Roger Craig

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Roger Craig is affiliated with the following schools: Stanford University, University of Massachusetts Medical School, Brandeis University

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Roger Craig

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Computer Science

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PhD Computer Science Stanford University

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Roger Craig's Published Works

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Published Works

Steric-model for activation of muscle thin filaments. (1997) (445)
Light-chain phosphorylation controls the conformation of vertebrate non-muscle and smooth muscle myosin molecules (1983) (339)
Atomic model of a myosin filament in the relaxed state (2005) (270)
Ca2+-induced tropomyosin movement in Limulus thin filaments revealed by three-dimensional reconstruction (1994) (263)
The location of C-protein in rabbit skeletal muscle (1976) (243)
Tropomyosin and actin isoforms modulate the localization of tropomyosin strands on actin filaments. (2000) (243)
Three-dimensional structure of vertebrate cardiac muscle myosin filaments (2008) (216)
Structure and function of myosin filaments. (2006) (190)
Structural basis for the activation of muscle contraction by troponin and tropomyosin. (2008) (173)
Tropomyosin positions in regulated thin filaments revealed by cryoelectron microscopy. (1999) (170)
A comparison of muscle thin filament models obtained from electron microscopy reconstructions and low-angle X-ray fibre diagrams from non-overlap muscle. (2006) (164)
Steric-blocking by tropomyosin visualized in relaxed vertebrate muscle thin filaments. (1995) (164)
Head-head and head-tail interaction: a general mechanism for switching off myosin II activity in cells. (2008) (162)
Tropomyosin position on F-actin revealed by EM reconstruction and computational chemistry. (2011) (151)
Electron microscopy of thin filaments decorated with a Ca2+-regulated myosin. (1980) (151)
Assembly of smooth muscle myosin into side-polar filaments (1977) (144)
Direct visualization of myosin-binding protein C bridging myosin and actin filaments in intact muscle (2011) (143)
Crossbridge and tropomyosin positions observed in native, interacting thick and thin filaments. (2001) (143)
An atomic model of the thin filament in the relaxed and Ca2+-activated states. (2006) (137)
An atomic model of fimbrin binding to F-actin and its implications for filament crosslinking and regulation (1998) (132)
Three-dimensional reconstruction of tarantula myosin filaments suggests how phosphorylation may regulate myosin activity. (2008) (122)
Structural basis for the regulation of muscle contraction by troponin and tropomyosin. (2008) (121)
Three-dimensional reconstruction of thin filaments decorated with a Ca2+-regulated myosin. (1982) (121)
The ultrastructural location of C-protein, X-protein and H-protein in rabbit muscle (1986) (120)
Myosin-binding protein C displaces tropomyosin to activate cardiac thin filaments and governs their speed by an independent mechanism (2014) (116)
Understanding the Organisation and Role of Myosin Binding Protein C in Normal Striated Muscle by Comparison with MyBP-C Knockout Cardiac Muscle (2008) (115)
Single particle analysis of relaxed and activated muscle thin filaments. (2005) (114)
Ca(2+)-induced tropomyosin movement in Limulus thin filaments revealed by three-dimensional reconstruction. (1994) (110)
Myosin filament structure in vertebrate smooth muscle (1996) (108)
Structure of A-segments from frog and rabbit skeletal muscle. (1977) (107)
Functional Analysis of Tpr: Identification of Nuclear Pore Complex Association and Nuclear Localization Domains and a Role in mRNA Export (1998) (105)
Structural changes accompanying phosphorylation of tarantula muscle myosin filaments (1987) (103)
Arrangement of the heads of myosin in relaxed thick filaments from tarantula muscle. (1985) (98)
The Troponin Tail Domain Promotes a Conformational State of the Thin Filament That Suppresses Myosin Activity* (2002) (96)
Tropomyosin and the steric mechanism of muscle regulation. (2008) (94)
Troponin organization on relaxed and activated thin filaments revealed by electron microscopy and three-dimensional reconstruction. (2001) (91)
Polymerization of vertebrate non-muscle and smooth muscle myosins. (1987) (88)
Electron microscopy and image analysis of myosin filaments from scallop striated muscle. (1983) (88)
The Globular Tail Domain of Myosin Va Functions as an Inhibitor of the Myosin Va Motor* (2006) (86)
The tail binds to the head–neck domain, inhibiting ATPase activity of myosin VIIA (2009) (84)
Structure of the actin-myosin complex in the presence of ATP. (1985) (75)
Axial arrangement of crossbridges in thick filaments of vertebrate skeletal muscle. (1976) (75)
The globular tail domain puts on the brake to stop the ATPase cycle of myosin Va (2008) (72)
Phosphorylation and calcium antagonistically tune myosin-binding protein C’s structure and function (2016) (71)
An atomic model for actin binding by the CH domains and spectrin-repeat modules of utrophin and dystrophin. (2003) (70)
3-D image reconstruction of reconstituted smooth muscle thin filaments containing calponin: visualization of interactions between F-actin and calponin. (1997) (70)
The influence of topology and glycosylation on the fate of heterologous secretory proteins made in Xenopus oocytes. (1981) (69)
Three-dimensional reconstruction of caldesmon-containing smooth muscle thin filaments (1993) (67)
The Tip of the Coiled-coil Rod Determines the Filament Formation of Smooth Muscle and Nonmuscle Myosin* (2001) (67)
Electron microscopy and 3D reconstruction of F-actin decorated with cardiac myosin-binding protein C (cMyBP-C). (2011) (67)
Phosphorylation of cardiac myosin binding protein C releases myosin heads from the surface of cardiac thick filaments (2017) (66)
Capturing time-resolved changes in molecular structure by negative staining. (2003) (65)
The C Terminus of Cardiac Troponin I Stabilizes the Ca2+-Activated State of Tropomyosin on Actin Filaments (2010) (61)
A molecular model of phosphorylation-based activation and potentiation of tarantula muscle thick filaments. (2011) (59)
Head-head interaction characterizes the relaxed state of Limulus muscle myosin filaments. (2009) (59)
Interacting-heads motif has been conserved as a mechanism of myosin II inhibition since before the origin of animals (2018) (55)
The Xenopus oocyte as a surrogate secretory system. The specificity of protein export. (2005) (54)
Three-dimensional image reconstruction of reconstituted smooth muscle thin filaments: effects of caldesmon. (1997) (53)
Regulation of myosin filament assembly by light-chain phosphorylation. (1983) (52)
Structural changes that occur in scallop myosin filaments upon activation (1985) (52)
Polymerization of myosin on activation of rat anococcygeus smooth muscle (1997) (51)
Three-dimensional organization of troponin on cardiac muscle thin filaments in the relaxed state. (2014) (50)
Blebbistatin stabilizes the helical order of myosin filaments by promoting the switch 2 closed state. (2008) (50)
Modes of Caldesmon Binding to Actin (2004) (48)
Electron microscopy of the actin-myosin head complex in the presence of ATP. (1992) (47)
Structural basis of the relaxed state of a Ca2+-regulated myosin filament and its evolutionary implications (2013) (46)
Structure of the myosin filaments of relaxed and rigor vertebrate striated muscle studied by rapid freezing electron microscopy. (1992) (46)
A method for quick‐freezing live muscles at known instants during contraction with simultaneous recording of mechanical tension (1988) (46)
Heterogeneity of Z-band structure within a single muscle sarcomere: implications for sarcomere assembly. (2003) (45)
Arthrin: a new actin-like protein in insect flight muscle. (1985) (45)
Three-dimensional reconstruction of thin filaments containing mutant tropomyosin. (2000) (44)
Calcium-dependent structural changes in scallop heavy meromyosin. (2001) (42)
Myosin light chain kinase binding to a unique site on F-actin revealed by three-dimensional image reconstruction (2001) (42)
An invertebrate smooth muscle with striated muscle myosin filaments (2015) (42)
Mechanism of the Ca2+-Dependent Interaction between S100A4 and Tail Fragments of Nonmuscle Myosin Heavy Chain IIA (2011) (40)
Fast skeletal muscle regulatory light chain is required for fast and slow skeletal muscle development (2007) (39)
Sequestration and turnover of guinea-pig milk proteins and chicken ovalbumin in Xenopus oocytes. (1979) (39)
Drosophila muscle regulation characterized by electron microscopy and three-dimensional reconstruction of thin filament mutants. (2004) (39)
Myosin-binding protein C corrects an intrinsic inhomogeneity in cardiac excitation-contraction coupling (2015) (39)
Orientation of myosin binding protein C in the cardiac muscle sarcomere determined by domain-specific immuno-EM. (2015) (38)
Visualization of caldesmon on smooth muscle thin filaments. (1997) (38)
Structure, sarcomeric organization, and thin filament binding of cardiac myosin-binding protein-C (2014) (38)
Disorder induced in nonoverlap myosin cross-bridges by loss of adenosine triphosphate. (1989) (33)
Pacemaker-induced transient asynchrony suppresses heart failure progression (2015) (31)
Inhibition of conformational change in smooth muscle myosin by a monoclonal antibody against the 17-kDa light chain. (1989) (31)
Caldesmon and the structure of smooth muscle thin filaments: electron microscopy of isolated thin filaments (1990) (30)
Skeletal myosin binding protein-C isoforms regulate thin filament activity in a Ca2+-dependent manner (2018) (30)
Mass determination of native smooth muscle myosin filaments by scanning transmission electron microscopy. (2002) (30)
Cardiac Myosin Binding Protein-C Plays No Regulatory Role in Skeletal Muscle Structure and Function (2013) (29)
Cryo-EM structure of the inhibited (10S) form of myosin II (2020) (29)
Helical order in tarantula thick filaments requires the "closed" conformation of the myosin head. (2004) (28)
Myosin-binding protein C corrects an intrinsic inhomogeneity in cardiac excitation-contraction coupling (2015) (27)
Mini-thin filaments regulated by troponin-tropomyosin. (2005) (26)
Towards an atomic model of the thick filaments of muscle. (1998) (26)
Myosin filaments isolated from skinned amphibian smooth muscle cells are side-polar (1989) (26)
Purification of native myosin filaments from muscle. (2001) (25)
Ca2+ causes release of myosin heads from the thick filament surface on the milliseconds time scale. (2003) (25)
The myosin interacting-heads motif present in live tarantula muscle explains tetanic and posttetanic phosphorylation mechanisms (2020) (24)
Controlling the gastrointestinal fate of nutraceutical and pharmaceutical-enriched lipid nanoparticles: From mixed micelles to chylomicrons (2017) (24)
An open or closed case for the conformation of calponin homology domains on F-actin? (2004) (23)
Mechanism of phosphorylation of the regulatory light chain of myosin from tarantula striated muscle (2004) (23)
Different head environments in tarantula thick filaments support a cooperative activation process. (2013) (23)
An Actin Subdomain 2 Mutation That Impairs Thin Filament Regulation by Troponin and Tropomyosin* (2000) (23)
The N terminus of myosin-binding protein C extends toward actin filaments in intact cardiac muscle (2021) (22)
Analysis of tarantula skeletal muscle protein sequences and identification of transcriptional isoforms (2009) (22)
Structural basis of the super- and hyper-relaxed states of myosin II (2021) (22)
Effects of a Cardiomyopathy-causing Troponin T Mutation on Thin Filament Function and Structure* (2001) (21)
Molecular structure and organization of filaments in single, skinned smooth muscle cells. (1987) (20)
Correlation of enzymatic properties and conformation of bovine erythrocyte myosin. (1989) (20)
Modulation of striated muscle contraction by binding of myosin binding protein C to actin (2011) (19)
Direct determination of myosin filament symmetry in scallop striated adductor muscle by rapid freezing and freeze substitution. (1991) (19)
Structural changes induced in Ca2+-regulated myosin filaments by Ca2+ and ATP (1989) (18)
An approach to improve the resolution of helical filaments with a large axial rise and flexible subunits. (2016) (17)
Erratum: An atomic model of fimbrin binding to F-actin and its implications for filament crosslinking and regulation (Nature Structural Biology (1998) 5 (787-792)) (1998) (17)
The cMyBP-C HCM variant L348P enhances thin filament activation through an increased shift in tropomyosin position. (2016) (16)
Altered C10 domain in cardiac myosin binding protein-C results in hypertrophic cardiomyopathy. (2019) (15)
Caldesmon and the structure of smooth muscle thin filaments: Immunolocalization of caldesmon on thin filaments (1989) (15)
Discrepancies in length of myosin head (1986) (14)
Changes in crossbridge attachment in a myosin-regulated muscle (1978) (14)
Visualization of myosin helices in sections of rapidly frozen relaxed tarantula muscle. (1992) (14)
Caldesmon and the Structure of Vertebrate Smooth Muscle Thin Filaments (1990) (14)
Getting into the thick (and thin) of it (2019) (13)
Three-dimensional reconstruction of thick filaments from rapidly frozen, freeze-substituted tarantula muscle. (1995) (13)
Ca2+ -induced tropomyosin movement in scallop striated muscle thin filaments. (2008) (12)
The ultrastructural basis of actin filament regulation. (2002) (12)
The mesa trail and the interacting heads motif of myosin II. (2019) (12)
The central role of the tail in switching off 10S myosin II activity (2019) (11)
Structural changes induced in scallop heavy meromyosin molecules by Ca2+ and ATP (1992) (11)
Relaxed tarantula skeletal muscle has two ATP energy-saving mechanisms (2021) (11)
E93K charge reversal on actin perturbs steric regulation of thin filaments. (2005) (11)
Amino terminus of cardiac myosin binding protein-C regulates cardiac contractility. (2021) (11)
Role of the myosin light chains in the regulation of contractile activity. (1982) (10)
Millisecond time-resolved changes occurring in Ca2+-regulated myosin filaments upon relaxation. (2008) (10)
Lattice arrangement of myosin filaments correlates with fiber type in rat skeletal muscle (2019) (9)
Structural Changes Induced in Ca:+-regulated Myosin Filaments by Ca 2+ and ATP (1989) (8)
Isolation, electron microscopy and 3D reconstruction of invertebrate muscle myofilaments. (2012) (8)
Through Thick and Thin--Interfilament Communication in Muscle. (2015) (8)
Direct visualization of myosin filament symmetry in tarantula striated muscle by electron microscopy. (1993) (8)
Fast skeletal myosin-binding protein-C regulates fast skeletal muscle contraction (2021) (7)
The structure of the vertebrate striated muscle thin filament: a tribute to the contributions of Jean Hanson (2004) (7)
Schistosome Muscles Contain Striated Muscle-Like Myosin Filaments in a Smooth Muscle-Like Architecture (2014) (6)
Dilated cardiomyopathy mutation E525K in human beta-cardiac myosin stabilizes the interacting-heads motif and super-relaxed state of myosin (2022) (5)
Muscle structure: First sight of crossbridge crystals (1985) (5)
Unfixed cryosections of striated muscle to study dynamic molecular events. (1994) (5)
Molecular structure of muscle filaments determined by electron microscopy. (2017) (5)
The role of myosin light chain phosphorylation in the regulation of contractile activity. (1983) (4)
Controlling the gastrointestinal fate of nutraceutical‐enriched lipid nanoparticles: From mixed micelles to chylomicrons (2015) (4)
Protein switches in muscle contraction. (1980) (4)
The Inhibited, Interacting-Heads Motif Characterizes Myosin II from the Earliest Animals with Muscles (2015) (4)
Cell biology: Muscle au naturel (1983) (4)
Electron microscopy and three-dimensional reconstruction of native thin filaments reveal species-specific differences in regulatory strand densities. (2010) (3)
Reference Free Single Particle Analysis Of Reconstituted Thin Filaments (2009) (3)
3D Reconstruction of the Folded, Inhibited Form of Vertebrate Smooth Muscle Myosin II by Single Particle Analysis (2017) (3)
Myosin II Head Interaction in Primitive Species (2016) (3)
Interacting-Heads Motif Explains the X-Ray Diffraction Pattern of Relaxed Vertebrate Skeletal Muscle. (2022) (3)
Determination of MyBP-C Orientation in the Cardiac Sarcomere by Immuno-EM (2013) (2)
Variants of the myosin interacting-heads motif. (2023) (2)
Tropomyosin Flexibility Evaluated by Electron Microscopy Image Analysis (2009) (2)
Improved Imaging, 3D Reconstruction and Homology Modeling of Tarantula Thick Filaments (2015) (2)
Signal sequences, secondary modification and the turnover of miscompartmentalized secretory proteins in Xenopus oocytes. (1983) (2)
Atomic Model of F-Actin-Tropomyosin (2011) (2)
Electron Tomography Reveals the Structure of the C-Zone in Striated Muscle (2007) (1)
Capturing Transient Molecular Structures on the Millisecond Time Scale for EM Imaging (2002) (1)
The Tail Binds To The Head-Neck Domain To Form A Folded-Back Conformation That Inhibits The Actin-Activated ATPase Activity Of Drosophila Myosin VIIA (2009) (1)
Phosphorylation and Calcium Antagonistically Tune Myosin‐binding Protein C's Molecular Structure and Function (2016) (1)
The role of myosin light chain phosphorylation in the regulation of contractile activity. (1983) (1)
Modulating Contraction by Binding of MyBP-C to Actin (2012) (1)
Three-Dimensional Structure of the Relaxed State of Calcium-Regulated Myosin Filaments (2010) (1)
Actin cables (1977) (1)
Skeletal Myosin-Binding Protein C Modulates Actomyosin Contractility in an Isoform-Dependent Manner (2017) (1)
EM and 3D-Reconstruction of Thin Filaments Reconstituted with Truncated Troponin I Associated with Myocardial Stunning (2009) (1)
Pushing the Boundary of Storm Resolution: Seeing the Actin Lattice in Muscle (2018) (0)
Near-Atomic Structure of the 10S form of Myosin II: Implications for Inhibition, Activation and Disease (2021) (0)
Crossbridge Arrangement in Cardiac Thick Filaments Isolated from cMyBP-C Phosphomimetic Mice (2015) (0)
Flexibility of Myosin II in Solution (2020) (0)
Em and Single Particle Analysis of Troponin at Low and High Ca2 (2010) (0)
Troponin-Tropomyosin Control of Thin Filament Activity Revealed by Electron Microscopy and 3-D Reconstruction. (2000) (0)
3D-Reconstruction Reveals the Organization of Troponin on Cardiac Thin Filaments (2013) (0)
Abstract 389: Amino Terminal Region of Cardiac Myosin Binding Protein-C is Necessary for Cardiac Function (2016) (0)
Two ATPtp Energy-Saving Mechanisms in Relaxed Tarantula Skeletal Muscle (2021) (0)
Zebrafish Myofilaments and their Assemblies are Good Structural Models for Studying Disease Mutations (2015) (0)
Structural Changes that upon Activation Occur in Scallop Myosin Filaments (2002) (0)
Resolving the Actin Lattice and Identifying the Relative Position of MYBP-C's N-Terminus in Cardiac Muscle using Storm Microscopy (2019) (0)
The C Terminus of Cardiac Troponin I Stabilizes the Ca 2 (cid:1) -Activated State of Tropomyosin on Actin Filaments (2010) (0)
sliding , G203S, K206Q) enhance filament Δ troponin I (K183 Familial hypertrophic cardiomyopathy mutations in (2015) (0)
Structure, sarcomeric organization, and thin filament binding of cardiac myosin-binding protein-C (2014) (0)
Muscle au naturel. (1983) (0)
A Molecular Model of Phosphorylation-Based Activation and Potentiation of Tarantula Muscle Thick Filaments (vol 414, pg 44, 2011) (2014) (0)
Abstract 18980: N-terminal Region of Cardiac Myosin Binding Protein-C Regulates Sarcomeric and Cardiac Function (2014) (0)
Skeletal myosin binding protein-C isoforms regulate thin filament activity in a Ca2+-dependent manner (2018) (0)
cryo-EM structure of tarantula myosin filament: Implications for analysis of myopathy mutations. (2023) (0)
An atomic model of fimbrin binding to F-actin and its implications for filament crosslinking and regulation (1998) (0)
Heavy meromyosin from Schistosoma mansoni muscle thick filament by negative stain EM (2015) (0)
10S myosin II (smooth muscle) (2020) (0)
The Central Role of the Tail in Switching Off Myosin II in Cells (2019) (0)
Structural Changes in Myosin Binding Protein C in Different Biochemical Conditions (2013) (0)
ID: 136: N-TERMINAL REGION OF CARDIAC MYOSIN BINDING PROTEIN-C IS NECESSARY FOR CARDIAC FUNCTION (2016) (0)
A mammalian centriole protein homologous to a component of the mitotic exit network plays a role in completion of cytokinesis, cell cycle progression and microtubule organization. (2002) (0)
Abstract 376: Amino Terminal C0-C1f Region of Cardiac Myosin Binding Protein-C is Essential for Normal Cardiac Function (2015) (0)
Corrigendum to “A Molecular Model of Phosphorylation-Based Activation and Potentiation of Tarantula Muscle Thick Filaments” [J. Mol. Biol. 414 (2011) 44–61] (2014) (0)
Abstract 16613: Functional Role of Fast Myosin Binding Protein-c Expressed in the Failing Myocardium (2014) (0)
Cryo-EM structure of the human cardiac myosin filament (2023) (0)
Actin Filaments Decorated with Cytoskeletal Proteins (1998) (0)
Cryo-EM structure of the inhibited (10S) form of myosin II (2020) (0)
The HCM Mutation L348P in cMyBP-C Enhances Thin Filament Activation through Tropomyosin Shift (2015) (0)
Structural basis of the super-relaxed and hyper-relaxed state of myosin II (2022) (0)
Specific Charged Residues on the Myosin Heavy Chain (K368 and R406) Contribute to Head Interaction of Relaxed Smooth Muscle Myosin (2013) (0)
Electron Microscopy and 3D Reconstruction of Regulated Thin Filaments Decorated with Cardiac Myosin Binding Protein C (2013) (0)
Abstract 18920: In vivo Pathophysiology of Hypertrophic Cardiomyopathy in a Highly Prevalent 25 bp Deletion Mutation in MYBPC3 (2014) (0)
Tarantula heavy meromyosin obtained by flexible docking to Tarantula muscle thick filament Cryo-EM 3D-MAP (2008) (0)
Steric-blocking by tropomyosin visualized in relaxed frog muscle thin filaments (1995) (0)
Myosin-Binding Protein C Corrects an Intrinsic Non-Uniformity in Cardiac Excitation-Contraction Coupling (2015) (0)
Phosphorylation-Induced Structural Change in CMYBP-C affects its Thin Filament Binding and Modulation of Tropomyosin Position (2014) (0)
Abstract 358: Pacemaker Induced Transient Asynchrony (PITA) Restores Contractile Reserve in Synchronous Heart Failure (2015) (0)
Visualization of Troponin on Muscle Thin Filaments by Single Particle Analysis (2012) (0)
[A method for quick freezing of muscles in tetanic contraction]. (1987) (0)
Skeletal Myosin Binding Protein-C Isoforms Modulate Actomyosin Contractility and are Regulated by Phosphorylation (2015) (0)
Thick Filament Activation and Post-Tetanic Potentiation Mechanisms Evolved Differently in Invertebrate and Vertebrate Striated Muscle (2020) (0)
[Method for direct determination of the rotational symmetry of thick muscle filaments by digital image processing]. (1991) (0)

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Published Works

What Schools Are Affiliated With Roger Craig?

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