Your search keyword '"Hennessey E"' showing total 4 results

1. Purification, crystallization and preliminary X-ray crystallographic analysis of squid heavy meromyosin.

Author

O'Neall-Hennessey E, Reshetnikova L, Senthil Kumar VS, Robinson H, Szent-Györgyi AG, and Cohen C

Subjects

Animals, Calcium metabolism, Crystallization, Crystallography, X-Ray, Myosin Subfragments isolation & purification, Protein Multimerization, Calcium chemistry, Decapodiformes chemistry, Muscles chemistry, Myosin Subfragments chemistry

Abstract

All muscle-based movement is dependent upon carefully choreographed interactions between the two major muscle components, myosin and actin. Regulation of vertebrate smooth and molluscan muscle contraction is myosin based (both are in the myosin II class), and requires the double-headed form of myosin. Removal of Ca2+ from these muscles promotes a relatively compact conformation of the myosin dimer, which inhibits its interaction with actin. Although atomic structures of single myosin heads are available, the structure of any double-headed portion of myosin, including the ∼375 kDa heavy meromyosin (HMM), has only been visualized at low (∼20 Å) resolution by electron microscopy. Here, the growth of three-dimensional crystals of HMM with near-atomic resolution (up to ∼5 Å) and their X-ray diffraction are reported for the first time. These crystals were grown in off-state conditions, that is in the absence of Ca2+ and the presence of nucleotide analogs, using HMM from the funnel retractor muscle of squid. In addition to the crystallization conditions, the techniques used to isolate and purify this HMM are also described. Efforts at phasing and improving the resolution of the data in order to determine the structure are ongoing.

Published

2013

2. Calcium-dependent structural changes in scallop heavy meromyosin.

Author

Stafford WF, Jacobsen MP, Woodhead J, Craig R, O'Neall-Hennessey E, and Szent-Györgyi AG

Subjects

Animals, Microscopy, Electron, Muscle Contraction physiology, Myosin Subfragments ultrastructure, Nucleotides chemistry, Protein Conformation, Ultracentrifugation, Calcium chemistry, Mollusca chemistry, Myosin Subfragments chemistry

Abstract

The mechanism of calcium regulation of scallop myosin is not understood, although it is known that both myosin heads are required. We have explored possible interactions between the heads of heavy meromyosin (HMM) in the presence and absence of calcium and nucleotides by sedimentation and electron microscope studies. The ATPase activity of the HMM preparation was activated over tenfold by calcium, indicating that the preparation contained mostly regulated molecules. In the presence of ADP or ATP analogs, calcium increased the asymmetry of the HMM molecule as judged by its slower sedimentation velocity compared with that in EGTA. In the absence of nucleotide the asymmetry was high even in EGTA. The shift in sedimentation occurred with a sharp midpoint at a calcium level of about 0.5 microM. Sedimentation of subfragment 1 was not dependent on calcium or on nucleotides. Modeling accounted for the observed sedimentation behavior by assuming that both HMM heads bent toward the tail in the absence of calcium, while in its presence the heads had random positions. The sedimentation pattern showed a single peak at all calcium concentrations, indicating equilibration between the two forms with a t(1/2) less than 70 seconds. Electron micrographs of crosslinked, rotary shadowed specimens indicated that 81 % of HMM molecules in the presence of nucleotide had both heads pointing back towards the tail in the absence of calcium, as compared with 41 % in its presence. This is consistent with the sedimentation data. We conclude that in the "off" state, scallop myosin heads interact with each other, forming a rigid structure with low ATPase activity. When molecules are switched "on" by binding of calcium, communication between the heads is lost, allowing them to flex randomly about the junction with the tail; this could facilitate their interaction with actin in contracting muscle., (Copyright 2001 Academic Press.)

Published

2001

3. Regulatory domains of myosins: influence of heavy chain on Ca(2+)-binding.

Author

Kalabokis VN, O'Neall-Hennessey E, and Szent-Györgyi AG

Subjects

Animals, Gizzard, Avian, Mollusca metabolism, Muscle, Smooth chemistry, Muscles chemistry, Protein Binding, Protein Conformation, Rabbits metabolism, Species Specificity, Turkeys metabolism, Calcium metabolism, Myosin Subfragments metabolism

Abstract

Light chain binding domains of rabbit skeletal, turkey gizzard and scallop myosin comprised of equimolar amounts of a short heavy chain fragment, essential light chain, and regulatory light chain have been obtained following extensive tryptic digestion. These complexes that are analogous to the regulatory domain prepared previously from scallop myosin by digestion with clostripain resist proteolysis due to the mutual protection of the heavy chain and the light chains, and are common structural features of the myosins studied. Specific Ca(2+)-binding by the regulatory domains reflects the behaviour of intact myosin; only scallop regulatory domain has a specific Ca(2+)-binding site. The heavy chain fragments of the different regulatory domains have been isolated under denaturing conditions and reconstituted with scallop essential light chain and scallop regulatory light chain or turkey gizzard regulatory light chain to yield regulatory domain hybrids. Hybrids containing the turkey gizzard regulatory light chain were used in Ca(2+)-binding studies since they were far more stable than their counterparts with the scallop regulatory light chain. The gizzard hybrid binds Ca2+ with a comparable specificity but somewhat lower affinity than native scallop regulatory domain. The rabbit regulatory domain hybrid also binds Ca2+, although with a reduced affinity and specificity. The results indicate that Ca(2+)-binding ability is determined by the light chains and modified by the heavy chains.

Published

1994

4. Isolation of the regulatory domain of scallop myosin: role of the essential light chain in calcium binding.

Author

Kwon H, Goodwin EB, Nyitray L, Berliner E, O'Neall-Hennessey E, Melandri FD, and Szent-Györgyi AG

Subjects

Animals, Binding Sites, Electrophoresis, Polyacrylamide Gel, Kinetics, Mollusca, Muscles metabolism, Myosins isolation & purification, Protein Denaturation, Calcium metabolism, Myosins metabolism

Abstract

The regulatory domain of scallop myosin, consisting of a regulatory light chain (R-LC), an essential light chain (E-LC), and a portion of heavy chain, occupies the neck region of myosin. This domain is directly involved in the regulation of molluscan muscle contraction, which is triggered by direct Ca2+ binding to myosin. We have isolated a soluble functional complex (regulatory complex) comprised of R-LC, E-LC, and a 10-kDa heavy chain fragment in a 1:1:1 stoichiometry by clostripain digestion of the myosin head (papain subfragment 1). N termini of the heavy chain fragments were either leucine-812 or valine-817. The isolated complex retained the specific Ca2(+)-binding site and bound Ca2+ with a similar affinity and selectivity as myosin. The individual components of the regulatory complex were isolated after complete denaturation with guanidine hydrochloride. The regulatory complex was reconstituted from isolated light chains and the heavy chain fragment. The renatured complex regained Ca2+ binding quantitatively. To elucidate the function of the E-LC in Ca2+ binding, we constructed hybrid regulatory complexes. The hybrid complexes reconstituted with molluscan E-LC and R-LC regained the specific Ca2(+)-binding site, whereas the hybrid complex formed with rabbit skeletal E-LC [alkali LC 2 (A2-LC)] and scallop R-LC did not. The results demonstrate that E-LCs from myosins regulated by direct Ca2+ binding are required for the specific Ca2+ binding in the molluscan muscle.

Published

1990