Ontogeny of the leg muscle tissue in the crooked neck dwarf mutant (cn/cn) chick embryo

The crooked neck dwarfism (cn/cn) is characterized, among other anomalies, by a muscular hypoplasia, particularly conspicuous in the tibiotarsal segment. Histological observations were performed between day 6 and day 12.5 of incubation. They show, in the tibiotarsal segment, that the hereditary muscular hypoplasia is not caused by a defect of the normal muscular splitting pattern. Indeed, in the mutant, the splitting of muscle masses proceeds normally up to the last partition (day 7-7.5), but is followed by the secondary fusion of individuated muscles into an unpatterned muscle tissue. Thus the mutant phenotype is the result of an inability of the muscle pattern to become stabilized into definitive structures.     

The crooked neck dwarf muscular dysgenesis in fowl is due to a selective alteration of the somitic myogenic cell line

Summary Muscular dysgenesis in trunk and limb regions of the crooked neck dwarf (cn/cn) fowl is characterized by a complete disorganization of the muscles, starting at 7.5 days of incubation and resulting, at the end of the incubation period, in a profound muscular atrophy. It has previously been attributed to progressively extending defects of the myotubes. In this paper, embryonic cn/cn head and neck muscles were subjected to histological and ultrastructural analysis. The mononucleated myoblasts of the skeletal muscles are not diseased. Pathology is only expressed in the multinucleated cells, mainly by impaired sarcomerogenesis and distension of the sarcoplasmic reticulum. In the non-skeletal (cardiac or smooth) muscles, the connective tissue scaffolding and the ultrastructural features are similar to those of normal muscles at the same age. The present report confirms that the cn defect is confined to the skeletal muscle cells. All of them belong to the same lineage, which is contained in the somitic mesoderm, whether the latter becomes segmented or not during embryogenesis.     

A loss-of-function mutation in natriuretic peptide receptor 2 (Npr2) gene is responsible for disproportionate dwarfism in cn/cn mouse

The achondroplastic mouse is a spontaneous mutant characterized by disproportionate dwarfism with short limbs and tail due to disturbed chondrogenesis during endochondral ossification. These abnormal phenotypes are controlled by an autosomal recessive gene (cn). In this study, linkage analysis using 115 affected mice of F2 progeny mapped the cn locus on an approximately 0.8-cM region of chromosome 4, and natriuretic peptide receptor 2 (Npr2) gene was identified as the most potent candidate for the cn mutant in this region. This gene encodes a receptor for C-type natriuretic peptide (CNP) that positively regulates longitudinal bone growth by producing cGMP in response to CNP binding to the extracellular domain. Sequence analyses of the Npr2 gene in cn/cn mice revealed a T to G transversion leading to the amino acid substitution of highly conserved Leu with Arg in the guanylyl cyclase domain. In cultured chondrocytes of cn/cn mice, stimulus with CNP did not significantly increase intracellular cGMP concentration, whereas it increased in +/+ mice. Transfection of the mutant Npr2 gene into COS-7 cells also showed similar results, indicating that the missense mutation of the Npr2 gene in cn/cn mice resulted in disruption of the guanylyl cyclase activity of the receptor. We therefore concluded that the dwarf phenotype of cn/cn mouse is caused by a loss-of-function mutation of the Npr2 gene, and cn/cn mouse will be a useful model to further study the molecular mechanism regulating endochondral ossification by CNP/natriuretic peptide receptor B signal.     

Clonal analysis of vertebrate myogenesis. I. Early developmental events in the chick limb

Early developmental events occurring in the prospective muscle tissue region of chick embryo leg buds have been subjected to an in vitro clonal analysis. Colony-forming cells are present at stage 20 (72 hr incubation), but none of the colonies exhibit morphological signs of muscle differentiation. After an additional 8 hr of incubation (stage 21), approximately 10% of the colony-forming cells have acquired the capacity to form multinucleated cells in vitro, and the percentage of clonable myoblasts increases to a level of approximately 60% during the next 3 days of incubation. Clonal analysis of myoblast populations within regions of the developing limb have indicated that, between stages 21 and 27, the dorsal and ventral segments of the myogenic region contain appreciably more clonable muscle cells than the anterior and posterior segments. In addition, during stages 21 and 22 there is a 3-fold difference in muscle-colony-forming cells between the proximal and distal halves of the dorsal-ventral segments, as well as between the proximal and distal halves of the anterior-posterior segments. Thus at least two temporal and regional gradients—proximal to distal and medial to lateral—of clonable myoblast content can be delineated within the developing chick limb. In addition to changes in the proportions of muscle-colony-forming cells, the extent of multinuclearity within individual muscle colonies increases with the developmental age of the embryo from which the clonable myoblasts are derived. The progressive changes in the relative proportions of muscle-colony-forming cells and in clonal morphology are discussed in terms of their possible cell lineage implications.     

Changes in protein and glycoprotein biosynthesis during differentiation of satellite cells in vitro

Satellite cells were isolated from leg skeletal muscles of adult mice and grown in culture. During the first few days in culture, satellite cells actively proliferated and starting on day 4 began to fuse into multinucleated myotubes. At various time points during the culture period, the biosynthesis of total cellular proteins and glycoproteins was analysed by pulse-labelling with radioactive leucine or sugars followed by electrophoretic analysis on two-dimensional gels. Our findings are: (1) Replicating mononucleated satellite cells on day 1 of culture did not synthesize detectable amounts of α and β tropomyosins, α-actin, and myosin light chains 1 and 2; (2) the synthesis of these polypeptides was readily detectable in multinucleated myotubes that formed by day 5–6 of culture; (3) other qualitative and quantitative differences in as yet unidentified proteins were observed in replicating cells as compared with multinucleated myotubes as well as to muscle fibroblasts; and (4) at least two distinct glucosamine-containing acidic glycoproteins of about 70 000 D and pI 5 were synthesized by myotubes, but not by replicating satellite cells.These data demonstrate that the biosynthetic programs for proteins and glycoproteins of cultured replicating satellite cells can be distinguished from those of multinucleated myotubes and from those of muscle fibroblasts. These data are interpreted to indicate that during muscle histogenesis in vivo, satellite cells become arrested prior to the expression of terminally differentiated traits.     

Signals from damaged but not undamaged skeletal muscle induce myogenic differentiation of rat bone-marrow-derived mesenchymal stem cells

The regenerative capacity of skeletal muscle has been usually attributed to resident satellite cells, which, upon activation by local or distant stimuli, initiate a myogenic differentiation program. Although recent studies have revealed that bone-marrow-derived progenitor cells may also participate in regenerative myogenesis, the signals and mechanisms involved in this process have not been elucidated. This study was designed to investigate whether signals from injured rat skeletal muscle were competent to induce a program of myogenic differentiation in expanded cultures of rat bone-marrow-derived mesenchymal stem cells (MSC). We observed that the incubation of MSC with a conditioned medium prepared from chemically damaged but not undamaged muscle resulted in a time-dependent change from fibroblast-like into elongated multinucleated cells, a transient increase in the number of MyoD positive cells, and the subsequent onset of myogenin, alpha-actinin, and myosin heavy chain expression. These results show that damaged rat skeletal muscle is endowed with the capacity to induce myogenic differentiation of bone-marrow-derived mesenchymal progenitors.     

Kinetics and characteristics of murine macrophage-lymphocyte interaction in presence of PHA: appearance of multinucleated giant cells in vitro

The appearance of cellular associations between macrophages and lymphocytes--which we have denominated macrophage-lymphocyte rosettes--and their kinetic formation in the presence of phytohemagglutinin (PHA) have been studied in B10 A (4R) mice. The greatest number of macrophage-lymphocyte rosettes was found from 6 to 12 hours after incubation with PHA. During this time, 42.38 +/- 10.70 of the total number of macrophages had lymphocytes attached to their membranes. This percentage decreased to 17.33 +/- 2.07% after 24 hours. The activation of macrophages after PHA treatment was tested by the phagocytic capacity of these cells. This activity increased significantly 24 hours after incubation. In our assay, an increase in the appearance of multinucleated giant cells when compared to controls was also observed. When the macrophages were lymphocyte depleted, the appearance of the multinucleated giant cells was significantly lower. The kinetics for these formations are also discussed.     

Incidence of multinucleated and polyploid aortic smooth muscle cells cultured from different age groups of spontaneously hypertensive rats.

Cell size and incidence of multinucleated, polyploid cells in cultured aortic smooth muscle cells from different age groups of spontaneously hypertensive rats (SHR) and normotensive Wistar-Kyoto rats (WKY) were compared. Smooth muscle cells from SHR were generally larger than those from WKY, and the percentage of multinucleated smooth muscle cells was always higher in SHR than WKY in the three age groups of rats studied (3-4, 10-12, and 28-30 weeks). In smooth muscle cells from the 3- to 4-week group, there was a positive correlation between cell diameter and the percentage of multinucleated smooth muscle cells. Microdensitometric measurements also showed that the incidence of polyploid smooth muscle cells was always higher in SHR than WKY in the three age groups. There was a positive correlation between DNA density and nuclear area measurements in all the age groups of SHR and WKY. We conclude that cultured aortic smooth muscle cells from different age groups of SHR and WKY contained heterogeneous populations of cells and that, under our culture conditions, the polyploidy of the smooth muscle cells found in vivo was maintained in the SHR and WKY.     

Endogenous peroxidase in mast cells localized with a semipermeable membrane technique

Synopsis Hamster mast cells have been found to give strong peroxidatic reactions at pH 5, 7.5 and 10 when sections of skeletal muscle are incubated for 2.5 h in the dark at room temperature on semipermeable membranes covering a gelled incubation medium consisting of 0.01% hydrogen peroxide, 5.5 mM diaminobenzidine and 1.36% agar dissolved in Universal buffer. The techniques is very efficient: with it, all mast cells react in marked contrast to the negative reaction they usually give with conventional techniques.The peroxidatic reactions are abolished if tissues are perfused beforehand with either aminotriazole or KCN but not if these inhibitors are incorporated in the gelled incubation medium. This and other evidence suggests that the mast cell reactions are not due to either catalase or haemoglobin adsorbed onto mast cell granules from lysed red blood cells.Skeletal muscle fibres do not exhibit any visible-peroxidase activity with the membrane technique.     

Author index

Satellite cells were isolated from leg skeletal muscles of adult mice and grown in culture. During the first few days in culture, satellite cells actively proliferated and starting on day 4 began to fuse into multinucleated myotubes. At various time points during the culture period, the biosynthesis of total cellular proteins and glycoproteins was analysed by pulse-labelling with radioactive leucine or sugars followed by electrophoretic analysis on two-dimensional gels. Our findings are: (1) Replicating mononucleated satellite cells on day 1 of culture did not synthesize detectable amounts of α and β tropomyosins, α-actin, and myosin light chains 1 and 2; (2) the synthesis of these polypeptides was readily detectable in multinucleated myotubes that formed by day 5–6 of culture; (3) other qualitative and quantitative differences in as yet unidentified proteins were observed in replicating cells as compared with multinucleated myotubes as well as to muscle fibroblasts; and (4) at least two distinct glucosamine-containing acidic glycoproteins of about 70 000 D and pI 5 were synthesized by myotubes, but not by replicating satellite cells.These data demonstrate that the biosynthetic programs for proteins and glycoproteins of cultured replicating satellite cells can be distinguished from those of multinucleated myotubes and from those of muscle fibroblasts. These data are interpreted to indicate that during muscle histogenesis in vivo, satellite cells become arrested prior to the expression of terminally differentiated traits.     

Vitellogenin synthesis by the fat body of the mosquito Aedes aegypti: evidence of transcriptional control

The acetylcholinesterase (AChE) activity of cultures from 11-day-old chick embryo muscle cells was studied for up to 4 weeks in vitro. AChE activity was found in mononucleated cells and multinucleated myotubes. The activity increased greatly after fusion. Maximum AChE levels were reached after 7–10 days of incubation and tended to decline thereafter. Multiple forms of AChE found in embryo muscle in situ were present in cultures before and after fusion. Selective inhibitors and substrates were used to show that AChE was released by the cells into their medium. Within a 2-day period the AChE that accumulated in the medium averaged over 6 times that remaining in the cells. Release of AChE from the cells was inhibited by cycloheximide, and AChE levels in cells and medium were much reduced when differentiation was inhibited by bromodeoxyuridine. Little AChE was present in subcultures of fibroblasts from muscle cultures. Acetyl-β-methylcholine and, to a lesser degree, choline itself, prevented the decrease in AChE levels of 2- to 3-week-old muscle cultures.     

Spatial analysis of limb bud myogenesis: A proximodistal gradient of muscle colony-forming cells in chick embryo leg buds

The regional distribution of myogenic cells in developing chick leg buds has been investigated using an in vitro clonal assay. Leg buds were embedded in gelatin and sectioned at intervals of 100–300 μm utilizing a vibratome, and cells dissected from prospective myogenic areas were analyzed for their ability to form colonies containing multinucleated myotubes. The results show that muscle colony-forming (MCF) cells from stage 23 ( to 4-day incubation) are exclusively of the early morphological type, and are found in the proximal two-thirds of the bud. Late-type MCF cells are first obtained from the proximal sections of stage 24–25 (4- to day) buds; in succeeding stages (26–29), late MCF cells supercede the early MCF cell type in the proximal regions, and extend into progressively more distal sections in a graded fashion. Results from sequential sections suggest that early and late MCF cells are located within the same muscle groups. The proportion of late MCF cells continues to increase throughout this period, until by stage 31 (7 days) only the most distal myogenic regions (the toe muscle regions) have an appreciable proportion of early MCF cells. Clonal plating efficiencies increase throughout the period of analysis, and by stage 31 precisely dissected myogenic regions yield plating efficiencies as high as 36% with greater than 95% of these colonies differentiating as muscle.     

Nuclear anarchy: asynchronous mitosis in multinucleated fungal hyphae

Multinucleated cells are found in diverse contexts and include filamentous fungi, developing insect embryos, skeletal muscle and metastasizing tumor cells. Some multinucleated cells such as those in muscles arise from cell fusion events, but many are formed through specialized cell cycles in which nuclear and cell division are uncoupled. Recent work in the fungus Ashbya gossypii illustrates how unique spatial and temporal regulation of conserved cell cycle regulators directs mitosis in multinucleated cells.     

Immunofluorescent localization of extracellular matrix components during muscle morphogenesis. II. In chick embryos with hereditary muscular dysgenesis (cn/cn)

The immunofluorescent distribution of types I and III collagen, fibronectin, and laminin during muscle morphogenesis of the crooked neck dwarf mutant chick embryo differs from that of the normal chick. The drastic difference is related to the inability of the mutant embryo to maintain a harmonious muscle pattern. The first sign of the defect is the disaggregation of type I collagen fibers of the tendons and the disorganization of the intermuscular spaces. The organization of the connective tissue never proceeds beyond the appearance of an epimysial envelope, rich in types I and III collagen, which becomes disorganized shortly after. No perimysial envelopes displaying types I and III collagen fibers and fibronectin, nor endomysial sheaths develop. Only large spaces filled with types I and III collagen fibers subdivide groups of muscle cells irregularly. On the whole, type III collagen is less abundant than type I collagen. Fibronectin disappears from the periphery of the muscle cell. Laminin is more thickly deposited in the basal lamina around irregularly sized muscle cells than around the normal muscle cell. The results are discussed in terms of morphogenetic interactions between connective tissue cells and muscle cells, and in terms of fibrosis, which characterizes some muscle diseases.     

cn.MOPS: mixture of Poissons for discovering copy number variations in next-generation sequencing data with a low false discovery rate

Quantitative analyses of next-generation sequencing (NGS) data, such as the detection of copy number variations (CNVs), remain challenging. Current methods detect CNVs as changes in the depth of coverage along chromosomes. Technological or genomic variations in the depth of coverage thus lead to a high false discovery rate (FDR), even upon correction for GC content. In the context of association studies between CNVs and disease, a high FDR means many false CNVs, thereby decreasing the discovery power of the study after correction for multiple testing. We propose 'Copy Number estimation by a Mixture Of PoissonS' (cn.MOPS), a data processing pipeline for CNV detection in NGS data. In contrast to previous approaches, cn.MOPS incorporates modeling of depths of coverage across samples at each genomic position. Therefore, cn.MOPS is not affected by read count variations along chromosomes. Using a Bayesian approach, cn.MOPS decomposes variations in the depth of coverage across samples into integer copy numbers and noise by means of its mixture components and Poisson distributions, respectively. The noise estimate allows for reducing the FDR by filtering out detections having high noise that are likely to be false detections. We compared cn.MOPS with the five most popular methods for CNV detection in NGS data using four benchmark datasets: (i) simulated data, (ii) NGS data from a male HapMap individual with implanted CNVs from the X chromosome, (iii) data from HapMap individuals with known CNVs, (iv) high coverage data from the 1000 Genomes Project. cn.MOPS outperformed its five competitors in terms of precision (1-FDR) and recall for both gains and losses in all benchmark data sets. The software cn.MOPS is publicly available as an R package at http://www.bioinf.jku.at/software/cnmops/ and at Bioconductor.     

Regeneration of the arterial wall in microporous,compliant, biodegradable vascular grafts after implantation into the rat abdominal aorta

Summary The ultrastructure of a new type of vascular graft, prepared from a mixture of polyurethane (95 weight %) and poly-L-lactic acid (5 weight %), was examined six weeks after implantation into the abdominal aorta of rats. These microporous, compliant, biodegradable, vascular grafts function as temporary scaffolds for the regeneration of the arterial wall.Smooth muscle cells, covering the grafts, regenerated a neo-media underneath an almost completely regenerated endothelial layer (neo-intima). These smooth muscle cells varied in morphology from normal smooth muscle cells to myofibroblasts. They were surrounded by elastic laminae and collagen fibers.Macrophages, epithelioid cells, multinucleated giant cells, fibroblasts and capillaries were present in the disintegrating graft lattices. The epithelioid cells and multinucleated giant cells engulfed polymer particles of the disintegrating grafts.The regeneration of the endothelial and smooth muscle cells is similar to the natural response of arterial tissue upon injury. The presence of macrophages, epithelioid cells, multinucleated giant cells, fibroblasts and capillaries in the graft lattices resembles the natural response of tissue against foreign body implants. Both of these responses result in the formation of a neo-artery that possesses sufficient strength, compliance and thromboresistance to function as a small caliber arterial substitute.Supported by Grant nr. 82.042 from the Dutch Heart Foundation     

Locus Adh and adaptation of cn and vg mutants in the experimental populations of Drosophila melanogaster Meig

Complex study of adaptation and allozyme belonging of alcoholdehydrogenase (ADH) in cn and vg mutants has been carried out in the initial pure lines, in their panmixia populations and in condition of substitution of the mutant genotype by saturating crossings. It was shown that the high level of adaptation of cn mutants and the low level of adaptation of vg mutants was combined with the presence of different ADH allozymes. During the saturating crossings the reliable coadaptation of the genes cn and Adh(S) as well as vg and Adh(F) was detected that confirmes the postulated earlier conception of gene adaptation complexes.     

Susceptibility of Differentiating Muscle Cells of the Fetal Mouse in Culture to Coxsackievirus A13

The interaction of coxsackievirus A13 with differentiating muscle cells, cultured from tissues of the fetal mouse, was studied. Cultures infected at that stage of myogenic differentiation characterized by the rapid formation of multinucleated myotubes produced maximum virus titers of over 10(7) plaque-forming units. Virus-induced cytopathic effect was characterized by a marked diminution in the number of multinucleated cells. The susceptibility of these cultures decreased appreciably when infection was initiated after the majority of the myotubes had formed. The demonstration of newly synthesized A13 virus antigen by immunofluorescence provided direct evidence that A13 virus replication occurred both in myoblasts and myotubes. The synthesis of A13 virus was markedly depressed in muscle cultures in which the formation of multinucleated cells was inhibited by BUDR or by fusion-inhibiting media. After reversal of this inhibition, the cultures acquired the increased susceptibility to A13 virus characteristic of cells undergoing myogenic differentiation. In contrast to the results obtained with coxsackievirus A13, the primary fetal mouse muscle cultures were resistant to poliovirus T1. It is suggested that changes in the surfaces of developing muscle cells may coincide with the formation and disappearance of specific virus receptors and thereby regulate the cell susceptibility to coxsackievirus A13.     

Cell therapy prospects in Duchenne muscular dystrophy

Skeletal muscle is made of multinucleated postmitotic fibers which are the agents of contraction. These fibers arise from mononuclear precursor cells which fuse after having migrated from the somites to the site of myogenesis. The cascade of events which result in muscle differentiation is well known nowadays (Sabourin & Rudnicki, 2000). Some precursor cells present in adults muscle are termed satellite cells (Mauro, 1961), because of their location between the plasma membrane and the extracellular matrix of muscle fibers. Since they have a role in muscle growth and regeneration, these cells were the first candidates for treating muscle dystrophies. Despite a large corpus of positive experimental data about transplantation of these cells, no hard clinical result has been obtained to date, However these investigations have led to fruitful thinking about heterogeneity of muscle cell precursors and the possible ways to use them for therapy.     

Glucose and amino acid metabolism in an established line of skeletal muscle cells

The suitability of an established myogenic line (L₆) for the study of skeletal muscle intermediary metabolism was investigated. Myoblasts were grown in tissue culture for ten days at which time they had differentiated into multinucleated myotubes. Myotube preparations were then incubated for up to 96 hours in 10 ml of Dulbecco's modified Eagle medium containing 10% fetal calf serum. Glucose was utilized at a nearly linear rate, 3.0 nmol/min/mg protein. Intracellular glucose was detectable throughout the incubation, even when medium glucose was as low as 16 mg%. During the initial 28 hours of incubation, when net lactate production was observed, only 35% of the glucose utilized was converted to lactate. Alanine was produced in parallel to lactate at an average rate of 0.6 nmol/min/mg protein. In concert with active glutamine utilization, high rates of ammoniagenesis were observed as medium glutamine decreased from 3.3 mM to 0.49 mM and medium ammonia increased from 2.3 mM to 6.2 mM, between zero time and 96 hours of incubation, respectively. The cells maintained stable ATP and citrate levels, and physiologic intracellular lactate/pyruvate ratios (10–24) throughout 96 hours of incubation. These results suggest (1) glucose utilization by skeletal muscle in tissue culture is limited by phosphorylation, not transport; (2) as much as 50% of glucose-derived pyruvate enters mitochondrial pathways; (3) glutamine carbon may be utilized simultaneously with glucose consumption and this process accounts for high rates of ammoniagenesis.