Phosphate release and force generation in skeletal muscle fibers.
about
The myosin power strokeDimethyl sulphoxide enhances the effects of P(i) in myofibrils and inhibits the activity of rabbit skeletal muscle contractile proteinsTemperature dependence of active tension in mammalian (rabbit psoas) muscle fibres: effect of inorganic phosphateSubstrate and product dependence of force and shortening in fast and slow smooth muscleEffects of thyroxine on myosin isoform expression and mechanical properties in guinea-pig smooth muscle.Endothermic force generation, temperature-jump experiments and effects of increased [MgADP] in rabbit psoas muscle fibres.Regulation of fibre contraction in a rat model of myocardial ischemia.A metabolite-sensitive, thermodynamically constrained model of cardiac cross-bridge cycling: implications for force development during ischemia.Relaxation of muscle fibers with adenosine 5'-[gamma-thio]triphosphate (ATP[gamma S]) and by laser photolysis of caged ATP[gamma S]: evidence for Ca2+-dependent affinity of rapidly detaching zero-force cross-bridges.Indirect coupling of phosphate release to de novo tension generation during muscle contraction.The direct molecular effects of fatigue and myosin regulatory light chain phosphorylation on the actomyosin contractile apparatus.Strain-dependent modulation of phosphate transients in rabbit skeletal muscle fibers.Nucleotide-dependent contractile properties of Ca(2+)-activated fast and slow skeletal muscle fibers.Effects of phosphate and ADP on shortening velocity during maximal and submaximal calcium activation of the thin filament in skeletal muscle fibers.Phosphate release and force generation in cardiac myocytes investigated with caged phosphate and caged calciumKinetics of relaxation from rigor of permeabilized fast-twitch skeletal fibers from the rabbit using a novel caged ATP and apyraseMechanical characterization of skeletal muscle myofibrils.Initiation of the power stroke in muscle: insights from the phosphate analog AlF4Paramagnetic probes attached to a light chain on the myosin head are highly disordered in active muscle fibers.Relaxation from rigor of skinned trabeculae of the guinea pig induced by laser photolysis of caged ATP.Kinetic mechanism of myofibril ATPase.Two step mechanism of phosphate release and the mechanism of force generation in chemically skinned fibers of rabbit psoas muscleMechanics of glycerinated muscle fibers using nonnucleoside triphosphate substrates.Muscle cross-bridges bound to actin are disordered in the presence of 2,3-butanedione monoxime.ATP analogs and muscle contraction: mechanics and kinetics of nucleoside triphosphate binding and hydrolysis.The ADP release step of the smooth muscle cross-bridge cycle is not directly associated with force generation.Glycolytic inhibition: effects on diastolic relaxation and intracellular calcium handling in hypertrophied rat ventricular myocytes.Calcium oscillations index the extent of calcium loading and predict functional recovery during reperfusion in rat myocardium.Kinetics of force redevelopment in isolated intact frog fibers in solutions of varied osmolarityRecent insights into muscle fatigue at the cross-bridge level.Force generation in single conventional actomyosin complexes under high dynamic loadDCM-related tropomyosin mutants E40K/E54K over-inhibit the actomyosin interaction and lead to a decrease in the number of cycling cross-bridges.Orthovanadate and orthophosphate inhibit muscle force via two different pathways of the myosin ATPase cycle.Direct observation of phosphate inhibiting the force-generating capacity of a miniensemble of Myosin molecules.Coupling between phosphate release and force generation in muscle actomyosin.An exceptionally fast actomyosin reaction powers insect flight muscle.The myofibrillar complex and fatigue: a review.The rates of Ca2+ dissociation and cross-bridge detachment from ventricular myofibrils as reported by a fluorescent cardiac troponin C.Brush border myosin-I structure and ADP-dependent conformational changes revealed by cryoelectron microscopy and image analysis.Trading force for speed: why superfast crossbridge kinetics leads to superlow forces
P2860
Q28216645-6C6F9718-7212-4AB5-B19A-9748B3E8B572Q28348925-17B65E6D-58E7-4E68-BEB8-3E68DB4063AAQ28363229-30ED5B8A-303A-4D0D-A4F5-12FB833F1482Q30664207-156C3DB5-A46A-4601-BF9A-0A6C5A670AEFQ30848085-F2C03938-FD08-4E88-904B-1D36A69273A9Q33217802-96939B8A-EE2B-4004-9606-4BE91F7152EAQ33538026-A8852D88-42FA-4DF5-8D3E-9DA055247F85Q33598914-6971A141-FD55-4E7D-B62C-9DBD3BCE2F48Q33647238-68805EE3-1741-4F94-8A69-106F790ACF97Q33777962-1F52178A-8F52-47F2-8091-8253F0FD31F8Q33784312-0B5ADE40-EC48-4C5E-A3C0-2180B91D153DQ33915329-F5C1507D-4EC9-4318-B934-75EAAC8FD23FQ33916874-71D63ECD-D3FF-4D33-B525-85BD19EE7D18Q34017005-637074EC-4134-4626-BC24-F2F769DF8403Q34017764-43560928-05C3-4CC3-8835-8C561D32A768Q34019096-B88904E2-2345-443A-B488-479453A981ECQ34041116-F74914C3-5922-4310-BFE0-EFF5715DF43AQ34048039-FAD0F6E9-D0B3-450B-B7B0-19F28A32965EQ34090140-594C03F5-E938-448B-8F9D-CE3A0D438160Q34115153-7EA2DA2A-8EE3-42A7-BC03-D546E2F64481Q34115321-8F3CE779-ADEC-4AC6-9A40-780AD4D752CEQ34126975-1F628072-6E71-4CA6-901C-D8233F4433A1Q34127188-5824A89B-C643-4A33-9B28-567D8BA84914Q34129440-5B00E835-8756-4E95-A91E-0D47FC2C2EEBQ34168127-0AB60BBF-29AB-42EF-923E-31508D05A6ABQ34170872-28113999-7CA5-4CF3-A864-5BFD05FF1348Q34224023-73F2288B-D015-41EB-BE24-0B39165B590AQ34245042-69043479-4C2C-488F-99EB-6758758199DDQ34257704-F0D5B1F7-75AA-4F98-9C2E-59D0099AEE77Q34295377-0C1798C6-3660-48A1-9FA7-8E34698C20CAQ34354132-B127AC2B-6D3D-4BF6-A73F-BD8904C098A2Q34450885-58A1279A-3B90-4C0F-B2EE-A969AE7D3393Q34536545-4838C3EE-F1EA-40FA-82FC-BC113DE24A0BQ35051582-AC81DBDA-F1A3-404D-AAEA-789B091ADC78Q35214252-CA4C373C-7293-43DE-9F6F-AB0C35B045C1Q35768746-E7FB4E14-D96F-4637-B618-921A2D7EF81CQ35806233-4876276B-AB7B-4A86-AEC8-E853A87C7258Q36201836-881D8CF8-463B-4E24-8050-4EF94B3BD918Q36276585-3A8323B2-8B02-439B-86D0-47EE8106DB86Q36372409-2A8046B5-EC13-46FB-A19E-B6BCD0EEFFED
P2860
Phosphate release and force generation in skeletal muscle fibers.
description
1985 nî lūn-bûn
@nan
1985年の論文
@ja
1985年学术文章
@wuu
1985年学术文章
@zh-cn
1985年学术文章
@zh-hans
1985年学术文章
@zh-my
1985年学术文章
@zh-sg
1985年學術文章
@yue
1985年學術文章
@zh
1985年學術文章
@zh-hant
name
Phosphate release and force generation in skeletal muscle fibers.
@ast
Phosphate release and force generation in skeletal muscle fibers.
@en
type
label
Phosphate release and force generation in skeletal muscle fibers.
@ast
Phosphate release and force generation in skeletal muscle fibers.
@en
prefLabel
Phosphate release and force generation in skeletal muscle fibers.
@ast
Phosphate release and force generation in skeletal muscle fibers.
@en
P2093
P356
P1433
P1476
Phosphate release and force generation in skeletal muscle fibers.
@en
P2093
Dantzig JA
Goldman YE
Hibberd MG
Trentham DR
P304
P356
10.1126/SCIENCE.3159090
P407
P577
1985-06-01T00:00:00Z