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• Articles by B.J. Thevenin
• Articles by S.B. Shohet

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• Conformational Selection During Weak Binding at the Actin an...

  Conformational Selection During Weak Binding at the Actin and Myosin Interface Biophysical Journal, Volume 79, Issue 3, 1 September 2000, Pages 1498-1510 Jin Xu and Douglas D. Root Abstract The molecular mechanism of the powerstroke in muscle is examined by resonance energy transfer techniques. Recent models suggesting a pre-cocking of the myosin head involving an enormous rotation between the lever arm and the catalytic domain were tested by measuring separation distances among myosin subfragment-2, the nucleotide site, and the regulatory light chain in the presence of nucleotide transition state analogs. Only small changes (<0.5nm) were detected that are consistent with internal conformational changes of the myosin molecule, but not with extreme differences in the average lever arm position suggested by some atomic models. These results were confirmed by stopped-flow resonance energy transfer measurements during single ATP turnovers on myosin. To examine the participation of actin in the powerstroke process, resonance energy transfer between the regulatory light chain on myosin subfragment-1 and the C-terminus of actin was measured in the presence of nucleotide transition state analogs. The efficiency of energy transfer was much greater in the presence of ADP-AlF, ADP-BeF, and ADP-vanadate than in the presence of ADP or no nucleotide. These data detect profound differences in the conformations of the weakly and strongly attached cross-bridges that appear to result from a conformational selection that occurs during the weak binding of the myosin head to actin. Abstract | Full Text | PDF (412 kb)

• Fluorescence Depolarization of Actin Filaments in Reconstruc...

  Fluorescence Depolarization of Actin Filaments in Reconstructed Myofibers: The Effect of S1 or pPDM-S1 on Movements of Distinct Areas of Actin Biophysical Journal, Volume 86, Issue 5, 1 May 2004, Pages 3020-3029 Yu.S. Borovikov, I.V. Dedova, C.G. dos Remedios, N.N. Vikhoreva, P.G. Vikhorev, S.V. Avrova, T.L. Hazlett and B.W. Van Der Meer Abstract Fluorescence polarization measurements were used to study changes in the orientation and order of different sites on actin monomers within muscle thin filaments during weak or strong binding states with myosin subfragment-1. Ghost muscle fibers were supplemented with actin monomers specifically labeled with different fluorescent probes at Cys-10, Gln-41, Lys-61, Lys-373, Cys-374, and the nucleotide binding site. We also used fluorescent phalloidin as a probe near the filament axis. Changes in the orientation of the fluorophores depend not only on the state of acto-myosin binding but also on the location of the fluorescent probes. We observed changes in polarization (i.e., orientation) for those fluorophores attached at the sites directly involved in myosin binding (and located at high radii from the filament axis) that were contrary to the fluorophores located at the sites close to the axis of thin filament. These altered probe orientations suggest that myosin binding alters the conformation of F-actin. Strong binding by myosin heads produces changes in probe orientation that are opposite to those observed during weak binding. Abstract | Full Text | PDF (143 kb)

• Application of Surface Plasmon Coupled Emission to Study of ...

  Application of Surface Plasmon Coupled Emission to Study of Muscle Biophysical Journal, Volume 91, Issue 7, 1 October 2006, Pages 2626-2635 J. Borejdo, Z. Gryczynski, N. Calander, P. Muthu and I. Gryczynski Abstract Muscle contraction results from interactions between actin and myosin cross-bridges. Dynamics of this interaction may be quite different in contracting muscle than in vitro because of the molecular crowding. In addition, each cross-bridge of contracting muscle is in a different stage of its mechanochemical cycle, and so temporal measurements are time averages. To avoid complications related to crowding and averaging, it is necessary to follow time behavior of a single cross-bridge in muscle. To be able to do so, it is necessary to collect data from an extremely small volume (an attoliter, 10 liter). We report here on a novel microscopic application of surface plasmon-coupled emission (SPCE), which provides such a volume in a live sample. Muscle is fluorescently labeled and placed on a coverslip coated with a thin layer of noble metal. The laser beam is incident at a surface plasmon resonance (SPR) angle, at which it penetrates the metal layer and illuminates muscle by evanescent wave. The volume from which fluorescence emanates is a product of two near-field factors: the depth of evanescent wave excitation and a distance-dependent coupling of excited fluorophores to the surface plasmons. The fluorescence is quenched at the metal interface (up to ∼10nm), which further limits the thickness of the fluorescent volume to ∼50nm. The fluorescence is detected through a confocal aperture, which limits the lateral dimensions of the detection volume to ∼200nm. The resulting volume is ∼2×10 liter. The method is particularly sensitive to rotational motions because of the strong dependence of the plasmon coupling on the orientation of excited transition dipole. We show that by using a high-numerical-aperture objective (1.65) and high-refractive-index coverslips coated with gold, it is possible to follow rotational motion of 12 actin molecules in muscle with millisecond time resolution. Abstract | Full Text | PDF (419 kb)

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Abstract

Single-photon radioluminescence (SPR), the excitation of fluorophores by short-range beta-decay electrons, was developed for the measurement of submicroscopic distances. The cytoplasmic domain of band 3 (cdb3) is the primary, multisite anchorage for the erythrocyte skeleton. To begin to define the membrane arrangement of the highly asymmetrical cdb3 structure, the distance from the bilayer of Cys-201 next to the "hinge" of cdb3 was measured by both SPR and resonance energy transfer (RET). cdb3 was labeled at Cys-201 with fluorescein maleimide. For SPR measurements, the bilayer was labeled with [3H]oleic acid. The corrected cdb3-specific SPR signal was 98 +/- 2 cps microCi-1 [mumol band 3]-1. From this and the signal from a parallel sample in which 3H2O was substituted for [3H]oleic acid to create uniform geometry between 3H and the fluorophores, a Cys-201-to-bilayer separation of 39 +/- 7 A was calculated. Confirmatory distances of 40 and 43 A were obtained by RET between fluorescein on Cys-201 and eosin and rhodamine B lipid probes, respectively. This distance indicates that Cys-201 lies near band 3's vertical axis of symmetry and that the subdomain of cdb3 between the hinge and the membrane is not significantly extended. In addition, these results validate SPR as a measure of molecular distances in biological systems.