Membranes used for western blot analysis of Na+ channels, DHPR (left panel), RyR1and SERCA1 (right panel). Lanes are marked as SHAM (S) or ICU (I); the value 110Â kDa refers to the protein marker size in the ladder lane (PDF 5931 kb)

Published
2016
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39. Additional file 4: Figure S3. of Intracellular Ca2+-handling differs markedly between intact human muscle fibers and myotubes

Author

Olsson, Karl, Cheng, Arthur, Alam, Seher, Mamdoh Al-Ameri, Rullman, Eric, Westerblad, Håkan, Lanner, Johanna, Bruton, Joseph, and Gustafsson, Thomas

Subjects
chemical and pharmacologic phenomena
Abstract

mRNA expression of slow type skeletal muscle/β-cardiac, type IIa and type IIx MHCs in human muscle fibers, myotubes and myoblasts. The mRNA quantity of MHC I, MHC IIa, and MHC IIx differs markedly between human muscle fibers, myotubes and myoblasts. (A) mRNA quantities of MHC I, MHC IIa, and MHC IIx in human muscle fibers, myotubes, and myoblasts. Data are arbitrary units where the values have been adjusted so that the mRNA quantities of the different MHC isoforms are approximately equal in muscle fibers so to better visualize the differences within each MHC isoform between the different cell types. Data are presented as the mean ± SEM. Aterisk denotes P

Published
2015
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40. Additional file 3: Figure S2. of Intracellular Ca2+-handling differs markedly between intact human muscle fibers and myotubes

Author

Olsson, Karl, Cheng, Arthur, Alam, Seher, Mamdoh Al-Ameri, Rullman, Eric, Westerblad, Håkan, Lanner, Johanna, Bruton, Joseph, and Gustafsson, Thomas

Abstract

Confirmation of reproducibility of [Ca2+]i transients and force production in human muscle fibers. Typical example of reproducibility of [Ca2+]i transients and force production following electrical stimulation in a human intercostal muscle fiber. (A) Percentage of peak ΔR/R0 (representing [Ca2+]i) and (B) force production in a human intercostal muscle fiber following a single 70 Hz 350 ms train of current pulses. Blue lines represent recordings following the first tetanus 30 min after Indo-1 injection, and red lines represent recordings 8 min thereafter.

Published
2015
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41. Additional file 2: Figure S1. of Intracellular Ca2+-handling differs markedly between intact human muscle fibers and myotubes

Author

Olsson, Karl, Cheng, Arthur, Alam, Seher, Mamdoh Al-Ameri, Rullman, Eric, Westerblad, Håkan, Lanner, Johanna, Bruton, Joseph, and Gustafsson, Thomas

Abstract

Confirmation of myotube formation. (A) Typical example of desmin staining (red) and DAPI (blue) showing myotube formation at 8 days of differentiation. Scale bars indicate 200 μm. (B) mRNA quantity of myogenin, a myogenic transcription factor involved in the terminal differentiation of myotubes, in myoblasts (dashed bar) and myotubes (black bar). Data are presented as the mean ± SEM. Asterisk denotes P

Published
2015
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43. Antioxidant treatments do not improve force recovery after fatiguing stimulation of mouse skeletal muscle fibres

Author

Cheng, Arthur J, Bruton, Joseph D, Lanner, Johanna T, and Westerblad, Håkan

Subjects
Mice, Inbred C57BL, Mice, Muscle Fatigue, Muscle Fibers, Skeletal, Muscle, Animals, NADPH Oxidases, Calcium, Female, Recovery of Function, Nitric Oxide Synthase, Reactive Oxygen Species, Antioxidants
Abstract

The contractile performance of skeletal muscle declines during intense activities, i.e. fatigue develops. Fatigued muscle can enter a state of prolonged low-frequency force depression (PLFFD). PLFFD can be due to decreased tetanic free cytosolic [Ca(2+) ] ([Ca(2+) ]i ) and/or decreased myofibrillar Ca(2+) sensitivity. Increases in reactive oxygen and nitrogen species (ROS/RNS) may contribute to fatigue-induced force reductions. We studied whether pharmacological ROS/RNS inhibition delays fatigue and/or counteracts the development of PLFFD. Mechanically isolated mouse fast-twitch fibres were fatigued by sixty 150 ms, 70 Hz tetani given every 1 s. Experiments were performed in standard Tyrode solution (control) or in the presence of: NADPH oxidase (NOX) 2 inhibitor (gp91ds-tat); NOX4 inhibitor (GKT137831); mitochondria-targeted antioxidant (SS-31); nitric oxide synthase (NOS) inhibitor (l-NAME); the general antioxidant N-acetylcysteine (NAC); a cocktail of SS-31, l-NAME and NAC. Spatially and temporally averaged [Ca(2+) ]i and peak force were reduced by ∼20% and ∼70% at the end of fatiguing stimulation, respectively, with no marked differences between groups. PLFFD was similar in all groups, with 30 Hz force being decreased by ∼60% at 30 min of recovery. PLFFD was mostly due to decreased tetanic [Ca(2+) ]i in control fibres and in the presence of NOX2 or NOX4 inhibitors. Conversely, in fibres exposed to SS-31 or the anti ROS/RNS cocktail, tetanic [Ca(2+) ]i was not decreased during recovery so PLFFD was only caused by decreased myofibrillar Ca(2+) sensitivity. The cocktail also increased resting [Ca(2+) ]i and ultimately caused cell death. In conclusion, ROS/RNS-neutralizing compounds did not counteract the force decline during or after induction of fatigue.

Published
2014

45. Doublet discharge stimulation increases sarcoplasmic reticulum Ca2+ release and improves performance during fatiguing contractions in mouse muscle fibres

Author

Cheng, Arthur J, Place, Nicolas, Bruton, Joseph D, Holmberg, Hans-Christer, and Westerblad, Håkan

Subjects
Mice, Inbred C57BL, Mice, Sarcoplasmic Reticulum, Muscle Fatigue, Muscle Fibers, Skeletal, Action Potentials, Animals, Calcium, In Vitro Techniques, Skeletal Muscle and Exercise, Electric Stimulation
Abstract

Double discharges (doublets) of motor neurones at the onset of contractions increase both force and rate of force development during voluntary submaximal contractions. The purpose of this study was to examine the role of doublet discharges on force and myoplasmic free [Ca(2+)] ([Ca(2+)]i) during repeated fatiguing contractions, using a stimulation protocol mimicking the in vivo activation pattern during running. Individual intact fibres from the flexor digitorum brevis muscle of mice were stimulated at 33°C to undergo 150 constant-frequency (five pulses at 70 Hz) or doublet (an initial, extra pulse at 200 Hz) contractions at 300 ms intervals. In the unfatigued state, doublet stimulation resulted in a transient (∼10 ms) approximate doubling of [Ca(2+)]i, which was accompanied by a greater force-time integral (∼70%) and peak force (∼40%) compared to constant frequency contractions. Moreover, doublets markedly increased force-time integral and peak force during the first 25 contractions of the fatiguing stimulation. In later stages of fatigue, addition of doublets increased force production but the increase in force production corresponded to only a minor portion of the fatigue-induced reduction in force. In conclusion, double discharges at the onset of contractions effectively increase force production, especially in early stages of fatigue. This beneficial effect occurs without additional force loss in later stages of fatigue, indicating that the additional energy cost induced by doublet discharges to skeletal muscle is limited.

Published
2013

46. Ryanodine receptor fragmentation and sarcoplasmic reticulum Ca 2+ leak after one session of high-intensity interval exercise

Author

Place, Nicolas, primary, Ivarsson, Niklas, additional, Venckunas, Tomas, additional, Neyroud, Daria, additional, Brazaitis, Marius, additional, Cheng, Arthur J., additional, Ochala, Julien, additional, Kamandulis, Sigitas, additional, Girard, Sebastien, additional, Volungevičius, Gintautas, additional, Paužas, Henrikas, additional, Mekideche, Abdelhafid, additional, Kayser, Bengt, additional, Martinez-Redondo, Vicente, additional, Ruas, Jorge L., additional, Bruton, Joseph, additional, Truffert, Andre, additional, Lanner, Johanna T., additional, Skurvydas, Albertas, additional, and Westerblad, Håkan, additional

Published
2015
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50. Effects of N-acetylcysteine on isolated mouse skeletal muscle : contractile properties, temperature dependence, and metabolism

Author

Katz, Abram, Hernandez, Andres, Ramos Caballero, Diana Marcela, Bonilla Briceno, Javier Fernando, Rivera Amezquita, Laura Victoria, Kosterina, Natalia, Bruton, Joseph D., Westerblad, Håkan, Katz, Abram, Hernandez, Andres, Ramos Caballero, Diana Marcela, Bonilla Briceno, Javier Fernando, Rivera Amezquita, Laura Victoria, Kosterina, Natalia, Bruton, Joseph D., and Westerblad, Håkan

Abstract

The effects of the general antioxidant N-acetylcysteine (NAC) on muscle function and metabolism were examined. Isolated paired mouse extensor digitorum longus muscles were studied in the absence or presence of 20 mM NAC. Muscles were electrically stimulated to perform 100 isometric tetanic contractions (300 ms duration) at frequencies resulting in similar to 85 % of maximal force (70-150 Hz at 25-40 A degrees C). NAC did not significantly affect peak force in the unfatigued state at any temperature but significantly slowed tetanic force development in a temperature-dependent fashion (e.g., time to 50 % of peak tension averaged 35 A +/- 2 ms [control] and 37 A +/- 1 ms [NAC] at 25 A degrees C vs. 21 A +/- 1 ms [control] and 52 A +/- 6 ms [NAC, P < 0.01] at 40 A degrees C). During repeated contractions, NAC maximally enhanced peak force by the fifth tetanus at all temperatures (by similar to 30 %). Thereafter, the effect of NAC disappeared rapidly at high temperatures (35-40 A degrees C) and more slowly at the lower temperatures (25-30 A degrees C). At all temperatures, the enhancing effect of NAC on peak force was associated with a slowing of relaxation. NAC did not significantly affect myosin light chain phosphorylation at rest or after five contractions (similar to 50 % increase vs. rest). After five tetani, lactate and inorganic phosphate increased about 20-fold and 2-fold, respectively, both in control and NAC-treated muscles. Interestingly, after five tetani, the increase in glucose 6-P was similar to 2-fold greater, whereas the increase in malate was inhibited by similar to 75 % with NAC vs. control, illustrating the metabolic effects of NAC. NAC slightly decreased the maximum shortening velocity in early fatigue (five to seven repeated tetani). These data demonstrate that the antioxidant NAC transiently enhances muscle force generation by a mechanism that is independent of changes in myosin light chain phosphorylation and inorganic phosphate. The slowing of, QC 20140331

Published
2014
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