Biochemical and ultrastructural aspects of Mr 165,000 M-protein in cross-striated chicken muscle

To better understand the relationship between the Mr 165,000 M-line protein (M-protein) and H-zone structure in skeletal and in cardiac muscle, as well as the possible interaction of M-protein with another skeletal muscle M-line component, the homodimeric creatine kinase isoenzyme composed of two M subunits (MM-CK), we performed biochemical, immunological, and ultrastructural studies on myofibrils extracted by different procedures. In contrast to MM-CK, M-protein could not be completely removed from myofibrils by low ionic strength extraction. Fab-fragments of antibodies against M-protein could not release M- protein quantitatively from either breast or heart myofibrils but remained bound to the myofibrillar structure, whereas monovalent antibodies against MM-CK cause the specific release of MM-CK and the concomitant disappearance of the M-line from chicken skeletal muscle myofibrils. When MM-CK was removed from skeletal myofibrils by low ionic strength extraction or, more specifically, by incubation with anti-MM-CK Fab, M-protein was still not released quantitatively upon treatment with anti-M-protein Fab as judged from immunofluorescence data. In the ultrastructural investigation of low ionic strength extracted muscle fibers, M protein could be localized in two stripes on both sides of the former M-line, suggesting a reduced attachment to the residual H-zone structure, whereas the specific removal of MM-CK resulted in the same dense staining pattern for M-protein within the M- line as observed in untreated fibers. However, the binding of M-protein to the residual M-line structure seemed to be reduced, as a considerable amount of this protein could be identified in the supernate of sequentially incubated myofibrils. The results indicate a strong binding of M-protein within the H-zone structure of skeletal as well as heart myofibrils.     

Muscle-type creatine kinase interacts with central domains of the M-band proteins myomesin and M-protein

Muscle-type creatine kinase (MM-CK) is a member of the CK isoenzyme family with key functions in cellular energetics. MM-CK interacts in an isoform-specific manner with the M-band of sarcomeric muscle, where it serves as an efficient intramyofibrillar ATP-regenerating system for the actin-activated myosin ATPase located nearby on both sides of the M-band. Four MM-CK-specific and highly conserved lysine residues are thought to be responsible for the interaction of MM-CK with the M-band. A yeast two-hybrid screen led to the identification of MM-CK as a binding partner of a central portion of myomesin (My7-8). An interaction was observed with domains six to eight of the closely related M-protein but not with several other Ig-like domains, including an M-band domain, of titin. The observed interactions were corroborated and characterised in detail by surface plasmon resonance spectroscopy (BiaCore). In both cases, they were CK isoform-specific and the MM-CK-specific lysine residues (K8. K24, K104 and K115) are involved in this interaction. At pH 6.8, the dissociation constants for the myomesin/MM-CK and the M-protein/MM-CK binding were in the range of 50-100 nM and around 1 microM, respectively. The binding showed pronounced pH-dependence and indicates a dynamic association/dissociation behaviour, which most likely depends on the energy state of the muscle. Our data propose a simple model for the regulation of this dynamic interaction.     

Isolation and characterization of a Mr = 38,000 protein from differentiating smooth muscle cells

In culture, vascular smooth muscle cells grow and form a confluent monolayer of cells. Under appropriate conditions, regions of the monolayer can be induced to draw away from the substrate and form multicellular nodules. The ultrastructure of the cells in the nodules appears to be similar to that of differentiated smooth muscle cells. The process of nodulation is associated with the synthesis of a unique protein whose molecular weight is estimated from gradient gel electrophoresis to be 38,000 (38-kDa Protein). The protein is secreted into the culture medium and can be detected either by metabolic labeling or by staining with Coomassie Blue. Partial purification of 38-kDa Protein was achieved using affinity chromatography. The protein is adsorbed to heparin-agarose, but not to gelatin-agarose. The concentration of 38-kDa Protein in nodular conditioned medium is estimated at 1.9 micrograms/ml and less than 0.01 microgram/ml in conditioned medium made from monolayer cells. The presence of 5% fetal bovine serum in the labeling medium does not affect 38-kDa Protein synthesis. Cross-reactivity with fibronectin was evaluated using polyvalent antibodies to 38-kDa Protein. The 38-kDa Protein is not antigenically related to fibronectin. Furthermore, we establish that the protein is not qualitatively influenced by the presence of ascorbate (50 micrograms/ml), beta-aminoproprionitrile fumarate (50 micrograms/ml) heparin (10 ng/ml), or fibronectin (20 micrograms/ml) in the culture medium. We find that the added components neither suppress 38-kDa Protein synthesis in nodular cultures nor enhance 38-kDa Protein synthesis in monolayer cultures. The 38-kDa Protein is not detected in either monolayer or nodular cell layers and appears to be a secreted protein. Its appearance in nodular conditioned medium during nodulation suggests a relationship with that process.     

Making muscle elastic: the structural basis of myomesin stretching

Skeletal and cardiac muscles are remarkable biological machines that support and move our bodies and power the rhythmic work of our lungs and hearts. As well as producing active contractile force, muscles are also passively elastic, which is essential to their performance. The origins of both active contractile and passive elastic forces can be traced to the individual proteins that make up the highly ordered structure of muscle. In this Primer, we describe the organization of sarcomeres--the structural units that produce contraction--and the nature of the proteins that make muscle elastic. In particular, we focus on an elastic protein called myomesin, whose novel modular architecture helps explain elasticity.     

Size and shape of skeletal muscle M-protein

M-protein was isolated from chicken pectoralis muscle and shown to be relatively homogeneous by the criterion of high-speed equilibrium ultracentrifugation. A sample of the protein was rotary shadowed with platinum and examined by electron microscopy. M-protein appears to be elongated with a length of 360 Å and a width of 41 Å to give an axial ratio of 9:1. These results are compatible with the suggestion that M-protein is a component of the M-filaments in the M-band of skeletal muscle myofibrils.     

Structure of the cross-striated adductor muscle of the scallop

The structure of the cross-striated adductor muscle of the scallop has been studied by electron microscopy and X-ray diffraction using living relaxed, glycerol-extracted (rigor), fixed and dried muscles. The thick filaments are arranged in a hexagonal lattice whose size varies with sarcomere length so as to maintain a constant lattice volume. In the overlap region there are approximately 12 thin filaments about each thick filament and these are arranged in a partially disordered lattice similar to that found in other invertebrate muscles, giving a thin-to-thick filament ratio in this region of 6:1.The thin filaments, which contain actin and tropomyosin, are about 1 μm long and the actin subunits are arranged on a helix of pitch 2 × 38.5 nm. The thick filaments, which contain myosin and paramyosin, are about 1.76 μm long and have a backbone diameter of about 21 nm. We propose that these filaments have a core of paramyosin about 6 nm in diameter, around which the myosin molecules pack. In living relaxed muscle, the projecting myosin heads are symmetrically arranged. The data are consistent with a six-stranded helix, each strand having a pitch of 290 nm. The projections along the strands each correspond to the heads of one or two myosin molecules and occur at alternating intervals of 13 and 16 nm. In rigor muscle these projections move away from the backbone and attach to the thin filaments.In both living and dried muscle, alternate planes of thick filaments are staggered longitudinally relative to each other by about 7.2 nm. This gives rise to a body-centred orthorhombic lattice with a unit cell twice the volume of the basic filament lattice.     

M-protein from chicken pectoralis muscle: isolation and characterization.

Proteins of chain molecular weights 170,000, 90,000 and 43,000 have been ascribed to the M-line in the literature; whether all the components are indeed from this region remains to be determined. We present here studies on the 170,000 and 90,000 molecular weight components isolated from high-salt extracts of washed chicken pectoralis muscle. Three components have been purified and characterized, two of chain molecular weight 170,000 and one of 90,000.The 90,000 chain molecular weight protein is identified as the enzyme glycogen phosphorylase b; it has physical characteristics and values of specific activity and pyridoxal-5′-phosphate content similar to those reported for this enzyme. Antibodies to the purified protein do not bind to the M-line region.The two 170,000 chain molecular weight proteins comigrate on sodium dodecyl sulphate/polyacrylamide gels in a band between myosin and C-protein designated “b” by Starr &; Offer (1971) in their classification of myosin contaminants. Both proteins are single chain molecules with a low α-helix content. They are distinguished by sedimentation coefficients of 5.1 S and 7.1 S. Antibodies to the 5 S protein bind strongly to the M-line, whereas those to the 7 S protein weakly stain the Z-line. The 7 S protein is identified as glycogen debranching enzyme. We conclude from these studies that of the three components isolated, only the 5 S protein is a likely constituent of the M-line.     

Heparin induces specific protein release from human intestinal smooth muscle cells

Human intestinal smooth muscle cells have recently been identified as the major cell type responsible for stricture formation in Crohn's disease. Heparin, a sulfated glycosaminoglycan, has been shown to be a key modulator of vascular smooth muscle cell growth both in vivo and in vitro and to affect the release of proteins from these cells. Heparin has also been shown to affect the growth of human intestinal smooth muscle cells. In this report we demonstrate that heparin, in addition to its effects on proliferation, also has very specific effects on proteins released by these cells in vitro. Examination of the culture medium proteins of heparin-treated human intestinal cells revealed an increase in three proteins of molecular weight between 150-250 kd, an increase in a 37 kd protein and a decrease in synthesis of lower molecular weight (less than 20 kd) proteins. In substrate-attached material a transient effect on a 48 kd protein was observed. No effects on intracellular labeled proteins could be demonstrated. The 35S-methionine labeled protein profile of human intestinal smooth muscle cells exposed to heparin is similar to that observed in rat vascular smooth muscle cells yet distinct differences do exist. Extracellular processing does not account for the released proteins nor is de novo protein synthesis required suggesting that altered intracellular protein processing is the mechanism for the heparin-induced protein pattern. The release of specific proteins following exposure to heparin may reflect a significant influence of this glycosaminoglycan on the metabolism of smooth muscle cells in general and particularly in the human intestine.     

Localization of the centrin-related 165,000-Mr protein of PtK2 cells during the cell cycle

In this study, we follow changes in localization of the centrin-related 165,000-Mr protein of PtK2 cells during the cell cycle. This protein is a component of a pericentriolar lattice that consists of pericentriolar satellites, pericentriolar matrix, and basal feet (Baron A.T., and J.L. Salisbury, J. Cell Biol. 107:2669-2678, 1988). By immunofluorescence microscopy, the 165,000-Mr protein is seen as a constellation of pericentrosomal spots. We observe that cells in late G1 and S are characterized by a dense centrosomal focus of spots with additional spots dispersed throughout the cytoplasm. In G2, one bright centrosomal focus of clustered spots is observed. As the cells proceed through prophase this single focus divides, forming two foci that move toward opposite sides of the nucleus. During prometaphase, each polar focus of spots disperses. At metaphase, the spots are distributed throughout each half-cytoplast from the poles to the chromosomes. During anaphase chromosome movement, some spots are seen beside and behind the trailing chromosome arms while others are clustered at the poles. At telophase, pericentrosomal spots radiate from the poles to surround each mass of chromatin. In early G1, pericentrosomal spots surround each newly formed nucleus. We conclude that the 165,000-Mr protein is a dynamic component of both the centrosome (pericentriolar matrix) and the mitotic apparatus (spindle matrix).     

Ribocharin: a nuclear Mr 40,000 protein specific to precursor particles of the large ribosomal subunit

Using a monoclonal antibody (No-194) we have identified, in Xenopus laevis and other amphibia, an acidic protein of Mr 40,000 (ribocharin) which is specifically associated with the granular component of the nucleolus and nucleoplasmic 65S particles. These particles contain the nuclear 28S rRNA and apparently represent the precursor to the large ribosomal subunit in nucleocytoplasmic transit. By immunoelectron microscopy ribocharin has been localized in the granular component of the nucleolus and in interchromatin granules. During mitosis ribocharin-containing particles are associated with surfaces of chromosomes and are recollected in the reconstituting nucleoli in late telophase. We suggest that ribocharin is a specific component of precursor particles of the large ribosomal subunit, which dissociates from the 65S particle before passage through the nuclear envelope, and is reutilized in ribosome biogenesis.     

The active state of cross-striated muscle cell sarcomere (an imitation model)]

An index of the sarcomere active state is introduced. It reflects the most important processes of sarcomere contraction, such as calcium diffusion taking into account permeability of calcium channels and its binding with troponin, formation of energy supplies and interaction of sarcomere contractile proteins. The effect of changes of the values of diffusion coefficients and chemical reactions rates was studied theoretically.