Myogenesis in the mouse embryo: differential onset of expression of myogenic proteins and the involvement of titin in myofibril assembly

A novel 550-kDa protein in skeletal muscle of chick embryo: purification and localization

We have found a novel protein with a molecular mass of 550 kDa on SDS-polyacrylamide gels, which is abundant in skeletal muscle tissues at an early stage of chick embryonic development. The 550-kDa protein decreased with the progress of development, and only a slight amount of the protein was present in adult chicken skeletal muscle. The 550-kDa protein was purified from the cytoplasm of 18 day embryos by a procedure including ultracentrifugation and gel filtration. The purified 550-kDa protein was essentially free of contaminants as judged by SDS-PAGE. By immunofluorescence and immunoelectron microscopy using the antibody raised against the 550-kDa protein, this protein was shown to be localized in the peripheries of adult muscle fibers and at the Z-disks of isolated myofibrils. These findings have led us to conclude that the 550-kDa protein is a novel myofibrillar protein in chicken skeletal muscle.

Mechanisms of thin filament assembly in embryonic chick cardiac myocytes: tropomodulin requires tropomyosin for assembly

Tropomodulin is a pointed end capping protein for tropomyosin-coated actin filaments that is hypothesized to play a role in regulating the precise lengths of striated muscle thin filaments (Fowler, V. M., M. A. Sussman, P. G. Miller, B. E. Flucher, and M. P. Daniels. 1993. J. Cell Biol. 120:411-420; Weber, A., C. C. Pennise, G. G. Babcock, and V. M. Fowler. 1994, J. Cell Biol. 127:1627-1635). To gain insight into the mechanisms of thin filament assembly and the role of tropomodulin therein, we have characterized the temporal appearance, biosynthesis and mechanisms of assembly of tropomodulin onto the pointed ends of thin filaments during the formation of striated myofibrils in primary embryonic chick cardiomyocyte cultures. Our results demonstrate that tropomodulin is not assembled coordinately with other thin filament proteins. Double immunofluorescence staining and ultrastructural immunolocalization demonstrate that tropomodulin is incorporated in its characteristic sarcomeric location at the pointed ends of the thin filaments after the thin filaments have become organized into periodic I bands. In fact, tropomodulin assembles later than all other well characterized myofibrillar proteins studied including: actin, tropomyosin, alpha-actinin, titin, myosin and C-protein. Nevertheless, at steady state, a significant proportion (approximately 39%) of tropomodulin is present in a soluble pool throughout myofibril assembly. Thus, the absence of tropomodulin in some striated myofibrils is not due to limiting quantities of the protein. In addition, kinetic data obtained from [35S]methionine pulse-chase experiments indicate that tropomodulin assembles more slowly into myofibrils than does tropomyosin. This observation, together with results obtained using a novel permeabilized cell model for thin filament assembly, indicate that tropomodulin assembly is dependent on the prior association of tropomyosin with actin filaments. We conclude that tropomodulin is a late marker for the assembly of striated myofibrils in cardiomyocytes; its assembly appears to be linked to their maturity. We propose that tropomodulin is involved in maintaining and stabilizing the final lengths of thin filaments after they are assembled.

Myofibrillogenesis in rodent skeletal muscle in vitro: two pathways involving thick filament aggregates

Thick filament aggregates play an important role in myofibrillogenesis in rodent skeletal muscle in vitro. This ultrastructural study describes these aggregates, shows their involvement in the process of myofibril formation, and correlates their appearance and function with current models of myofibrillogenesis. Initially, following myoblast fusion in normal mouse skeletal muscle in vitro, abundant stress fiber-like structures (SFLS) are found near the periphery of early myotubes. These undergo internal rearrangements, forming subcortical sarcomeres and early myofibrils. However, additional thick filaments are synthesized, and some join appositionally to the nascent myofibrils, increasing their diameter. More interiorly, this thick filament synthesis accelerates, with filaments aligning into aggregates resembling discrete A-bands, usually with M-lines and M-regions. The ends of these 'A-band' aggregates are infiltrated with ribosomes and capped by flocculent material. Ultimately, aggregates are incorporated into preexisting myofibrils or associate end-to-end to form new, parallel myofibrils, the flocculent material forming putative I-bands with diminished Z-lines and few thin filaments. As differentiation continues, Z-lines and thin filaments appear, forming true myofibrils. Dysgenic mouse skeletal muscle develops similarly, but when this non-contractile cell matures (i.e., generates action potentials), filaments and their organization break down. Cloned myogenic rat L5/A10 cells also follow this developmental pattern, but in mature, contracting myotubes, Z-lines remain irregular and thin filaments are reduced. In all three types of muscle developing in vitro, thick filament aggregates are a common and predominant feature and as such appear to constitute an additional or alternate pathway to previously described models of myofibrillogenesis.

Inhibition of CapZ during myofibrillogenesis alters assembly of actin filaments

The actin filaments of myofibrils are highly organized; they are of a uniform length and polarity and are situated in the sarcomere in an aligned array. We hypothesized that the barbed-end actin-binding protein, CapZ, directs the process of actin filament assembly during myofibrillogenesis. We tested this hypothesis by inhibiting the actin-binding activity of CapZ in developing myotubes in culture using two different methods. First, injection of a monoclonal antibody that prevents the interaction of CapZ and actin disrupts the non-striated bundles of actin filaments formed during the early stages of myofibril formation in skeletal myotubes in culture. The antibody, when injected at concentrations lower than that required for disrupting the actin filaments, binds at nascent Z-disks. Since the interaction of CapZ and the monoclonal antibody are mutually exclusive, this result indicates that CapZ binds nascent Z-disks independent of an interaction with actin filaments. In a second approach, expression in myotubes of a mutant form of CapZ that does not bind actin results in a delay in the appearance of actin in a striated pattern in myofibrils. The organization of alpha-actinin at Z-disks also is delayed, but the organization of titin and myosin in sarcomeres is not significantly altered. We conclude that the interaction of CapZ and actin is important for the organization of actin filaments of the sarcomere.

Nebulette: a 107 kD nebulin-like protein in cardiac muscle

A 107-kD protein has been identified in primary cultures of chicken embryonic cardiomyocytes by immunoprecipitations with certain anti-nebulin monoclonal antibodies (mAbs). These mAbs, prepared against a fragment of human skeletal muscle nebulin located near the carboxyl terminus, detect a 107-kD protein in extracts of adult chicken heart, adult mouse heart, and adult rabbit heart by immunoblot analysis. A partial cDNA corresponding to this protein has been isolated by immunological screening of a chicken heart cDNA expression vector library. The partial cDNA encodes a 380-amino acid open reading frame composed entirely of nebulin-like 35-residue modules marked by the highly conserved sequence motifs: SXXXYK and TPD. The open reading frame exhibits 60-85% homology with skeletal muscle nebulins from a variety of species. This cDNA recognizes an approximately 8-kb transcript in cardiac RNA and does not hybridize to skeletal muscle RNAs by northern analysis. Immunofluorescence localization of this nebulin-like protein in primary cultures of chicken cardiomyocytes and embryonic chicken cardiac myofibrils indicates that the protein is localized to the I-Z-I complex of the myofibrils, extending approximately 25% of the thin filament length. Comparisons of the distribution of this protein relative to actin, myosin, and titin in spreading cardiomyocytes suggest that the cardiac nebulin-like protein becomes aligned with the nascent myofibrils early during myofibrillogenesis. To distinguish this petite nebulin-like protein from the 600-900 kD skeletal muscle nebulin, we have named it nebulette.

Titin-related proteins in invertebrate muscles

The localization of filaments connecting the Z-line and the A-band in insect flight muscles and the identification of very large proteins as their components is reviewed. The characterization of twitchin in the obliquely striated muscles of Caenorhabditis elegans is reported and the deductions made from its amino acid sequence are considered. The characterization of mini-titins in obliquely striated molluscan muscles is compared. The identification of projectin in the muscles of Drosophila melanogaster by anti-twitchin-antibodies, its sequence analysis and the characterization of mini-titins in arthropod and mollusc fast-striated muscles are summarized. The possible biological functions of the different proteins in various invertebrate muscles are discussed.

Mice lacking vimentin develop and reproduce without an obvious phenotype

To address the biological role of vimentin in the context of the living organism, we have introduced a null mutation of the vimentin gene into the germ line of mice. Surprisingly, animals homozygous for this mutation developed and reproduced without an obvious phenotype. Immunoblotting, immunofluorescence, and immunogold labeling analysis confirmed the absence of vimentin and of the corresponding filament network. Furthermore, no compensatory expression of another intermediate filament could be demonstrated. While these results leave open the question of the possible role of vimentin in unusual situations or pathological conditions, they show that a conspicuous developmental and cell-specific structure that is an integral part of the cytoskeleton can be eliminated without apparent effect on mouse reproduction and development.

Expression of M-cadherin protein in myogenic cells during prenatal mouse development and differentiation of embryonic stem cells in culture

Molecules regulating morphogenesis by cell-cell interactions are the cadherins, a class of calcium-dependent adhesion molecules. One of its members, M-cadherin, has been isolated from a myoblast cell line (Donalies et al. [1991] Proc. Natl. Acad. Sci. U.S.A. 88:8024-8028). In mouse development, expression of M-cadherin mRNA first appears at day 8.5 of gestation (E8.5) in somites and has been postulated to be down-regulated in developing muscle masses (Moore and Walsh [1993] Development 117:1409-1420). Affinity-purified polyclonal M-cadherin antibodies, detecting a protein of approximately 120 kDa, were used to study the cell expression pattern of M-cadherin protein. It was first visualized in somites at E10 1/3 and could be confined to desmin positive, myotomal cells. At all subsequent prenatal stages, M-cadherin was only found in myogenic cells of somitic origin. The detection of the protein at E10 1/3 suggests a translational delay of M-cadherin mRNA of 1 to 2 days (E8.5 vs. E10 1/3). This was further supported by the finding that during differentiation of ES cell line BLC6 into skeletal muscle cells in culture, expression of M-cadherin mRNA can be detected 2 days prior to M-cadherin protein. During prenatal development, the pattern of M-cadherin expression changes: In E10 1/3 embryos and also in myotomal cells of later stages, M-cadherin is evenly distributed on the cell surface. In developing muscle masses (tested at E16 to E18), however, M-cadherin protein becomes clustered most likely at sites of cell-cell contact as indicated by double-labelling experiments: M-cadherin-staining is the positive image of laminin negative areas excluding the presence of a basal lamina at M-cadherin positive sites. Furthermore, M-cadherin is coexpressed with the neuronal cell adhesion molecule N-CAM which has been shown to mediate cell-cell contact in myogenic cells. In summary, our results are in line with the idea that M-cadherin might play a central role in myogenic morphogenesis.

Immunofluorescent studies on titin and myosin in developing hearts of normal and cardiac mutant axolotls

Homozygous recessive cardiac mutant gene c in the axolotl, Ambystoma mexicanum, results in a failure of the embryonic heart to initiate beating. Previous studies show that mutant axolotl hearts fail to form sarcomeric myofibrils even though hearts from their normal siblings exhibit organized myofibrils beginning at stage 34-35. In the present study, the proteins titin and myosin are studied using normal (+/+) axolotl embryonic hearts at stages 26-35. Additionally, titin is examined in normal (+/c) and cardiac mutant (c/c) embryonic axolotl hearts using immunofluorescent microscopy at stages 35-42. At tailbud stage 26, the ventromedially migrating sheets of precardiac mesoderm appear as two-cell-layers. Myosin shows periodic staining at the cell peripheries of the presumptive heart cells at this stage, whereas titin is not yet detectable by immunofluorescent microscopy. At preheartbeat stages 32-33, a myocardial tube begins to form around the endocardial tube. In some areas, periodic myosin staining is found to be separated from the titin staining; other areas in the heart at this stage show a co-localization of the two proteins. Both titin and myosin begin to incorporate into myofibrils at stage 35, when normal hearts initiate beating. Additionally, areas with amorphous staining for both proteins are observed at this stage. These observations indicate that titin and myosin accumulate independently at very early premyofibril stages; the two proteins then appear to associate closely just before assembly into myofibrils. Staining for titin in freshly frozen and paraffin-embedded tissues of normal embryonic hearts at stages 35, 39, and 41 reveals an increased organization of the protein into sarcomeres as development progresses. The mutant siblings, however, first show titin staining only limited to the peripheries of yolk platelets. Although substantial quantities of titin accumulate in mutant hearts at later stages of development (39 and 41), it does not become organized into myofibrils as in normal cells at these stages.

Titin and nebulin: protein rulers in muscle?

Titin and nebulin are giant muscle proteins, both of which are approximately 1 micron long and are composed of many repeating domains. Titin domains resemble type III fibronectin and C-2 immunoglobulins. Both proteins are likely to be involved in specifying and stabilizing the highly ordered structure of muscle, probably by acting as 'protein rulers' to regulate the assembly of myosin and actin filaments precisely.

Expression and localization of the phosphoglucomutase-related cytoskeletal protein, aciculin, in skeletal muscle

Recently, a 60/63 kDa cytoskeletal protein, highly homologous to the glycolytic enzyme phosphoglucomutase (PGM 1), was isolated from smooth muscle tissue and shown to localize in various adherens-type junctions of muscle and some nonmuscle cells. Since this protein, tentatively named ‘aciculin’, was enriched in muscle tissues and cells, we have attempted to study its expression and localization during myodifferentiation. C2C12 mouse myoblasts did not express any aciculin before cell fusion in culture. Immediately after cell fusion aciculin became detectable and its content continued to rise during myotube maturation. In early myotubes aciculin appeared first at cell tips and was predominantly localized to focal adhesions of immature myotubes. As myotubes matured in culture, aciculin became associated with growing myofibrils, and finally was found redistributed in striations, corresponding to sarcomere Z-discs. Immunoblotting showed that aciculin content in chicken breast skeletal muscle remained very low until day 11 of embryogenesis, but significantly increased in late prenatal and early postnatal development. By immunofluorescence, aciculin was not revealed in thigh skeletal muscle of day 11 chicken embryos, but was prominently localized at myotendinous junctions in thigh muscle of day 16 embryos. Myotendinous junctions appeared to be major sites of aciculin accumulation in developing and mature skeletal muscle fibers in vivo, suggesting some role for this protein in thin filament-membrane interactions and, potentially, in force transmission at these cell-matrix contacts. In adult skeletal muscle faint aciculin staining appeared at the sarcolemma and as striations in register with Z-discs. Since the protein was not identified in glycerinated myofibrils but was localized to striations in C2C12 myotubes and within the limited areas on skeletal muscle tissue sections, we conclude that aciculin is a component of skeletal muscle costameres. In cultured C2C12 myotubes we found some codistribution of aciculin with clusters of acetylcholine receptors, suggesting its presence at neuromuscular junctions. However, we did not detect any significant concentration of aciculin at neuromuscular junctions in both embryonic and adult skeletal muscle. Taken together, our data show that aciculin expression in skeletal muscle is differentiation-dependent and upregulated during muscle development, and that this novel cytoskeletal protein is a component of various cell-matrix adherens junctions in muscle cells.

Expression of myosin isoforms and of desmin, vimentin and titin in Tunisian Duchenne-like autosomal recessive muscular dystrophy

Morphological, morphometrical, histoenzymological, immunocytochemical and biochemical analysis were performed on muscle biopsies taken from patients suffering from tunisian autosomal recessive Duchenne-like muscular dystrophy (TDLMD) selected both by Duchenne-like clinical criteria and by the presence of normal dystrophin. Data were compared to that obtained from DMD biopsies characterized by the absence of dystrophin. The distribution of myosin heavy chain isoforms, desmin, vimentin and titin were determined in type I and type II muscle fibers. The protein pattern appeared to be less affected in TDLMD than in DMD biopsies. The regenerating fibers were mainly but not exclusively type IIC; a noticeable percentage of both type I and type II fibers coexpressed fast and slow MHC isoforms in TDLMD. This percentage was lower than in DMD. The expression of embryonic, fetal, and fast/slow myosin isoforms in type IIC fibers in TDLMD and DMD suggest different fiber type transformations in these two diseases.

Barrier inhibition of a temporal neuraxial influence on early chick somitic myogenesis

Skeletal myogenesis in the chick embryo first occurs in the somite. Somites are transient, paired mesodermal structures adjacent to the neural tube. Somites form from the segmental plate mesenchyme at approximately 90-min intervals. We identify somitic myogenic cells by using confocal microscopy to detect the muscle specific intermediate filament protein, desmin, in whole mount chick embryo preparations. The appearance of desmin in somitic cells does not occur at a constant interval after the somite has formed. The rate of chick somitic myogenic onset, as evidenced by detection of desmin, is approximately 1.5 times faster than the rate of somitogenesis (Borman and Yorde [1994] J. Histochem. Cytochem. 42:265-272). Somitic myogenesis does not appear to be directly linked to somitogenesis but instead may be regulated by some influence external to the somite. Here we have specifically addressed the issue of whether an impermeable barrier placed between the neuraxis and the somites can prevent the onset of somitic myogenesis. When tantalum foil barriers are placed medial to the caudalmost 3-5 somites of embryos having up to 20 somites total (stage 13), the predominant result is an inhibition of myogenic cells lateral to the barrier. Conversely, when the tantalum foil is placed medial to the caudal somites of an embryo having 21 somites (stage 14) or more, desmin is detected lateral to the barrier in most cases. There is a temporal influence originating in the neuraxis which plays a role in the onset of somitic myogenesis. Although the nature of this interaction between the neuraxis and the somites is not yet clear, we have defined a precise temporal location within the developing embryo at which this tissue interaction is taking place.

Connectin, an elastic protein of striated muscle

Connectin, also called titin, a giant elastic protein of striated muscle (approximately 3000 kDa) mainly consists of fibronectin type III and immunoglobulin C2 globular domains, the beta-sheets of which are parallel to the main axis of the molecule. One connectin molecule runs through the I band and binds onto the myosin filament up to the M line starting from the Z line. It positions the myosin filament at the center of a sarcomere. Connectin is also responsible for resting tension generation. Biodiversity of the connectin family exists in invertebrate muscle.

Biochemical and immunocytochemical analysis in chronic proximal spinal muscular atrophy

Immunocytochemical and biochemical analyses were carried out on patients affected by chronic SMA. Three groups of patients were identified. In group I, the muscle presented a fascicular atrophy; a high percentage of atrophic type II fibers; and fibers expressing fast, slow, embryonic, and fetal myosin isoforms. In group II, the muscle was characterized by atrophic fibers and normal/hypertrophic fibers expressing only slow myosin isoforms. In group III, the muscle was characterized by fiber type grouping and fibers coexpressing fast and slow myosin isoforms but never embryonic or fetal MHC isoforms. The muscles of groups I and III contained both fast and slow myosins whereas group II muscles were predominantly slow by immunocytochemical analysis or only slow by biochemical analysis. In view of these results, immunocytochemical and histochemical analyses could help to classify chronic SMA and help to understand the different pathogenic processes which seem to be related to the maturational stage of the muscle at the age of onset of the disease.

Desmin organization during the differentiation of the dorsal myotome in Xenopus laevis

The reorganization of desmin-type intermediate filaments during muscle differentiation has been studied primarily in cultured cell systems. Here we describe the process of desmin reorganization during the differentiation of the dorsal myotomal muscle of the clawed frog Xenopus laevis. This muscle differs from those described previously primarily in that the desmin system forms de novo, i.e., without the presence of a pre-existing vimentin filament system. The most striking observation is that prior to myotomal segmentation and rotation desmin is concentrated at the medial and lateral tips of the myocytes. It remains concentrated in these regions following somite rotation and is located primarily to the intersomite junctions as late as the stage 33-35 tadpole. As the muscle matures (stage 30 and later) desmin becomes increasingly associated with the sarcolemma and with the Z-discs. The concentration of desmin at the nascent intersomite junction suggests that desmin is involved in coupling somites to one another in the early Xenopus embryo.

The evolution of titin and related giant muscle proteins

Titin and twitchin are giant proteins expressed in muscle. They are mainly composed of domains belonging to the fibronectin class III and immunoglobulin c2 families, repeated many times. In addition, both proteins have a protein kinase domain near the C-terminus. This paper explores the evolution of these and related muscle proteins in an attempt to determine the order of events that gave rise to the different repeat patterns and the order of appearance of the proteins. Despite their great similarity at the level of sequence organization, titin and twitchin diverged from each other at least as early as the divergence between vertebrates and nematodes. Most of the repeating units in titin and twitchin were estimated to derive from three original domains. Chicken smooth-muscle myosin light-chain kinase (smMLCK) also has a kinase domain, several immunoglobulin domains, and a fibronectin domain. From a comparison of the kinase domains, titin is predicted to have appeared first during the evolution of the family, followed by twitchin and with the vertebrate MLCKs last to appear. The so-called C-protein from chicken is also a member of this family but has no kinase domain. Its origin remains unclear but it most probably pre-dates the titin/twitchin duplication.

Inhibition of desmin expression blocks myoblast fusion and interferes with the myogenic regulators MyoD and myogenin

The muscle-specific intermediate filament protein, desmin, is one of the earliest myogenic markers whose functional role during myogenic commitment and differentiation is unknown. Sequence comparison of the presently isolated and fully characterized mouse desmin cDNA clones revealed a single domain of polypeptide similarity between desmin and the basic and helix-loop-helix region of members of the myoD family myogenic regulators. This further substantiated the need to search for the function of desmin. Constructs designed to express anti-sense desmin RNA were used to obtain stably transfected C2C12 myoblast cell lines. Several lines were obtained where expression of the anti-sense desmin RNA inhibited the expression of desmin RNA and protein down to basal levels. As a consequence, the differentiation of these myoblasts was blocked; complete inhibition of myoblast fusion and myotube formation was observed. Rescue of the normal phenotype was achieved either by spontaneous revertants, or by overexpression of the desmin sense RNA in the defective cell lines. In several of the cell lines obtained, inhibition of desmin expression was followed by differential inhibition of the myogenic regulators myoD and/or myogenin, depending on the stage and extent of desmin inhibition in these cells. These data suggested that myogenesis is modulated by at least more than one pathway and desmin, which so far was believed to be merely an architectural protein, seems to play a key role in this process.

Assembly of body wall muscle and muscle cell attachment structures in Caenorhabditis elegans

C. Elegans has four muscle quadrants that are used for locomotion. Contraction is converted to locomotion because muscle cells are anchored to the cuticle (the outer covering of the worm) by a specialized basement membrane and hemidesmosome structures in the hypodermis (a cellular syncytium that covers the worm and secretes the cuticle). To study muscle assembly, we have used antibodies to determine the spatial and temporal distribution of muscle and attachment structure components in wild-type and mutant C. elegans embryos. Myofibrillar components are first observed diffusely distributed in the muscle cells, and are expressed in some dividing cells. Later, the components accumulate at the membrane adjacent to the hypodermis where the sarcomeres will form, showing that the cells have become polarized. Assembly of muscle attachment structures is spatially and temporally coordinated with muscle assembly suggesting that important developmental signals may be passed between muscle and hypodermal cells. Analysis of embryos homozygous for mutations that affect muscle assembly show that muscle components closer to the membrane than the affected protein assemble quite well, while those further from the membrane do not. Our results suggest a model where lattice assembly is initiated at the membrane and the spatial organization of the structural elements of the muscle is dictated by membrane proximal events, not by the filament components themselves.

The premyofibril: evidence for its role in myofibrillogenesis

When cardiac muscle cells are isolated from embryonic chicks and grown in culture they attach to the substrate as spherical cells with disrupted myofibrils, and over several days in culture, they spread and extend lamellae. Based on antibody localizations of various cytoskeletal proteins within the spreading cardiomyocyte, three types of myofibrils have been identified: 1) fully formed mature myofibrils that are centrally positioned in the cell, 2) premyofibrils that are closest to the cell periphery, and 3) nascent myofibrils located between the premyofibrils and the mature myofibrils. Muscle-specific myosin is localized in the A-bands in the mature, contractile myofibrils, and along the nascent myofibrils in a continuous pattern, but it is absent from the premyofibrils. Antibodies to non-muscle isoforms of myosin IIB react with the premyofibrils at the cell periphery and with the nascent myofibrils, revealing short bands of myosin between closely spaced bands of alpha-actinin. In the areas where the nascent myofibrils border on the mature myofibrils, the bands of non-muscle myosin II reach lengths matching the lengths of the mature A-bands. With the exception of a small transition zone consisting of one myofibril, or sometimes several sarcomeres, bordering the nascent myofibrils, there is no reaction of these non-muscle myosin IIB antibodies with the mature myofibrils in spreading myocytes. C-protein is found only in the mature myofibrils, and its presence there may prevent co-polymerization of non-muscle and muscle myosins. Antibodies directed against the non-muscle myosin isoforms, IIA, do not stain the cardiomyocytes. In contrast to the cardiomyocytes, the fibroblasts in these cultures stain with antibodies to both non-muscle myosin IIA and IIB. The premyofibrils near the leading edge of the lamellae show no reaction with antibodies to either titin or zeugmatin, whereas the nascent myofibrils and mature myofibrils do. The spacings of the banded alpha-actinin staining range from 0.3 to 1.4 microns in the pre- and nascent myofibrils and reach full spacings (1.8-2.5 microns) in the mature myofibrils. Based on these observations, we propose a premyofibril model in which non-muscle myosin IIB, titin, and zeugmatin play key roles in myofibrillogenesis. This model proposes that pre- and nascent myofibrils are composed of minisarcomeres that increase in length, presumably by the concurrent elongation of actin filaments, the loss of the non-muscle myosin II filaments, the fusion of dense bodies or Z-bodies to form wide Z-bands, and the capture and alignment of muscle myosin II filaments to form the full spacings of mature myofibrils.

Myofibrillogenesis in primary tissue cultures of adult human skeletal muscle: expression of desmin, titin, and nebulin

To investigate the in vitro development of myofibrils in skeletal muscle cells derived from adult human muscle biopsies, immunohistochemical analysis was performed using monoclonal antibodies against desmin, titin, and nebulin. Diffuse desmin reactivity was detected 48 h after plating in about 60% of all mononucleated cells. This supports the use of desmin as a marker for undifferentiated rhabdomyosarcomas in man. Titin was visible from day 4 onwards, while nebulin was not found in mononucleated cells. After 1 week polynucleated myotubes appeared, and grew up to 30 days. Desmin was distributed diffusely throughout the cytoplasm until day 21, when the pattern became patchy. Titin began to be organized in a predominantly longitudinal orientation at day 15, while nebulin, which appeared for the first time in fusing myoblasts on the fifth to the seventh day, was almost immediately organized in a dotted longitudinal pattern, which became a Z line connected striation in matured myotubes.

Immunohistochemical localisation of the 90, 70 and 25 kDa heat shock proteins in control and caffeine treated rat embryos

Human and animal experimental data demonstrate that in utero exposure to caffeine results in intrauterine growth retardation and long-term behavioural and reproductive effects. We have suggested that the disruption of normal transcription and translation associated with the initiation of the heat shock response may be a possible mechanism of action of caffeine. This hypothesis was investigated using immunohistochemistry to determine whether an acute (3 h) dose of 30 mg/kg caffeine alters the distribution of hsp 90, 70 and 25 in 10.5-12.5 g.d. rat embryos. In the control embryos hsps 90 and 70 were distributed throughout the embryo with no areas of specific accumulation. Hsp 25 was localised to the developing myocardium of 10.5, 11.5 and 12.5 g.d. embryos and the myotome of 11.5 and 12.5 g.d. embryos. The appearance of hsp 25 was correlated with the onset of muscle fibre differentiation and it is suggested that hsp 25 is associated with cytoskeletal proteins. Following dosing with caffeine no change in the distribution of staining for hsp 90, 70 and 25 was found. These results strongly suggest that caffeine's mechanism of action does not involve initiation of the heat shock response.

Desmin pathology in neuromuscular diseases

Desmin is an intermediate filament protein that in striated muscle is normally located at Z-bands, beneath the sarcolemma, and prominently at neuromuscular junctions. It is abundant during myogenesis and in regenerating fibers, but decreases in amount with maturation; in regenerating and denervated muscle fibers it is co-expressed with vimentin. Aggregates of desmin occur as nonspecific cytoplasmic bodies or cytoplasmic spheroid complexes, similar to the aggregates of keratin filaments in Mallory bodies or the neurofilament aggregates in Lewy bodies. In all three instances, alpha-B crystallin may be associated with desmin. There are now increasing numbers of neuromuscular disorders in which abnormal amounts of desmin, some abnormally phosphorylated, feature prominently in muscle fibres. Several of these diseases, including spheroid body myopathy, granulo-filamentous body myopathy and the dystrophinopathies, are familial. Ultrastructural and immunohistochemical studies of desmin have considerably broadened our understanding of the pathology of the cytoskeleton in muscle fibers and in certain hereditary neuromuscular diseases.

Titin aggregates associated with intermediate filaments align along stress fiber-like structures during human skeletal muscle cell differentiation

Differentiating human skeletal muscle cell cultures were used to study the association of titin with other sarcomeric and cytoskeletal proteins during myofibrillogenesis. Several developmental stages of these cultures were double stained with antibodies to titin in combination with antibodies to alpha-actin, alpha-actinin, myosin heavy chain (MHC), nebulin, desmin, and beta-tubulin. The first indications of titin expression were found in postmitotic mononuclear myoblasts where it is located in a random, punctate fashion. At the light microscope level no evidence was found for an association of these titin spots with any of the other proteins studied, with the exception of MHC, which colocalized with titin in a small minority of the titin expressing cells. Subsequently the titin spots were found to be linked to longitudinally oriented stress fiber-like structures (SFLS), containing alpha-actinin and sarcomeric alpha-actin, but not MHC, nebulin or desmin. Upon further maturation titin antibodies seemed to stain SFLS in a rather homogeneous fashion together with MHC, alpha-actin and alpha-actinin. Thereafter a more periodic localization of titin, MHC, alpha-actin and alpha-actinin on SFLS became obvious. From these structures myofibrils developed as a result of further differentiation. Initially only short stretches with a striated titin, MHC, F-actin and alpha-actinin organization were found. Nebulin was integrated in these young myofibrils at a later developmental stage. Desmin was not found to be incorporated in these myofibrils until complete alignment of the sarcomeres in mature myotubes had occurred. At the ultrastructural level titin antibodies recognized aggregates that were associated with intermediate filaments (IF) in postmitotic mononuclear myoblasts. At a later maturational stage, prior to the development of cross-striated myofibrils, the IF-associated titin aggregates were found in close association with subsarcolemmally located SFLS. We conclude that IF and SFLS play an important role in the very early stages of in vitro human myofibrillogenesis. On the basis of our results we assume that titin aggregates are targeted to SFLS through IF. The association of titin with SFLS might be crucial for the unwinding of titin necessary for the assembly of sarcomeres and the first association of titin with other sarcomeric proteins.

Desmin-lacZ transgene, a marker of regenerating skeletal muscle

Transgenic C57 mice bearing a transgene of the desmin gene linked to the lacZ reporter gene which encoded for the enzyme beta-galactosidase were used. In the muscle cell, a blue nuclear product appearing in the presence of the X-gal substrate for the enzyme provided evidence of the expression of the desmin gene. However, no transgene expression was observed 2 weeks postnatal in skeletal muscles, even though endogenous desmin was present. In order to investigate the regulatory mechanisms of the desmin gene during regeneration, adult pectoralis fragments (without expression of the desmin transgene) from transgenic mice were implanted into the tibialis anterior of 4 day or 6 week old Swiss mice. Adult pectoralis transplants reexpressed the transgene from day 4 to 10 after implantation. In addition, lesions were performed in adult transgenic pectoralis and transgenic expression in injured muscles was observed 2 days later. This new transgenic mouse is a powerful tool for the study of the various steps of skeletal muscle regeneration.

Incorporation of microinjected biotin-labelled actin into nascent myofibrils of cardiac myocytes: an immunoelectron microscopic study

Incorporation of microinjected biotin-labelled actin into nascent myofibrils of cultured cardiac muscle cells was investigated by immunogold electron microscopy. At the proximal parts of myofibrils, gold labelling was first found (at about 4 min after injection) around the A-band level. This observation suggests that polymerization of actin or the addition of newly-formed actin filaments occurs preferentially in association with myosin filaments to increase the myofibrillar girth. The distal terminals of developing myofibrils were also labelled at about 4 min after injection. This rapid incorporation of actin subunits at the myofibrillar ends suggests the continued reorganization and/or de novo formation of myofibrils at these positions. Along the extending direction of the myofibrillar terminals, gold particles were arranged in rows on the inner surface of the sarcolemma. These rows of particles continued to become longer with incubation. It appears that actin subunits are added at the membrane-associated ends of pre-existing actin filaments to increase the length of myofibrils.

Rhabdomyosarcomas in young pigs in a swine breeding farm: a morphologic and immunohistochemical study

Within a 6-month-period, solitary or multiple tumors were observed in 25 young pigs in their first weeks of life in a swine breeding farm. The herd comprised approximately 100 animals, and affected pigs were observed in several litters. The number of affected littermates varied from one to three. Five animals, all from different litters and with a total of 11 tumors, were studied. Histologically the tumors were classified as undifferentiated sarcomas. Electron microscopic examination of the tumors (n = 3) revealed myogenic differentiation, characterized by the presence of numerous cytoplasmic filaments with longitudinal densities and cytoplasmic dense bodies. Immunohistochemically, all 11 tumors were labeled by vimentin and desmin antibodies. Two tumors from which frozen material was available were additionally labeled by a titin antibody but did not show immunoreactivity with antibodies directed against myosin and alpha-sarcomeric actin. The tumors were finally diagnosed as undifferentiated rhabdomyosarcomas. The high incidence of these tumors within a short period of time in multiple young animals in different litters indicates a common causative event. The clinical history suggests a genetic cause.

Dynamics of actin and assembly of connectin (titin) during myofibrillogenesis in embryonic chick cardiac muscle cells in vitro

Immunogold electron microscopy of cardiac myocytes microinjected with biotin-labeled actin showed that gold labeling was first found around the A band level of myofibrils at their proximal parts. This observation suggests that polymerization of actin and/or the addition of newly formed actin filaments occurs preferentially in association with myosin filaments to increase the myofibrillar girth. At the distal portions of developing myofibrils, their terminal ends were initially labeled, suggesting that continued reorganization and/or de novo formation of myofibrils occurs at these locations. Soon, gold particles were seen along the termini of growing myofibrils. This appears to indicate that actin subunits are added at the membrane-associated ends of preexisting actin filaments to increase the length of myofibrils. Adhesion plaque proteins, e.g., vinculin, do not appear to play any role in assembling actin monomers at these sites on the inner surface of the sarcolemma. Immunofluorescence and immunoelectron microscopy of cardiomyocytes double-stained with antibodies against two distant domains of connectin (titin) filaments and other sarcomeric proteins showed that these domains of connectin filaments and myosin were synthesized almost simultaneously on large polyribosomes and/or associated immediately after the synthesis of these molecules. Connectin and myosin bands were formed after alpha-actinin striations (Z bands) were seen on preformed I-Z-I-like structures.(ABSTRACT TRUNCATED AT 250 WORDS)

Desmin sequence elements regulating skeletal muscle-specific expression in transgenic mice

During the development of the mouse embryo, desmin is one of the first muscle proteins detected in both the heart and the somites. The expression of the desmin gene differs from most other muscle genes, since it is initiated in replicating myoblasts and accumulates as the muscle differentiates. We have characterized a muscle-specific enhancer which directs the expression of desmin in vitro in the myoblasts and myotubes of C2 cells but not in non-myogenic cells. We report here on the generation and characterization of transgenic mice bearing a transgene in which the 1 kb DNA 5′ regulatory sequence of the desmin gene is linked to a reporter gene coding for Escherichia coli beta-galactosidase (Des1-nlacZ). The enhancer activity of the desmin promoter is very strong and the reporter gene expression is easily detected in tissue sections. We have demonstrated that the regulatory elements present in the transgene Des1-nlacZ are sufficient to direct muscle-specific and developmentally regulated expression of nlacZ in skeletal muscles. Endogenous desmin expression and transgene activity were found to be correlated during the development of skeletal muscles. The transgene was expressed in the committed mononucleate myoblasts as well as in the myotubes. In addition, we have shown that the desmin-derived sequences direct a highly selective expression of nlacZ in cells that leave the somites and invade the limb bud, indicating that the cells that migrate from the somites are already predetermined for myogenesis. In contrast, smooth and cardiac muscle cells were beta-galactosidase negative both during embryonic and foetal development. Interestingly, the transgene was found to be expressed in the conduction system of the heart, which exhibits many features characteristic of skeletal muscles.

Localization of CapZ during myofibrillogenesis in cultured chicken muscle

Actin filaments undergo dramatic changes in their organization during myofibrillogenesis. In mature skeletal muscle, both CapZ and the barbed end of the actin filaments are located at Z-discs. In vitro, CapZ binds the barbed end of actin filaments and prevents actin subunit addition and loss; CapZ also nucleates actin polymerization in vitro. Taken together, these properties suggest that CapZ may function to organize actin filaments during myofibrillogenesis. We report here that the amount of CapZ in myofibrils from adult chicken pectoral muscle is sufficient to "cap" each actin filament of the sacromere. Double immunofluorescence microscopy of skeletal muscle cells in culture was used to determine the spatial and temporal distributions of CapZ relative to actin, alpha-actinin, titin, and myosin during myofibrillogenesis. Of particular interest was the assembly of CapZ at nascent Z-discs in relation to the organization of actin filaments in nascent myofibrils. In myoblasts and young myotubes, CapZ was diffusely distributed in the cytoplasm. As myotubes matured, CapZ was initially observed in a uniform distribution along non-striated actin filaments called stress fiber-like structures (SFLS). CapZ was observed in a periodic pattern characteristic of mature Z-discs along the SFLS prior to the appearance of a striated staining pattern for actin. In older myotubes, when actin was observed in a pattern characteristic of I-bands, CapZ was distributed in a periodic pattern characteristic of mature Z-discs. The finding that CapZ was assembled at nascent Z-discs before actin was observed in a striated pattern is consistent with the hypothesis that CapZ directs the location and polarity of actin filaments during I-band formation in skeletal muscle cells. The assembly of CapZ at nascent Z-disc structures also was observed relative to the assembly of sarcomeric alpha-actinin, titin, and thick filaments. Titin and myosin were observed in structures having the organization of mature sarcomeres prior to the appearance of CapZ at nascent Z-discs. The distribution of CapZ and sarcomeric alpha-actinin in young myotubes was not coincident; in older myotubes, both CapZ and alpha-actinin were co-localized at Z-discs. In cardiac myocytes, CapZ was detected at Z-discs and was distributed in a punctate pattern throughout the cytoplasm. CapZ also was co-localized with A-CAM and vinculin at cell-cell junctions formed by the myocytes.

Structural analysis of muscle development: transverse tubules, sarcoplasmic reticulum, and the triad

Increased interest in the mechanism of excitation-contraction (E-C) coupling over the last few years has been accompanied by numerous investigations into the development of the underlying cellular structures. Areas of particular interest include: (1) the compartmentalization and specialization of an external and an internal membrane system, the T-tubules, and the sarcoplasmic reticulum, respectively; (2) interactions between the membrane proteins of both systems upon the formation of a junction, the triad; and (3) membrane-cytoskeletal interactions leading to the orderly arrangement of the triads with respect to the myofibrils. Structural studies using newly available specific molecular probes and a variety of in vivo and in vitro model systems have provided new insights into the cellular and molecular mechanisms involved in the development of the E-C coupling apparatus in skeletal muscle.

Targeted inactivation of the muscle regulatory gene Myf-5 results in abnormal rib development and perinatal death

The Myf-5 gene, a member of the myogenic basic HLH factor family, has been inactivated in mice after homologous recombination in ES cells. Mice lacking Myf-5 were unable to breathe and died immediately after birth, owing to the absence of the major distal part of the ribs. Other skeletal abnormalities, except for complete ossification of the sternum, were not apparent. Histological examination of skeletal muscle from newborn mice revealed no morphological abnormalities. Northern blot analysis demonstrated normal levels of muscle-specific mRNAs including MyoD, myogenin, and Myf-6. However, the appearance of myotomal cells in early somites was delayed by several days. These results suggest that while Myf-5 plays a crucial role in the formation of lateral sclerotome derivatives, Myf-5 is dispensable for the development of skeletal muscle, perhaps because other members of the myogenic HLH family substitute for Myf-5 activity.

Association of titin and myosin heavy chain in developing skeletal muscle

To understand molecular interactions that organize developing myofibrils, we examined the biosynthesis and interaction of titin and myosin heavy chain in cultures of developing muscle. Use of pulse-labeling, immunoprecipitation, and a reversible cross-linking procedure demonstrates that within minutes of synthesis, titin and myosin heavy chain can be chemically cross-linked into very large, detergent-resistant complexes retaining many features of intact myotubes. These complexes, predominantly of titin and myosin, occur very early in myofibrillogenesis as well as later. These data suggest that synthesis and assembly of titin and myosin are temporally and spatially coordinated in nascent myofibrils and support the hypothesis that titin molecules help to organize sarcomere formation.

The fate of desmin and titin during the degeneration and regeneration of the soleus muscle of the rat

We studied the fate of desmin and titin in rat skeletal muscle during a cycle of degeneration and regeneration induced in vivo by the inoculation of a snake venom. Cryosections of muscle were labelled using antibodies to the two proteins, and examined at fixed time points after venom injection. Early pathological changes in the muscle, such as hypercontraction, preceded the loss of desmin. Immunolabelling using anti-desmin antibodies showed that desmin bridges were still intact when adjacent myofibrils were no longer aligned. The results suggested that although the hydrolysis of desmin is not necessary for the hypercontraction of muscle fibres, it probably contributes to complete fibre breakdown. Titin, or at least the part which lies close to the M-line, remained intact longer than desmin, but was also hydrolysed prior to complete disintegration of the fibres. Both desmin and titin were re-expressed in the regenerating myotubes by 2 days after venom inoculation, and became well organised even before the myofibrils became aligned. We conclude that desmin and titin are involved in both establishing and maintaining the structural integrity of the muscle fibres.

Activation of the gene encoding the glycolytic enzyme beta-enolase during early myogenesis precedes an increased expression during fetal muscle development

We define the spatial and temporal patterns of expression of the gene encoding the glycolytic enzyme, beta-enolase, during mouse ontogenesis. Transcripts were detected by in situ hybridization using 35S labelled cRNA probes. The beta-enolase gene is expressed only in striated muscles. It is first detected in the embryo, in the cardiac tube and in newly formed myotomes. In the muscle masses of the limb, beta gene expression occurs at a low level in primary fibers, and subsequently greatly increases at a time which corresponds to the onset of innervation and secondary fiber formation. Later in development, it becomes undetectable in slow-twitch fibers. Our results demonstrate the multistep regulation of the beta-enolase gene. The regulation of this muscle-specific gene in somites is discussed in terms of the myogenic sequences of the MyoD family shown to be present when it is activated.

Roles for the integrin VLA-4 and its counter receptor VCAM-1 in myogenesis

Mammalian myogenesis is biphasic: primary myoblasts fuse to form primary myotubes, then secondary myoblasts align along the primary myotubes and form secondary myotubes, which comprise most of adult muscle. We provide evidence that an integrin (VLA-4) and its counter receptor (VCAM-1) have a role in secondary myogenesis. Both receptors are synthesized by cultured muscle cells: VLA-4 is induced as myotubes form, whereas VCAM-1 is present on myoblasts and myotubes. In vivo, both molecules are expressed at sites of secondary myogenesis, VLA-4 on primary and secondary myotubes, and VCAM-1 on secondary myoblasts and on regions of secondary myotubes apposed to primary myotubes. These patterns suggest that VLA-4-VCAM-1 interactions influence alignment of secondary myoblasts along primary myotubes and/or the fusion of secondary myoblasts. In support of the latter possibility, antibodies to VLA-4 or VCAM-1 inhibit myotube formation in culture.

Expression of NCAM isoforms during skeletal myogenesis in the mouse embryo

We have examined the developmental patterns of neural cell adhesion molecule (NCAM) gene expression in embryonic mouse skeletal muscle cells by in situ hybridization. Moreover, by utilising exon-specific cRNA probes, we have examined tissue specific splicing of the NCAM gene. We show that there is a distinct sequence of NCAM isoform expression during skeletal muscle development. Since NCAMs are also expressed in other cell types, particularly neurons, NCAM mRNAs have been colocalised with acetylcholine receptor alpha (AChR alpha) gene transcripts to identify muscle-specific expression. NCAM is first detected in somites as they first form, prior to their differentiation into muscle and nonmuscle compartments. Myotomes, the first skeletal muscle masses to form in the embryo, express mRNAs for the transmembrane 180 and 140 kDa isoforms of NCAM. Both of these transcripts are also detected in the neural tube, and their spatial pattern of expression changes with development. Transcripts containing the muscle-specific domain (MSD) of the NCAM gene are not detected prior to 11 days postcoitum (p.c.), at a time when rostral somites already contain well-developed myotomes. As the level of MSD mRNAs increases at 12 days p.c., the 140 and 180 kDa transcript levels decrease in skeletal muscle masses. The level of all NCAM isoform transcripts declines between 13 and 15 days p.c. in muscle. However, the 180 and 140 kDa NCAM isoforms are expressed at a high level in neural tissue and in other locations in the developing embryo such as in smooth muscle, around vibrissae follicles, and in the perichondrial zone of digits.

The role of beta 1 integrin in spreading and myofibrillogenesis in neonatal rat cardiomyocytes in vitro

The influence of the extracellular matrix (ECM) on cell behavior, myofibrillogenesis and cytoarchitecture was investigated in neonatal rat cardiac myocytes in vitro. Cell behavior was examined by analyzing cell spreading on different ECM components under a variety of experimental conditions. Area measurements were made on digitized images of cells grown for various time intervals on fibronectin (FN), laminin (LN), collagens I and III (C I+III), plastic, and bovine serum albumin (BSA). The amount of spreading was varied on the different matrices and was maximal on FN greater than LN greater than C I+III greater than plastic greater than BSA. Addition of anti-beta 1 integrin antibodies to myocytes cultured on FN, LN and C I+III blocked spreading outward on the substrates and altered normal myofibrillogenesis, especially on LN. Concomitantly, the integrin antibodies induced the formation of giant pseudopodial processes which protruded upward from the substrates. These pseudopods contained actin polygonal networks which exhibited a regular geometrical configuration. Effects of the ECM on cytoarchitecture was examined by analyzing the temporal and spatial patterns of fluorescence and immunogold labeling of cytoskeletal and integrin proteins as myocytes spread in culture. The first indication of sarcomeric patterns was the appearance at 4 hours of striations formed by lateral alignment of alpha-actinin aggregates into Z bands. At later times, vinculin at 8 hours and beta 1 integrin at 22 hours became co-localized with alpha-actinin at the Z bands and focal adhesions. These data indicate that ECM components influence myocyte spreading and that myofibril assembly and/or stability is associated with ECM-integrin-cytoskeleton associations.

Towards a molecular understanding of titin

Titin is at present the largest known protein (M(r) 3000 kDa) and its expression is restricted to vertebrate striated muscle. Single molecules span from M- to Z-lines and therefore over 1 micron. We have isolated cDNAs encoding five distant titin A-band epitopes, extended their sequences and determined 30 kb (1000 kDa) of the primary structure of titin. Sequences near the M-line encode a kinase domain and are closely related to the C-terminus of twitchin from Caenorhabditis elegans. This suggests that the function of this region in the titin/twitchin family is conserved throughout the animal kingdom. All other A-band sequences consist of 100 amino acid (aa) repeats predicting immunoglobulin-C2 and fibronectin type III globular domains. These domains are arranged into highly ordered 11 domain super-repeat patterns likely to match the myosin helix repeat in the thick filament. Expressed titin fragments bind to the LMM part of myosin and C-protein. Binding strength increases with the number of domains involved, indicating a cumulative effect of multiple binding sites for myosin along the titin molecule. We conclude that A-band titin is likely to be involved in the ordered assembly of the vertebrate thick filament.

Evolution of muscle specific proteins in Werdnig-Hoffman's disease

The pattern of expression of desmin, vimentin, titin and different myosin isoforms expressed in atrophic and hypertrophic type I and type II muscle fibers was investigated in 7 biopsies from patients of various ages all diagnosed as suffering from Werdnig-Hoffman's disease. The results revealed that there was a progressive atrophy affecting both type I and type II muscle fibers. The proportion of atrophic type II fibers increased with age. These atrophic fibers expressed predominantly fast MHC together with variable amounts of embryonic and fetal abnormal concentrations of desmin, vimentin and titin were also observed in some of these fibers. Hypertrophic type I fibers expressed exclusively slow MHC. These results are in good agreement with the hypothesis that Werdnig-Hoffman's disease is associated with a persistence of slow twitch type I motor units and a loss of phasic type II motor units. They also confirm that the atrophic fibers were frequently immature although embryonic MLC was never detected in these muscles. In addition we have demonstrated that the hypertrophic fibers were not completely normal since they frequently contained abnormal concentrations of desmin and titin at their periphery.

Coordinated development of myofibrils, sarcoplasmic reticulum and transverse tubules in normal and dysgenic mouse skeletal muscle, in vivo and in vitro

We studied the development of transverse (T)-tubules and sarcoplasmic reticulum (SR) in relationship to myofibrillogenesis in normal and dysgenic (mdg/mdg) mouse skeletal muscle by immunofluorescent labeling of specific membrane and myofibrillar proteins. At E16 the development of the myofibrils and membranes in dysgenic and normal diaphragm was indistinguishable, including well developed myofibrils, a delicate network of T-tubules, and a prominent SR which was not yet cross-striated. In diaphragms of E18 dysgenic mice, both the number and size of muscle fibers and myofibrillar organization were deficient in comparison to normal diaphragms, as previously reported. T-tubule labeling was abnormal, showing only scattered tubules and fragments. However, many muscle fibers displayed cross striation of sarcomeric proteins and SR comparable to normal muscle. In cultured myotubes, cross-striated organization of sarcomeric proteins proceeded essentially in two stages: first around the Z-line and later in the A-band. Sarcomeric organization of the SR coincided with the first stage, while the appearance of T-tubules in the mature transverse orientation occurred infrequently, only after A-band maturation. In culture, myofibrillar and membrane organization was equivalent in normal and dysgenic muscle at the earlier stage of development, but half as many dysgenic myotubes reached the later stage as compared to normal. We conclude that the mdg mutation has little effect on the initial stage of membrane and myofibril development and that the deficiencies often seen at later stages result indirectly from the previously described absence of dihydropyridine receptor function in the mutant.

Desmin at myotendinous junctions

Myofibrils are linked to the cell membrane at myotendinous junctions located at the ends of muscle fibers, and at costameres, sites positioned periodically along lateral surfaces of muscle cells. Both of these sites are enriched in proteins that link active components of myofibrils to the cell membrane. Costameres are also enriched in desmin intermediate filaments that link passive components of myofibrils to the lateral surfaces of muscle cells. In this study, the possibility that desmin is also found between the terminal Z-disk of myofibrils and the myotendinous junction membrane is examined by immunocytochemistry and by KI-extraction procedures. Data presented show that desmin is located in the filamentous core of cellular processes at myotendinous junctions at sites 30 nm or more from the membrane. This core lies deep to subsarcolemmal material previously shown to contain talin, vinculin, and dystrophin. The distance from desmin to the membrane suggests desmin does not interact directly with membrane proteins at the junction. Immunoblots and indirect immunofluorescence of junctional regions of muscle compared to nonjunctional regions show no apparent enrichment of desmin at junctional sites, although vinculin, another costameric and junctional component, is significantly enriched at junctional regions. These findings show that passive elements of myofibrils may be continuous from myotendinous junctions of muscle origin to insertion via desmin filaments located between terminal Z-disks and the junctional membrane. This can provide a system in parallel to that involving thin filaments, vinculin, and talin for linking myofibrils to the cell membrane at myotendinous junctions.

Expression and organization of muscle specific proteins during the early developmental stages of the rabbit heart

The expression and intracellular distribution patterns of muscle-specific proteins were studied during rabbit embryo development (7-13 dpc) using monoclonal antibodies against titin, myosin, tropomyosin and actin, as well as the intermediate filament proteins desmin, keratin and vimentin. From our panel, titin appeared to be the first muscle-specific protein to be exclusively expressed in the embryonic rabbit heart. Upon differentiation (myocyte and myotube formation), titin reorganizes from dot-like aggregates into a cross-striated pattern (in 9- to 30-somite embryos) via a transiently filamentous distribution. When the expression and organization of the other muscle proteins was studied in relation to titin, it became apparent that tropomyosin followed upon titin with respect to its exclusive expression in the heart anlagen and its organization into a striated pattern. Myosin and desmin were organized into cross-striated patterns after titin and tropomyosin, but this arrangement had not reached its final form in 13-dpc embryos. Actin, keratin and vimentin were distributed in cytoplasmic filaments in the embryonic stages we investigated. Since the first pulsations are already detected in 3-somite embryos, we conclude that the organization of titin, tropomyosin, myosin and desmin into a striated pattern does not seem to be essential for the initiation of muscle cell contraction in the heart anlagen. Furthermore, this study shows that, in comparison with studies on mouse, chick and rat, the sequence of expression of muscle-specific and intermediate filament proteins during cardiomyogenesis is species-dependent, and that their expression and organization varies in time in different regions of the developing heart.

MyoD, myogenin independent differentiation of primordial myoblasts in mouse somites

The accumulation of two myogenic regulatory proteins, MyoD and myogenin, was investigated by double-immunocytochemistry and correlated with myosin heavy chain expression in different classes of myoblasts in culture and during early myogenesis in vivo. During in vitro differentiation of fetal myoblasts, MyoD-positive cells were detected first, followed by the appearance of cells positive for both MyoD and myogenin and finally by the appearance of differentiated myocytes and myotubes expressing myosin heavy chain (MHC). A similar pattern of expression was observed in cultures of embryonic and satellite cells. In contrast, most myogenic cells isolated from newly formed somites, expressed MHC in the absence of detectable levels of myogenin or MyoD. In vivo, the appearance of both myogenin and MyoD proteins was only detected at 10.5 d postcoitum (d.p.c.), when terminally differentiated muscle cells could already be identified in the myotome. Parasagittal sections of the caudal myotomes of 10.5-d-old embryos showed that expression of contractile proteins preceded the expression of myogenin or MyoD and, when coexpressed, MHC and myogenin did not co-localize within all the cells of the myotome. In the limb bud, however, many myogenin (or MyoD) positive/MHC negative cells could be observed in the proximal region at day 11. During further embryonic development the expression of these proteins remained constant in all the muscle anlagens examined, decreasing to a low level during the late fetal period. Western and Northern analysis confirmed that the myogenin protein could only be detected after 10.5 d.p.c. while the corresponding message was clearly present at 9.5 d.p.c., strongly suggesting a posttranscriptional regulation of myogenin during this stage of embryonic development. These data show that the first myogenic cells which appear in the mouse myotome, and can be cultured from it, accumulate muscle structural proteins in their cytoplasm without expressing detectable levels of myogenin protein (although the message is clearly accumulated). Neither MyoD message or protein are detectable in these cells, which may represent a distinct myogenic population whose role in development remains to be established.

Spatial relationship of nebulin relative to other myofibrillar proteins during myogenesis in embryonic chick skeletal muscle cells in vitro

The developmental expression of nebulin was studied in embryonic chick skeletal muscle cells in vitro by means of immunofluorescence microscopy. Initially nebulin appeared homogeneously or in a punctate form in the cytoplasm, and then it was assembled into I-Z-I-like complexes containing actin and alpha-actinin but not myosin and connectin (titin). Striated patterns of nebulin ('singlets') in myofibrils appeared simultaneously with those of alpha-actinin (Z-bands), myosin (A-bands) and connectin ('doublets'), but earlier than those of actin. After actin striations were formed as myofibrils matured, each nebulin band started to exhibit 'droplets'. The delayed development of nebulin compared to the I-Z-I brush formation and the myofibril maturation seems to indicate that this giant myofibrillar protein is unnecessary for both the initial (formation of I-Z-I-like structures) and the subsequent (regular alignment of myofibrils) phases of myofibrillogenesis.