Conformational Changes between the Active-Site and Regulatory Light Chain of Myosin as Determined by Luminescence Resonance Energy Transfer: The Effect of Nucleotides and Actin

Myosin is thought to generate movement of actin filaments via a conformational change between its lightchain domain and its catalytic domain that is driven by the binding of nucleotides and actin. To monitor this change, we have measured distances between a gizzard regulatory light chain (Cys 108) a...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 1998-12, Vol.95 (26), p.15309-15314
Main Authors: Xiao, Ming, Li, Handong, Snyder, Gregory E., Cooke, Roger, Yount, Ralph G., Selvin, Paul R.
Format: Article
Language:English
Subjects:
Actins
Actins - metabolism
Active sites
Adenine Nucleotides - metabolism
Adenosine Diphosphate - metabolism
Animals
Binding Sites
Biological Sciences
Cellular biology
Chickens
Energy Transfer
Fluorescence
Fluorescent Dyes
Gizzard, Avian
Ligands
Luminescence
Luminescent Measurements
Models, Molecular
Muscle, Skeletal - metabolism
Muscle, Smooth - metabolism
Muscular system
Myosin Light Chains - chemistry
Myosin Light Chains - metabolism
Nucleotides
Protein Conformation
Protein Structure, Secondary
Quantum Theory
Rabbits
Rotation
Terbium
Vanadates
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Summary:Myosin is thought to generate movement of actin filaments via a conformational change between its lightchain domain and its catalytic domain that is driven by the binding of nucleotides and actin. To monitor this change, we have measured distances between a gizzard regulatory light chain (Cys 108) and the active site (near or at Trp 130) of skeletal myosin subfragment 1 (S1) by using luminescence resonance energy transfer and a photoaffinity ATP-lanthanide analog. The technique allows relatively long distances to be measured, and the label enables site-specific attachment at the active-site with only modest affect on myosin's enzymology. The distance between these sites is 66.8 ± 2.3 angstrom when the nucleotide is ADP and is unchanged on binding to actin. The distance decreases slightly with ADP-BeF3, (-1.6 ± 0.3 angstrom) and more significantly with ADP-AlF4(-4.6 ± 0.2 angstrom). During steady-state hydrolysis of ATP, the distance is temperature-dependent, becoming shorter as temperature increases and the complex with ADP· Piis favored over that with ATP. We conclude that the distance between the active site and the light chain varies as Acto-S1-ADP ≈ S1-ADP > S1-ADP-BeF3> S1-ADP-AlF4≈ S1-ADP-Piand that S1-ATP > S1-ADP-Pi. The changes in distance are consistent with a substantial rotation of the light-chain binding domain of skeletal S1 between the prepowerstroke state, simulated by S1-ADP-AlF4, and the post-powerstroke state, simulated by acto-S1-ADP.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.95.26.15309