Your search keyword '"D H, Hu"' showing total 4 results

1. Sodium dodecyl sulfate gel electrophoresis studies of connectin-like high molecular weight proteins of various types of vertebrate and invertebrate muscles

Author

D H, Hu, S, Kimura, and K, Maruyama

Subjects

Molecular Weight, Species Specificity, Muscles, Vertebrates, Animals, Muscle Proteins, Connectin, Electrophoresis, Polyacrylamide Gel, Rabbits, Chickens, Invertebrates, Protein Kinases

Abstract

Using an SDS gel electrophoresis method, connectin, very high molecular weight (approximately 10(6) dalton) protein, was detected in an SDS extract of whole tissues of various types of muscles of vertebrates and invertebrates. Connectin bands were clearly recognized in all the types of striated muscles (skeletal and cardiac) of the vertebrates examined: rabbit, chicken, turtle, snake, newt, frog, and fish. This was also the case with skeletal muscle of prochordate, Amphioxus. In invertebrates, the situation was much complicated. Connectin-like protein bands were detected in C. elegans (nematode), but not in earthworm (annelid). Smaller sizes of proteins (approximately 10(6)) were faintly found in molluscan adductor muscles. In arthropods, connectin-like proteins were clearly detected in some muscles (e.g., claw muscles of crab and crayfish; leg muscles of several insects) but not at all in other muscles (e.g., tail muscles of crayfish and shrimp; thoracic muscles of some insects). These peculiar observations might be related to the presence of such specific elastic proteins as projectin in honeybee flight muscle. The present study has revealed that connectin is an elastic protein of vertebrate striated muscle, skeletal and cardiac muscles.

Published

1986

2. Elastic properties and beta-sheet structure of connectin threads

Author

Y, Mitsui, H, Higuchi, S, Terashima, S, Takahashi, D H, Hu, K, Maruyama, and H, Noda

Subjects

X-Ray Diffraction, Protein Conformation, Muscles, Temperature, Animals, Muscle Proteins, Connectin, Chickens, Protein Kinases, Elasticity

Abstract

Connectin is a very long and flexible protein of striated muscle, linking myosin filaments to z discs in a sarcomere. Isolated native connectin in solution frequently forms elastic threads upon concentration of the solution, by side-by-side association of molecules. An X-ray diffraction study was performed to examine the presence of beta-sheet structure in artificially prepared threads. The elastic properties of such threads were measured at various temperatures. Negative temperature dependence of the elastic coefficient suggests that the elasticity of connectin threads is due to deformation of the three-dimensional structure and not to rubber-like behavior.

Published

1987

3. Cross-linking of native myosin forms oligomers of myosin heavy chain dimers

Author

D H, Hu, S, Kimura, and K, Maruyama

Subjects

Maleimides, Protein Denaturation, Cross-Linking Reagents, Glutaral, Myosins

Abstract

Chemical cross-linking of native myosin in 0.6 M NaCl with p-phenylene bis maleimide or glutaraldehyde resulted in rapid formation of myosin heavy chain dimers and their oligomers. Monomers and odd-number oligomers disappeared after the prolonged treatment with these reagents. When denatured myosin was cross-linking, myosin heavy chain monomers and odd-number oligomers remained after the prolonged treatment, although dimers and their even-number oligomers were abundant. For high molecular weight markers, myosin heavy chain oligomers formed from denatured myosin with glutaraldehyde or p-phenylene bis maleimide are recommended.

Published

1988

4. Binding of actin filaments to connectin

Author

K, Maruyama, D H, Hu, T, Suzuki, and S, Kimura

Subjects

Myosin Subfragments, Animals, Muscle Proteins, Connectin, In Vitro Techniques, Myosins, Chickens, Protein Kinases, Actins, Peptide Fragments, Potassium Chloride, Protein Binding

Abstract

The binding of actin filaments to connectin, a muscle elastic protein, was investigated by means of turbidity and sedimentation measurements and electron microscopy. In the presence of less than 0.12 M KCl at pH 7.0, actin filaments bound to connectin. Long actin filaments formed bundles. Short actin filaments also aggregated into irregular bundles or a meshwork, and were frequently attached perpendicularly to long bundles. The binding of F-actin to connectin was saturated at an equal weight ratio (molar ratio, 50 : 1), as determined by a cosedimentation assay. Larger amounts of sonicated short actin filaments appeared to bind to connectin than intact F-actin. Myosin S1-decorated actin filaments did not bind to connectin. The addition of S1 to connectin-induced actin bundles resulted in partial disaggregation. Thus, connectin does not appear to interfere with actin-myosin interactions, since myosin S1 binds to actin more strongly than connectin.

Published

1987