1 / 40

CS35: Models for skeletal muscle contraction

NTP metabolism and transduction. CS35: Models for skeletal muscle contraction. Biochemistry 655 6 April 2011. Goals. Understand the role of fibre diffraction in modeling skeletal muscle The equatorial pattern ([1,0] and [1,1] reflections) The meridional pattern (axial repeats)

miriam
Download Presentation

CS35: Models for skeletal muscle contraction

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. NTP metabolism and transduction CS35: Models for skeletal muscle contraction Biochemistry 655 6 April 2011

  2. Goals • Understand the role of fibre diffraction in modeling skeletal muscle • The equatorial pattern ([1,0] and [1,1] reflections) • The meridional pattern (axial repeats) • Symmetry mismatches • The time-dependence of events involved in contraction • Assembling actomyosin from crystal structures • Multiple states of myosin • Problems associated with the fitting of actin crystal structures (Page, Schutt) • The actin helix-ribbon transition • Possible descent of myosin and actin from class I, II aaRS

  3. Actin conformational changes

  4. Internal rigid body mechanics of Actin

  5. Hinge-bending Shear Rigid-bodies Actin dynamics

  6. Motif 1 is “domain swapped” in HSP70 and SerRS Motif 2 superimposes on the HSP70 ATP-binding motif Strand-loop-helix that fixes thea-NH2 group in Class II aaRS also in HSP70 Class I & II tertiary scaffolds can be coded as SASORFs!!Carter & Duax, Molecular Cell, (2002) 10:705-708 Myosin? Actin?

  7. NTP metabolism and transduction CS36: Energy transduction revisited: a retrospective and summary Biochemistry 655 18 November 2009

  8. Goals • Discuss the allosteric behavior of myosin (Shriver & Sykes). • Multiple energy wells • Different ligand affinities • Recite the abstract from Marsten, et al. • Understand the meaning of all terms! • Describe the effect of AMPPNP • Is it really non-hydrolyzable? • If so, how to explain its effects on glycerol extracted muscle? • Walking through the cross-bridge cycle in reverse. • Understand why the “series elastic component” is necessary. • Terrill Hill’s model • Efficiency of energy conversion • The actin helix-ribbon transition (Schutt)

  9. ATP ADP + Pi Myosin is an allosteric enzyme

  10. Deconstruct this sentence!

  11. Chemomechanical coupling

More Related