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.     

Ultrastructural differences between the anterior and posterior adductors of the strawberry cockle, Fragum unedo

Adductors of Fragum unedo were observed ultrastructurally and their muscle cells were classified according to the statistically analyzed diameter of their thick myofilaments. Two types of smooth muscle cells were observed in the opaque portion of the anterior adductor: A-type cells containing thick myofilaments of about 46 nm in diameter and B-type cells having 62 nm thick myofilaments. The posterior adductor was also composed of two kinds of cells: the B-type cell, which had thick myofilaments of about 67 nm in diameter, and the C-type, containing thick myofilaments of 90 nm. Two types of oblique-striated cells were commonly recognized in the translucent portions of anterior and posterior adductors. Our observations thus indicate that the posterior adductor generally consists of cells which have thicker myofilaments than the ones of the anterior adductor.     

Cell types differing in thick myofilament diameter in obliquely striated muscle of a polychaete annelid, Neanthes

The fine structure of the obliquely striated muscle cells of the longitudinal muscle of an annelid was investigated. The characteristics of myofilaments and cell components, such as sarcoplasmic reticular system (S.R.), T-systems and J-rods corresponded to those previously reported, but it was noted for the first time that the cells could be classified into two types with respect to the diameters of their thick myofilaments. In one type, the thick myofilaments were about 29 nm in diameter (A-type) and in the other they were about 41 nm in diameter (B-type). Most of the obliquely striated muscles described to date have been composed of a single type of cell, but we found two types of cell mixed together in the longitudinal muscle. The A-type cells with slender thick myofilaments were distributed mainly in the inner part of the muscle and the B-type cells with broader thick myofilaments were distributed in the outer part.     

Fine structural study of the abdominal muscle receptor organs of the crayfish (Procambarus clarkii). Fast and slow receptor muscles

Receptor muscles of the abdominal muscle receptor organs of the crayfish, Procambarus clarkii, were examined by electron microscopy. Both the fast and the slow receptor strand comprises a single muscle fibre which is divided by invagination of the cell membrane into numerous cytoplasmic processes in its intermediate region (the so-called intercalated tendon). Most of these myofibrillar processes insert in this region, but some of them pass through the intermediate region without interruption and join the other portion of the fibre. Thus the receptor muscles, whilst maintaining cytoplasmic continuity throughout their whole length, are modified in their intermediate regions, becoming fasciculated and providing spaces which are occupied by the connective tissue and the dendrites of the sensory neurone. Clear-cut differences in fine structure are shown between the muscle of the two types of receptor unit. The fast receptor muscle shows the typical features of arthropod fast muscles, including short sarcomere length (on average 3.3 μm), cylindrical myofibrils, well-developed sarcoplasmic reticulum, and regular hexagonal array of the myofilaments. By contrast, the slow receptor muscle fibre is characterized by long sarcomeres (average 6.5 μm) and unique organization of the myofilaments, with very thick ‘thick’ filaments having diameters in the range of 25–36 nm surrounded by about 12 thin filaments.     

Ultrastructural features of cardiac muscle cells in a tarantula spider

The ultrastructural features of cardiac muscle cells and their innervation were examined in the tarantula spider Eurypelma marxi Simon. The cells are transversely striated and have an A band length of about three microns. H zones are indistinct and M lines are absent. Thick and thin myofilament diameters are approximately 200 and 70 Å respectively. Eight to 12 thin filaments usually surround each thick one. Accumulations of thick and thin myofilaments occur perpendicular to the bulk of the myofilaments in some cells. The Z line is discontinuous and thick filaments may pass through the spaces in the Z line. Extensive systems of sarcoplasmic reticulum and transverse tubules are present; these form numerous dyadic junctions in both A and I band regions. Sarcolemmal invaginations form Z line tubules; lateral extensions of the plasma membrane portion of these invaginations form dyads. Nerve branches of the cardiac ganglion make multiple neuromuscular synapses with at least some of the cardiac muscle cells. Both large granular and small agranular vesicles are present in the presynaptic terminals. Intercalated discs similar to those present in other arthropod hearts occur between the ends of adjacent cardiac muscle cells.     

Two kinds of thick filament in smooth muscle cells in the adductor of a clam, Chlamys nobilis

The ultrastructure of the opaque portion of the adductor muscle in the pecten Chlamys nobilis was investigated. The opaque portion was composed of smooth muscle cells that contained thin and thick filaments. The thick filaments were classified into two kinds, thinner and thicker, according to the statistical analysis of diameters. They were also classified as being shorter and longer, when isolated native filaments were examined. The thick filaments may consequently be classified into two kinds: thinner and shorter filaments, and thicker and longer ones. The thinner and shorter filaments were about 26.5 nm in diameter and 7.5 mum in length, and the thicker and longer ones were about 42.0 nm in diameter and 13.0 mum in length, respectively. A regular periodicity was apparent on the surface of the core after removal of myosin molecules from its surface. The periodicity seemed similar for the two kinds of thick filament.     

Fine structure of the nephridial muscle layer cells of Phascolosoma granulatum (Sipuncula)

The nephridial muscle layer of Phascolosoma granulatum consists of a network of longitudinal and circular cells separated by connective tissue matrix. The muscle fibers are densely packed with thick and thin myofilaments, among which are scattered cytoplasmic dense bodies. The nucleus and noncontractile cytoplasmic organelles occupy a lateral projection from the contractile portion of the fiber. Cytoplasmic dense bodies are the result of a clustering of an indeterminate number of the thin actin filaments that fill the cytoplasm between thick filaments. Attached to the cytoplasmic face of the cell membrane are membrane-associated electron-dense plaques. These sites are linked to the contractile myofilaments by narrow filamentous bridges. Extracellular narrow filaments extend from these plaques to collagen fibers of the connective tissue matrix. Differences in length of the dense plaques may be related to differences in thick myofilament diameter in three types of muscle fiber, types A, B and C, statistically distinguished by mean fiber size differences. The plaques may serve as connecting links for the transmission of tension from contractile units to the connective tissue of the muscle layer. © 1993 Wiley-Liss, Inc.     

横纹肌肌原纤维的第三肌丝──肌联蛋白

实验研究证明,在动物横纹肌肌原纤维中,除包含有粗肌丝、细肌丝外,还有纤肌丝的存在,肌联蛋白（肌巨蛋白）是具有挠性的线状蛋白质,分子量为3000 000,长度约为0.9μm,跨越肌原纤维的M－线和Z－线,形成纤肌丝.其生理功能是在粗肌丝装配中具有分子模板作用,并将粗肌丝稳定于肌原纤维肌小节中央以及可参与肌球蛋白活性的调节.     

螫虾腹屈肌的肌球蛋白-副肌球蛋白丝

利用甘油梯度离心方法分离和纯化螯虾腹屈肌粗肌丝,电子显微镜照片显示粗肌丝上有数条纵行条纹,指示其可能由数根亚丝所组成。粗肌丝的 SDS-聚丙烯酰胺凝胶电泳表明其含有肌球蛋白和副肌球蛋白,肌球蛋白仅包含有二种轻链。副肌球蛋白类晶体呈针状,具有14.5nm 和72.5nm 的横纹周期。实验结果表明,螯虾腹屈肌粗肌丝是肌球蛋白-副肌球蛋白丝。     

THE RELATIONSHIP BETWEEN MYOFILAMENT PACKING DENSITY AND SARCOMERE LENGTH IN FROG STRIATED MUSCLE

In cross-sections of single fibers from the frog semitendinosus muscle the number of thick myofilaments per unit area (packing density) is a direct function of the sarcomere length. Our data, derived from electron microscopic studies, fit well with other data derived from in vivo, low-angle X-ray diffraction studies of whole semitendinosus muscles. The data are consistent with the assumption that the sarcomere of a fibril maintains a constant volume during changes in sarcomere length. The myofilament lattice, therefore, expands as the sarcomere shortens. Since the distance between adjacent myofilaments is an inverse square root function of sarcomere length, the interaction of the thick and the thin myofilaments during sarcomere shortening may occur over distances which increase 70 A or more. The "expanding-sarcomere, sliding-filament" model of sarcomere shortening is discussed in terms of the current concepts of muscle architecture and contraction.     

A COMPARATIVE STUDY ON THE FINE STRUCTURE OF THE BASALAR MUSCLE OF THE WING AND THE TIBIAL EXTENSOR MUSCLE OF THE LEG OF THE LEPIDOPTERAN ACHALARUS LYCIADES

Basalar and tibial extensor muscle fibers of Achalarus lyciades were examined with light and electron microscopes. Basalar muscle fibers are 100–150 µ in diameter. T-system membranes and sarcoplasmic reticulum make triadic contacts midway between Z lines and the middle of each sarcomere. The sarcoplasmic reticulum is characterized by a transverse element situated among myofilaments halfway between Z lines in every sarcomere. The morphology of Z lines, hexagonal packing of thin and thick myofilaments, and thin/thick myofilament ratios are similar to those of fast-acting insect muscles. Tibial extensor muscle fibers are 50–100 µ in diameter. Except for a lack of the transverse element, the T system and sarcoplasmic reticulum are similar to those of basalar muscle. Wavy Z lines, lack of a hexagonal packing of myofilaments, and larger thin/thick myofilament ratios are similar to those of other postural muscles of insects. The morphology of basalar and tibial extensor muscle is compared to that of other insect muscle with known functions, and reference is made to the possible contribution of the transverse element of sarcoplasmic reticulum in basalar flight muscle to speed and synchrony in this muscle.     

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.     

A comparative electron microscope study of visceral muscle fibers in Cambarus,Drosophila and Lumbricus

Summary The arrangement of myofilaments in the striated visceral muscle fibers of two arthropods (crayfish and fruitfly) and in the unstriated visceral fibers of one annelid (earthworm) was studied comparatively. Transverse sections through the A bands of arthropod visceral fibers indicate that each thick myofilament is surrounded by approximately 12 thin filaments. The myofilaments are less organized in the visceral fibers of the earthworm than in muscle fibers of the crayfish and fruitfly. The thick myofilaments of the earthworm are composed of subunits, 20–30 Å in diameter. The presence of two distinct sets of myofilaments in these slowly contracting striated and unstriated visceral muscle fibers suggests that contraction is accomplished via a sliding filament mechanism.In crayfish visceral fibers the sarcolemma invaginates at irregular intervals to form a long and unbranched tubular system at any level in the sarcomere. Dyads formed by the apposition of T and SR membranes are observed frequently. The distribution of the T and SR systems in the visceral fibers of the fruitfly and the earthworm is markedly reduced and dyads are infrequently observed. The reduced T and SR systems may be related to the slow contraction of these fibers. Transport of specific substances across the sarcolemma could initiate contraction or relaxation in these fibers.This study was supported by a training grant GM-00582-06 from the U.S. Public Health Service.     

OBSERVATIONS ON THE FINE STRUCTURE OF PHARYNGEAL MUSCLE IN THE PLANARIAN DUGESIA TIGRINA

Pharyngeal muscle of the planarian Dugesia tigrina was studied by electron microscopy after osmium tetroxide fixation. The muscle cell was observed to contain one myofibril or bundle of myofilaments parallel to its longitudinal axis. The myofilaments were of two types, different in size and distribution. No Z lines or myofilament organization into cross or helical striations were seen. Dense bodies were seen as projections from an invagination of the plasma membrane and as dense lines parallel to the myofilaments. The muscle cells are surrounded by a plasma membrane which is structurally associated with dense body projections, with vesicles and cisternae of sarcoplasmic reticulum, and with synaptic nerve endings. The cell has sarcoplasmic projections perpendicular to its long axis; these projections are seen to contain the nucleus or mitochondria and granules. Mitochondria and granules are also seen in a sarcoplasm rim around the fibril. The dense bodies may serve as attachment for thin myofilaments and function in transmission of stimuli from plasma membrane to the interior of the fibril.     

The relation between excitation-contraction coupling and fine structure of a molluscan muscle,the radular retractor of the whelk,Buccinum undatum

The Buccinum radula is of the rachiglossate type with two outer rows of fierce hook-like attack teeth and a medial row of straight sharp-pointed shredding teeth. Individual cells of the radular retractor muscle are 10–12 m in diameter and separated at the closest by gaps of only 40 nm, providing areas of potential electrical contact. The cell membranes are heavily invested with long finger-like invaginations, associated with sarcoplasmic reticular cisternae, and surface caveolae; the latter are associated with the numerous dense body membrane attachment plaques found in this muscle. The radular retractor muscle possesses a significant sarcoplasmic reticulum of peripheral cisternae and deeper vesicles associated with mitochondria. The surface caveolae may result from myofilament force exerted via attachment plaques at the cell membrane, while deeper invaginations may constitute a rudimentary transverse tubular system to relay surface depolarization to associated sarcoplasmic reticular cisternae inducing calcium release to effect excitation-contraction coupling. The radular retractor muscle possesses the usual thick paramyosin and thin actin myofilaments, the latter associated with dense bodies and attachment plaques presumably to transduce force to the cell membrane. The mitochondria are unusually large and packed into dense central clusters surrounded by large deposits of glycogen granules. The nerve endings on the radular retractor muscle fibres show four different types of transmitter vesicle, presumably related to the four kinds of agonist action in this muscle, cholinergic, serotonergic, peptidergic and purinergic. All nerve endings have mixed vesicle populations, clear evidence of co-transmission. In this muscle we see a modification of usual smooth muscle structure to effect fast sustained contractions, an ultrastructural configuration functionally designed for the muscle's central role in the feeding cycle.Abbreviations ABRM anterior byssus retractor muscle - EC coupling excitation-contraction coupling - RP radular protractor muscle - RR radular retractor muscle - SR sarcoplasmic reticulum - T-system transverse tubular system     

Ultrastructural diversity in motor units of crustacean stomach muscles

The physiological and ultrastructural properties of muscle fiber.s comprising three motor units in the gastric mill of blue crabs are described. In their contractile properties muscle fibers in all motor units are similar and resemble the slow type fibers in crustacean limb muscles. The majority of fibers generate large excitatory post-synaptic potentials which do not facilitate strongly. Structurally two types of fibers are found. The one type has long sarcomeres (greater than 6 mum), thin to thick myofilament ratios of 5-6:1 and diads located near the ends of the A-band. The other type has shorter sarcomeres (less than 6 mum), thin to thick myofilament ratios of 3:1 and diads located at mid sarcomere level. Both types of fibers occur within a single motor unit and this differs from the vertebrate situation. Furthermore, the finding of fibers with a low thin to thick myofilament ratio of 3:1 demonstrates that they are not exclusive to fast type crustacean muscle but also occur in slow stomach muscles.     

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     

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.     

THE EFFECTS OF ACTINOMYCIN D ON MUSCLE CELLS OF ASCIDIAN EMBRYO*

The effect of actinomycin D on muscle cells development of the ascidian, Herdmania momus was studied ultrastructurally. No myofilament was formed when the drug was given at any stage before early tail-bud stage (stage 3). Some aggregates of myofilaments in various size were formed when the treatment was started at stage 4 (4.5 hr after fertilization at about 28°C). Above 60% of myofibrils of fully differentiated muscle cells were formed when the treatment was initiated at stage 5 (5 hr after fertilization). Muscle cells of the tadpoles treated from stage 7 (6 hr after fertilization), at which myofilaments were first detectable in normal development, differentiated almost normally. It is therefore suggested that most mRNAs for muscle proteins are synthesized preceding the onset of myofilament formation and are relatively stable. It is also suggested that mRNAs for myosin, actin and Z band materials are almost simultaneously synthesized. One of the characteristic features of the muscle cell development of the ascidian embryo is almost synchronous differentiation of relatively small numbers of cells (about 54–60 cells). The significance of these results is discussed in relation to mosaic natures of the muscle development.     

The fine structure of muscle cells and their attachments in the tardigrade Macrobiotus hufelandi

Fine structural observations on three functional types of muscle cell are presented and the insertions of somatic muscle cells on to the cuticle are described. The contractile apparatus is composed of two kinds of myofilament, thick and thin, along with dense bodies in somatic cells, and a SR system is present in all three cell types. Somatic muscle cells are compared with previous reports of smooth muscle structure in invertebrate and vertebrate material, and their insertions are compared with those of arthropods.