Takashi Obinata

Identification of an Actin Binding Region and a Protein Kinase C Phosphorylation Site on Human Fascin

Fascin is a 55-58-kDa actin-bundling protein, the actin binding of which is regulated by phosphorylation (Yamakita, Y., Ono, S., Matsumura, F., and Yamashiro, S. (1996) J. Biol. Chem. 271, 12632-12638). To understand the mechanism of fascin-actin interactions, we dissected the actin binding region and its regulatory site by phosphorylation of human fascin. First, we found that the C-terminal half constitutes an actin binding domain. Partial digestion of human recombinant fascin with trypsin yielded the C-terminal fragment with molecular masses of 32, 30, and 27 kDa. The 32- and 27-kDa fragments purified as a mixture formed a dimer and bound to F-actin at a saturation ratio of 1 dimer:11 actin molecules with an affinity of 1.4 × 106 M−1. Second, we identified the phosphorylation site of fascin as Ser-39 by sequencing a tryptic phosphopeptide purified by chelating column chromatography followed by C-18 reverse phase high performance liquid chromatography. Peptide map analyses revealed that the purified peptide represented the major phosphorylation site of in vivo as well as in vitro phosphorylated fascin. The mutation replacing Ser-39 with Ala eliminated the phosphorylation-dependent regulation of actin binding of fascin, indicating that phosphorylation at this site regulates the actin binding ability of fascin.

Thyroid hormone regulates developmental changes in muscle during flounder metamorphosis

Morphological and biochemical changes in the muscular tissue of metamorphosing flounder were studied in relation to the regulatory role of thyroid hormone. Premetamorphic larvae were reared in seawater alone or seawater containing either thyroxine (T4) or an antithyroid drug (thiourea, TU). Histological changes in the muscle were examined and biochemical changes in the muscle proteins were evaluated by SDS-PAGE and immunoblotting for troponin T (TNT). The muscle tissue of premetamorphic larvae was characterized by abundant vacuoles and basophilic sarcoplasm. In control fish, the larval muscle transformed into the adult type during metamorphic climax; the fibers were filled with abundant myofibrils and the vacuoles disappeared. Analysis by SDS-PAGE showed that the bands at 41.5, 35.5, 34.0, 33.5, 25.5, 23.0, 20.0, and 19.0 kDa clearly increased in density from the climax stage. Premetamorphic larvae possessed two immunoreactive TNT isoforms of 41.5 and 34.0 kDa, the former being predominant. At the climax stage an additional isoform appeared at 33.5 kDa, and the 34.0- and 33.5-kDa TNT became predominant. The administration of T4 precociously induced these histological and biochemical changes in the muscle tissue of flounder larvae. In contrast, TU treatment inhibited these developmental changes in the larval muscle. Our results suggest that the developmental changes in the muscular tissue of metamorphosing flounder are regulated by thyroid hormone.

Complete primary structure of chicken cardiac C-protein (MyBP-C) and its expression in developing striated muscles

C-protein (MyBP-C) is a myosin binding protein of about 140 kDa which is known to modulate myosin assembly in striated muscles. A cardiac-type isoform of C-protein appears not only in cardiac muscle but also in skeletal muscle before skeletal muscle-type isoforms become detectable during myogenesis, suggesting that the cardiac isoform is involved in the early phase of myofibrillogenesis (Bähler et al., 1985; Kawashima et al., 1986). In this study, in order to understand the structure and functional domains of the cardiac-type C-protein, we cloned and sequenced full-length cDNAs encoding chicken cardiac C-protein from lambda gt11 cDNA libraries which were prepared with poly (A)+ RNA from embryonic chicken cardiac muscle as well as embryonic chicken skeletal muscle by using antibodies specific for cardiac C-protein. Two cDNA variants, probably generated by alternative RNA splicing and encoding different C-protein isoforms, were detected. As judged by the cDNA sequences determined, overall homology of the peptide sequence between cardiac and skeletal muscle C-proteins (Einheber et al., 1990; Fürst et al., 1992, Weber et al., 1994) was about 50-55%. Like other myosin binding proteins, skeletal C-proteins, 86 kDa protein and M-protein, cardiac C-protein contains several copies of fibronectin type III motifs and immunoglobulin C2 motifs in the molecule, but their number and arrangements differed somewhat from those in the other proteins. Northern blot analysis with the cloned cDNA as a probe demonstrated that mRNA of 5.0 kb is transcribed in both cardiac and embryonic skeletal muscle, and that it is specifically expressed in cardiac muscle among adult tissues.

Types of troponin components during development of chicken skeletal muscle

Abstract Changes in troponin components during development of chicken skeletal muscles have been investigated by using electrophoretic, immunoelectrophoretic, and immunoelectron microscopic methods. Previous reports ( S. V. Perry and H. A. Cole, 1974, Biochem. J. 141, 733–743 ; J. M. Wilkinson, 1978, Biochem. J. 169, 229–238 ) pointed out that breast and leg muscles of adult chicken contain different types of troponin-T (TN-T), i.e., breast- and leg-type TN-T, respectively. However, the present paper indicates that the embryonic breast muscle contains leg-type TN-T. As development progresses two types of TN-T, i.e., breast- and leg-type TN-T, are found, and finally breast-type TN-T becomes the only species of TN-T present in the breast muscle. This change is well coordinated with the change of tropomyosin in the breast muscle. In contrast, the leg muscle contains leg-type TN-T through all the developmental stages. Leg-type TN-T is present in myogenic cells in vitro, irrespective of their origin, whether from the breast or leg muscle. The types of troponin-I and troponin-C in both breast and leg muscles do not change during development. The significance of the changes in the types of TN-T is discussed in terms of differential gene expression during development of chicken breast and leg muscles.

Myogenesis and histogenesis of skeletal muscle on flexible membranes in vitro.

SummaryPrimary muscle cell cultures consisting of single myocytes and fibroblasts are grown on flexible, optically clear biomembranes. Muscle cell growth, fusion and terminal differentiation are normal. A most effective membrane for these cultures is commercially available Saran Wrap. Muscle cultures on Saran will, once differentiated, contract vigorously and will deform the Saran which is pinned to a Sylgard base. At first, the muscle forms a two-dimensional network which ultimately detaches from the Saran membrane allowing an undergrowth of fibroblasts so that these connective tissue cells completely surround groups of muscle fibers. A three-dimensional network is thus formed, held in place through durable adhesions to stainless steel pins. This three-dimensional, highly contractile network is seen to consist of all three connective tissue compartments seenin vivo, the endomysium, perimysium and epimysium. Finally, this muscle shows advanced levels of maturation in that neonatal and adult isoforms of myosin heavy chain are detected together with high levels of myosin fast light chain 3.

SITE-DIRECTED MUTAGENESIS OF THE PHOSPHORYLATION SITE OF COFILIN : ITS ROLE IN COFILIN-ACTIN INTERACTION AND CYTOPLASMIC LOCALIZATION

It has been demonstrated that the activity of ADF and cofilin, which constitute a functionally related protein family, is markedly altered by phosphorylation, and that the phosphorylation site is Ser 3 in their amino acid sequences [Agnew et al., 1995: J. Biol. Chem. 270:17582-17587; Moriyama et al., 1996: Genes Cells 1:73-86]. In order to clarify the function of the phosphorylated and unphosphorylated forms of cofilin in living cells especially in the process of cytokinesis, we generated analogs of the unphosphorylated form (A3-cofilin) and phosphorylated form (D3-cofilin) by converting the phosphorylation site (Ser 3) of cofilin to Ala and Asp, respectively. The mutated proteins were produced in an Escherichia coli expression system, and conjugated with fluorescent dyes. In in vitro functional assay, labeled A3-cofilin retained the authentic ability to bind to and sever F-actin, while labeled D3-cofilin failed to interact with actin. They were then injected into living cells to examine their cellular distribution. They exhibited distinct localization patterns in the cytoplasm; A3-cofilin was highly concentrated at the membrane ruffles and cleavage furrow, where endogenous cofilin is also known to be enriched. In contrast, D3-cofilin showed only diffuse distribution both in the cytoplasm and nucleus. These results suggest that the subcellular distribution of cofilin as well as its interacting with actin in vivo is regulated by its phosphorylation and dephosphorylation.

Colocalization of ADF and cofilin in intranuclear actin rods of cultured muscle cells

SummaryImmunofluorescence microscopy revealed that two actin-binding proteins of low molecular weight with different functional activity. ADF and cofilin, are transported into nuclei of cultured myogenic cells to form rod structures there together with actin, when the cells were incubated in medium containing dimethylsulfoxide. In most cases, ADF and cofilin colocalized in the same nuclear actin rods, but ADF appeared to predominate in mononucleated cells, while cofilin was present in multinucleated myotubes. In some mononucleated cells, the nuclear actin rods were composed of ADF and actin but devoid of cofilin. An ADF homologue in mammals, destrin, was also translocated into nuclear actin rods under similar conditions. As a nuclear transport signal sequence exists in cofilin and ADF but not in actin, ADF and/or cofilin may be responsible for the nuclear import of actin in myogenic cells under certain conditions.

Generation of functional beta-actinin (CapZ) in an E. coli expression system.

Abstractβ-actinin (CapZ) is a heterodimeric actin-binding protein which caps the barbed end of actin filaments and nucleates actin-polymerization in a Ca2+-independent manner. In myofibrils it is localized in the Z-lines. As judged by these properties of β-actinin, it is conceivable that β-actinin is involved in the regulation of actin assembly, especially in the formation of I-Z-I complex during myofibrillogenesis. In this study, we devised a system to produce functional β-actinin in E. Coli.The cDNAs of βI′ and βII subunits of β-actinin were obtained by RT-PCR methods using the published sequence as references, and subcloned in a pET vector. When the proteins were produced with the cDNA of either βI′ or βII in E. coli, the proteins were insoluble and non-functional. However, when the cDNAs encoding the two subunits were cloned into a single vector and␣both proteins were expressed simultaneously, the proteins became soluble and purified as a functional heterodimer. The␣activity of the purified proteins was not distinguishable from that of β-actinin purified from skeletal muscle.

The identification of randomly formed thin filaments in differentiating muscle cells of the chick embryo.

Abstract The appearance of thin filaments, 60–80 A in width, in the myoblasts of early chick embryos incubated for 3 days at 39°C was observed with the electron microscope. The filaments were distributed randomly throughout the cytoplasmic matrix of the myoblasts where myofibrils had not yet been formed. These filaments were isolated from 4-day embryos by differential centrifugation; they were found in the top layers of the so-called “microsomal fraction.” The fraction showed considerable flow birefringence and an ATPase activity. Mixing of the fraction with rabbit myosin caused marked increase in the flow birefringence, and the addition of ATP to the mixture in 0.6 M KCl solution resulted in a decrease in the birefringence. The ATPase activity of myosin was enhanced about 100% by the addition of the fraction at low ionic strength. No changes in birefringence or ATPase activity took place when actin was added to the fraction. The demonstration of the reaction of the “microsomal fraction” with added myosin strongly suggests that the thin filaments in question are F-actin filaments.

Distribution of microtubules and other cytoskeletal filaments during myotube elongation as revealed by fluorescence microscopy

SummaryDistribution of microtubules and other cytoskeletal filaments in growing skeletal muscle cells (myotubes) was studied in vitro by fluorescence microscopy using fluorescin-labeled antibodies and phalloidin, a specific antiactin drug. In the distal elongating tips of myotubes, microtubules were the major cytoskeletal elements; actin and intermediate filaments were much less abundant. On the other hand, colcemidand nocodozole-treatments caused disruption of microtubules and also prompt retraction of growth tips to form myosacs, a type of deformed myotube. Actin filaments remained unaffected during the retraction. The difference in the distribution of the 3 cytoskeletal filaments in the region of growth tips was most remarkable in the case of those myotubes in the process of recovery from myosacs. In an early phase of recovery, the cellular processes extending from myosacs were enriched with both microtubules and intermediate filaments, but not with actin filaments. Later, when the processes became further developed, intermediate filaments were scarce at the extreme ends. Fluorescein-labeled actin introduced by a micro-injection method was minimally incorporated into filaments in the cellular processes. We conclude that microtubules make up the cytoskeletal element which is most responsible for elongation or spreading of growth tips of myotubes in vitro.