Your search keyword '"Department of Kinesiology and Physical Education"' showing total 16 results

1. What are the potential mechanisms of fatigue-induced skeletal muscle hypertrophy with low-load resistance exercise training?

Author

Flewwelling LD, Hannaian SJ, Cao V, Chaillou T, Churchward-Venne TA, and Cheng AJ

Abstract

High-load resistance exercise (>60% of 1-repetition maximum) is a well-known stimulus to enhance skeletal muscle hypertrophy with chronic training. However, studies have intriguingly shown that low-load resistance exercise training (RET) (≤60% of 1-repetition maximum) can lead to similar increases in skeletal muscle hypertrophy as compared to high-load RET. This has raised questions about the underlying mechanisms for eliciting the hypertrophic response with low-load RET. A key characteristic of low-load RET is performing resistance exercise to, or close to, task failure, thereby inducing muscle fatigue. The primary aim of this evidence-based narrative review is to explore whether muscle fatigue may act as an indirect or direct mechanism contributing to skeletal muscle hypertrophy during low-load RET. It has been proposed that muscle fatigue could indirectly stimulate muscle hypertrophy through increased muscle fibre recruitment, mechanical tension, ultrastructural muscle damage, the secretion of anabolic hormones, and/or alterations in the expression of specific proteins involved in muscle mass regulation (e.g., myostatin). Alternatively, it has been proposed that fatigue could directly stimulate muscle hypertrophy through the accumulation of metabolic by-products (e.g., lactate), and/or inflammation and oxidative stress. This review summarizes the existing literature eluding to the role of muscle fatigue as a stimulus for low-load RET-induced muscle hypertrophy and provides suggested avenues for future research to elucidate how muscle fatigue could mediate skeletal muscle hypertrophy.

Published

2024

2. Acute effects of a ketone monoester, whey protein, or their coingestion on mTOR trafficking and protein-protein colocalization in human skeletal muscle.

Author

Hannaian SJ, Lov J, Cheng-Boivin Z, Abou Sawan S, Hodson N, Gentil BJ, Morais JA, and Churchward-Venne TA

Subjects

Humans, Male, Young Adult, Adult, Double-Blind Method, 3-Hydroxybutyric Acid pharmacology, 3-Hydroxybutyric Acid metabolism, Postprandial Period, Ketones metabolism, Muscle Proteins metabolism, Whey Proteins metabolism, Whey Proteins pharmacology, Whey Proteins administration & dosage, TOR Serine-Threonine Kinases metabolism, Muscle, Skeletal metabolism, Muscle, Skeletal drug effects, Protein Transport drug effects

Abstract

We recently demonstrated that acute oral ketone monoester intake induces a stimulation of postprandial myofibrillar protein synthesis rates comparable to that elicited following the ingestion of 10 g whey protein or their coingestion. The present investigation aimed to determine the acute effects of ingesting a ketone monoester, whey protein, or their coingestion on mechanistic target of rapamycin (mTOR)-related protein-protein colocalization and intracellular trafficking in human skeletal muscle. In a randomized, double-blind, parallel group design, 36 healthy recreationally active young males (age: 24.2 ± 4.1 yr) ingested either: 1 ) 0.36 g·kg -1 bodyweight of the ketone monoester (R)-3-hydroxybutyl (R)-3-hydroxybutyrate (KET), 2 ) 10 g whey protein (PRO), or 3 ) the combination of both (KET + PRO). Muscle biopsies were obtained in the overnight postabsorptive state (basal conditions), and at 120 and 300 min in the postprandial period for immunofluorescence assessment of protein translocation and colocalization of mTOR-related signaling molecules. All treatments resulted in a significant (Interaction: P < 0.0001) decrease in tuberous sclerosis complex 2 (TSC2)-Ras homolog enriched in brain (Rheb) colocalization at 120 min versus basal; however, the decrease was sustained at 300 min versus basal ( P < 0.0001) only in KET + PRO. PRO and KET + PRO increased (Interaction: P < 0.0001) mTOR-Rheb colocalization at 120 min versus basal; however, KET + PRO resulted in a sustained increase in mTOR-Rheb colocalization at 300 min that was greater than KET and PRO. Treatment intake increased mTOR-wheat germ agglutinin (WGA) colocalization at 120 and 300 min (Time: P = 0.0031), suggesting translocation toward the fiber periphery. These findings demonstrate that ketone monoester intake can influence the spatial mechanisms involved in the regulation of mTORC1 in human skeletal muscle. NEW & NOTEWORTHY We explored the effects of a ketone monoester (KET), whey protein (PRO), or their coingestion (KET + PRO) on mTOR-related protein-protein colocalization and intracellular trafficking in human muscle. All treatments decreased TSC2-Rheb colocalization at 120 minutes; however, KET + PRO sustained the decrease at 300 min. Only PRO and KET + PRO increased mTOR-Rheb colocalization; however, the increase at 300 min was greater in KET + PRO. Treatment intake increased mTOR-WGA colocalization, suggesting translocation to the fiber periphery. Ketone bodies influence the spatial regulation of mTOR.

Published

2024

3. Oxidation alters myosin-actin interaction and force generation in skeletal muscle filaments.

Author

Elkrief D, Cheng YS, Matusovsky OS, and Rassier DE

Subjects

Actin Cytoskeleton metabolism, Muscle Contraction, Muscle, Skeletal metabolism, Myosins metabolism, Actins metabolism, Chlorides metabolism

Abstract

The interaction between actin and myosin is the basis of contraction and force production in muscle fibers. Studies have shown that actin and myosin oxidation cause myofibrillar weakness in healthy and diseased muscles. The degree to which oxidation of each of these proteins contributes to an attenuated force in myofibrils is unclear. In this study, we show that exposure of actin and myosin to the chemical 5-amino-3-(4-morpholinyl)-1,2,3-oxadiazolium chloride (SIN-1), an NO and O 2 donor, affected actin-myosin interactions, as shown by a decreased myosin-propelled actin velocity in the in vitro motility assay. We also observed that oxidation of actin and myosin resulted in a decrease in force generated by myosin and actin filaments, as determined by a system of microfabricated cantilevers. Although myosin is more sensitive to oxidative modifications than actin, as indicated by a steeper decrease in velocity and force by the filaments, modifications on actin are sufficient to affect force and velocity and also contribute to a decrease in contractile activity in muscles.•- donor, affected actin-myosin interactions, as shown by a decreased myosin-propelled actin velocity in the in vitro motility assay. We also observed that oxidation of actin and myosin resulted in a decrease in force generated by myosin and actin filaments, as determined by a system of microfabricated cantilevers. Although myosin is more sensitive to oxidative modifications than actin, as indicated by a steeper decrease in velocity and force by the filaments, modifications on actin are sufficient to affect force and velocity and also contribute to a decrease in contractile activity in muscles.

Published

2022

4. An increase in force after stretch of diaphragm fibers and myofibrils is accompanied by an increase in sarcomere length nonuniformities and Ca 2+ sensitivity.

Author

Contini M, Altman D, Cornachione A, Rassier DE, and Bagni MA

Subjects

Animals, Diaphragm, Isometric Contraction physiology, Mice, Muscle Contraction physiology, Muscle Fibers, Skeletal physiology, Myofibrils physiology, Sarcomeres physiology

Abstract

When muscle fibers from limb muscles are stretched while activated, the force increases to a steady-state level that is higher than that produced during isometric contractions at a corresponding sarcomere length, a phenomenon known as residual force enhancement (RFE). The mechanisms responsible for the RFE are an increased stiffness of titin molecules that may lead to an increased Ca 2+ sensitivity of the contractile apparatus, and the development of sarcomere length nonuniformities. RFE is not observed in cardiac myofibrils, which makes this phenomenon specific to certain preparations. The aim of this study was to investigate whether the RFE is present in the diaphragm, and its potential association with an increased Ca 2+ sensitivity and the development of sarcomere length nonuniformities. We used two preparations: single intact fibers and myofibrils isolated from the diaphragm of mice. We investigated RFE in a variety of lengths across the force-length relationship. RFE was observed in both preparations at all lengths investigated and was larger with increasing magnitudes of stretch. RFE was accompanied by an increased Ca 2+ sensitivity as shown by a change in the force-pCa 2+ curve, and increased sarcomere length nonuniformities. Therefore, RFE is a phenomenon commonly observed in skeletal muscles, with mechanisms that are similar across preparations.

Published

2022

5. The load dependence and the force-velocity relation in intact myosin filaments from skeletal and smooth muscles.

Author

Cheng YS, de Souza Leite F, and Rassier DE

Subjects

Actin Cytoskeleton metabolism, Adenosine Triphosphate metabolism, Animals, Female, Muscle, Smooth metabolism, Myofibrils metabolism, Myosins metabolism, Mytilus edulis, Psoas Muscles metabolism, Rabbits, Time Factors, Actin Cytoskeleton physiology, Muscle Contraction, Muscle Strength, Muscle, Smooth physiology, Myofibrils physiology, Myosins physiology, Psoas Muscles physiology

Abstract

In the present study we evaluated the load dependence of force produced by isolated muscle myosin filaments interacting with fluorescently labeled actin filaments, using for the first time whole native myosin filaments. We used a newly developed approach that allowed the use of physiological levels of ATP. Single filaments composed of either skeletal or smooth muscle myosin and single filaments of actin were attached between pairs of nano-fabricated cantilevers of known stiffness. The filaments were brought into contact to produce force, which caused sliding of the actin filaments over the myosin filaments. We applied load to the system by either pushing or pulling the filaments during interactions and observed that increasing the load increased the force produced by myosin and decreasing the load decreased the force. We also performed additional experiments in which we clamped the filaments at predetermined levels of force, which caused the filaments to slide to adjust the different loads, allowing us to measure the velocity of length changes to construct a force-velocity relation. Force values were in the range observed previously with myosin filaments and molecules. The force-velocity curves for skeletal and smooth muscle myosins resembled the relations observed for muscle fibers. The technique can be used to investigate many issues of interest and debate in the field of muscle biophysics.

Published

2020

6. Force generated by myosin cross-bridges is reduced in myofibrils exposed to ROS/RNS.

Author

Persson M, Steinz MM, Westerblad H, Lanner JT, and Rassier DE

Subjects

Actins antagonists & inhibitors, Actins chemistry, Actins physiology, Animals, Isometric Contraction physiology, Molsidomine chemistry, Molsidomine pharmacology, Myofibrils physiology, Myofibrils ultrastructure, Myosins chemistry, Myosins physiology, Nitric Oxide Donors chemistry, Oxidative Stress, Psoas Muscles drug effects, Psoas Muscles physiology, Psoas Muscles ultrastructure, Rabbits, Tissue Culture Techniques, Isometric Contraction drug effects, Molsidomine analogs & derivatives, Myofibrils drug effects, Myosins antagonists & inhibitors, Nitric Oxide Donors pharmacology, Oxidants pharmacology, Peroxynitrous Acid pharmacology

Abstract

Skeletal muscle weakness is associated with oxidative stress and oxidative posttranslational modifications on contractile proteins. There is indirect evidence that reactive oxygen/nitrogen species (ROS/RNS) affect skeletal muscle myofibrillar function, although the details of the acute effects of ROS/RNS on myosin-actin interactions are not known. In this study, we examined the effects of peroxynitrite (ONOO - ) on the contractile properties of individual skeletal muscle myofibrils by monitoring myofibril-induced displacements of an atomic force cantilever upon activation and relaxation. The isometric force decreased by ~50% in myofibrils treated with the ONOO - donor (SIN-1) or directly with ONOO - , which was independent of the cross-bridge abundancy condition (i.e., rigor or relaxing condition) during SIN-1 or ONOO - treatment. The force decrease was attributed to an increase in the cross-bridge detachment rate ( g ) in combination with a conservation of the force redevelopment rate (k app ) and hence, an increase in the population of cross-bridges transitioning from force-generating to non-force-generating cross-bridges during steady-state. Taken together, the results of this study provide important information on how ROS/RNS affect myofibrillar force production which may be of importance for conditions where increased oxidative stress is part of the pathophysiology.Tr ) and hence, an increase in the population of cross-bridges transitioning from force-generating to non-force-generating cross-bridges during steady-state. Taken together, the results of this study provide important information on how ROS/RNS affect myofibrillar force production which may be of importance for conditions where increased oxidative stress is part of the pathophysiology.

Published

2019

7. Protein arginylation of cytoskeletal proteins in the muscle: modifications modifying function.

Author

Rassier DE and Kashina A

Subjects

Animals, Arginine chemistry, Cytoskeletal Proteins chemistry, Humans, Muscle, Skeletal chemistry, Muscle, Skeletal cytology, Protein Structure, Tertiary, Arginine metabolism, Cytoskeletal Proteins metabolism, Muscle Contraction physiology, Muscle, Skeletal metabolism

Abstract

The cytoskeleton drives many essential processes in normal physiology, and its impairments underlie many diseases, including skeletal myopathies, cancer, and heart failure, that broadly affect developed countries worldwide. Cytoskeleton regulation is a field of investigation of rapidly emerging global importance and a new venue for the development of potential therapies. This review overviews our present understanding of the posttranslational regulation of the muscle cytoskeleton through arginylation, a tRNA-dependent addition of arginine to proteins mediated by arginyltransferase 1. We focus largely on arginylation-dependent regulation of striated muscles, shown to play critical roles in facilitating muscle integrity, contractility, regulation, and strength.

Published

2019

8. Sarcomere mechanics in striated muscles: from molecules to sarcomeres to cells.

Author

Rassier DE

Subjects

Animals, Biomechanical Phenomena physiology, Calcium metabolism, Isometric Contraction physiology, Muscle Fibers, Skeletal metabolism, Muscle Fibers, Skeletal physiology, Muscle, Striated metabolism, Myofibrils metabolism, Myofibrils physiology, Sarcomeres metabolism, Connectin metabolism, Muscle Contraction physiology, Muscle, Striated physiology, Sarcomeres physiology

Abstract

Muscle contraction is commonly associated with the cross-bridge and sliding filament theories, which have received strong support from experiments conducted over the years in different laboratories. However, there are studies that cannot be readily explained by the theories, showing 1 ) a plateau of the force-length relation extended beyond optimal filament overlap, and forces produced at long sarcomere lengths that are higher than those predicted by the sliding filament theory; 2 ) passive forces at long sarcomere lengths that can be modulated by activation and Ca 2+ , which changes the force-length relation; and 3 ) an unexplained high force produced during and after stretch of activated muscle fibers. Some of these studies even propose "new theories of contraction." While some of these observations deserve evaluation, many of these studies present data that lack a rigorous control and experiments that cannot be repeated in other laboratories. This article reviews these issues, looking into studies that have used intact and permeabilized fibers, myofibrils, isolated sarcomeres, and half-sarcomeres. A common mechanism associated with sarcomere and half-sarcomere length nonuniformities and a Ca 2+ -induced increase in the stiffness of titin is proposed to explain observations that derive from these studies., (Copyright © 2017 the American Physiological Society.)

Published

2017

9. Reply to "Letter to the editor: Comments on Cornachione et al. (2016): "The increase in non-cross-bridge forces after stretch of activated striated muscle is related to titin isoforms".

Author

Rassier DE

Subjects

Muscle Contraction, Muscle Proteins, Muscle, Striated, Protein Isoforms, Sarcomeres, Connectin, Muscle, Skeletal

Published

2016

10. Reply to "Letter to the editor: Titin-actin interaction: the report of its death was an exaggeration".

Author

Rassier DE

Subjects

Animals, Connectin metabolism, Muscle Contraction, Muscle Strength, Myocardium metabolism, Myofibrils metabolism, Psoas Muscles metabolism

Published

2016

11. Reduction in single muscle fiber rate of force development with aging is not attenuated in world class older masters athletes.

Author

Power GA, Minozzo FC, Spendiff S, Filion ME, Konokhova Y, Purves-Smith MF, Pion C, Aubertin-Leheudre M, Morais JA, Herzog W, Hepple RT, Taivassalo T, and Rassier DE

Subjects

Age Factors, Aged, Aged, 80 and over, Biopsy, Fluorescent Antibody Technique, Humans, Kinetics, Male, Myosin Heavy Chains analysis, Quadriceps Muscle chemistry, Sarcopenia diagnosis, Sarcopenia metabolism, Young Adult, Aging, Athletes, Muscle Contraction, Muscle Fibers, Skeletal chemistry, Muscle Strength, Quadriceps Muscle physiopathology, Sarcopenia physiopathology

Abstract

Normal adult aging is associated with impaired muscle contractile function; however, to what extent cross-bridge kinetics are altered in aging muscle is not clear. We used a slacken restretch maneuver on single muscle fiber segments biopsied from the vastus lateralis of young adults (∼23 yr), older nonathlete (NA) adults (∼80 yr), and age-matched world class masters athletes (MA; ∼80 yr) to assess the rate of force redevelopment (ktr) and cross-bridge kinetics. A post hoc analysis was performed, and only the mechanical properties of "slow type" fibers based on unloaded shortening velocity (Vo) measurements are reported. The MA and NA were ∼54 and 43% weaker, respectively, for specific force compared with young. Similarly, when force was normalized to cross-sectional area determined via the fiber shape angularity data, both old groups did not differ, and the MA and NA were ∼43 and 48% weaker, respectively, compared with young (P < 0.05). Vo for both MA and NA old groups was 62 and 46% slower, respectively, compared with young. Both MA and NA adults had approximately two times slower values for ktr compared with young. The slower Vo in both old groups relative to young, coupled with a similarly reduced ktr, suggests impaired cross-bridge kinetics are responsible for impaired single fiber contractile properties with aging. These results challenge the widely accepted resilience of slow type fibers to cellular aging., (Copyright © 2016 the American Physiological Society.)

Published

2016

12. Reduced passive force in skeletal muscles lacking protein arginylation.

Author

Leite FS, Minozzo FC, Kalganov A, Cornachione AS, Cheng YS, Leu NA, Han X, Saripalli C, Yates JR 3rd, Granzier H, Kashina AS, and Rassier DE

Subjects

Aminoacyltransferases genetics, Animals, Elastic Modulus physiology, Mice, Mice, Knockout, Muscle Proteins chemistry, Muscle Proteins physiology, Myofibrils chemistry, Myofibrils ultrastructure, Stress, Mechanical, Structure-Activity Relationship, Aminoacyltransferases metabolism, Connectin chemistry, Connectin physiology, Myofibrils physiology, Protein Processing, Post-Translational physiology

Abstract

Arginylation is a posttranslational modification that plays a global role in mammals. Mice lacking the enzyme arginyltransferase in skeletal muscles exhibit reduced contractile forces that have been linked to a reduction in myosin cross-bridge formation. The role of arginylation in passive skeletal myofibril forces has never been investigated. In this study, we used single sarcomere and myofibril measurements and observed that lack of arginylation leads to a pronounced reduction in passive forces in skeletal muscles. Mass spectrometry indicated that skeletal muscle titin, the protein primarily linked to passive force generation, is arginylated on five sites located within the A band, an important area for protein-protein interactions. We propose a mechanism for passive force regulation by arginylation through modulation of protein-protein binding between the titin molecule and the thick filament. Key points are as follows: 1) active and passive forces were decreased in myofibrils and single sarcomeres isolated from muscles lacking arginyl-tRNA-protein transferase (ATE1). 2) Mass spectrometry revealed five sites for arginylation within titin molecules. All sites are located within the A-band portion of titin, an important region for protein-protein interactions. 3) Our data suggest that arginylation of titin is required for proper passive force development in skeletal muscles., (Copyright © 2016 the American Physiological Society.)

Published

2016

13. The increase in non-cross-bridge forces after stretch of activated striated muscle is related to titin isoforms.

Author

Cornachione AS, Leite F, Bagni MA, and Rassier DE

Subjects

Animals, Calcium metabolism, In Vitro Techniques, Myocardium cytology, Protein Isoforms, Psoas Muscles cytology, Rabbits, Time Factors, Connectin metabolism, Muscle Contraction, Muscle Strength, Myocardium metabolism, Myofibrils metabolism, Psoas Muscles metabolism

Abstract

Skeletal muscles present a non-cross-bridge increase in sarcomere stiffness and tension on Ca(2+) activation, referred to as static stiffness and static tension, respectively. It has been hypothesized that this increase in tension is caused by Ca(2+)-dependent changes in the properties of titin molecules. To verify this hypothesis, we investigated the static tension in muscles containing different titin isoforms. Permeabilized myofibrils were isolated from the psoas, soleus, and heart ventricle from the rabbit, and tested in pCa 9.0 and pCa 4.5, before and after extraction of troponin C, thin filaments, and treatment with the actomyosin inhibitor blebbistatin. The myofibrils were tested with stretches of different amplitudes in sarcomere lengths varying between 1.93 and 3.37 μm for the psoas, 2.68 and 4.21 μm for the soleus, and 1.51 and 2.86 μm for the ventricle. Using gel electrophoresis, we confirmed that the three muscles tested have different titin isoforms. The static tension was present in psoas and soleus myofibrils, but not in ventricle myofibrils, and higher in psoas myofibrils than in soleus myofibrils. These results suggest that the increase in the static tension is directly associated with Ca(2+)-dependent change in titin properties and not associated with changes in titin-actin interactions., (Copyright © 2016 the American Physiological Society.)

Published

2016

14. Mitochondrial functional specialization in glycolytic and oxidative muscle fibers: tailoring the organelle for optimal function.

Author

Picard M, Hepple RT, and Burelle Y

Subjects

Animals, Calcium metabolism, Cell Death physiology, Humans, Mice, Muscle Contraction physiology, Oxidation-Reduction, Rats, Reactive Oxygen Species metabolism, Glycolysis physiology, Mitochondria, Muscle physiology, Muscle Fibers, Fast-Twitch physiology, Muscle Fibers, Slow-Twitch physiology, Oxidative Phosphorylation

Abstract

In skeletal muscle, two major types of muscle fibers exist: slow-twitch oxidative (type I) fibers designed for low-intensity long-lasting contractions, and fast-twitch glycolytic (type II) fibers designed for high-intensity short-duration contractions. Such a wide range of capabilities has emerged through the selection across fiber types of a narrow set of molecular characteristics suitable to achieve a specific contractile phenotype. In this article we review evidence supporting the existence of distinct functional phenotypes in mitochondria from slow and fast fibers that may be required to ensure optimal muscle function. This includes differences with respect to energy substrate preferences, regulation of oxidative phosphorylation, dynamics of reactive oxygen species, handling of Ca2+, and regulation of cell death. The potential physiological implications on muscle function and the putative mechanisms responsible for establishing and maintaining distinct mitochondrial phenotype across fiber types are also discussed.

Published

2012

15. Effects of blebbistatin and Ca2+ concentration on force produced during stretch of skeletal muscle fibers.

Author

Minozzo FC and Rassier DE

Subjects

Animals, Biomechanical Phenomena, Muscle Fibers, Skeletal cytology, Muscle, Skeletal cytology, Rabbits, Stress, Mechanical, Calcium metabolism, Heterocyclic Compounds, 4 or More Rings pharmacology, Muscle Contraction drug effects, Muscle Contraction physiology, Muscle Fibers, Skeletal drug effects, Muscle Fibers, Skeletal physiology, Muscle, Skeletal drug effects, Muscle, Skeletal physiology

Abstract

When activated muscle fibers are stretched at low speeds [≤ 2 optimal length (L(o))/s], force increases in two phases, marked by a change in slope [critical force (P(c))] that happens at a critical sarcomere length extension (L(c)). Some studies attribute P(c) to the number of attached cross bridges before stretch, while others attribute it to cross bridges in a pre-power-stroke state. In this study, we reinvestigated the mechanisms of forces produced during stretch by altering either the number of cross bridges attached to actin or the cross-bridge state before stretch. Two sets of experiments were performed: 1) activated fibers were stretched by 3% L(o) at speeds of 1.0, 2.0, and 3.0 L(o)/s in different pCa(2+) (4.5, 5.0, 5.5, 6.0), or 2) activated fibers were stretched by 3% L(o) at 2 L(o)/s in pCa(2+) 4.5 containing either 5 μM blebbistatin(+/-) or its inactive isomer (+/+). All stretches started at a sarcomere length (SL) of 2.5 μm. When fibers were activated at a pCa(2+) of 4.5, P(c) was 2.47 ± 0.11 maximal force developed before stretch (P(o)) and decreased with lower concentrations of Ca(2+). L(c) was not Ca(2+) dependent; the pooled experiments provided a L(c) of 14.34 ± 0.34 nm/half-sarcomere (HS). P(c) and L(c) did not change with velocities of stretch. Fibers activated in blebbistatin(+/-) showed a higher P(c) (2.94 ± 0.17 P(o)) and L(c) (16.30 ± 0.38 nm/HS) than control fibers (P(c) 2.31 ± 0.08 P(o); L(c) 14.05 ± 0.63 nm/HS). The results suggest that forces produced during stretch are caused by both the number of cross bridges attached to actin and the cross bridges in a pre-power-stroke state. Such cross bridges are stretched by large amplitudes before detaching from actin and contribute significantly to the force developed during stretch.

Published

2010

16. The mechanical behavior of individual sarcomeres of myofibrils isolated from rabbit psoas muscle.

Author

Pavlov I, Novinger R, and Rassier DE

Subjects

Animals, Biomechanical Phenomena, Myofibrils, Rabbits, Models, Biological, Muscle Contraction physiology, Psoas Muscles physiology, Sarcomeres physiology

Abstract

The goal of this study was to develop a system to experiment with sarcomeres mechanically isolated from skeletal muscles. Single myofibrils from rabbit psoas were transferred into a temperature-controlled (22 degrees C or 15 degrees C) experimental chamber, and sarcomeres were isolated using precalibrated glass microneedles that were pierced externally, adjacent to the Z-lines. The force produced during activation was measured by tracking the displacement of the microneedles, and the sarcomere and half-sarcomere changes were measured by continuously tracking the Z-lines and A-bands position during the experiments. Sarcomeres produced a stress (force/cross-sectional area) of 112.75 +/- 4.96 nN/microm(2) (15 degrees C) and 128.47 +/- 5.58 nN/microm(2) (22 degrees C) at lengths between 2.0 microm and 2.4 microm. The descending limb was fitted with linear regression for length between 2.4 microm and 3.5 microm, which provided an abscissa extrapolating to 3.87 microm. The force-length relation was remarkably similar to a theoretical curve based on the degree of filament overlap. During sarcomere activation, we tracked the distance between the center of the A-band and the Z-lines. At lengths below 1.6 microm, movements of A-band were not detected. A-band movements increased with length to achieve a maximum displacement of 59.40 +/- 10.1 nm from the center at 2.0 microm-2.4 microm. A-band displacement decreased linearly in sarcomere lengths between 2.6 microm and 3.6 microm. A technique for monitoring force and length in single sarcomeres isolated from myofibrils represents a reliable technique to evaluate contractile mechanisms at the most basic, intact level of muscle organization, opening the possibility to clarify long-standing issues in the field of muscle contraction.

Published

2009