scholarly journals The myosin II coiled-coil domain atomic structure in its native environment

2021 ◽  
Vol 118 (14) ◽  
pp. e2024151118
Author(s):  
Hamidreza Rahmani ◽  
Wen Ma ◽  
Zhongjun Hu ◽  
Nadia Daneshparvar ◽  
Dianne W. Taylor ◽  
...  
Keyword(s):  
Atomic Structure ◽  
Coiled Coil ◽  
Thick Filament ◽  
Terminal Segment ◽  
The Other ◽  
Cardiac Myosin ◽  
Thick Filaments ◽  
C Terminus ◽  
Α Helix ◽  
Lethocerus Indicus

The atomic structure of the complete myosin tail within thick filaments isolated from Lethocerus indicus flight muscle is described and compared to crystal structures of recombinant, human cardiac myosin tail segments. Overall, the agreement is good with three exceptions: the proximal S2, in which the filament has heads attached but the crystal structure doesn’t, and skip regions 2 and 4. At the head–tail junction, the tail α-helices are asymmetrically structured encompassing well-defined unfolding of 12 residues for one myosin tail, ∼4 residues of the other, and different degrees of α-helix unwinding for both tail α-helices, thereby providing an atomic resolution description of coiled-coil “uncoiling” at the head–tail junction. Asymmetry is observed in the nonhelical C termini; one C-terminal segment is intercalated between ribbons of myosin tails, the other apparently terminating at Skip 4 of another myosin tail. Between skip residues, crystal and filament structures agree well. Skips 1 and 3 also agree well and show the expected α-helix unwinding and coiled-coil untwisting in response to skip residue insertion. Skips 2 and 4 are different. Skip 2 is accommodated in an unusual manner through an increase in α-helix radius and corresponding reduction in rise/residue. Skip 4 remains helical in one chain, with the other chain unfolded, apparently influenced by the acidic myosin C terminus. The atomic model may shed some light on thick filament mechanosensing and is a step in understanding the complex roles that thick filaments of all species undergo during muscle contraction.

scholarly journals CryoEM Structure of Drosophila Flight Muscle Thick Filaments at 7Å Resolution

2020 ◽  
Author(s):  
Nadia Daneshparvar ◽  
Dianne W. Taylor ◽  
Thomas S. O’Leary ◽  
Hamidreza Rahmani ◽  
Fatemeh Abbasi Yeganeh ◽  
...  
Keyword(s):  
Drosophila Melanogaster ◽  
Striated Muscle ◽  
Flight Muscle ◽  
Coiled Coil ◽  
Thick Filament ◽  
Fruit Fly ◽  
Actin Binding ◽  
Thick Filaments ◽  
Flight Muscles ◽  
Lethocerus Indicus

AbstractStriated muscle thick filaments are composed of myosin II and several non-myosin proteins. Myosin II’s long α-helical coiled-coil tail forms the dense protein backbone of filaments while its N-terminal globular head containing the catalytic and actin binding activities extends outward from the backbone. Here we report the structure of thick filaments of the flight muscle of the fruit fly Drosophila melanogaster at 7 Å resolution. Its myosin tails are arranged in curved molecular crystalline layers identical to flight muscles of the giant waterbug Lethocerus indicus. Four non-myosin densities are observed, three of which correspond to ones found in Lethocerus; one new density, possibly stretchin-Mlck, is found on the backbone outer surface. Surprisingly, the myosin heads are disordered rather than ordered along the filament backbone. Our results show striking myosin tail similarity within flight muscle filaments of two insect orders separated by several hundred million years of evolution.Significance StatementMyosin thick filaments are one of striated muscle’s key structures, but also one of its least understood. A key question is how the myosin a-helical coiled-coil tail is arranged in the backbone. At 7Å resolution, sufficient to resolve individual a-helices, the myosin tail arrangement in thick filaments from the flight muscle of the fruit fly Drosophila melanogaster is strikingly similar to the myosin tail arrangement in flight muscles of the giant waterbug Lethocerus indicus. Nearly every other thick filament feature is different. Drosophila and Lethocerus evolved separately >245 million years ago suggesting myosin tail packing into curved molecular crystalline layers forms a highly conserved thick filament building block and different properties are obtained by alterations in non-myosin proteins.

scholarly journals Hydrophobicity variations along the surface of the coiled-coil rod may mediate striated muscle myosin assembly in Caenorhabditis elegans.

1996 ◽  
Vol 135 (2) ◽  
pp. 371-382 ◽  
Author(s):  
P E Hoppe ◽  
R H Waterston
Keyword(s):  
Caenorhabditis Elegans ◽  
Striated Muscle ◽  
Coiled Coil ◽  
Thick Filament ◽  
Surface Hydrophobicity ◽  
Filament Assembly ◽  
Thick Filaments ◽  
Characteristic Variation ◽  
Muscle Myosin

Caenorhabditis elegans body wall muscle contains two isoforms of myosin heavy chain, MHC A and MHC B, that differ in their ability to initiate thick filament assembly. Whereas mutant animals that lack the major isoform, MHC B, have fewer thick filaments, mutant animals that lack the minor isoform, MHC A, contain no normal thick filaments. MHC A, but not MHC B, is present at the center of the bipolar thick filament where initiation of assembly is thought to occur (Miller, D.M.,I. Ortiz, G.C. Berliner, and H.F. Epstein. 1983. Cell. 34:477-490). We mapped the sequences that confer A-specific function by constructing chimeric myosins and testing them in vivo. We have identified two distinct regions of the MHC A rod that are sufficient in chimeric myosins for filament initiation function. Within these regions, MHC A displays a more hydrophobic rod surface, making it more similar to paramyosin, which forms the thick filament core. We propose that these regions play an important role in filament initiation, perhaps mediating close contacts between MHC A and paramyosin in an antiparallel arrangement at the filament center. Furthermore, our analysis revealed that all striated muscle myosins show a characteristic variation in surface hydrophobicity along the length of the rod that may play an important role in driving assembly and determining the stagger at which dimers associate.

scholarly journals The Vaccinia Virus 14-Kilodalton (A27L) Fusion Protein Forms a Triple Coiled-Coil Structure and Interacts with the 21-Kilodalton (A17L) Virus Membrane Protein through a C-Terminal α-Helix

1998 ◽  
Vol 72 (12) ◽  
pp. 10126-10137 ◽  
Author(s):  
María-Isabel Vázquez ◽  
German Rivas ◽  
David Cregut ◽  
Luis Serrano ◽  
Mariano Esteban
Keyword(s):  
Amino Acids ◽  
Vaccinia Virus ◽  
Structural Model ◽  
Analytical Ultracentrifugation ◽  
Transmembrane Domain ◽  
Coiled Coil ◽  
C Terminus ◽  
Α Helix ◽  
Mutant Forms ◽  
Helical Region

ABSTRACT The vaccinia virus 14-kDa protein (encoded by the A27L gene) plays an important role in the biology of the virus, acting in virus-to-cell and cell-to-cell fusions. The protein is located on the surface of the intracellular mature virus form and is essential for both the release of extracellular enveloped virus from the cells and virus spread. Sequence analysis predicts the existence of four regions in this protein: a structureless region from amino acids 1 to 28, a helical region from residues 29 to 37, a triple coiled-coil helical region from residues 44 to 72, and a Leu zipper motif at the C terminus. Circular dichroism spectroscopy, analytical ultracentrifugation, and chemical cross-linking studies of the purified wild-type protein and several mutant forms, lacking one or more of the above regions or with point mutations, support the above-described structural division of the 14-kDa protein. The two contiguous cysteine residues at positions 71 and 72 are not responsible for the formation of 14-kDa protein trimers. The location of hydrophobic residues at the a and d positions on a helical wheel and of charged amino acids in adjacent positions, e and g, suggests that the hydrophobic and ionic interactions in the triple coiled-coil helical region are involved in oligomer formation. This conjecture was supported by the construction of a three-helix bundle model and molecular dynamics. Binding assays with purified proteins expressed in Escherichia coli and cytoplasmic extracts from cells infected with a virus that does not produce the 14-kDa protein during infection (VVindA27L) show that the 21-kDa protein (encoded by the A17L gene) is the specific viral binding partner and identify the putative Leu zipper, the predicted third α-helix on the C terminus of the 14-kDa protein, as the region involved in protein binding. These findings were confirmed in vivo, following transfection of animal cells with plasmid vectors expressing mutant forms of the 14-kDa protein and infected with VVindA27L. We find the structural organization of 14kDa to be similar to that of other fusion proteins, such as hemagglutinin of influenza virus and gp41 of human immunodeficiency virus, except for the presence of a protein-anchoring domain instead of a transmembrane domain. Based on our observations, we have established a structural model of the 14-kDa protein.

scholarly journals A Structural Model for Phosphorylation Control of Dictyostelium Myosin II Thick Filament Assembly

1999 ◽  
Vol 147 (5) ◽  
pp. 1039-1048 ◽  
Author(s):  
Wenchuan Liang ◽  
Hans M. Warrick ◽  
James A. Spudich
Keyword(s):  
Structural Model ◽  
Myosin Ii ◽  
Coiled Coil ◽  
Thick Filament ◽  
Tail Region ◽  
Filament Assembly ◽  
Dictyostelium Myosin ◽  
Thick Filaments ◽  
Coil Structure

Myosin II thick filament assembly in Dictyostelium is regulated by phosphorylation at three threonines in the tail region of the molecule. Converting these three threonines to aspartates (3×Asp myosin II), which mimics the phosphorylated state, inhibits filament assembly in vitro, and 3×Asp myosin II fails to rescue myosin II–null phenotypes. Here we report a suppressor screen of Dictyostelium myosin II–null cells containing 3×Asp myosin II, which reveals a 21-kD region in the tail that is critical for the phosphorylation control. These data, combined with new structural evidence from electron microscopy and sequence analyses, provide evidence that thick filament assembly control involves the folding of myosin II into a bent monomer, which is unable to incorporate into thick filaments. The data are consistent with a structural model for the bent monomer in which two specific regions of the tail interact to form an antiparallel tetrameric coiled–coil structure.

scholarly journals NMR structure and dynamics of monomeric neutrophil-activating peptide 2

1999 ◽  
Vol 338 (3) ◽  
pp. 591-598 ◽  
Author(s):  
Helen YOUNG ◽  
Vikram ROONGTA ◽  
Thomas J. DALY ◽  
Kevin H. MAYO
Keyword(s):  
Solution Structure ◽  
Computational Modelling ◽  
Terminal Segment ◽  
Conformational Exchange ◽  
15N Nmr ◽  
Model Free ◽  
C Terminus ◽  
Internal Mobility ◽  
Α Helix ◽  
Β Sheet

Neutrophil-activating peptide 2 (NAP-2), which demonstrates a range of proinflammatory activities, is a 72-residue protein belonging to the α-chemokine family. Although NAP-2, like other α-chemokines, is known to self-associate into dimers and tetramers, it has been shown that the monomeric form is physiologically active. Here we investigate the solution structure of monomeric NAP-2 by multi-dimensional 1H-NMR and 15N-NMR spectroscopy and computational modelling. The NAP-2 monomer consists of an amphipathic, triple-stranded, anti-parallel β-sheet on which is folded a C-terminal α-helix and an aperiodic N-terminal segment. The backbone fold is essentially the same as that found in other α-chemokines. 15N T1, T2 and nuclear Overhauser effects (NOEs) have been measured for backbone NH groups and used in a model free approach to calculate order parameters and conformational exchange terms that map out motions of the backbone. N-terminal residues 1 to 17 and the C-terminus are relatively highly flexible, whereas the β-sheet domain forms the most motionally restricted part of the fold. Conformational exchange occurring on the millisecond time scale is noted at the top of the C-terminal helix and at proximal residues from β-strands 1 and 2 and the connecting loop. Dissociation to the monomeric state is apparently responsible for increased internal mobility in NAP-2 compared with dimeric and tetrameric states in other α-chemokines.

scholarly journals Structure of myosin filaments from relaxed Lethocerus flight muscle by cryo-EM at 6 Å resolution

2016 ◽  
Vol 2 (9) ◽  
pp. e1600058 ◽  
Author(s):  
Zhongjun Hu ◽  
Dianne W. Taylor ◽  
Michael K. Reedy ◽  
Robert J. Edwards ◽  
Kenneth A. Taylor
Keyword(s):  
Flight Muscle ◽  
Three Dimensional ◽  
Coiled Coil ◽  
Thick Filament ◽  
Coiled Coils ◽  
Muscle Physiology ◽  
Layer Arrangement ◽  
Thick Filaments ◽  
Unusual Position ◽  
Filament Structure

We describe a cryo–electron microscopy three-dimensional image reconstruction of relaxed myosin II–containing thick filaments from the flight muscle of the giant water bug Lethocerus indicus. The relaxed thick filament structure is a key element of muscle physiology because it facilitates the reextension process following contraction. Conversely, the myosin heads must disrupt their relaxed arrangement to drive contraction. Previous models predicted that Lethocerus myosin was unique in having an intermolecular head-head interaction, as opposed to the intramolecular head-head interaction observed in all other species. In contrast to the predicted model, we find an intramolecular head-head interaction, which is similar to that of other thick filaments but oriented in a distinctly different way. The arrangement of myosin’s long α-helical coiled-coil rod domain has been hypothesized as either curved layers or helical subfilaments. Our reconstruction is the first report having sufficient resolution to track the rod α helices in their native environment at resolutions ~5.5 Å, and it shows that the layer arrangement is correct for Lethocerus. Threading separate paths through the forest of myosin coiled coils are four nonmyosin peptides. We suggest that the unusual position of the heads and the rod arrangement separated by nonmyosin peptides are adaptations for mechanical signal transduction whereby applied tension disrupts the myosin heads as a component of stretch activation.

scholarly journals CryoEM structure of Drosophila flight muscle thick filaments at 7 Å resolution

2020 ◽  
Vol 3 (8) ◽  
pp. e202000823
Author(s):  
Nadia Daneshparvar ◽  
Dianne W Taylor ◽  
Thomas S O’Leary ◽  
Hamidreza Rahmani ◽  
Fatemeh Abbasiyeganeh ◽  
...  
Keyword(s):  
Striated Muscle ◽  
Flight Muscle ◽  
Myosin Ii ◽  
Coiled Coil ◽  
Fruit Fly ◽  
Actin Binding ◽  
Thick Filaments ◽  
Flight Muscles ◽  
Lethocerus Indicus ◽  
Globular Head

Striated muscle thick filaments are composed of myosin II and several non-myosin proteins. Myosin II’s long α-helical coiled-coil tail forms the dense protein backbone of filaments, whereas its N-terminal globular head containing the catalytic and actin-binding activities extends outward from the backbone. Here, we report the structure of thick filaments of the flight muscle of the fruit fly Drosophila melanogaster at 7 Å resolution. Its myosin tails are arranged in curved molecular crystalline layers identical to flight muscles of the giant water bug Lethocerus indicus. Four non-myosin densities are observed, three of which correspond to ones found in Lethocerus; one new density, possibly stretchin-mlck, is found on the backbone outer surface. Surprisingly, the myosin heads are disordered rather than ordered along the filament backbone. Our results show striking myosin tail similarity within flight muscle filaments of two insect orders separated by several hundred million years of evolution.

scholarly journals Multiple Forms of Cardiac Myosin-binding Protein C Exist and Can Regulate Thick Filament Stability

2007 ◽  
Vol 129 (5) ◽  
pp. 419-428 ◽  
Author(s):  
Irina Kulikovskaya ◽  
George B. McClellan ◽  
Rhea Levine ◽  
Saul Winegrad
Keyword(s):  
Protein C ◽  
Heart Function ◽  
Binding Protein ◽  
Thick Filament ◽  
Stable Form ◽  
Cardiac Myosin ◽  
Myosin Binding Protein ◽  
Myosin Binding Protein C ◽  
Thick Filaments ◽  
Myosin Binding

Although absence or abnormality of cardiac myosin binding protein C (cMyBP-C) produces serious structural and functional abnormalities of the heart, function of the protein itself is not clearly understood, and the cause of the abnormalities, unidentified. Here we report that a major function of cMyBP-C may be regulating the stability of the myosin-containing contractile filaments through phosphorylation of cMyBP-C. Antibodies were raised against three different regions of cMyBP-C to detect changes in structure within the molecule, and loss of myosin heavy chain was used to monitor degradation of the thick filament. Results from Western blotting and polyacrylamide gel electrophoresis indicate that cMyBP-C can exist in two different forms that produce, respectively, stable and unstable thick filaments. The stable form has well-ordered myosin heads and requires phosphorylation of the cMyBP-C. The unstable form has disordered myosin heads. In tissue with intact cardiac cells, the unstable unphosphorylated cMyBP-C is more easily proteolyzed, causing thick filaments first to release cMyBP-C and/or its proteolytic peptides and then myosin. Filaments deficient in cMyBP-C are fragmented by shear force well tolerated by the stable form. We hypothesize that modulation of filament stability can be coupled at the molecular level with the strength of contraction by the sensitivity of each to the concentration of calcium ions.

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