A study of the fine structure of the accessory muscle of the horseshoe crab,Tachypleus gigas

The accessory muscle of the walking leg of the horseshoe crab, Tachypleus gigas, was examined electron microscopically. The muscle fibers vary in size but are small in diameter, when compared with other arthropod skeletal muscles. They are striated with A, I, Z and poorly defined H bands. The sarcomere length ranges from 3-10 μm with most sarcomeres in the range of about 6 μm. The myofilaments are arranged in lamellae in larger fibers and less well organized in the smaller ones. Each thick filament is surrounded by 9-12 thin filaments which overlap. The SR is sparse but well organized to form a fenestrated collar around the fibrils. Individual SR tubules are also seen among the myofibrils. Long transverse tubules extend inward from the sarcolemma to form dyads or triads with the SR at the A-I junction. Both dyads and triads coexist in a single muscle fiber, a feature believed to have evolutionary significance. The neuromuscular relationship is unique. In the region of synaptic contact, the sarcolemma is usually elevated to form a large club-shaped structure containing no myofilaments and few other organelles. The axons or axon terminals and glial elements penetrate deep into the club-shaped sarcoplasm and form synapses with the fiber. As many as 13 terminals have been observed within a single section. Synaptic vesicles of two types are found in the axon terminals.     

CORRELATED MORPHOLOGICAL AND PHYSIOLOGICAL STUDIES ON ISOLATED SINGLE MUSCLE FIBERS : I. Fine Structure of the Crayfish Muscle Fiber

Single fibers isolated from walking leg muscles of crayfish have 8- to 10-µ sarcomeres which are divided into A, I, and Z bands. The H zone is poorly defined and no M band is distinguishable. Changes in the width of the I band, accompanied by change in the overlap between thick and thin myofilaments, occur when the length of the sarcomere is changed by stretching or by shortening the fiber. The thick myofilaments (ca. 200 A in diameter) are confined to the A band. The thin myofilaments (ca. 50 A in diameter) are difficult to resolve except in swollen fibers, when they clearly lie between the thick filaments and run to the Z disc. The sarcolemma invaginates at 50 to 200 sites in each sarcomere. The sarcolemmal invaginations (SI) form tubes about 0.2 µ in diameter which run radially into the fiber and have longitudinal side branches. Tubules about 150 A in diameter arise from the SI and from the sarcolemma. The invaginations and tubules are all derived from and are continuous with the plasma membrane, forming the transverse tubular system (TTS), which is analogous with the T system of vertebrate muscle. In the A band region each myofibril is enveloped by a fenestrated membranous covering of sarcoplasmic reticulum (SR). Sacculations of the SR extend over the A-I junctions of the myofibrils, where they make specialized contacts (diads) with the TTS. At the diads the opposing membranes of the TTS and SR are spaced 150 A apart, with a 35-A plate centrally located in the gap. It appears likely that the anion-permselective membrane of the TTS which was described previously is located at the diads, and that this property of the diadic structures therefore may function in excitation-contraction coupling.     

Fine structure and differentiation of ascidian muscle, 2. Morphometrics and differentiation of the caudal muscle cells of Distaplia occidentalis tadpoles

The locomotor function of the caudal muscle cells of ascidian larvae is identical with that of lower vertebrate somatic striated (skeletal) muscle fibers, but other features, including the presence of transverse myomuscular junctions, an active Golgi apparatus, a single nucleus, and partial innervation, are characteristic of vertebrate myocardial cells. Seven stages in the development of the compound ascidian Distaplia occidentalis were selected for an ultrastructural study of caudal myogenesis. A timetable of development and differentiation was obtained from cultures of isolated embryos in vitro. The myoblasts of the neurulating embryo are yolky, undifferentiated cells. They are arranged in two bands between the epidermis and the notochord in the caudal rudiment and are actively engaged in mitosis. Myoblasts of the caudate embryo continue to divide and rearrange themselves into longitudinal rows so that each cell simultaneously adjoins the epidermis and the notochord. The formation of secretory granules by the Golgi apparatus coincides with the onset of proteid-yolk degradation and the accumulation of glycogen in the ground cytoplasm. Randomly oriented networks of thick and thin myofilaments appear in the peripheral sarcoplasm of the muscle cells of the comma embryo. Bridges interconnect the thick and thin myofilaments (actomyosin bridges) and the thick myofilaments (H-bridges), but no banding patterns are evident. The sarcoplasmic reticulum (SR), derived from evaginations of the nuclear envelope, forms intimate associations (peripheral couplings) with the sarcolemma. Precursory Z-lines are interposed between the networks of myofilaments in the vesiculate embryo, and the nascent myofibrils become predominantly oriented parallel to the long axis of the muscle cell. Muscle cells of the papillate embryo contain a single row of cortical myofibrils. Myofibrils, already spanning the length of the cell, grow only in diameter by the apposition of myofilaments. The formation of transverse myomuscular junctions begins at this stage, but the differentiating junctions are frequently oriented obliquely rather than orthogonally to the primary axes of the myofibrils. With the appearance of H-bands and M-lines, a single perforated sheet of sarcoplasmic reticulum is found centered on the Z-line and embracing the I-band. The sheet of SR establishes peripheral couplings with the sarcolemma. In the prehatching tadpole, a second collar of SR, centered on the M-line and extending laterally to the boundaries with the A-bands, is formed. A single perforated sheet surrounds the myofibril but is discontinuous at the side of the myofibril most distant from the sarcolemma. To produce the intricate architecture of the fully differentiated collar in the swimming tadpole (J. Morph., 138: 349, 1972). the free ends of the sheet must elevate from the surface of the myofibril, recurve, and extend peripherally toward the sarcolemma to establish peripheral couplings. Morphological changes in the nucleus, nucleolus, mitochondria, and Golgi bodies are described, as well as changes in the ground cytoplasmic content of yolk, glycogen, and ribosomes. The volume of the differentiating cells, calculated from the mean cellular dimensions, and analyses of cellular shape are presented, along with schematic diagrams of cells in each stage of caudal myogenesis. In an attempt to quantify the differences observed ultrastructurally, calculations of the cytoplasmic volume occupied by the mqjor classes of organelles are included. Comparison is made with published accounts on differentiating vertebrate somatic striated and cardiac muscles.     

Immunocytochemical electron microscopic study and Western blot analysis of paramyosin in different invertebrate muscle cell types of the fruit flyDrosophila melanogaster, the earthwormEisenia foetida, and the snailHelix aspersa

Summary The presence and distribution pattern of paramyosin have been examined in different invertebrate muscle cell types by means of Western blot analysis and electron microscopy immunogold labelling. the muscles studied were: transversely striated muscle with continuous Z lines (flight muscle fromDrosophila melanogaster), transversely striated muscle with discontinuous Z lines (heart muscle from the snailHelix aspersa), obliquely striated body wall muscle from the earthwormEisenia foetida, and smooth muscles (retractor muscle from the snail and pseudoheart outer muscular layer from the earthworm). Paramyosin-like immunoreactivity was localized in thick filaments of all muscles studied. Immunogold particle density was similar along the whole thick filament length in insect flight muscle but it predominated in filament tips of fusiform thick filaments in both snail heart and earthworm body wall musculature when these filaments were observed in longitudinal sections. In obliquely sectioned thick filaments, immunolabelling was more abundant at the sites where filaments disappeared from the section. These results agree with the notion that paramyosin extended along the whole filament length, but that it can only be immunolabelled when it is not covered by myosin. In all muscles examined, immunolabelling density was lower in cross-sectioned myofilaments than in longitudinally sectioned myofilaments. This suggests that paramyosin does not form a continuous filament. The results of a semiquantitative analysis of paramyosin-like immunoreactivity indicated that it was more abundant in striated than in smooth muscles, and that, within striated muscles, transversely striated muscles contain more paramyosin than obliquely striated muscles.     

THE MYOFILAMENT LATTICE: STUDIES ON ISOLATED FIBERS : I. The Constancy of the Unit-Cell Volume with Variation in Sarcomere Length in a Lattice in which the Thin-to-Thick Myofilament Ratio is 6:1

The spacing between the thick myofilaments of muscle fibers from the walking legs of crayfish (Orconectes) was determined by optical transform analysis of electron micrograph plates of fixed single fibers and by X-ray diffraction of living single fibers. Sarcomere lengths were determined by light diffraction prior to fixation and prior to the in vivo experiments. From these combined measurements, it is demonstrated that the unit-cell volume of the myofilament lattice is constant during muscle shortening, indicating that the myofilament lattice works in a constant-volume manner. It is further demonstrated with X-ray diffraction measurements of living single fibers that the myofilament lattice continues to work at constant volume after the sarcolemma is removed from the fiber. This indicates that the constant-volume behavior of muscle is inherent to the myofilament lattice.     

可口革囊星虫肾管肌组织的结构特征

采用显微及亚显微技术观察了可1：7革囊星虫肾管肌组织的结构特征。肾管肌组织位于柱状上皮层下,由纵肌及环肌组成。肌细胞（肌纤维）呈长梭形,核位于细胞边缘并明显突向细胞外基质中,核周围有较多线粒体及少量内质网。肌纤维表面有许多囊状或指状突起的肌质囊,内含肌浆、光面内质网、线粒体及糖原颗粒。肌质囊之间的肌膜内面具膜相关电子致密斑。肌纤维内含粗、细两种肌丝,细肌丝围绕在粗肌丝周围,在肌丝之间分布有糖原颗粒、线粒体及胞质致密体。线粒体及糖原为肌纤维的代谢提供能量,肌组织的收缩对促进肾管的过滤排泄及繁殖时配子进入肾管可能起重要作用。     

Physiology and excitation-contraction coupling in the intestinal muscle of the crayfish Procambarus clarkii

The intestinal muscles of Procambarus clarkii are striated and yet they are specialized to produce slow peristaltic waves of contraction, not unlike those seen in vertebrate visceral smooth muscle. These muscles cannot be tetanized either by repetitive stimulation or by elevated potassium saline. The excitation-contraction (E-C) coupling mechanism was explored and compared with that known in crustacean skeletal muscle. Contraction is dependent on external Ca2+ which triggers the release of intracellular calcium from the sarcoplasmic reticulum (SR) via calcium-induced calcium release (CICR). Whereas contraction force is proportional to [Ca2+]o up to that in normal saline (13.4 mM), higher levels of Ca2+ reduce force. Ryanodine, which blocks calcium release from the SR, abolishes electrically stimulated contractions and CICR. Relaxation is achieved by removal of calcium from the cytosol in at least two ways, first by the re-loading of calcium into the SR by Ca2+-ATPases and second by the movement of calcium out of the cell by extruding it across the sarcolemma via Na+/Ca2+-exchangers. It is hypothesized that the inability of this muscle to show tetanus arises from inactivation of the voltage-gated calcium channels by high calcium. This is supported by the result that caffeine application causes an increase in tonus and size of phasic contractions by circumventing the sarcolemma and dumping SR calcium stores.     

Structural proteins in the myofilaments and regulation of contraction in vertebrate smooth muscle.

The contractile systems of vertebrate smooth and striated muscles are compared. Smooth muscles contain relatively large amounts of actin and tropomyosin organized into thin filaments, and smaller amounts of myosin in the form of thick filaments. The protein contents are consistent with observed thin:thick filament ratios of about 15-18:1 in smooth compared to 2:1 in striated muscle. The basic characteristics of both types of contractile proteins are similar; but there are a variety of quantitative differences in protein structures, enzymatic activities and filament stabilities. Biochemical and X-ray diffraction data generally support recent ultrastructural evidence concerning the organization of the myofilaments in smooth muscle, although a basic contractile unit comparable to the sarcomere in striated muscle has not been discerned. Myofilament interactions and contraction in smooth muscle are controlled by changes in the Ca2+ concentration. Recent evidence suggests the Ca2+-binding regulatory site is associated with the myosin in vertebrate smooth muscle (as in a variety of invertebrate muscles), rather than with troponin which is the regulatory protein associated with the thin filament in vertebrate striated muscle.     

螯虾横纹肌粗肌丝超微结构的计算机图象分析

本文在微机ＡＳＴ／３８６和真彩色图形采集卡ＣＡ－５４０构成的趁科象处理系统上开发了一个软件,包括用于对动物横纹肌粗肌丝的超微结构进行分析的专用模块,一般图象处理系统的通用模块和文件管理模块三大部分。本系统对动物横纹肌粗肌丝的亚结构从旋转功率谱的角度分析了其对称性的存在,并运用图象的迭加,旋转平衡和旋转滤波等手段来处理,显示其对称性;同时,对存在的不对称结构也作了相应的分析处理。利用本系统,对螯虾的     

Ultrastructure of the epidermis in the ice worm, Mesenchytraeus solifugus

The ice worm is adapted for life at O°C. A survey of the ultrastructure of the cuticle, epidermal epithelium and basement membrane does not reveal any features which self-evidently correlate with such metabolic specialization; instead, these tissues are much like those of the earthworm and some freshwater oligochaetes. The cuticular fibers are unstriated. Epithelial cells aresuggested as the source of cuticular material. Epithelial microvilli penetrate the cuticle. There is an array of membrane bound bodies on the cuticle surface. The basement membrane fibers are transversely striated and are oriented in crossed lamellae. The junctional complex is represented by azonula adhaerens and septate desmosome.     

THE STRUCTURE OF INTERSEGMENTAL MUSCLE FIBERS IN AN INSECT, PERIPLANETA AMERICANA L

The organization of intersegmental muscle fibers associated with the dorsal abdominal sclerites of the cockroach is described. These fibers correspond closely, in the disposition and derivation of the membranes of the transverse tubular system and sarcoplasmic reticulum cisternae, with insect synchronous flight muscle fibers, but differ markedly from these in their fibrillar architecture and mitochondrial content. The mitochondria are small and generally aligned alongside the prominent I bands of the sarcomere, and, in the best-oriented profiles of the A bands, thick filaments are associated with orbitals of twelve thin filaments, a configuration that has also been observed in striated fibers of insect visceral muscle. These structural features of insect muscles are compared and discussed in terms of possible variations in the control of contraction and relaxation, and in the nature of their mechanical role.     

Fine structure of muscles in the tickHyalomma (Hyalomma) dromedarii (Ixodoidea: Ixodidae)

Skeletal and visceral muscles are distinguished in the unfed nymphHyalomma (Hyalomma) dromedarii according to position, structure and function. The skeletal muscles include the capitulum, dorsoventral and leg oblique muscles. Their muscle fibres have the striated pattern of successive sarcomeres whose thick myosin filaments are surrounded by orbitals of up to 12 thin actin filaments. The cell membrane invaginates into tubular system (T) extending deeply into the sarcoplasm and closely associated to cisternae of sarcoplasmic reticulum (SR). The T and SR forming two-membered dyads are considered to be the main route of calcium ions whose movements are synchronized with the motor impulse to control contraction and relaxation in most muscles. Two types of skeletal muscle fibres are recognized, and are suggested as representing different physiological phases.In the visceral-muscle fibres investing tick internal organs, the actin and myosin filaments are slightly interrupted, and the T and SR are well demonstrated. Both skeletal and visceral muscles are invaginated by tracheoles and innervated by nerve-axons containing synaptic vesicles.     

The fine structure of muscle in a marine turbellarian

Summary The fine structure of the myofibers of Notoplana acticola as studied by electron microscopy indicates that they are composed of thick myofilaments about 200 Å wide with tapering ends and thin myofilaments about 50 Å wide, arranged alongside each other parallel to the long axis of the cell. There is no orderly transverse arrangement of filaments; instead they appear staggered in the fiber. In cross sections 6 to 10 thin filaments form an orbit around one thick filament with possible cross-linkage between the two types of filaments.Dense bodies are associated with the sarcolemma and with the sarcoplasmic reticulum, and appear to serve as attachments for the thin filaments. Dense bodies are compared to elements forming a fragmented Z-disc.Mitochondria, situated in the periphery or the center of fibers, are associated with granules interpreted as glycogen.The sarcoplasmic reticulum consists of: sacs or cisternae in close proximity to the sarcolemma, longitudinal tubular elements between and parallel to the myofilaments, and a tubular network around the filaments. There is no well-defined sarcolemmal-derived transverse tubule system as described in striated muscles. It is hypothesized that in these muscles, the functional equivalent of the T system may be the area of sarcolemma in contact with the cisternae of the sarcoplasmic reticulum.This work was supported by Grant No. GM 10292 from the U. S. Public Health Service to Professor Richard M. Eakin, Department of Zoology at the University of California, Berkeley, USA, where this investigation was conducted during the author's sabbatical leave of absence from the University of Illinois.I wish to thank Professor Eakin for valuable discussions and for his kind hospitality in extending the facilities of his laboratory and the use of the electron microscope to me, and the John Simon Guggenheim Memorial Foundation for the Fellowship which I held during 1964–65.     

The Fine Structure of Some Blood Vessels of the Earthworm, Eisenia foetida

The fine structure of the main dorsal and ventral circulatory trunks and of the subneural vessels and capillaries of the ventral nerve cord of the earthworm, Eisenia foetida, has been studied with the electron microscope. All of these vessels are lined internally by a continuous extracellular basement membrane varying in thickness (0.03 to 1 µ) with the vessel involved. The dorsal, ventral, and subneural vessels display inside this membrane scattered flattened macrophagic or leucocytic cells called amebocytes. These lie against the inner lining of the basement membrane, covering only a small fraction of its surface. They have long, attenuated branching cell processes. All of these vessels are lined with a continuous layer of unfenestrated endothelial cells displaying myofilaments and hence qualifying for the designation of "myoendothelial cells." The degree of muscular specialization varies over a spectrum, however, ranging from a delicate endowment of thin myofilaments in the capillary myoendothelial cells to highly specialized myoendothelial cells in the main pulsating dorsal blood trunk, which serves as the worm's "heart" or propulsive "aorta." The myoendothelial cells most specialized for contraction display well organized sarcoplasmic reticulum and myofibrils with thick and thin myofilaments resembling those of the earthworm body wall musculature. In the ventral circulatory trunk, circular and longitudinal myofilaments are found in each myoendothelial cell. In the dorsal trunk, the lining myoendothelial cells contain longitudinal myofilaments. Outside these cells are circular muscle cells. The lateral parts of the dorsal vessels have an additional outer longitudinal muscle layer. The blood plasma inside all of the vessels shows scattered particles representing the circulating earthworm blood pigment, erythrocruorin.     

The ultrastructure of the striated muscle of the tail of Cercaria chackai Nadakal et al., 1969

The electron microscopic study of the tail of Cercaria chackai reveals that it contains four sets of striated muscle bundles located central to the nonstriated circular and longitudinal muscles. The striated muscle consists of longitudinally oriented lamellar myofibres. Each myofibre contains a single "U" shaped myofibril. The banding pattern is analogous to that of vertebrate striated muscle. The sarcolemma is a simple surface membrane. There are no transverse tubular extensions of sarcolemma. The sarcoplasmic reticulum (SR) is very well developed with cisternae, tubules, and vesicles. SR cisternae form dyadic couplings with the sarcolemma. There is a set of flattened tubules of SR origin traversing the myofibril exactly at the Z region. These tubules are unique to the striated muscle of the cercarian tail and may have functional significance. A diagrammatic reconstruction of the myofibre is presented.     

Ultrastructure of muscle cells in the adductor of the boring clam Tridacna crocea

The ultrastructure of the adductor muscle of the boring clam (Tridacna crocea) was investigated. The adductor was composed of opaque and translucent portions. The opaque portion contained smooth muscle cells; the translucent portion contained obliquely striated cells. Smooth muscle cells were classified, according to the statistically analyzed diameters of their thick myofilaments, into two types, S-1 and S-2. S-1 cells had thick myofilaments, 50–60 nm in diameter. S-2 cells had thick myofilaments of two sizes, about 55–65 nm and 85–100 nm in diameter, respectively. Obliquely striated muscle cells in the translucent portion were also classified into two types: O-1 cells, with thick myofilaments 30–35 nm in diameter, and O-2 cells, with myofilaments of 50–60 nm.     

The fine structure of fast and slow crustacean muscles

Known phasic and tonic muscle fibers of the crab Cancer magister were studied by electron microscopy. Phasic fibers have sarcomeres about 4.5 µ long, small polygonal myofibrils, and a well-developed sarcoplasmic reticulum. The thick myofilaments, disposed in hexagonal array, are each surrounded by six thin filaments. The tonic fibers have a sarcomere length of about 12 µ, larger myofibrils, a poorly developed sarcoplasmic reticulum, and a disorderly array of myofilaments. Each thick myofilament is surrounded by 10–12 thin filaments. The same morphological type of slow muscle has been found in the crustaceans, Macrocyclops albidus, Cypridopsis vidua, and Balanus cariosus, in each case in an anatomical location consistent with tonic action. A search of the literature indicates that this type of muscle is found in all classes of arthropods and is confined to visceral and postural muscles or specializations of these.     

Ultrastructural investigations on the muscular systems in the barnacle, Tetraclita squamosa japonica

Four muscular systems of the Tetraclita squamosa barnacle were observed by means of an electron microscope and it was revealed that these systems each bore different types of muscle cells. The four systems were the adductor (A), the lateral scutal depressor (LSD), the ventral scutal depressor (VSD), and the tergal depressor (TD). The A-system included cross stiated muscle cells which showed long sarcomeres (about 10 μm) and rather disordered arrays of myofilaments. The LSD-system included cross striated muscles which had medium length sarcomeres (about 6.7 μm) and rather ordered myofilamental arrays. The VSD-system was constructed of cross striated muscle cells which bore shorter sarcomeres (4.6 μm) than the previous three systems and ordered myofilamental arrays. This last type of cell also bore well-developed sarcoplasmic reticular systems. The TD-system included smooth muscle cells which showed rather ordered arrays of myofilaments and dense-bodies. Each muscular system, as described above, included to its advantage one type of cross striated or smooth muscle cell for its characteristic contraction. The relations between ultrastructures and functions of each muscular system will now be discussed.     

The myofilament lattice: studies on isolated fibers. IV. Lattice equilibria in striated muscle.

Accounts of similarities between the thick filament lattice of striated muscle and smectic liquid-crystalline structures have focused upon an equilibrium between electrostatic (repulsive) and van der Waal's (attractive) forces. In living, intact muscle the fiber volume constitutes an additional important parameter which influences the amount of interaxial separation between the filaments. This is demonstrable by comparison of the lattice behavior of living fibers with that of fibers from which the sarcolemma has either been removed or made leaky by glycerination. These comparisons were made mainly by low-angle X-ray diffraction under conditions of changes in sarcomere length, ionic strength or osmolarity, and pH. Single fibers with the sarcolemma removed and glycerinated muscle have lattices which behave in accord with equilibrium liquid-crystalline systems in which the thick filament spacing is determined by the balance between electrostatic and van der Waal's forces. Conversely, osmotic and shortening studies demonstrate that the living, intact muscle has a lattice which behaves in accord with the so-called non-equilibrium (volume-constrained) liquid-crystalline condition in which the interaxial separation between the thick filaments is solely due to the amount of volume available as determined by the Donnan steady-state across the sarcolemma.     

Ultrastructural investigations on the muscular systems in the barnacle, Tetraclita squamosa japonica

Four muscular systems of the Tetraclita squamosa barnacle were observed by means of an electron microscope and it was revealed that these systems each bore different types of muscle cells. The four systems were the adductor (A), the lateral scutal depressor (LSD), the ventral scutal depressor (VSD), and the tergal depressor (TD). The A-system included cross stiated muscle cells which showed long sarcomeres (about 10 mum) and rather disordered arrays of myofilaments. The LSD-system included cross striated muscles which had medium length sarcomeres (about 6.7 mum) and rather ordered myofilamental arrays. The VSD-system was constructed of cross striated muscle cells which bore shorter sarcomeres (4.6 mum) than the previous three systems and ordered myofilamental arrays. This last type of cell also bore well-developed sarcoplasmic reticular systems. The TD-system included smooth muscle cells which showed rather ordered arrays of myofilaments and dense-bodies. Each muscular system, as described above, included to its advantage one type of cross striated or smooth muscle cell for its characteristic contraction. The relations between ultrastructures and functions of each muscular system will now be discussed.