Altered Contractility of Skeletal Muscle in Mice Deficient in Titin’s M-Band Region

We investigated the contractile phenotype of skeletal muscle deficient in exons MEx1 and MEx2 (KO) of the titin M-band by using the cre-lox recombination system and a multidisciplinary physiological approach to study skeletal muscle contractile performance. At a maximal tetanic stimulation frequency, intact KO extensor digitorum longus muscle was able to produce wild-type levels of force. However, at submaximal stimulation frequency, force was reduced in KO mice, giving rise to a rightward shift of the force-frequency curve. This rightward shift of the force-frequency curve could not be explained by altered sarcoplasmic reticulum Ca²⁺ handling, as indicated by analysis of Ca²⁺ transients in intact myofibers and expression of Ca²⁺-handling proteins, but can be explained by the reduced myofilament Ca²⁺ sensitivity of force generation that we found. Western blotting experiments suggested that the excision of titin exons MEx1 and MEx2 did not result in major changes in expression of titin M-band binding proteins or phosphorylation level of the thin-filament regulatory proteins, but rather in a shift toward expression of slow isoforms of the thick-filament-associated protein, myosin binding protein-C. Extraction of myosin binding protein-C from skinned muscle normalized myofilament Ca²⁺ sensitivity of the KO extensor digitorum longus muscle. Thus, our data suggest that the M-band region of titin affects the expression of genes involved in the regulation of skeletal muscle contraction.     

Measurement of the Impedance of Frog Skeletal Muscle Fibers

Impedance measurements are necessary to determine the passive electrical properties of cells including the equivalent circuits of the several pathways for current flow. Such measurements are usually made with microelectrodes of high impedance (some 15 MΩ) over a wide frequency range (1-10,000 Hz) and so are subject to many errors. An input amplifier has been developed which has negligible phase shift in this frequency range because it uses negative feedback to keep tiny the voltage on top of the microelectrode. An important source of artifact is the extracellular potential produced by capacitive current flow through the wall of the microelectrodes and the effective resistance of the bathing solution. This artifact is reduced some 10 times by shielding the current microelectrode with a conductive paint. The residual artifact is analyzed, measured, and subtracted from our results. The interelectrode coupling capacitance is reduced below 2 × 10^-17 F and can be neglected. Phase and amplitude measurements are made with phase-sensitive detectors insensitive to noise. The entire apparatus is calibrated at different signal to noise ratios and the nature of the extracellular potential is investigated. The phase shift in the last 5-20 μm of the microelectrode tip is shown to be small and quite independent of frequency under several conditions. Experimental measurements of the phase characteristic of muscle fibers in normal Ringer are presented. The improvements in apparatus and the physiological significance of impedance measurements are discussed. It is suggested that the interpretation of impedance measurements is sensitive to small errors and so it is necessary to present objective evidence of the reliability of one's apparatus and measurements.     

Regulation of Cardiac Muscle Contractility

The heart's physiological performance, unlike that of skeletal muscle, is regulated primarily by variations in the contractile force developed by the individual myocardial fibers. In an attempt to identify the basis for the characteristic properties of myocardial contraction, the individual cardiac contractile proteins and their behavior in contractile models in vitro have been examined. The low shortening velocity of heart muscle appears to reflect the weak ATPase activity of cardiac myosin, but this enzymatic activity probably does not determine active state intensity. Quantification of the effects of Ca⁺⁺ upon cardiac actomyosin supports the view that myocardial contractility can be modified by changes in the amount of calcium released during excitation-contraction coupling. Exchange of intracellular K⁺ with Na⁺ derived from the extracellular space also could enhance myocardial contractility directly, as highly purified cardiac actomyosin is stimulated when K⁺ is replaced by an equimolar amount of Na⁺. On the other hand, cardiac glycosides and catecholamines, agents which greatly increase the contractility of the intact heart, were found to be without significant actions upon highly purified reconstituted cardiac actomyosin.     

Transduction of Skeletal Muscles with Common Reporter Genes Can Promote Muscle Fiber Degeneration and Inflammation

Recombinant adeno-associated viral vectors (rAAV vectors) are promising tools for delivering transgenes to skeletal muscle, in order to study the mechanisms that control the muscle phenotype, and to ameliorate diseases that perturb muscle homeostasis. Many studies have employed rAAV vectors carrying reporter genes encoding for β-galactosidase (β-gal), human placental alkaline phosphatase (hPLAP), and green fluorescent protein (GFP) as experimental controls when studying the effects of manipulating other genes. However, it is not clear to what extent these reporter genes can influence signaling and gene expression signatures in skeletal muscle, which may confound the interpretation of results obtained in experimentally manipulated muscles. Herein, we report a strong pro-inflammatory effect of expressing reporter genes in skeletal muscle. Specifically, we show that the administration of rAAV6:hPLAP vectors to the hind limb muscles of mice is associated with dose- and time-dependent macrophage recruitment, and skeletal muscle damage. Dose-dependent expression of hPLAP also led to marked activity of established pro-inflammatory IL-6/Stat3, TNFα, IKKβ and JNK signaling in lysates obtained from homogenized muscles. These effects were independent of promoter type, as expression cassettes featuring hPLAP under the control of constitutive CMV and muscle-specific CK6 promoters both drove cellular responses when matched for vector dose. Importantly, the administration of rAAV6:GFP vectors did not induce muscle damage or inflammation except at the highest doses we examined, and administration of a transgene-null vector (rAAV6:MCS) did not cause damage or inflammation at any of the doses tested, demonstrating that GFP-expressing, or transgene-null vectors may be more suitable as experimental controls. The studies highlight the importance of considering the potential effects of reporter genes when designing experiments that examine gene manipulation in vivo.     

Measurement of Maximum Isometric Force Generated by Permeabilized Skeletal Muscle Fibers

Analysis of the contractile properties of chemically skinned, or permeabilized, skeletal muscle fibers offers a powerful means by which to assess muscle function at the level of the single muscle cell. Single muscle fiber studies are useful in both basic science and clinical studies. For basic studies, single muscle fiber contractility measurements allow investigation of fundamental mechanisms of force production, and analysis of muscle function in the context of genetic manipulations. Clinically, single muscle fiber studies provide useful insight into the impact of injury and disease on muscle function, and may be used to guide the understanding of muscular pathologies. In this video article we outline the steps required to prepare and isolate an individual skeletal muscle fiber segment, attach it to force-measuring apparatus, activate it to produce maximum isometric force, and estimate its cross-sectional area for the purpose of normalizing the force produced.     

Experimental Evaluation of Fiber Orientation Based Material Properties of Skeletal Muscle in Tension

Biomechanical researches are essential to develop new techniques to improve the clinical relevance. Skeletal muscle generates the force which results in the motion of human body, so it is essential to study the mechanical and structural properties of skeletal muscle. Many researchers have carried out mechanical study of skeletal muscle with in-vivo testing. This work aims to examine anisotropic mechanical behavior of skeletal muscle with in vitro test (tensile test). It is important to understand the mechanical and structural behavior of skeletal muscle when it is subjected to external loading; the research aims to determine the structural properties of skeletal muscle by tensile testing. Tensile testing is performed on 5 samples of skeletal muscle of a goat at the rate of 1mm/min with fiber orientation along the length and 45° inclined to the length. It is found that muscle is stiffer in the direction parallel to the muscle fiber than at 45° to the muscle fibers. The tensile strength of the skeletal muscle along the fiber direction is 0.44 MPa at maximum load of 110 N and for direction 45° inclined to the muscle fibers, the strength is 0.234 MPa at max load 43 N. The displacement of Muscle sample against the maximum load is small along the length of the muscle fiber i.e. under longitudinal elongation [15.257 mm] as compared to 45° inclined to the length of skeletal muscle [17.775 mm] and under cross fiber elongation [19.7291mm by FEA]. The testing is not performed for 90° fiber orientation due to unavailability of soft tissue in cross fiber direction of the required specification, but finite element analysis is done on the skeletal muscle for the cross fiber orientation. As the fiber orientation within skeletal muscle differs with respect to the length of the muscle, the stiffness of skeletal muscle is also changing effectively. Hence skeletal muscle exhibits the anisotropic mechanical behavior.     

小鼠骨骼肌纤维类型定量PCR内参基因的筛选

旨在筛选定量PCR检测不同骨骼肌纤维类型的稳定内参基因,为骨骼肌的能量和糖代谢等功能研究提供基础数据.试验选用6周龄小鼠,采集腓肠肌(Gastrocnemius muscle,GAS)、比目鱼肌(Soleus,SOL)、胫骨前肌(Tibialis anterior muscle,TA)和趾长伸肌(Extensor di...     

Measurement of Intracellular pH of Bullfrog Skeletal Muscle and Renal Tubular Cells with Double-Barreled Antimony Microelectrodes

A pencil-type antimony microelectrode of double-barreled design with a tip of less than 1 to 2 μm in outside diameter was constructed and used to measure intracellular pH(pHi) on frog sartorius muscle and renal tubular cells. Simultaneous observations of membrane potential difference (EM) were made. The results obtained were as follows: (1) The in vivo pHi of frog sartorius muscle was 7.12 ± 0.07 (SD) (n = 144); the simultaneously measured E_M was -51.1 ± 7.9 mV. The in vivo pHi of frog proximal tubule was 7.49 ± 0.07 (n = 221) and the E_M peri across the peritubular membrane was -50.2 ± 9.0 mV. (2) In proximal tubule in vivo, there was a negative correlation between pHi and E_M (r = -.62, p <. 05). On the other hand, in sartorius muscle in vivo, a positive correlation between the two was found (r =. 85, p <. 001). (3) In in vitro sartorius muscle, the pHi was 7.03 ± 0.14 (n = 9) and E_M was -62.4 ± 4.4 mV within one hour after isolation. (4) Increasing the external potassium concentration in the preparations to 75 mM caused a progressive depolarization by 43.3 ± 15.9 (m = 4) mV, while pHi changed in the alkaline direction by 0.22 ± 0.03 pH unit. (5) These results indicate that the pHi in both tissues does not obey the Donnan rule.     

Development of Vertebrate Skeletal Muscle

An investigation of developing skeletal muscle necessitatesthe study of three categories; the derivation of muscle cellsor fibers, myofilament synthesis and interactions, assemblyof myofilaments into functional sarcomeres of striated myofibrils.With few exceptions, skeletal muscle cells are of mesodermalorigin, and consist of rounded mononucleated cells which elongateand fuse with one another to become myotubes. Within the sarcoplasm,myofibrillar proteins are synthesized and grouped into interactingthick and thin filaments. Crude, non-striated myofibrils resultfrom linear arrangements of thick and thin filaments which arehorizontally aligned by the invaginating sarcotubular system.After Z-lines form, providing attachment sites for thin filaments,a typical banding pattern follows. The newly formed Z-linespull apart, followed by the attached thin filaments, and repeating"relaxed" sarcomeres are the resulting striated myofibrillarpattern.     

Na+,K+-ATPase Na+ Affinity in Rat Skeletal Muscle Fiber Types

Previous studies in expression systems have found different ion activation of the Na⁺/K⁺-ATPase isozymes, which suggest that different muscles have different ion affinities. The rate of ATP hydrolysis was used to quantify Na⁺,K⁺-ATPase activity, and the Na⁺ affinity of Na⁺,K⁺-ATPase was studied in total membranes from rat muscle and purified membranes from muscle with different fiber types. The Na⁺ affinity was higher (K _m lower) in oxidative muscle compared with glycolytic muscle and in purified membranes from oxidative muscle compared with glycolytic muscle. Na⁺,K⁺-ATPase isoform analysis implied that heterodimers containing the β₁ isoform have a higher Na⁺ affinity than heterodimers containing the β₂ isoform. Immunoprecipitation experiments demonstrated that dimers with α₁ are responsible for approximately 36% of the total Na,K-ATPase activity. Selective inhibition of the α₂ isoform with ouabain suggested that heterodimers containing the α₁ isoform have a higher Na⁺ affinity than heterodimers containing the α₂ isoform. The estimated K _m values for Na⁺ are 4.0, 5.5, 7.5 and 13 mM for α₁β₁, α₂β₁, α₁β₂ and α₂β₂, respectively. The affinity differences and isoform distributions imply that the degree of activation of Na⁺,K⁺-ATPase at physiological Na⁺ concentrations differs between muscles (oxidative and glycolytic) and between subcellular membrane domains with different isoform compositions. These differences may have consequences for ion balance across the muscle membrane.     

Adult and Embryonic Skeletal Muscle Microexplant Culture and Isolation of Skeletal Muscle Stem Cells

Cultured embryonic and adult skeletal muscle cells have a number of different uses. The micro-dissected explants technique described in this chapter is a robust and reliable method for isolating relatively large numbers of proliferative skeletal muscle cells from juvenile, adult or embryonic muscles as a source of skeletal muscle stem cells. The authors have used micro-dissected explant cultures to analyse the growth characteristics of skeletal muscle cells in wild-type and dystrophic muscles. Each of the components of tissue growth, namely cell survival, proliferation, senescence and differentiation can be analysed separately using the methods described here. The net effect of all components of growth can be established by means of measuring explant outgrowth rates. The micro-explant method can be used to establish primary cultures from a wide range of different muscle types and ages and, as described here, has been adapted by the authors to enable the isolation of embryonic skeletal muscle precursors.Uniquely, micro-explant cultures have been used to derive clonal (single cell origin) skeletal muscle stem cell (SMSc) lines which can be expanded and used for in vivo transplantation. In vivo transplanted SMSc behave as functional, tissue-specific, satellite cells which contribute to skeletal muscle fibre regeneration but which are also retained (in the satellite cell niche) as a small pool of undifferentiated stem cells which can be re-isolated into culture using the micro-explant method.Download video file.^{(90M, mov)}     

A Histochemical Method for the Simultaneous Demonstration of Capillaries and Fiber Type in Skeletal Muscle

A modified ATPasc method for the simultaneous demonstration of capillaries and fiber types in skeletal muscle is presented. Muscle biopsies were obtained front mice, hamsters, rats, cats, and dogs, quick frozen, and sectioned at 8 μm in a cryostat. The frozen slides were fixed in a neutral formalin solution at 4 C for 5 min, and then incubated at 37 C for 1 hr in a medium containing ATP, Pb²⁺, and Ca²⁺ in a tris-maleate buffer (pH 7.2). Dilute (NH₄)₂S was used as a developer. To test the reliability of the proposed method, serial sections of each biopsy were stained separately for capillaries (amylase-PAS method) and for fiber types by a standard myosin ATPase (m-ATPase) method. Fiber type percent and capillary parameters were determined for each biopsy. No difference in results was observed for parameters determined using the modified ATPase method compared to the standard capillary and fiber type staining methods. This modified technique is therefore suitable for the simultaneous demonstration of capillaries and fiber types in skeletal muscle.     

Interactions of ELF Magnetic Fields with Mouse Skeletal Muscle

The second generation of female OF1 mice exposed chronically to a magnetic field of 50 Hz and 15 μT (rms) was studied to find out the possible alterations in the skeletal muscle caused by this exposure. Animals were sacrificed at the age of 14 weeks, and their skeletal muscle studied by spectrophotometric and histopathological techniques. Calcium concentration was found to be significantly decreased in the experimental animals, while H₂O content, Na, K, Fe, Ni, Mg, and Zn concentrations were not significantly different from those of control animals. Histologically, we found variation in fiber size, rounded and widely separated fibers, centrally located nuclei, and intermyofibrillar lipids. We could not find necrosis, inflammatory infiltrate, or loss of either the filaments or the cross-striation.     

High-Speed Imaging of Amoeboid Movements Using Light-Sheet Microscopy

Light-sheet microscopy has been developed as a powerful tool for live imaging in biological studies. The efficient illumination of specimens using light-sheet microscopy makes it highly amenable to high-speed imaging. We therefore applied this technology to the observation of amoeboid movements, which are too rapid to capture with conventional microscopy. To simplify the setup of the optical system, we utilized the illumination optics from a conventional confocal laser scanning microscope. Using this set-up we achieved high-speed imaging of amoeboid movements. Three-dimensional images were captured at the recording rate of 40 frames/s and clearly outlined the fine structures of fluorescent-labeled amoeboid cellular membranes. The quality of images obtained by our system was sufficient for subsequent quantitative analysis for dynamics of amoeboid movements. This study demonstrates the application of light-sheet microscopy for high-speed imaging of biological specimens.     

Effects of Fiber Type and Size on the Heterogeneity of Oxygen Distribution in Exercising Skeletal Muscle

The process of oxygen delivery from capillary to muscle fiber is essential for a tissue with variable oxygen demand, such as skeletal muscle. Oxygen distribution in exercising skeletal muscle is regulated by convective oxygen transport in the blood vessels, oxygen diffusion and consumption in the tissue. Spatial heterogeneities in oxygen supply, such as microvascular architecture and hemodynamic variables, had been observed experimentally and their marked effects on oxygen exchange had been confirmed using mathematical models. In this study, we investigate the effects of heterogeneities in oxygen demand on tissue oxygenation distribution using a multiscale oxygen transport model. Muscles are composed of different ratios of the various fiber types. Each fiber type has characteristic values of several parameters, including fiber size, oxygen consumption, myoglobin concentration, and oxygen diffusivity. Using experimentally measured parameters for different fiber types and applying them to the rat extensor digitorum longus muscle, we evaluated the effects of heterogeneous fiber size and fiber type properties on the oxygen distribution profile. Our simulation results suggest a marked increase in spatial heterogeneity of oxygen due to fiber size distribution in a mixed muscle. Our simulations also suggest that the combined effects of fiber type properties, except size, do not contribute significantly to the tissue oxygen spatial heterogeneity. However, the incorporation of the difference in oxygen consumption rates of different fiber types alone causes higher oxygen heterogeneity compared to control cases with uniform fiber properties. In contrast, incorporating variation in other fiber type-specific properties, such as myoglobin concentration, causes little change in spatial tissue oxygenation profiles.