Mechanical design of the first proximal Ig domain of human cardiac titin revealed by single molecule force spectroscopy.
about
Isopeptide bonds block the mechanical extension of pili in pathogenic Streptococcus pyogenesContour length and refolding rate of a small protein controlled by engineered disulfide bonds.Secondary and tertiary structure elasticity of titin Z1Z2 and a titin chain model.Discovery through the computational microscope.Mechanical strength of 17,134 model proteins and cysteine slipknotsProperties of titin immunoglobulin and fibronectin-3 domains.Force-dependent chemical kinetics of disulfide bond reduction observed with single-molecule techniques.Towards design principles for determining the mechanical stability of proteins.Ca2+ binding enhanced mechanical stability of an archaeal crystallin.Specific bonds between an iron oxide surface and outer membrane cytochromes MtrC and OmcA from Shewanella oneidensis MR-1.The Nanomechanics of Lipid Multibilayer Stacks Exhibits Complex Dynamics.Phosphorylation modulates the mechanical stability of the cardiac myosin-binding protein C motif.Single-molecule Force Spectroscopy Predicts a Misfolded, Domain-swapped Conformation in human γD-Crystallin ProteinMechanical stability of helical beta-peptides and a comparison of explicit and implicit solvent models.Mechanical stability and differentially conserved physical-chemical properties of titin Ig-domains.Modulation of titin-based stiffness by disulfide bonding in the cardiac titin N2-B unique sequenceBinding of Myomesin to Obscurin-Like-1 at the Muscle M-Band Provides a Strategy for Isoform-Specific Mechanical Protection.Structure of giant muscle proteins.A fluorescence energy transfer-based mechanical stress sensor for specific proteins in situ.Determination of contact maps in proteins: A combination of structural and chemical approaches.Mechanically induced titin kinase activation studied by force-probe molecular dynamics simulations.Single-molecule studies on PolySUMO proteins reveal their mechanical flexibilitySecondary structure, mechanical stability, and location of transition state of proteinsEngineering proteins with enhanced mechanical stability by force-specific sequence motifs.Diatom adhesive mucilage contains distinct supramolecular assemblies of a single modular protein.Mechanically unfolding the small, topologically simple protein L.Adhesive modular proteins occur in the extracellular mucilage of the motile, pennate diatom Phaeodactylum tricornutum.Selection of optimal variants of Gō-like models of proteins through studies of stretchingToward a molecular understanding of the anisotropic response of proteins to external forces: insights from elastic network models.Mechanochemical evolution of the giant muscle protein titin as inferred from resurrected proteins.Disulfide isomerization reactions in titin immunoglobulin domains enable a mode of protein elasticity.The Work of Titin Protein Folding as a Major Driver in Muscle Contraction.Tuning protein mechanics through an ionic cluster graft from an extremophilic protein.
P2860
Q28272641-CEE9D6CD-4081-44DD-BD97-69A60FD92BEBQ30357288-6DC32417-38D7-404C-805B-2CF39B0A5349Q30479873-FEC5760B-1F9C-4FC0-B5BD-9ECEDCCC917AQ33511109-194C0430-46FE-4691-B464-38258664ACE4Q33513957-B2864938-C9C7-4170-A02B-67CC285C17C1Q34342430-1B08807D-9A3B-4C85-A307-3BEF9195FAD8Q34624392-733C8EA7-88BF-455B-BC06-BDA7820A03DBQ34976764-11F382A7-B993-405E-A8A1-79A93709E149Q35146699-D868A819-5B20-4E10-9A16-A2514FCFB9C3Q35879446-24643A2C-6DD2-4D9E-878A-9CD159DBC58AQ36371598-671522FF-F9A2-4EC8-856E-B41DE509FD7BQ36554361-9858BF93-2D2F-4212-B711-96E11CA08548Q36594729-0848FFC2-A3AE-4555-A7E7-4A65E629CD20Q36899961-0D73E9DB-F742-45EB-8B2F-FF8DBF40A3D0Q37163199-72826D13-02C4-46E7-BE82-04BC1F62F3C9Q37281915-EF3FCE2D-F5A1-41BD-8858-8F74B14BD4EAQ37574394-BDC1DBEC-04B2-4D74-B30F-DEAA4B9D4DB0Q38174598-E4012B97-B349-4710-A765-B55E9F0A586CQ38619850-31255AE5-AB8D-49E7-A306-9D655CC4DDA8Q40152267-926C22D9-55B8-4DF5-AEB1-6C63B23FDBC2Q40317260-D1D91293-0985-407D-B717-748AD140127AQ40912791-CAF41F2A-A4B4-481A-BE2C-D5C3AD273EBEQ41678915-3EF6BB21-4874-4AAF-9601-770BC0EC184AQ41947472-A54430AC-D7AC-4981-9BA2-1AEB21E25C1CQ42067845-7923E126-F28D-42BA-9000-06A8325FB992Q42161294-2975D8E3-1AE2-41A9-AAB0-37BE02868A11Q42231258-2EBAC223-E5EC-4EF3-A69C-D0C5A1A8F5BDQ42771246-C9F6C4EA-2BAD-4C46-875D-A50CDA65855EQ43111576-353C515F-6823-4535-A631-B99EC64AA781Q46341464-28C9D1B3-D14C-41F5-B56B-1277F20340DEQ48043256-658F5516-882C-45F4-90C3-B584AD859645Q50058195-2A3C764E-28B4-4EB2-B9A9-68CB914B0D5AQ51546845-085F42B2-57BE-4B6C-BCDB-88C1517B4B9A
P2860
Mechanical design of the first proximal Ig domain of human cardiac titin revealed by single molecule force spectroscopy.
description
2003 nî lūn-bûn
@nan
2003年の論文
@ja
2003年学术文章
@wuu
2003年学术文章
@zh
2003年学术文章
@zh-cn
2003年学术文章
@zh-hans
2003年学术文章
@zh-my
2003年学术文章
@zh-sg
2003年學術文章
@yue
2003年學術文章
@zh-hant
name
Mechanical design of the first ...... e molecule force spectroscopy.
@en
Mechanical design of the first ...... e molecule force spectroscopy.
@nl
type
label
Mechanical design of the first ...... e molecule force spectroscopy.
@en
Mechanical design of the first ...... e molecule force spectroscopy.
@nl
prefLabel
Mechanical design of the first ...... e molecule force spectroscopy.
@en
Mechanical design of the first ...... e molecule force spectroscopy.
@nl
P1476
Mechanical design of the first ...... e molecule force spectroscopy.
@en
P2093
Julio M Fernandez
P356
10.1016/J.JMB.2003.09.036
P407
P50
P577
2003-11-01T00:00:00Z