Cellular localization of insulin-like growth factor-II protein in the sea bass (Dicentrarchus labrax) from hatching to adult

The cellular localization of IGF-II protein was investigated during larval and postlarval developmental stages of sea bass (Dicentrarchus labrax) by immunohistochemistry using antisera raised against Sparus aurata IGF-II. At hatching, IGF-II immunoreactivity was already present in the skin, developing intestine and skeletal muscle. During larval life IGF-II protein was also observed in heart musculature, in kidney and gill epithelia as well as in liver. In fry skeletal muscle a moderate IGF-II immunostaining was detected in red fibres, whereas white muscle fibres exhibited a faint immunoreactivity. In adults, a marked IGF-II immunostaining was observed in red muscle fibres. A moderate immunoreactivity was also present in white fibres as well as in heart striated myocardial fibres. These results are in agreement with previous findings on the spatial localization of IGF-II and IGF type 1 receptor in S. aurata and Umbrina cirrosa, confirming the role of IGF system during development and growth of fish.     

Muscle growth in yolk-sac larvae of the Atlantic halibut as influenced by temperature in the egg and yolk-sac stage

Atlantic halibut eggs and yolk-sac larvae were incubated at 1, 5 and 8° C. Eggs incubated at 8° C gave slightly shorter larvae at hatching with a significantly smaller total cross-sectional area of white muscle fibres than eggs incubated at 5° C. Transport of eggs 2 days prior to hatching gave significantly longer larvae at hatching with a significantly larger red fibre cross-sectional area than when eggs were transported shortly after the blastopore closure. A higher survival until 230 degree days after hatching was also observed in the former group. All eggs incubated at 1° C died before hatching and all larvae incubated at 1° C died before 45 degree days after hatching. From hatching until 230 degree days the total white cross-sectional area increased threefold in all temperature groups. The increase in white cross-sectional area was entirely due to hypertrophy between hatching and 150 degree days (10 mm L _S). Recruitment of new white fibres increased in germinal zones at the dorsal, ventral and lateral borders of the myotome from 150 degree days onwards, but at 230 degree days (12–13 mm L _S) the recruitment fibre zone constituted <10% of the total white cross-sectional area. Larval incubation at 8° C gave slightly longer larvae with a significantly larger cross-sectional area of recruitment fibres at 230 degree days than incubation at 5° C. The larval group incubated at 8° C also had a significantly lower survival until 230 degree days than did the 5° C group. Incubation temperature regimes did not affect the volume density of myofibrils in the axial muscle fibres at 230 degree days. Thus hypertrophy is the predominant mechanism of axial white muscle growth in Atlantic halibut yolk-sac larvae and an increased rearing temperature during the yolk-sac stage increases white muscle fibre hyperplasia.     

Differentiation of swimming muscles and gills,and development of anaerobic power in the larvae of cyprinid fish (Pisces,Teleostei)

Summary Histological, histochemical, morphometric and electrophoretic methods were combined to study the differentiation of the swimming muscles and of the gills in the larvae and juveniles of cyprinids during the first 3 months after hatching. The bodies of recently hatched larvae are always surrounded by a single layer of muscle fibres (red layer) which possess strong cytochrome oxidase (COX) activity but whose myofibrils do not show the arrangement typical of the fibres of adult red muscle. The contribution of the red layer to total muscle mass decreases from about 12% on day 3 to 4% on day 40 post-hatching, after which the red layer becomes indistinguishable from the developing mass of adult red muscles. The adult fibres seem to originate through splitting from the larval fibres. The inner muscle masses of recently hatched larvae also display conspicuous COX activity which, however, disappears gradually. The development of the gill surface follows a time course which during the first 40 days is a mirror image of that of the larval red layer of muscle fibres, i.e. increasing at about the same rate as the latter decreases. The most cathodic of the isoenzymes of LDH (M₄), an indicator of the glycolytic capacity of the white muscle of adult fish, develops only slowly in the larvae. In whole body homogenates, the dominant isoenzyme after hatching is the aerobic H₄-form, and it is not until 2 weeks or so that the anaerobic M₄ is the strongest fraction in electropherograms of total body homogenates. In the bleak, Alburnus alburnus (Linné, 1758), which spends the first 8–10 days after hatching on the bottom of the aquarium, the M₄ isoenzyme takes much longer to develop than in Rutilus rutilus (Linné, 1758) or Chondrostoma nasus (Linné, 1758) which start swimming within 3 days after hatching. All these findings suggest that in the early larvae swimming is almost entirely aerobic, being powered by the deep layers of muscle fibres. During this developmental phase the superficial red layer perhaps is the main respiratory organ.     

Life styles and patterns of development of gills and muscles in larval cyprinids (Cyprinidae; Teleostei)

A morphometric study of gill structures and of the body musculature during the first weeks after hatching was carried out on larvae of six cyprinid species: Leuciscus cephalus, L. leuciscus, Rutilus rutilus, Alburnus albumus, Chondrostoma nasus and Abramis brama . In all species a unicellular layer of red muscle fibres covers the central muscle mass; this layer is of greatest extent shortly after hatching but diminishes gradually in mass by contracting towards the lateral region of the body until it merges with (or gives rise to) the adult red muscle fibres proper. There is a close relationship between the rate of differentiation of gill structures and the rate at which the larval red muscle layer disappears, the pattern of this relationship reflecting the life style of the species. The longer the larvae delay the start of their free-swimming existence after hatching (which in A. alburnus may be as long as 10 days) the longer does the red layer of muscle fibres serve as the organ of gas exchange and the longer is gill development suppressed. It appears that the metabolism of the swimming muscles is almost entirely aerobic so long as gas exchange takes place across the whole body surface, the glycolytic capacity of the central muscle mass developing only slowly in conjunction with the switch from red layer to gills as the major respiratory organ.     

The larval development of lateral musculature in gilthead sea bream Sparus aurata and sea bass Dicentrarchus labrax

Fibre-type differentiation of the lateral musculature has been studied in Sparus aurata (L.) and Dicentrarchus labrax (L.) during larval development. Histochemical and ultrastructural techniques show two presumptive muscle layers and two germinative zones of presumptive myoblasts. At hatching, myotomal muscle consists of a monolayer of thin undifferentiated cells near the skin (first germinative zone) overlying another mono-layer of small diameter fibres extending hypaxially and epaxially away from the transverse septum. Below this, there is a much thicker, deep layer of fibres, generally large in diameter and polygonal in shape. The presumptive myoblasts are located between these two layers of fibres in the second germinative zone. Initially, the superficial and deep muscle fibres show high and low myosin ATPase activity, respectively. Both layers grow by generating new fibres from the two mentioned germinative zones. At the end of larval life, the superficial layer changes its histochemical profile from high to low myosin ATPase activity and, at the same time, intermediate or pink muscle fibres can be observed by oxidative activity (the NADH-TR reaction). Morphometric analysis shows a significant increase in mean fibre diameter during successive ages, as shown by the Student's t-test (hypertrophic growth). Skewness and kurtosis values of fibre diameters point to the generation of a new fibre population from the germinative zones (hyperplastic growth).     

Growth and multiplication of white skeletal muscle fibres in carp larvae in relation to somatic growth rate

A morphometric analysis of white axial muscle of common carp Cyprinus carpio was undertaken in order to quantify increase in fibre size, fibre nuclei and fibre number in relation to somatic growth rate during early life. In fast-growing carp larvae fed zooplankton, length and height of fibres from the central part of dorsolateral muscle increased at the same rate (0.75) relative to the total length of the larvae during the first 2 weeks of feeding. During this period, the number of nuclei per fibre increased threefold while the number of nuclei per unit fibre surface remained constant. In fast-growing larvae fed a formulated diet, the total cross-sectional area of one epaxial quadrant of white muscle and the total area of white fibres increased at almost the same rate (3.15; 3.23) relative to larval total length during the first 28 days of exogenous feeding. The total number of white fibres increased faster (2.07) relative to the total length of larvae than the mean area of white fibres (1.16). Hyperplasia accounted for 64% of muscle growth in these larvae. The proportion of fibres with a width < 10 μm decreased from 72% at first feeding to 14% 28 days later, while the proportion of fibres with a width >20 μm which was 0% at first feeding increased up to 34% in the same time. The recruitment of new white fibres seemed to be almost the same in the whole muscle quadrant at first feeding and 18 or 28 days later but, 8 days after first feeding, a transient significant recruitment of new fibres was shown at the apex of the myotome. Comparisons between fast- and slow-growing groups of larvae showed that for a given larval total length: (1) the mean width of central white fibres was higher and the proportion of central fibres with a width <10 μm was lower in slow-growing larvae than in fast-growing ones; (2) the total number of white fibres was lower for a higher total cross-sectional area of white muscle in slow-growing larvae than in fast-growing ones. These results suggest that, in Cyprinus carpio larvae, slow-growing conditions are related to a decreased contribution of hyperplasia to muscle growth.     

Muscle differentiation in blackspot seabream (Pagellus bogaraveo, Brunnich): histochemical and immunohistochemical study of the fibre types

The aim of this work was to gain insights into the mechanism of muscle differentiation and growth in Pagellus bogaraveo, by studying muscle fibre phenotypes identified by immunohistochemistry. At hatching, several layers of deep fast-white fibres were covered by a superficial fibre monolayer. At 5 days, slow-red fibres appeared near the lateral line nerve. At 40 days, the intermediate-pink muscle became visible, and in the slow-red and fast-white muscle layers transitions from larval myosin isoforms to the isoforms typical of adult muscle occurred. Between 70 and 100 days, small fibres with a distinct ATPase profile appeared throughout the fast-white muscle, marking the onset of “mosaic” hyperplasia. The myosin of the original superficial monolayer fibres underwent two myosin transformations, before being slowly replaced by an adult slow-red isoform. In juveniles and adults, the slow-red muscle layer could be resolved into two distinct types. The analysis of fibre phenotypes indicated that post-larval muscle growth occurred by two distinct stages of hyperplasia. This study offers a basis for further comparative and experimental studies with this economically relevant species, namely for identifying factors influencing its muscle growth dynamics and disclosing underlying mechanisms.     

鳜慢肌胚后发育与生长特征

鱼类快肌和慢肌分别占据骨骼肌的不同位置,表现不同的生长发育特征。为了解鳜(Sinipercachuatsi)慢肌纤维的胚后发育特征,本研究通过制作孵化后1～33日龄鳜个体的石蜡切片,采用慢肌特异抗体的免疫组织化学染色,观察了背鳍起点处躯干横切面慢肌的发育变化特征,并利用图像分析软件统计慢肌纤维的数目和面积。结果表明,孵化后鳜仔鱼慢肌位于水平肌隔附近,呈楔形,向背、腹两侧生长。孵化后1～9日龄为单层肌纤维,11日龄发育为多层肌纤维,19日龄覆盖侧线附近,33日龄延伸至背侧第2背肌节、腹侧腹部肌肉2/3处,并在水平肌隔和侧线处分别形成两个肌群。位于骨骼肌最外层的扁平状表层细胞,可能为慢肌增生生长的主要来源。躯干单侧慢肌肌纤维数目由孵化后6个增加至315个,总面积从13.18μm2增加到7 839.58μm2,孵化后13日龄的增生生长占优势,其他发育阶段,肥大生长一直占主导优势。     

New insights into skeletal muscle development and growth in teleost fishes

Recent research has significantly broadened our understanding of how the teleost somite is patterned to achieve embryonic and postembryonic myogenesis. Medial (adaxial) cells and posterior cells of the early epithelial somite generate embryonic superficial slow and deep fast muscle fibers, respectively, whereas anterior somitic cells move laterally to form an external cell layer of undifferentiated Pax7-positive myogenic precursors surrounding the embryonic myotome. In late embryo and in larvae, some of the cells contained in the external cell layer incorporate into the myotome and differentiate into new muscle fibers, thus contributing to medio-lateral expansion of the myotome. This supports the suggestion that the teleost external cell layer is homologous to the amniote dermomyotome. Some of the signalling molecules that promote lateral movement or regulate the myogenic differentiation of external cell precursors have been identified and include stromal cell-derived factor 1 (Sdf1), hedgehog proteins, and fibroblast growth factor 8 (Fgf8). Recent studies have shed light on gene activations that underlie the differentiation and maturation of slow and fast muscle fibers, pointing out that both adaxially derived embryonic slow fibers and slow fibers formed during the myotome expansion of larvae initially and transiently bear features of the fast fiber phenotype.     

Postlarval muscle growth in fish: a DNA flow cytometric and morphometric analysis

The mechanism of postlarval fish myotomal growth was investigated in trout (Salmo gairdneri) by means of morphometric and cytofluorometric analysis. The mechanism by which new fibres are added during postlarval growth (hyperplasia) is not fully understood. In histological cross sections these new fibres have a small diameter which give the muscle a "mosaic" appearance. One hypothesis suggested that they could be derived from the proliferative activity of satellite cells. DNA cytofluorometric analysis of nuclei suspensions obtained from trout white myotomal muscle during different developmental stages (eleutherembyronic; alevin; yearling and adult) showed a consistently low S-cytometric phase during all stage in which myofibres of small diameters were present. The percentage of such small fibres, determined by morphometric analysis, suggested that satellite cells are the proliferative population. In fact, their percentages, as determined by morphometric analysis in histological section, bear a linear relationship with the S-cytometric phase percent nuclei (R = 0.927). Only in adults (67 cm in size) there was a significant decrease in the S-cytometric phase. At this stage, in histological sections, the myotomal muscle no longer had a "mosaic" appearance because of the disappearance of the small fibres. It may, therefore, be supposed that in the cm 67 adult specimens, the proliferative population is entering the G0 phase. It is known, in fact, that muscle growth proceeds only by fibre hypertrophy in trout longer than 70 cm in length (Stickland, 1983).     

The lateral musculature of the common bully, Gobiomorphus cotidianus, a freshwater fish from New Zealand

A histochemical and ultrastructural study has shown that the myotome of the common bully, Gobiomorphus cotidianus , is composed of three muscle fibre types: white, pink and small diameter fibres. There are no red fibres. Both white and pink fibres have characteristics similar to these fibres found in other teleosts. The small diameter fibres are located in the position usually occupied by red fibres and are identified by their small size and poor staining characteristics. At the ultrastructural level these small fibres are seen to have few mitochondria and a poorly developed sarcoplasmic reticulum. It is suggested that the small diameter fibres are a type of tonic muscle used for positioning the trunk.     

A comparison of the distribution of muscle type in the tadpole tails of Xenopus laevis and Rana temporaria: an histological and ultrastructural study

The types and the distribution of muscle fibres were analysed and compared in the tails of Xenopus laevis and Rana temporaria tadpoles. The filter feeding tadpoles of X. laevis were found to have both white muscle fibres adjacent to the notochord used for normal locomotory swimming and a superficial layer of small red fibres. The red fibres are probably used for the continuous flickering movement of the tail associated with the maintenance of the mid-water filter feeding position. R. temporaria, a grazing detritus feeding tadpole, was found to have only white muscle fibres used for normal locomotory swimming. Smaller superficial fibres were not red fibres but were thought to be immature white fibres.     

Temperature- and developmentally-induced variation in the histochemical profile of myofibrillar ATPase activity in carp

The histochemical profile of calcium activated acid stable myofibrillar ATPase (mATPase) activity in developing larval and juvenile carp was investigated. In the larval fish, differentiation of pink muscle fibres occurred after metamorphosis which was delayed by a week at 17° C compared to larvae grown at 27° C. After metamorphosis the 27° C group exhibited some small myofibres with acid stable mATPase activity in the deep white muscle. This was similar for the juvenile carp which were acclimated for more than a month at 25° C. In contrast, the cold (12° C) acclimated juvenile fish, contained very few small white muscle fibres with acid stable mATPase activity. It was also noted that the cold acclimated fish had lower background acid stable mATPase activity than the warm acclimated fish. Results indicate that after metamorphosis and more evidently in juveniles, temperature can influence the rate of myofibre hyperplasia.     

Histochemical and immunohistochemical profile of pink muscle fibres in some teleosts

Summary The pink muscle of several Teleosts was examined immunohistochemically using antisera specific for the myosins of red and white muscle, and histochemically using various methods for demonstrating myosin ATPase (in ATPase) activity.In the catfish the pink muscle consists of 2 different layers of fibres. The superficial layer has a low mATPase activity after both acid and alkali pre-incubation, whereas the deeper layer has a high mATPase activity after acid and alkali pre-incubation, being more resistent to these conditions even than is the white muscle.In the trout the pink muscle is composed of fibres with the same mATPase activity as in the superficial pink muscle of the catfish, whereas in the rock goby, goldfish, mullet and guppy the pink muscle is like the deep pink layer of the catfish.Immunohistochemically the fibres of the pink muscle behave like the white muscle fibres except in the guppy and rock goby in which at the level of the lateral line there occurs a transition zone between red and pink fibres. The fibres of this region react with both anti-fast and (to a lesser extent) anti-slow myosin antisera, and have a mATPase activity which, going from the superficial to the deeper fibres, gradually loses the red muscle characteristics to acquire those of the main pink muscle layer.     

Muscle development in cultured blackspot seabream Pagellus bogaraveo: preliminary histochemical and immunohistochemical data on the fibre types

We studied muscle ontogeny and fibre type characteristics in the blackspot seabream, a new species for commercial aquaculture. Myosin ATPase and SDH histochemistry and immunohistochemistry were tested at different ontogenetic stages, using a panel of antibodies to myosin isoforms and parvalbumin. In general, deep white muscle was parvalbumin‐positive, and superficial 'red' muscle was parvalbumin‐negative at all ages examined. At 6 days of age (transition from endogenous to exogenous feeding) three layers of muscle fibres were observed with different antimyosin reactivities: superficial monolayer, presumptive slow red (present only as a small group of fibres adjacent to the lateral line nerve), and presumptive fast‐white (forming the bulk of the muscle). The superficial monolayer and presumptive slow fibres were positive for SDH. At 60 days of age (transition from live to artificial feeding) an additional fibre type was identified: a typical 'pink' or intermediate layer. In juveniles, the axial muscle consisted mainly of fast white fibres covered by a slow‐red layer and between them a pink layer. Surprisingly, the red layer could be resolved into two distinct types by myosin immunostaining. Red fibres were also present along the horizontal septum, near the notochord. Both red and white muscle layers showed a mosaic appearance, which was confirmed by ATPase reaction. The work was financed by British Council, CRUP, and FCT (PhD Grant SFRH‐BD‐14068–2003).     

Morphological and histochemical characterization of the pectoral fin muscle of the stripped weakfish,Cynoscion guatucupa

The fibres of superficial and deep abductor muscles of the pectoral fins of the stripped weakfish, Cynoscion guatucupa have been studied using histochemical techniques: succinic dehydrogenase (SDH) for mitochondria, periodic acid–Schiff (PAS) for glycogen, myosin‐adenosintriphosphatase (mATPase) to identify different fibre types based on the contraction speed and modified ATPase to identify capillaries. The fibre diameters were measured, and the capillaries of the main fibre types – red, pink and white— were counted. The two muscles showed both macroscopically and microscopically two well‐differentiated zones with predominant white fibres. The area of insertion of muscles into the fin rays had red, pink and white fibres. The origin zone of the muscle into the bone was composed by white fibres only. Both zones of white muscle evidenced a mosaic of small, medium and large polygonal white fibres. Red, pink and white muscles showed a wide histochemical diversity of fibre subtypes. The area per peripheral capillary increased from the red to the white muscles. Due to the predominance of white fibres, the pectoral fins of C. guatucupa were mainly involved in rapid movements to stop/discontinue and stabilize the body during swimming.     

Histochemical and immunohistochemical profile of pink muscle fibres in some teleosts

The pink muscle of several Teleosts was examined immunohistochemically using antisera specific for the myosins of red and white muscle, and histochemically using various methods for demonstrating myosin ATPase (mATPase) activity. In the catfish the pink muscle consists of 2 different layers of fibres. The superficial layer has a low mATPase activity after both acid and alkali pre-incubation, whereas the deeper layer has a high mATPase activity after acid and alkali pre-incubation, being more resistent to these conditions even than is the white muscle. In the trout the pink muscle is composed of fibres with the same mATPase activity as in the superficial pink muscle of the catfish, whereas in the rock goby, goldfish, mullet and guppy the pink muscle is like the deep pink layer of the catfish. Immunohistochemically the fibres of the pink muscle behave like the white muscle fibres except in the guppy and rock goby in which at the level of the lateral line there occurs a transition zone between red and pink fibres. The fibres of this region react with both anti-fast and (to a lesser extent) anti-slow myosin antisera, and have a mATPase activity which, going from the superficial to the deeper fibres, gradually loses the red muscle characteristics to acquire those of the main pink muscle layer.     

Studies on the swimming musculature of the rainbow trout I. Fibre types

A histochemical study has been made on the myotomal musculature of the rainbow trout Salmo gairdneri Richardson. Four main types of fibre can be distinguished on the basis of differences in fibre size, lipid content and succinic dehydrogenase and myofibrillar adenosine triphosphatase activity (ATPase activity). Early histological studies have concluded that in addition to a superficial strip of muscle small diameter 'red' fibres occur throughout the trout myotome. These small diameter fibres occurring in the bulk of the myotome are shown to differ from the superficial fibres with respect to their oxidative metabolism and myofibrillar ATPase. The relevance of this finding to studies on the energetics and swimming efficiency of this species are discussed.     

Myostatin precursor is present in several tissues in teleost fish: a comparative immunolocalization study

In this study, the distribution of myostatin was investigated during larval and postlarval developmental stages of Sparus aurata(sea bream), Solea solea(sole) and Brachydanio rerio(zebrafish) by immunohistochemistry using antisera raised against a synthetic peptide located within the precursor region of sea bream myostatin. All the three species examined showed the strongest immunoreactivity in red skeletal muscle in juveniles and adults. During larval development of sea bream, strong staining was detected in skin and brain. Immunoreactivity was also found in muscle, pharynx, gills, pancreas and liver. From metamorphosis, immunoreactivity was identifiable in the oesophagus, in the apical portion of the stomach epithelium, in the intestinal epithelium and in renal tubules. In larval zebrafish at hatching, the most intense myostatin immunoreactivity was evident in the skin epithelium. Immunoreactivity was also found in the retina and brain. In the adult, an intense immunostaining occurred in the gastrointestinal tract as well as in the ovary. In sole larvae, immunoreactivity was found in liver and intestine. Our results support the hypothesis suggested earlier that myostatins in fish have retained a different partition (compared with mammals) of the expression patterns and functions which characterized the ancestral gene before the duplication event that gave rise to growth differentiation factor-11 (GDF-11) and GDF-8 (myostatin).     

Succinic dehydrogenase activity of the respiratory muscles of a fresh-water teleost, Bagarius bagarius (Ham.) (Sisoridae, Pisces).

Functional morphology including the origin, insertion, and innervation of the respiratory muscles in relation to buccal pressure pump and opercular suction pumps in a fresh-water bottom dwelling siluroid fish, Bagarius bagarius have been studied. Histochemical studies were made on the succinic dehydrogenase activity of adductor mandibulae, retractor tentaculi, levator operculi, dilatator operculi, adductor operculi, intermandibularis, interhyoideus, hyohyoideus superior and constrictor branchialis. The intensity of reaction reveals the presence of three types of muscle fibres in some of the respiratory muscles. The muscle containing red muscle fibres are mostly innervated by the branches of the VIIth cranial nerve. The retractor tentaculi consists of superficial white muscle fibres and the interior part is dominated by red muscle fibres. The muscles (adductor operculi, levator operculi, dilatator operculi, interhyoideus, hyohyoideus superior) concerned with the opercular suction pumps are of mixed type and consist of white and red muscle fibres, whereas adductor mandibulae and intermandibularis are made up entirely of white muscle fibres. The adductor muscle bundles of the constrictor branchialis, which are responsible for movement of gill filaments, are dominated by the red muscle fibres. The abductor part, however, is made up entirely of white muscle fibres.