1 / 18

RLC

Crystal Structure of Myosin S1. Motor Domain. RLC. Active Site. ELC. Lever Arm. Myopathy Loop. 50 kD Cleft. Actin-Binding Loop. Helix-Loop-Helix. Lever-Arm. Pi, ADP. ATP. Hydrolysis. Structure/Function Relationships in Myosin. Hydrolyze ATP Bind Actin Generate Powerstroke

arden
Download Presentation

RLC

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Crystal Structure of Myosin S1 Motor Domain RLC Active Site ELC Lever Arm Myopathy Loop 50 kD Cleft Actin-Binding Loop Helix-Loop-Helix Lever-Arm

  2. Pi, ADP ATP Hydrolysis Structure/Function Relationships in Myosin • Hydrolyze ATP • Bind Actin • Generate Powerstroke • Coordinate Functions

  3. Myosin: “A Whale of a Protein” Blow Hole Tail Mouth

  4. Structure/Function Relationships in Myosin Lever-arm - generates powerstroke. Active Site - hydrolyzes ATP. Rigid Relay Loop - along with converter domain coordinates active site and lever arm. Actin-binding Cleft - mediates affinity for actin.

  5. How Can the Details of Changes Be Established? Crystallograhy can provide some information about changes since myosin can be crystallized in different nucleotide states. However, to address DYNAMIC changes in the protein other methods are required which are 1) compatible with biological reaction conditions, 2) sensitive to structural changes, and 3) have excellent temporal resolution. Fluorescence Spectroscopy

  6. 2936 441 512 Skel. YLRKSPFDAKSSVFVVHPKES / EKM.FLWMVIRIN / KKEGIEWEFID Card. EAQTRPFDLKKDVFVPDDKQE / ERM.FNWMVTRIN / KKEGIEWTFID Dcty KLTVSDKRYIWYNPDPKERDS / GRL.FLWLVKKIN / LKEKINWTFID Smooth LAQA.DWSAKKLVWVPSEKHG / ERL.FRWILTRVN / QREGIEWNFID    FF F F 546 597 625 Skel. / ILEEECMFPKATD / DYNISGWLEKNK / KTLALLFATY... Card. / ILEEECMFPKATD / DYNIIGWLQKNK / KLLSTLFANY... Dicty / LLDEQSVFPNATD / MYEIQDWLEKNK / NVVTKLFND.... Smooth / LLDEECWFPKATD / TYNASAWLTKNM / KFVADLWKDVDRI    M F W

  7. Upper 50 kDa Subdomain F425W ELC Actin-Binding Cleft V413W W546M Lower 50 kDa Subdomain

  8. FHC – Familial Hypertrophic Cardiomyopathy R413Q mutation Normal

  9. Steady-State Fluorescence Properties MAX(nm) 333 0.36 344 0.20 351 0.14

  10. Acrylamide Quenching F0/F = 1 + KSV[Q] KSV (M-1) kq (M-1·ns-1) 11.5 6.4 5.3 1.7

  11. Relative Fluorescence of 625 MDE Bound to Actin

  12. Actin-Induced Conformational Changes Trp625 - Unchanged Trp546 -adopts a more buried conformation MAX (nm) MAX (nm) 334 344 333

  13. Actin Bound Fluorescence: ADP-Bound vs. Rigor MAX 347 341 338 MAX 336 337

  14. DHNBS Quenching: ADP-Bound vs. Rigor

  15. Fluorescence from F425W-MDE in the absence of actin

  16. Steady-State Fluorescence of F425W-MDE Nucleotide Bound Peak Intensity MAX KSV (M-1·ns-1) None 100% 338 4.1 ± 0.02 MgADP 97% 339 4.1 ± 0.02 MgATP 80% 345 5.7 ± 0.06

  17. Structural Model of Acto-Myosin Interactions A:M-ATP A:M-ADP A:M Actin V413W W546 Cleft Conformational Changes F425W Weak Binding Cleft Closure Motor Domain Rotation

More Related