Assembly of connectin (titin) in relation to myosin and alpha-actinin in cultured cardiac myocytes

Exon- and contraction-dependent functions of titin in sarcomere assembly

Titin-truncating variants (TTNtvs) are the major cause of dilated cardiomyopathy (DCM); however, allelic heterogeneity (TTNtvs in different exons) results in variable phenotypes, and remains a major hurdle for disease diagnosis and therapy. Here, we generated a panel of ttn mutants in zebrafish. Four single deletion mutants in ttn.2 or ttn.1 resulted in four phenotypes and three double ttn.2/ttn.1 mutants exhibited more severe phenotypes in somites. Protein analysis identified ttn^xu071 as a near-null mutant and the other six mutants as hypomorphic alleles. Studies of ttn^xu071 uncovered a function of titin in guiding the assembly of nascent myofibrils from premyofibrils. By contrast, sarcomeres were assembled in the hypomorphic ttn mutants but either became susceptible to biomechanical stresses such as contraction or degenerated during development. Further genetic studies indicated that the exon usage hypothesis, but not the toxic peptide or the Cronos hypothesis, could account for these exon-dependent effects. In conclusion, we modeled TTNtv allelic heterogeneity during development and paved the way for future studies to decipher allelic heterogeneity in adult DCM.

The GSTM2 C-Terminal Domain Depresses Contractility and Ca2+ Transients in Neonatal Rat Ventricular Cardiomyocytes

The cardiac ryanodine receptor (RyR2) is an intracellular ion channel that regulates Ca²⁺ release from the sarcoplasmic reticulum (SR) during excitation–contraction coupling in the heart. The glutathione transferases (GSTs) are a family of phase II detoxification enzymes with additional functions including the selective inhibition of RyR2, with therapeutic implications. The C-terminal half of GSTM2 (GSTM2C) is essential for RyR2 inhibition, and mutations F157A and Y160A within GSTM2C prevent the inhibitory action. Our objective in this investigation was to determine whether GSTM2C can enter cultured rat neonatal ventricular cardiomyocytes and influence contractility. We show that oregon green-tagged GSTM2C (at 1 μM) is internalized into the myocytes and it reduces spontaneous contraction frequency and myocyte shortening. Field stimulation of myocytes evoked contraction in the same percentage of myocytes treated either with media alone or media plus 15 μM GSTM2C. Myocyte shortening during contraction was significantly reduced by exposure to 15 μM GSTM2C, but not 5 and 10 μM GSTM2C and was unaffected by exposure to 15 μM of the mutants Y160A or F157A. The amplitude of the Ca²⁺ transient in the 15 μM GSTM2C - treated myocytes was significantly decreased, the rise time was significantly longer and the decay time was significantly shorter than in control myocytes. The Ca²⁺ transient was not altered by exposure to Y160A or F157A. The results are consistent with GSTM2C entering the myocytes and inhibiting RyR2, in a manner that indicates a possible therapeutic potential for treatment of arrhythmia in the neonatal heart.

CUG-BP, Elav-like family member 1 (CELF1) is required for normal myofibrillogenesis, morphogenesis, and contractile function in the embryonic heart

BACKGROUND

CUG-BP, Elav-like family member 1 (CELF1) is a multifunctional RNA binding protein found in a variety of adult and embryonic tissues. In the heart, CELF1 is found exclusively in the myocardium. However, the roles of CELF1 during cardiac development have not been completely elucidated.

RESULTS

Myofibrillar organization is disrupted and proliferation is reduced following knockdown of CELF1 in cultured chicken primary embryonic cardiomyocytes. In vivo knockdown of Celf1 in developing Xenopus laevis embryos resulted in myofibrillar disorganization and a trend toward reduced proliferation in heart muscle, indicating conserved roles for CELF1 orthologs in embryonic cardiomyocytes. Loss of Celf1 also resulted in morphogenetic abnormalities in the developing heart and gut. Using optical coherence tomography, we showed that cardiac contraction was impaired following depletion of Celf1, while heart rhythm remained unperturbed. In contrast to cardiac muscle, loss of Celf1 did not disrupt myofibril organization in skeletal muscle cells, although it did lead to fragmentation of skeletal muscle bundles.

CONCLUSIONS

CELF1 is required for normal myofibril organization, proliferation, morphogenesis, and contractile performance in the developing myocardium. Developmental Dynamics 245:854-873, 2016. © 2016 Wiley Periodicals, Inc.

Morphological Modifications in Myofibrils by Suppressing Tropomyosin 4α in Chicken Cardiac Myocytes

Tropomyosin (TPM) localizes along F-actin and, together with troponin T (TnT) and other components, controls calcium-sensitive muscle contraction. The role of the TPM isoform (TPM4α) that is expressed in embryonic and adult cardiac muscle cells in chicken is poorly understood. To analyze the function of TPM4α in myofibrils, the effects of TPM4α-suppression were examined in embryonic cardiomyocytes by small interference RNA transfection. Localization of myofibril proteins such as TPM, actin, TnT, α-actinin, myosin and connectin was examined by immunofluorescence microscopy on day 5 when almost complete TPM4α-suppression occurred in culture. A unique large structure was detected, consisting of an actin aggregate bulging from the actin bundle, and many curved filaments projecting from the aggregate. TPM, TnT and actin were detected on the large structure, but myosin, connectin, α-actinin and obvious myofibril striations were undetectable. It is possible that TPM4α-suppressed actin filaments are sorted and excluded at the place of the large structure. This suggests that TPM4α-suppression significantly affects actin filament, and that TPM4α plays an important role in constructing and maintaining sarcomeres and myofibrils in cardiac muscle.

The sarcomere and sarcomerogenesis

Striated muscle owes its name to the microscopic appearance, caused by the longitudinal alignment of thousands of highly ordered contractile units, the sarcomeres. The assembly (and disassembly) of these multiprotein complexes (sarcomere assembly or sarcomerogenesis) follows ordered pathways, which are regulated on the transcriptional, translational and posttranslational level. Furthermore, myofibril assembly involves the participation of transient scaffolds and adaptors, notably the microtubule network. Studies in cell culture and developing embryos have revealed common pathways of sarcomere assembly in heart and skeletal muscle. Disruptions in these pathways are implicated in muscle diseases.

N-RAP scaffolds I-Z-I assembly during myofibrillogenesis in cultured chick cardiomyocytes

N-RAP is a muscle-specific protein with an N-terminal LIM domain (LIM), C-terminal actin-binding super repeats homologous to nebulin (SR) and nebulin-related simple repeats (IB) in between the two. Based on biochemical data, immunofluorescence analysis of cultured embryonic chick cardiomyocytes and the targeting and phenotypic effects of these individual GFP-tagged regions of N-RAP, we proposed a novel model for the initiation of myofibril assembly in which N-RAP organizes alpha-actinin and actin into the premyofibril I-Z-I complexes. We tested the proposed model by expressing deletion mutants of N-RAP (i.e. constructs containing two of the three regions of N-RAP) in chick cardiomyocytes and observing the effects on alpha-actinin and actin organization into mature sarcomeres. Although individually expressing either the LIM, IB, or SR regions of N-RAP inhibited alpha-actinin assembly into Z-lines, expression of either the LIM-IB fusion or the IB-SR fusion permitted normal alpha-actinin organization. In contrast, the LIM-SR fusion (LIM-SR) inhibited alpha-actinin organization into Z-lines, indicating that the IB region is critical for Z-line assembly. While permitting normal Z-line assembly, LIM-IB and IB-SR decreased sarcomeric actin staining intensity; however, the effects of LIM-IB on actin assembly were significantly more severe, as estimated both by morphological assessment and by quantitative measurement of actin staining intensity. In addition, LIM-IB was consistently retained in mature Z-lines, while mature Z-lines without significant IB-SR incorporation were often observed. We conclude that the N-RAP super repeats are essential for organizing actin filaments during myofibril assembly in cultured embryonic chick cardiomyocytes, and that they also play an important role in removal of the N-RAP scaffold from the completed myofibrillar structure. This work strongly supports the N-RAP scaffolding model of premyofibril assembly.

Dynamics of actin and alpha-actinin in nascent myofibrils and stress fibers

Actin labeled with fluorescein isothiocyanate (FITC) and alpha-actinin labeled with rhodamine (rh) were co-injected into chick embryonic cardiac myocytes and fibroblasts. In cardiomyocytes, FITC-actin was distributed in nonstriated lines, linearly arranged punctate structures with short intervals, and cross-striated bands with regular sarcomeric intervals. rh-alpha-Actinin was seen to be distributed in the same pattern in the former two portions, and in the center of each striation in the latter portion. Photobleaching of structures incorporated with these fluorescent analogs revealed that the fluorescent recovery rate of actin decreased in the order of nonstriated > punctated > striated portions, while that of alpha-actinin was low and stable at all portions. During the transition phase from punctate to regular sarcomere structures of these proteins, short spaced alpha-actinin dots adjoined each other and aligned with Z bands of neighboring myofibrils. It appears that both the difference in exchangeability between actin and alpha-actinin molecules and the movement of alpha-actinin dots during this phase of myofibrillogenesis are related to sarcomere lengthening and I-Z-I brush formation; adjoining dots of low-exchangeable alpha-actinin may provide favorable situations for exchangeable actin molecules in filaments to elongate and/or rearrange. In fibroblasts, both FITC-actin and rh-alpha-actinin formed nonstriated lines. In these cells, exchangeabilities of both proteins were high and similar in rate. This seems to indicate that stress fibers are constantly exchanging their components for motile and other vital functions of these cells. The high exchangeabilities of both proteins in stress fibers showthat these fibers are clearly different from nonstriated, stress-fiber like structures of nascent myofibrils.

The second EF-hand is responsible for the isoform-specific sorting of myosin essential light chain

It has been known that isoforms of myosin essential light chain (LC) exhibit the isoform-specific sorting within cardiac myocytes and fibroblasts. In order to analyze which domain of LC is responsible for the sorting, various chimeric cDNA constructs between human nonmuscle isoform (LC3nm) and chicken fast skeletal muscle isoform (LC3f) were generated and expressed in cultured chicken cardiac myocytes. If chimeras contained LC3f sequence at the place that was restricted by BssHII and PstI, they were preferentially sorted to sarcomeres and precisely localized at A-bands, and their incorporation levels into the A-bands were identical with that of the wild type LC3f. However, other chimeras were distributed throughout the cytoplasm like the wild type LC3nm. Comparison of amino acid sequences revealed that 12 amino acids are different between chicken LC3f and human LC3nm in the BssHII-PstI fragment, and these amino acids are located within the second EF-hand of LC. These results indicated that the second EF-hand is responsible for the isoform-specific sorting of LC. Although the second EF-hand is not included in the key contacts with myosin heavy chain, it is supposed that this domain is important for the relative disposition of neighboring domains. Thus, the 12 amino acids in the second EF-hand might play a key role for modulation of overall configuration of LC, thereby influencing the precise association of the key contacts.

Developmental relationship of myosin binding proteins (myomesin, connectin and C-protein) to myosin in chicken somites as studied by immunofluorescence microscopy

The developmental relationship of myosin binding proteins (myomesin, connectin and C-protein) to myosin was studied in chicken cervical somites by immunofluorescence microscopy. Muscle and non-muscle myosins initially appeared as slender rods at the same sites, and then, fused to form non-striated fibrils. As muscle myosin formed striated structures (A bands), non-muscle myosin disappeared from this structure. Myomesin (reactive with monoclonal antibodies MyB4 and MyBB78) and connectin (carboxy terminal region, reactive with monoclonal antibody T51) were seen as dots in the center of these myosin rods. These proteins then formed characteristic mature striations on non-striated fibrils of myosin. Earlier alignment of these myosin binding proteins rather than myosin indicates that the correct assembly of these proteins seems to be related to the formation of initial myosin rods as well as subsequent linear and periodic alignment of myosin molecules to form early A bands. Connectin spots reactive with 9D10 were scattered around myosin rods/myomesin dots/connectin T51 dots. These spots may represent radiating connectin filaments from these rods/dots to link myosin rods to the I-Z-I structures of myofibrils to be incorporated. Since the slow isoform of C-protein formed its characteristic bands ("doublets") prior to H zone formation within A bands by myosin, this isoform may help to precisely align myosin filaments within the A band region. The presence of the slow, then the slow and the cardiac, and finally the co-existence of the slow and the fast isoforms of C-protein may interfere with the incorporation and co-polymerization of non-adult isoforms into myofibrils.

Fast skeletal muscle isoforms exhibit the highest incorporation level into myofibrils and stress fibers among members of myosin alkali light chain isoform family

Isoproteins of myosin alkali light chain (LC) were co-expressed in cultured chicken cardiomyocytes and fibroblasts and their incorporation levels into myofibrils and stress fibers were compared among members of the LC isoform family. In order to distinguish each isoform from the other, cDNAs of LC isoforms were tagged with different epitopes. Expressed LCs were detected with antibodies to the tags and their distribution was analyzed by confocal microscopy. In cardiomyocytes, the incorporation level of LC into myofibrils was shown to increase in the order from nonmuscle isoform (LC3nm), to slow skeletal muscle isoform (LC1sa), to slow skeletal/ventricular muscle isoform (LC1sb), and to fast skeletal muscle isoforms (LC1f and LC3f). Thus, the hierarchal order of the LC affinity for the cardiac myosin heavy chain (MHC) is identical to that obtained in the rat (Komiyama et al., 1996. J. Cell Sci., 109: 2089-2099), suggesting that this order may be common for taxonomic animal classes. In fibroblasts, the affinity of LC for the nonmuscle MHC in stress fibers was found to increase in the order from LC3nm, to LC1sb, to LC1sa, and to LC1f and LC3f. This order for the nonmuscle MHC is partly different from that for the cardiac MHC. This indicates that the order of the affinity of LC isoproteins for MHC varies depending on the MHC isoform. Further, for both the cardiac and nonmuscle MHCs, the fast skeletal muscle LCs exhibited the highest affinity. This suggests that the fast skeletal muscle LCs may be evolved isoforms possessing the ability to associate tightly with a variety of MHC isoforms.

Ca2+/calmodulin-dependent kinase II and calcineurin play critical roles in endothelin-1-induced cardiomyocyte hypertrophy

Endothelin-1 (ET-1) induces cardiac hypertrophy. Because Ca(2+) is a major second messenger of ET-1, the role of Ca(2+) in ET-1-induced hypertrophic responses in cultured cardiac myocytes of neonatal rats was examined. ET-1 activated the promoter of the beta-type myosin heavy chain gene (beta-MHC) (-354 to +34 base pairs) by about 4-fold. This activation was inhibited by chelation of Ca(2+) and the blocking of protein kinase C activity. Similarly, the beta-MHC promoter was activated by Ca(2+) ionophores and a protein kinase C activator. beta-MHC promoter activation induced by ET-1 was suppressed by pretreatment with the calmodulin inhibitor, W7, the Ca(2+)/calmodulin-dependent kinase II (CaMKII) inhibitor, KN62, and the calcineurin inhibitor, cyclosporin A. beta-MHC promoter activation by ET-1 was also attenuated by overexpression of dominant-negative mutants of CaMKII and calcineurin. ET-1 increased the activity of CaMKII and calcineurin in cardiac myocytes. Pretreatment with KN62 and cyclosporin A strongly suppressed ET-1-induced increases in [(3)H]phenylalanine uptake and in cell size. These results suggest that Ca(2+) plays a critical role in ET-1-induced cardiomyocyte hypertrophy by activating CaMKII- and calcineurin-dependent pathways.

Initiation and maturation of I-Z-I bodies in the growth tips of transfected myotubes

While over a dozen I-Z-I proteins are expressed in postmitotic myoblasts and myotubes it is unclear how, when, or where these first assemble into transitory I-Z-I bodies (thin filament/Z-band precursors) and, a short time later, into definitive I-Z-I bands. By double-staining the growth tips of transfected myotubes expressing (a) MYC-tagged s-alpha-actinins (MYC/s-alpha-actinins) or (b) green fluorescent protein-tagged titin cap (GFP/T-cap) with antibodies against MYC and I-Z-I band proteins, we found that the de novo assembly of I-Z-I bodies and their maturation into I-Z-I bands involved relatively concurrent, cooperative binding and reconfiguration of, at a minimum, 5 integral Z-band molecules. These included s-alpha-actinin, nebulin, titin, T-cap and alpha-actin. Resolution of the approximately 1.0 microm polarized alpha-actin/nebulin/tropomyosin/troponin thin filament complexes occurred subsequent to the maturation of Z-bands into a dense tetragonal configuration. Of particular interest is finding that mutant MYC/s-alpha-actinin peptides (a) lacking spectrin-like repeats 1–4, or consisting of spectrin-like repeats 1–4 only, as well as (b) mutants/fragments lacking titin or alpha-actin binding sites, were promptly and exclusively incorporated into de novo assembling I-Z-I bodies and definitive I-Z-I bands as was exogenous full length MYC/s-alpha-actinin or GFP/T-cap.

Relation of nebulin and connectin (titin) to dynamics of actin in nascent myofibrils of cultured skeletal muscle cells

Cultured embryonic chicken skeletal muscle cells microinjected with rhodamine (rh)-labeled actin were stained with antibodies against nebulin and connectin (titin). In premyofibril areas, nebulin was observed as dotted structures, many of which were arranged in a linear fashion. These structures were associated with injected rh-actin. Among these linearly arranged dots of nebulin and rh-actin, numerous small nebulin dots without rh-actin incorporation were scattered. It is probable that the dots of nebulin and/or its associated protein(s) represent a preformed scaffold upon which actin monomers accumulate; exogenously introduced actin associates initially with small nebulin dots, which in turn coalesce to form rh-actin dots and are arranged linearly. In developing myofibrils, two patterns of nebulin distribution were found: "singlets" and "doublets." Recovery of rh-actin's fluorescence after photobleaching was slowest in the nonstriated dotted portions, followed by the striated myofibrillar portions with nebulin singlets and those with doublets, in that order. Thus, the distribution patterns of nebulin seem to be related to the accessibility/exchangeability of actin into nascent myofibrils. It is possible that early nebulin filaments exhibiting singlets are not tightly associated with actin filaments and that this loose association allows myofibrils to exchange nonadult isoforms of actin and other proteins into adult types. Connectin formed a striated pattern before the formation of rh-actin/nebulin striations. It appears that connectin does not have any significant role in the accessibility of actin into nascent myofibrils.

Thick filament assembly occurs after the formation of a cytoskeletal scaffold

The development of myofibrils involves the formation of contractile filaments and their assembly into the strikingly regular structure of the sarcomere. We analysed this assembly process in cultured human skeletal muscle cells and in rat neonatal cardiomyocytes by immunofluorescence microscopy using antibodies directed against cytoskeletal and contractile proteins. In particular, the question in which temporal order the respective proteins are integrated into developing sarcomeres was addressed. Although sarcomeric myosin heavy chain is expressed as one of the first myofibrillar proteins, its characteristic A band arrangement is reached at a very late stage. In contrast, titin, then myomesin and finally C-protein (MyBP-C) gradually form a regularly arranged scaffold on stress fiber-like structures (SFLS), on non-striated myofibrils (NSMF) and on nascent striated myofibrils (naSMF). Immediately subsequent to the completion of sarcomere cytoskeleton formation, the labeling pattern of myosin changes from the continuous staining of SFLS to the periodic staining characteristic for mature myofibrils. This series of events can be seen most clearly in the skeletal muscle cell cultures and--probably due to a faster developmental progression less well in cardiomyocytes. We therefore conclude that the correct assembly of a cytoskeletal scaffold is a prerequisite for correct thick filament assembly and for the integration of the contractile apparatus into the myofibril.

Exchangeability of actin in cardiac myocytes and fibroblasts as determined by fluorescence photobleaching recovery

Rhodamine (Rho)-labeled muscle and non-muscle actins were microinjected into cultured embryonic chicken cardiac myocytes and fibroblasts. After incorporation of the fluorescent actin analog into cellular structures, small areas of labeled structures were photobleached with a laser pulse, and fluorescence recovery (FR) was measured to determine the exchangeability of isoactins in these structures. With both Rho-muscle and Rho-non-muscle actins, the FR rate in any part of stress fibers was consistently faster than that observed in any part of myofibrils. Thus, although non-striated (proximal and terminal) portions of nascent myofibrils are similar in appearance and composition to stress fibers, our data clearly revealed differences in actin stability between these two structures. Further, although cardiomyocytes were incapable of discriminating between the incorporation of muscle and non-muscle actin isoforms into myofibrils, FR after photobleaching of Rho-muscle actin was faster than that of Rho-non-muscle actin in immature non-striated portions. This indicates that actin molecules in cardiac myofibrils cannot be readily exchanged by heterotypic non-muscle actin. Fluorescently labeled actin incorporated into non-striated (proximal and terminal) portions of myofibrils and terminal portions of stress fibers was found to be more stable than alpha-actinin. The relative stability of actin could facilitate the formation of nascent Z-bands of myofibrils and the reorganization of stress fibers at these portions.

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.

Cytoplasmic body myopathy: familial cases with accumulation of desmin and dystrophin. An immunohistochemical, immunoelectron microscopic and biochemical study

Muscle biopsy samples from five patients with cytoplasmic body myopathy (CBM) were investigated by immunohistochemical (antibodies to desmin, actin, dystrophin, spectrin, alpha actinin and utrophin), immunoelectron microscopic (antibodies to desmin, actin and dystrophin) and biochemical (desmin, dystrophin, actin and utrophin western blots) methods. Using immunofluorescence it was shown that the centers of cytoplasmic bodies (CB) were stained by anti-actin, anti-utrophin and three different anti-dystrophin antibodies. The peripheries were labeled by the anti-desmin antibody. Moreover, fibers containing CB showed a markedly increased staining of their entire sarcoplasm with the anti-desmin antibody. Using immunoelectron microscopy it was shown that anti-dystrophin antibodies selectively stained the external limit of the central granular region. Anti-desmin antibody labeled the filamentous halo, and anti-actin antibody stained the central core and the radiating filaments. Biochemical studies showed storage of desmin and dystrophin, both of normal molecular weight. Our results suggest that CBM should be considered along with a wider group of intermediate filament pathologies that include desmin-storage myopathies.

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.

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.

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.

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)

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.

The distribution of desmin and titin in normal and dystrophic human muscle

We have used monoclonal antibodies to desmin and titin, and a combination of immunofluorescence and immunogold labelling to study the disposition of these two proteins in normal human muscle fibres and in fibres at various stages of degeneration in dystrophic muscle. The normal pattern of desmin labelling, in particular the subsarcolemmal labelling, became disrupted at an early stage of fibre breakdown. There was a change from a transverse to a longitudinal orientation of the labelled intermediate filaments as the myofibrils sheared relative to one another. Thus, while it is probable that the desmin filaments are able to play a role in the mechanical integration of the myofibrils in healthy muscle, our results suggest that they cannot withstand the excessive forces generated by the hypercontraction and stretching of dystrophic muscle. However, small accumulations of desmin persisted between the damaged myofibrils until necrosis reached an advanced stage. In general, the degradation of titin appeared to occur before the degradation of desmin, and at the ultrastructural level, labelling with antibodies to epitopes from parts of the titin molecule close to the A-I-band junction was lost before labelling with an antibody to an epitope in the A-band. This suggests that different regions of the titin molecule break down at different stages in the breakdown of the fibre. We propose that lysis of titin in the I-band may underlie 'slippage', an abnormality often seen in dystrophic muscle, in which the A-band slips to one pole of the sarcomere such that it abuts onto the Z-line. Breakdown of the A-band section of titin may facilitate the disassembly of the A-filaments.