Genetic inactivation of acetylcholinesterase causes functional and structural impairment of mouse soleus muscles.

Acetylcholinesterase (AChE) plays an essential role in neuromuscular transmission. Not surprisingly, neuromuscular transmission during repetitive nerve stimulation is severely depressed in the AChE knockout mouse (KO). However, whether this deficit in AChE leads to skeletal muscle changes is not known. We have studied the in vitro contractile properties of the postural and locomotor soleus muscles of adult KO and normal (wildtype, WT) mice, and this was completed by histological and biochemical analyses. Our results show that muscle weight, cross-sectional area of muscle fibres and absolute maximal isometric force are all reduced in KO mice compared with WT mice. Of interest, the relative amount of slow myosin heavy chain (MHC-1) in muscle homogenates and the percentage of muscle fibres expressing MHC-1 are decreased in the KO mice. Surprisingly, AChE ablation does not modify twitch kinetics, absolute maximal power, fatigue resistance or citrate synthase activity, despite the reduced number of slow muscle fibres. Thus, a deficit in AChE leads to alterations in the structure and function of muscles but these changes are not simply related to the reduced body weight of KO mice. Our results also suggest that this murine model of congenital myasthenic syndrome with endplate AChE deficiency combines alterations in both neurotransmission and intrinsic muscle properties.

Comparative evolution of muscular dystrophy in diaphragm, gastrocnemius and masseter muscles from old male mdx mice.

X chromosome-linked muscular dystrophic mdx mouse lacks the sarcolemmal protein dystrophin and represents a genetic homologue of human Duchenne muscular dystrophy (DMD). The present study analysed some aspects of pathological processes such as fibrosis, frequency of centralized nuclei, presence of degenerative or regenerative fibres, expression of utrophin and associated protein complexes, and myosin heavy chain isoforms in three muscles [diaphragm (DIA), gastrocnemius (GTC) and masseter (MAS)] from old male mdx mice. All parameters investigated comparatively in these pathological muscles provided evidence that the MAS mdx muscle presents a slight deterioration pattern in comparison to that of DIA and GTC muscles. Utrophin and associated proteins are present in many cell clusters with continuous membrane labelling in MAS muscle. Respective proportions of myosin heavy chain isoforms, measured by electrophoresis/densitometry, showed only slight change in GTC muscle, significant evolution in DIA muscle but drastic isoform conversions in MAS muscle. These results highlighted the difference in deterioration susceptibility of various muscles to muscular dystrophy. The reason why this occurs in MAS muscles is still obscure and discussed in terms of the comparative developmental origins of these muscles.

SFRP2 expression in rabbit myogenic progenitor cells and in adult skeletal muscles.

Satellite cells derived from fast- and slow-twitch muscles have different properties in culture. We have used the differential display technique to retrieve genes differentially expressed in fast- and slow-twitch muscle satellite cell cultures. Amongst these genes we have identified, cloned, sequenced and studied the expression in muscle of rabbit secreted frizzled related protein 2 (SFRP2) mRNA, whose importance in cell fate determination has been well documented. It has been shown that SFRP2 is widely expressed in the developing embryo but its expression in the adult is much more restricted. We show that primary cultures of satellite cells from adult rabbit fast- and slow-twitch muscles strongly and differentially express SFRP2 mRNA. Embryonic rabbit muscle cell primary cultures also strongly express SFRP2 mRNA whereas the myoblast C2.7 cell line shows little expression. We also studied SFRP2 mRNA expression in growing, regenerating and denervated muscles. Embryonic rabbit muscles express SFRP2 mRNA but this rapidly falls off after birth. In adult rabbit muscles SFRP2 mRNA is detected within 1 day of either muscle damage or denervation. Thereafter the SFRP2 mRNA expression profiles are different for fast- and slow-twitch muscle. The function of SFRP2 in muscle is unknown but its putative activity as a Wnt antagonist and its precocious expression after muscle damage suggest a role in satellite cell activation.

Electrical stimulation-induced changes in double-wrapped muscles for dynamic graciloplasty.

HYPOTHESIS: Treatment of fecal incontinence has been greatly improved by electrical stimulation of gracilis muscle transposed around the anal canal. Various configurations of the muscle have been used: single alpha, gamma, epsilon muscle loops, split sling, or double wrap. We report herein experimental data on muscle transformation and damage induced by the latter surgical approach. DESIGN, INTERVENTIONS, AND MAIN OUTCOME MEASURES: This study was conducted on 4 groups of New Zealand white rabbits. Group 1 had unstimulated transposed gracilis muscles. Group 2 had left transposed gracilis muscles stimulated only. Group 3 had both right and left transposed gracilis muscles stimulated. Group 4 were the controls (not operated on). Muscle properties were studied by electrophysiological,immunohistochemical,and biochemical techniques. RESULTS: Transformation from fast-contractile glycolytic muscle fibers into fast-intermediate to slow-contractile oxidative muscle fiber types induced a fatigue resistance of the transposed muscle that has undergone long-term stimulation and muscle alterations characterized by fiber atrophy and fibrosis. CONCLUSIONS: Whatever technique of dynamic graciloplasty is used, muscle degeneration associated with mobilization might result primarily from the surgical dissection, whereby collateral blood supply to the gracilis is interrupted and exacerbated by long-term stimulation.

Anal sphincter reconstruction by dynamic graciloplasty after abdominoperineal resection for cancer.

PURPOSE: Chronic low-frequency electrical stimulation can safely transform fatiguing muscle into fatigue-resistant muscle. This fundamental discovery was used to reconstruct the anal sphincter. Dynamic graciloplasty was found to be effective in the treatment of fecal incontinence. Our study was undertaken to investigate the oncologic, functional, and quality of life results of dynamic graciloplasty anal reconstruction after an abdominoperineal resection for carcinoma. METHODS: Between April 1993 and April 1996, nine patients (4 males) with a median age of 51.2 (range, 29-69) years underwent an abdominoperineal resection for carcinoma (4 had a rectal adenocarcinoma and 5 had an epidermoidal anal tumor) and an anal sphincter reconstruction with electrically stimulated graciloplasty. Oncologic and functional results were evaluated after a mean follow-up of 32 (range, 14-50) months. A quality of life questionnaire was filled out by seven patients. RESULTS: Sphincter reconstruction required the same hospitalization period as abdominoperineal resection. Two patients died from evolutive disease. Three patients were operated on twice, one for immediate colonic necrosis, two for colonic perforation after enema. One of them refused the graciloplasty and had an abdominoperineal resection. Six patients were dysfunctioned. The mean resting pressure was 24 +/- 10 mmHg, and the mean pressure during stimulation was 95 +/- 25 mmHg. Five patients were continent for solids and liquid; four wore less than three pads per day, and one wore more than three. Four patients used enemas twice a week; one patient had spontaneous evacuation. The quality of life questionnaire showed that the mean scores for social interaction, symptoms, and psychological and physical states were 2.1, 2.2, 2.4, and 2.7, respectively. The mean value was 1.5. CONCLUSIONS: Total anorectal reconstruction with dynamic graciloplasty is an oncologically safe procedure. Functional results improve with time, but careful patient selection guarantees a successful functional outcome. Technical progress is necessary to improve the quality of life.

Expression of specific white adipose tissue genes in denervation-induced skeletal muscle fatty degeneration.

Denervation of skeletal muscle results in rapid atrophy with loss of contractile mass and/or progressive degeneration of muscle fibers which are replaced to a greater or lesser degree by connective and fatty tissues. In this study, we show that denervated rabbit muscles are transformed into a white adipose tissue, depending on their fiber types. This tissue does express LPL, G3PDH and particularly the ob gene, a white adipose tissue-specific marker, and does not express the brown adipose tissue molecular marker UCP1 mRNA.

Expression of lactate dehydrogenase, myosin heavy chain and myogenic regulatory factor genes in rabbit embryonic muscle cell cultures.

The expression of myogenic regulatory factors (MRFs), lactate dehydrogenase (LDH) and myosin heavy chains (MyHC), as markers of myogenesis, metabolism and contractility respectively, were investigated during differentiation of rabbit embryonic muscle cells in primary culture. Myf5, MyoD and myogenin mRNAs were abundantly expressed at day 1 of culture. The expression of Myf5 and MyoD mRNA transcripts decreased sharply as myoblasts fused and differentiated into myotubes, whilst myogenin mRNA was maintained throughout the duration of the culture. In contrast, MRF4 mRNA was weakly expressed on day 1 of culture, its expression increased slightly as myoblasts fused and reached a maximum level in 7-day-old cultures containing striated myofibres. The specific activity of LDH increased linearly during myoblast proliferation and fusion. In 7-day-old cultures, LDH-M mRNA (dominant in glycolytic muscles) and LDH-H mRNA (predominant in perinatal and oxidative muscles) represented 38% and 62% of total LDH mRNA respectively. At this stage, immunocytochemical staining with perinatal and adult-type MyHC antibodies showed that embryonic and perinatal MyHC isoforms were expressed in all myotubes, while few of them were stained by type I MyHC antibody. However, none of them expressed adult type II MyHC. The latter results were further supported by RT-PCR analysis of adult-type MyHC mRNA which showed that only the type I MyHC mRNA transcript was expressed. These data were in agreement with those reported in vivo on perinatal rabbit muscles. They differed from those obtained on cultured satellite cells isolated from adult rabbit fast-twitch or slow-twitch muscles which did not express embryonic MyHC, and instead expressed fast- or slow-type MyHC according to their muscle origin. Taken together, these results further suggest that myogenic mononucleated cells express different properties in vitro according to their developmental origin as well as properties related to those of the muscles from which they were isolated.

Differential expression of myosin heavy chain mRNA and protein isoforms in four functionally diverse rabbit skeletal muscles during pre- and postnatal development.

Myosin heavy chains (hcs) are the major determinant in the speed of contraction of skeletal muscle, and various isoforms are differentially expressed depending on the functional activity of the muscle. Using the rapid amplification of cDNA ends (3' RACE) method, we have characterised the 3' end of the embryonic, perinatal, type 1, 2a, 2x, and 2b myosin hc genes in rabbit skeletal muscle and used them as probes in RNase protection assays to quantitatively monitor their expression in different type of skeletal muscles just before and after birth. SDS PAGE was used to study the changes in the expression level of their respective protein and to determine the relative abundance of each myosin hc isoform in the muscles studied. The results show that for each anatomical muscle, the developmental changes in myosin hc gene expression at the mRNA level correlate strongly to those observed at the protein level. By studying their developmental expression in four functionally diverse skeletal muscles (semimembranosus proprius, diaphragm, tibialis anterior, and semimembranosus accessorius), it was shown that all muscles express the embryonic, perinatal, and type 1 isoform during prenatal development up to the E27 stage. In the diaphragm, low levels of the type 2a and 2x transcripts, which are adult fast isoforms, were also detected at the E27 stage. During the first week of postnatal growth the myosin hc transition leading to the expression of the adult isoforms is complex, and as many as five different myosin heavy chains are concurrently expressed in some muscles at around birth. As the animal matures, individual muscles become adapted to perform highly specialised functions, and this is reflected in the myosin hc composition within these muscles. Accordingly, the expression of the type 1 isoform, and the sequence of appearance and the expression levels of the type 2 isoforms, were exclusively dependent on the muscle type and largely reflect the functional activity of each muscle during the postnatal growth period.

Transformation of slow- or fast-twitch rabbit muscles after cross-reinnervation or low frequency stimulation does not alter the in vitro properties of their satellite cells.

We previously showed that satellite cells isolated from rabbit fast-twitch and slow-twitch muscles presented different behaviours in culture; cells from slow muscle differentiated more quickly and fused into more numerous myotubes than those from fast muscle. Moreover, only slow-muscle derived satellite cells expressed in vitro the slow type I myosin heavy chain isoform (MyHC). We wanted to investigate whether the properties of satellite cells originating from different muscles were under the influence of the adult fibre type on which they were located. For this purpose, we transformed the properties of the adult rabbit fast-twitch semimembranosus accessorius (SMa; approximately 100% type II fibres) and the slow-twitch semimembranosus proprius (SMp; 100% type I fibre) muscles by (1) cross-reinnervating the SMp with the main branch of the fast SMa nerve; or (2) electrical stimulation at 10 Hz of the SMa muscle. We studied their satellite cells in vitro. Five-month cross-reinnervation of the SMp induced a large shift of its MyHC type characteristics towards those of a fast muscle, and three-month electrical stimulation at low frequency transformed the fast-twitch SMa into a slow-twitch muscle, as shown by SDS-PAGE of MyHC. In spite of the transformation of their muscle characteristics, satellite cells in culture kept their original properties. Indeed, as shown by MyoD and myogenin gene expression as markers of fusion, satellite cells isolated from cross-reinnervated and from control SMp began to fuse by eight days of culture, and expressed MyoD and myogenin at that stage. Later they differentiated into numerous myotubes. Satellite cells isolated from electrically stimulated and control SMa presented a similar behaviour in culture: they did not express MyoD and myogenin at eight days, and fused by ten days into only a few myotubes. Moreover, MyHC gene expression showed that, in contrast with slow-muscle derived satellite cells, the type I MyHC gene was not expressed by satellite cells isolated from the stimulated SMa in spite of its homogeneous type I fibre composition. Taken together, these data support the idea that once constituted, muscle fibre types per se do not influence the properties of their associated satellite cells.

Rabbit slow and fast skeletal muscle-derived satellite myoblast phenotypes do not involve constitutive differences in the components of the insulin-like growth factor system.

The insulin-like growth factor (IGF) system is actively involved in the control of proliferation and differentiation of several myogenic cell lines, and phenotypic differences between myoblasts are associated with modifications of the equilibrium of the components of the IGF system. To determine whether this observation is a physiologic feature that also concerns the phenotypes of ex vivo adult satellite myoblasts in primary cell culture, we investigated the IGF system in rabbit slow-twitch muscle-derived satellite myoblasts (SSM), which differ phenotypically from fast-twitch muscle-derived satellite myoblasts (FSM) by their proliferation and differentiation kinetics in vitro. The expression of IGF-I and IGF-II were similar in SSM and FSM as well as their concentrations measured in cell-conditioned media. Ligand blotting of conditioned media samples indicated the presence of five IGF binding protein (IGFBP) species of Mr 37-40, 32, 30-31, 28, and 24 kDa. The 30-31 kDa doublet was visible in SSM-conditioned medium only and associated with the presence of a 22-kDa protein, which may represent a proteolytic fragment. In contrast, the 32-kDa band was observed in FSM conditioned medium only. The other IGFBP moieties were present in both SSM- and FSM-conditioned media. Cross-linking experiments revealed the presence of the M6P/IGF-II receptor on both SSM and FSM membranes. We also observed an IGF-I receptor form bearing unusual high affinity for IGF-II: the binding of [125I]IGF-I on this receptor was preferentially displaced by IGF-I but that of [125I]IGF-II was mostly inhibited by IGF-II, suggesting that the two tracers did not bind on the same epitopes. [125I]IGF-II binding to this receptor was greater on SSM than on FSM membranes. Autophosphorylation of WGA-purified receptors revealed an approximately 400-kDa band after SDS-PAGE under nonreducing conditions, which corresponded to the alpha 2 beta 2 form of the IGF-I receptor, and two beta subunit moieties of Mr 101 and 105 kDa under reducing conditions in both SSM and FSM extracts. Phosphorylation of the 105-kDa moiety was more intensively increased than that of the 101-kDa protein after growth factor stimulation. Basal phosphorylation state of the two beta subunits was similarly stimulated by IGF-I and IGF-II and less by insulin. Since both insulin and IGF-I receptors were expressed in FSM and SSM, one of the two beta subunits may actually correspond to that of the insulin receptor. We conclude that the IGF system is not considerably affected by the phenotypes of SSM and FSM. The differences observed, which mostly concern IGFBP species, more likely appear as regulatory adaptations than as phenotypic changes targeting the components of the IGF system.

Expression of myosin isoforms in denervated, cross-reinnervated, and electrically stimulated rabbit muscles.

The expression of myosin heavy (MyHC) and light (MyLC) chain isoforms was analyzed after denervation and cross-reinnervation by a fast nerve of the slow-twitch Semimembranosus proprius (SMp) muscle, and after denervation and electrical stimulation at low frequency of the fast-twitch Semimembranous accessorius (SMa) muscle of the rabbit. The control SMp (100% type I fibers) expressed 100% type I MyHC and 100% slow-type (1S', 1S and 2S) MyLC isoforms. Five month denervation did not alter significantly the MyHC expression of the muscle, but induced the expression of a new type 1 MyLC corresponding most probably to an embryonic MyLC. Five-month cross-reinnervation of the SMp by the fast SMa nerve induced a large change of its fiber type properties. As shown by immunocytochemistry, almost all fibers were stained by fast myosin antibody, but a high proportion of them co-expressed slow myosin. This result was in agreement with biochemical data showing that fast MyHC and MyLC isoforms became predominant. The control SMa (nearly 100% type II fibers) expressed almost 100% type II MyHC (70% type IIb and 22% IIx/d) and 100% fast-type (1F, 2F and 3F) MyLC isoforms. Five month denervation of the SMa induced a shift in its MyHC, with 98% type IIx/d and 2% type IIb isoforms, and no change in the proportions of its MyLC. Three month electrical stimulation at 10 Hz of the SMa transformed its fiber type composition. All fibers reacted with the slow myosin antibody and a minor proportion of them were stained by the fast myosin antibody. These observations were in agreement with the biochemical analysis showing a large predominance of the slow-type MyHC and MyLC isoforms. Taken together, these results obtained from rabbit muscles which are normally homogeneous in either fast-twitch or slow-twitch fiber types, further support the idea that the different myosin isoforms, particularly the MyHC, are differentially regulated by motor innervation. Type I MyHC is maintained in denervated SMp muscle, but is not expressed in denervated SMa. Type IIb isoform is the most sensitive to neural influence, as it disappears rapidly in denervated and electrically stimulated fast-twitch SMa muscle, and is barely expressed in cross-reinnervated slow-twitch SMp muscle. In contrast, type IIa and type IIx/d are less dependent upon motor innervation. In addition to the previous studies of d'Albis et al. analysis of these results leads us to conclude that, in the rabbit, sensitivity to motor innervation increases from the glycolytic to the oxydative types of fibers, in the order IIB > IIX/IID > IIA > I.

Expression of myosin heavy chain and of myogenic regulatory factor genes in fast or slow rabbit muscle satellite cell cultures.

We investigated the myogenic properties of rabbit fast or slow muscle satellite cells during their differentiation in culture, with a particular attention to the expression of myosin heavy chain and myogenic regulatory factor genes. Satellite cells were isolated from Semimembranosus proprius (slow-twitch muscle; 100% type I fibres) and Semimembranosus accessorius (fast-twitch muscle; almost 100% type II fibres) muscles of 3-month-old rabbits. Satellite cells in culture possess different behaviours according to their origin. Cells isolated from slow muscle proliferate faster, fuse earlier into more numerous myotubes and mature more rapidly into striated contractile fibres than do cells isolated from fast muscle. This pattern of proliferation and differentiation is also seen in the expression of myogenic regulatory factor genes. Myf5 is detected in both fast or slow 6-day-old cell cultures, when satellite cells are in the exponential stage of proliferation. MyoD and myogenin are subsequently detected in slow satellite cell cultures, but their expression in fast cell cultures is delayed by 2 and 4 days respectively. MRF4 is detected in both types of cultures when they contain striated and contractile myofibres. Muscle-specific myosin heavy chains are expressed earlier in slow satellite cell cultures. No adult myosin heavy chain isoforms are detected in fast cell cultures for 13 days, whereas cultures from slow cells express neonatal, adult slow and adult fast myosin heavy chain isoforms at that time. In both fast and slow satellite cell cultures containing striated contractile fibres, neonatal and adult myosin heavy chain isoforms are coexpressed. However, cultures made from satellite cells derived from slow muscles express the slow myosin heavy chain isoform, in addition to the neonatal and the fast isoforms. These results are further supported by the expression of the mRNA encoding the adult myosin heavy chain isoforms. These data provide further evidence for the existence of satellite cell diversity between two rabbit muscles of different fibre-type composition, and also suggest the existence of differently preprogrammed satellite cells.

Changes in fibre type, metabolic character and acetylcholinesterase forms in rabbit skeletal muscle following stretch and electrical stimulation.

Several trials have been made to reconstruct the neoanal sphincter using continuous electrical stimulation of the rotative gracilis muscle flap, with a view to improving Pickrell's technique. To detect muscle alterations with this technique, the gracilis of the rabbit was transposed on the external side of the thigh, either to be made into a rotative muscle flap, or to be stimulated (10 Hz). Our data show that the simple transposition of the muscle did not significantly affect its fibre type composition. On the contrary, slow-twitch fibres were predominant in the transposed-stimulated gracilis muscle. The control gracilis muscle presented a glycolytic metabolism, it developed an intermediate metabolism after transposition with a predominant oxidative metabolism after stimulation. The AChE molecular form pattern of the control gracilis was characteristic of fast-twitch rabbit muscle. Surprisingly, the AChE polymorphism of transposed and transposed-stimulated gracilis muscles did not differ. They were both similar to slow-twitch rabbit muscles. Taken together, these data could explain the uncertain clinical results after Pickrell's procedure and should foster the development of electrically stimulated neoanal sphincter.

Expression of acetylcholinesterase gene during in vitro differentiation of rabbit muscle satellite cells.

We investigated the myogenic properties and the expression of acetylcholinesterase (AChE) in culture of satellite cells (SCs) isolated from slow and fast rabbit muscles. Slow SCs form myotubes more rapidly (day 9 vs day 11) than fast SCs, and differentiate further into striated and contractile fibers. AChE activity and mRNA expression are higher in SCs cultured from slow than from fast muscles, as also observed in the muscles themselves. However, the two types of SC cultures do not show obvious difference in their patterns of AChE molecular forms. Taken together, these preliminary data support the view that there might be more than one SC population in skeletal muscles.

Expression of acetylcholinesterase molecular forms during in vitro differentiation of rabbit embryonic muscle cells.

We investigated the myogenic properties of rabbit myoblasts in culture, and examined particularly the expression of acetylcholinesterase (AChE). In the presence of horse serum, myoblasts proliferate quickly and begin to fuse by day 3 of culture. Differentiated myotubes presenting some spontaneous contractions are clearly visible from days 6 to 9. The cultures degenerate from day 10 onwards. The specific activity of AChE is low during the proliferation phase of myogenic cells, increases sharply as myotubes differentiated, then decreases as cultures degenerate. In 7-day-old cultures, globular forms are largely predominant and asymmetric forms, detected as A12, represent only 1% of the total activity.

Neural influence on the expression of acetylcholinesterase molecular forms in fast and slow rabbit skeletal muscles.

With the aim of investigating the roles of motor innervation and activity on muscle characteristics, we studied the molecular forms of acetylcholinesterase (AChE) in fast-twitch (semimembranosus accessorius; SMa) and slow-twitch (semimembranosus proprius; SMp) muscles of the rabbit. We have shown that SMa and SMp express different patterns and tissue distribution of AChE forms and that the effect of long denervation varies with age. Three principal findings concerning expression of AChE molecular forms emerge from these studies. (1) The activity of AChE and the pattern of its molecular forms are particularly altered in adult denervated SMa and SMp muscles. AChE activity increases by 10-fold in both muscles, but asymmetric forms disappear in SMa and increase by 20-fold in SMp muscles. A similar alteration of AChE is found after tenotomy of these muscles, showing that the effect of denervation may be partly due to suppression of muscle activity. (2) The different changes occurring in the composition of AChE molecular forms in adult denervated SMa and SMp muscles are consistent with fluorescent staining with anti-AChE monoclonal antibodies and with DBA or VVA lectins, which bind to AChE asymmetric, collagen-tailed forms. These lectins poorly stain denervated SMa muscle surfaces but intensely stain neuromuscular junctions and extrasynaptic areas in denervated SMp muscle. (3) In contrast with the adult, denervation of 1-day-old muscles does not markedly modify the total amount of AChE or the proportions of its molecular forms, despite dramatic effects on muscle structure. These results are supported by studies of labeling with fluorescent DBA: the lectin only slightly stains the muscle fiber surface of denervated 15-day-old SMp muscle. Taken together, these data show that denervated muscles escape physiological regulation, producing increased levels of AChE with highly variable cellular distribution and patterns of molecular forms, depending on the age of operation and on the type of muscle.

Effects of thyroid state alterations in ovo on the plasma levels of thyroid hormones and on the populations of fibers in the plantaris muscle of male and female chickens.

Propylthiouracil (PTU), thyroxine (T4) or thyreoliberin (TRH) were injected in ovo to modify the thyroid state of chicken embryos. Significant sexual differences were observed in the effects of these treatments on the plasma concentrations of thyroid hormones and on plantaris muscle characteristics (DNA, RNA, populations of muscle fibers) in 3- and 35-day old male and female chickens. The T4 plasma concentration is lower in control males; it is decreased in PTU treated females and in the T4 treated females at 35 days. The T3 plasma concentration is lowered at 3 days in all treated chickens and also at 35 days in the TRH treated animals. The slow (STnO) and the fast (FTOG) fibers of the plantaris are always more numerous in males. In controls, the number of FTOG fibers remains steady between 3 and 35 days; at the same time, the number of STnO fibers rises in males only. Both PTU and T4 treatments increase the number of the FTOG and the STnO fibers respectively before and after the 3rd day. TRH treatment increases the number of STnO fibers at 3 and 35 days in males, but reduces it at 3 days in females. Thus changes in the number of FTOG fibers can be induced during in ovo myogenesis, whereas the number of STnO fibers may increase after hatching.

[Properties of skeletal muscle fibers. II. Hormonal influences]. / Propriétés des fibres musculaires squelettiques. II. Influences hormonales.

The skeletal muscle contains fibers with various contractile and metabolic properties. These populations of muscle fibers differ in their sensitivity and their response to circulating hormones which also affect the muscular differentiation (multiplication and fusion of myoblasts into myotubes). This review deals with the regulations of energy metabolism and of protein synthesis in muscles by several hormones acting either directly, or in association with other hormones, or by induction of growth factors. In most cases, hormonal effects seem to depend on the type and level of activity of the constitutive muscle fibers. The muscle fiber types involved in the anabolic properties of estrogens have not yet been clearly described. In the case of growth hormone and insulin, the slow fiber type is mainly affected; their effects are partially mediated through an increased secretion of somatomedins (IGFs) or by interaction on IGF receptors. The other reported hormones or factors induce a shift toward a more potent fast contracting activity, ultimately increasing the percentage of fast glycolytic fibers. Androgens, catecholamines and beta-agonists are anabolic and produce an enlargement of these fibers, whereas thyroid hormones or glucocorticoids in excess increase their catabolism.

A synapse-specific carbohydrate at the neuromuscular junction: association with both acetylcholinesterase and a glycolipid.

With the aim of investigating the roles of carbohydrates in synapse formation, we have characterized a synapse-specific saccharide at the vertebrate neuromuscular junction. Two lectins of similar specificity (Dolichos biflorus agglutinin, DBA, and Vicia villosa-B4 agglutinin, VVA-B4) stain synaptic but not extrasynaptic regions of the rat muscle fiber surface and thus define a synapse-specific carbohydrate. Using these and other probes, we show that the carbohydrate moiety concentrated at the neuromuscular junction resembles N-acetylgalactosamine (GalNAc) linked in the beta-anomeric form to the termini of oligosaccharides. VVA-B4 also selectively stains neuromuscular junctions in human, mouse, rabbit, guinea pig, chick, frog, axolotl, snake, fish, and lamprey muscles, a phylogenetic conservatism that suggests a synapse-related role for GalNAc beta-terminal saccharides. AChE from muscle binds to DBA- and VVA-B4-agarose, and is thereby identified as a glycoconjugate bearing the synapse-specific carbohydrate. Assay of AChE isoforms reveals that asymmetric, collagen-tailed forms, known to be highly concentrated at the rat neuromuscular junction, bind DBA and VVA-B4, while globular forms, which are more widely distributed, do not. A second class of GalNAc-bearing glycoconjugates is demonstrable immunohistochemically with monoclonal antibodies to stage-specific embryonic antigen (SSEA)-3 (Shevinsky et al., 1982) and GM2 (Natoli et al., 1986), which recognize GalNAc-bearing glycolipids. These antibodies selectively stain neuromuscular junctions, where they recognize glycolipid-like molecules that bind VVA-B4 but are distinguishable from AChE. The association of a synapse-specific carbohydrate with at least 2 different synapse-specific molecules raises the possibility that the former plays a role in determining a property that the latter share, such as concentration at the synapse.