Skeletal muscle structure

Lieber, R.L. Skeletal Muscle Structure and Function. Williams Wilkins, Baltimore (1992)... 

Dal Corso S, Napolis L, Malaguti C, et al. Skeletal muscle structure and function in response to electrical stimulation in moderately impaired COPD patients. Respir Med 2007 101 1236-1243. 

The cells of the latter three types contain only a single nucleus and are called myocytes. The cells of skeletal muscle are long and multinucleate and are referred to as muscle fibers. At the microscopic level, skeletal muscle and cardiac muscle display alternating light and dark bands, and for this reason are often referred to as striated muscles. The different types of muscle cells vary widely in structure, size, and function. In addition, the times required for contractions and relaxations by various muscle types vary considerably. The fastest responses (on the order of milliseconds) are observed for fast-twitch skeletal... 

FIGURE 17.11 The structure of a skeletal muscle cell, showing the mauuer iu which t-tubules enable the sarcolemmal membrane to contact the ends of each myofibril iu the muscle fiber. The foot structure is shown iu the box. 

FIGURE 17.13 The three-dimensional structure of an actin monomer from skeletal muscle. This view shows the two domains (left and right) of actin. 

Myofibrillar Structural Proteins of Rabbit Skeletal Muscle ... 

The structure of heart myocytes is different from that of skeletal muscle fibers. Heart myocytes are approximately 50 to 100 p,m long and 10 to 20 p,m in diameter. The t-tubules found in heart tissue have a fivefold larger diameter than those of skeletal muscle. The number of t-tubules found in cardiac muscle differs from species to species. Terminal cisternae of mammalian cardiac muscle can associate with other cellular elements to form dyads as well as triads. The association of terminal cisternae with the sarcolemma membrane in a dyad structure is called a peripheral coupling. The terminal cisternae may also form dyad structures with t-tubules that are called internal couplings (Figure 17.31). As with skeletal muscle, foot structures form the connection between the terminal cisternae and t-tubule membranes. 

Therapeutic Function Skeletal muscle relaxant Chemical Name 5-chloro-2(3H)-benzoxazolone Common Name 5-chloro-2-hydroxybenzoxazole Structural Formula ... 

Therepeutic Function Analgesic, skeletal muscle relaxant Chemical Name a-[ (2-Pyridinylemino)methyl] benzenemethenol Common Name Feny ram idol Structural Formula ... 

In striated muscles, SR is well developed to surround the myofibrils and is divided into two parts, the terminal cisternae (TC) and longitudinal tubules (LT). TC forms triad (skeletal muscle) or dyad (heart) structure with transverse tubules. The ryanodine receptor is located only in the TC, whereas the Ca2+ pump/SERCA is densely packed in both TC and LT. 

The structure of the contractile apparatus of smooth muscle at the next higher level is also characteristically different from other muscles. The concentrations of actin and myosin in smooth muscle are about three times higher for actin and four times lower for myosin than in skeletal muscle. Correspondingly, in smooth muscle the ratio of the numbers of moles of actin to moles of myosin, and the ratio of the number of actin filaments to those of myosin filaments, are about 12 times larger than for other muscles. Thus, the arrangements of the two sets of filaments are bound to be quite different just on the basis of numbers of actin and myosin... 

The compliance in series with the active force. Force exerted by the activated elements must be transmitted or borne by whatever structural elements are in series with them. In skeletal muscle there is clearly a tendon in series but not so with smooth muscle. In smooth muscle, the total length of contractile apparatus is broken up into individual cells with intercalating extracellular connective structures. In addition, the portions of the crossbridges in series with the pulling site must also be stretched before force can rise to isometric levels. Taken together, the... 

Organization into macromolecular structures. There are no apparent templates necessary for the assembly of muscle filaments. The association of the component proteins in vitro is spontaneous, stable, and relatively quick. Filaments will form in vitro from the myosins or actins from all three kinds of muscle. Yet in vitro smooth muscle myosin filaments are found to be stable only in solutions somewhat different from in vivo conditions. The organizing principles which govern the assembly of myosin filaments in smooth muscle are not well understood. It is clear, however, a filament is a sturdy structure and that individual myosin molecules go in and out of filaments whose structure remains in a functional steady-state. As described above, the crossbridges sticking out of one side of a smooth muscle myosin filament are all oriented and presumably all pull on the actin filament in one direction along the filament axis, while on the other side the crossbridges all point and pull in the opposite direction. The complement of minor proteins involved in the structure of the smooth muscle myosin filament is unknown, albeit not the same as that of skeletal muscle since C-protein and M-protein are absent. 

Figure 1. Muscle development. A skeletal muscle fiber is formed by the fusion of many single cells (myoblasts) into a multinucleated myotube. Myotubes then develop into the muscle fiber (see text). Sarcomeres form in longitudinal structures called myofibrils. The repeating structure of the sarcomere contains interdigitating thick and thin filaments.

Tanabe, T., Takeshima, H., Mikami, A., Flockerzi, V., Takahashi, H., Kangawa, K., Kojima, M., Matsuo, H., Hirose, T., Numa, S. (1987). Primary structure of the receptor for calcium channel blockers from skeletal muscle. Nature 328, 313-318. 

Acquired disease of muscle is more common than is generally appreciated. It may result from the use of drugs—prescription or nonprescription—that have a recognized capacity to compromise the structure or function of skeletal muscle. Drugs particularly well recognized as myotoxic include clofibrate and its derivatives, anabolic steroids, penicillamine, and emetine. Many nonprescription drugs, including alcohol and laxatives, are directly or indirectly myotoxic. Other forms of acquired myopathies include the acute myopathic conditions caused by the bites of many snakes. 

Smooth muscles have molecular structures similar to those in striated muscle, but the sarcomeres are not aligned so as to generate the striated appearance. Smooth muscles contain a-actinin and tropomyosin molecules, as do skeletal muscles. They do not have the troponin system, and the fight chains of smooth muscle myosin molecules differ from those of striated muscle myosin. Regulation of smooth muscle contraction is myosin-based, unlike striated muscle, which is actin-based. However, like striated muscle, smooth muscle contraction is regulated by Ca. ... 

CK has a dimeric structure composed of two subunits designated M and B ( )> M for muscle and B for brain, with the isoenzymes being designated MM, MB and BB. The MM dimer is found in skeletal muscle and minimally in smooth and cardiac muscle. The BB dimer is found in brain and minimally in lung and smooth muscle (42). The MB isoenzyme of intermediate electrophoretic mobility is found chiefly in myocardium (43) and very little in skeletal muscle and smooth muscle. 

The intracellular hgand-gated Ca " channels include the channels in endoplasmic and sarcoplasmic reticulum (SR) membranes that are opened upon binding of the second messenger, inositol triphosphate (IP3). These are intracellular Ca release channels that allow Ca to exit from intracellular stores, and consequently to increase the concentration of cytoplasmic Ca [5]. A second type of intracellular Ca release channel is the Ca - and ryanodine-sensitive channel that was originally characterized and isolated from cardiac and skeletal muscle [5-7] but appears to exist in many types of cells. It has become evident that IP3-gated channels and ryanodine-sensitive channels are structurally related but distinct proteins [8] that are present in many cell types [9]. While very interesting, time and space will not allow for further discussion of these channels. 

Fig. 1. Subunit structure of dihydropyridine-sensitive channels from skeletal muscle. Cartoon...

Both the G- and V-agents have the same physiological action on humans. They are potent inhibitors of the enzyme acetylcholinesterase (AChE), which is required for the function of many nerves and muscles in nearly every multicellular animal. Normally, AChE prevents the accumulation of acetylcholine after its release in the nervous system. Acetylcholine plays a vital role in stimulating voluntary muscles and nerve endings of the autonomic nervous system and many structures within the CNS. Thus, nerve agents that are cholinesterase inhibitors permit acetylcholine to accumulate at those sites, mimicking the effects of a massive release of acetylcholine. The major effects will be on skeletal muscles, parasympathetic end organs, and the CNS. 

Just a year after Stephenson s classical paper of 1956, J. del Castillo and B. Katz published an electrophysiological study of the interactions that occurred when pairs of agonists with related structures were applied simultaneously to the nicotinic receptors at the endplate region of skeletal muscle. Their findings could be best explained in terms of a model for receptor activation that has already been briefly introduced in Section 1.2.3 (see particularly Eq. (1.7)). In this scheme, the occupied receptor can isomerize between an active and an inactive state. This is very different from the classical model of Hill, Clark, and Gaddum in which no clear distinction was made between the occupation and activation of a receptor by an agonist. 

Unconscious control involuntary All innervated structures except skeletal muscle (e.g., cardiac and smooth muscles glands)... 

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