Presentation is loading. Please wait.

Presentation is loading. Please wait.

How Myosin Generates Force on Actin Filaments

Published byBertha Farmer Modified over 5 years ago

Similar presentations

Presentation on theme: "How Myosin Generates Force on Actin Filaments"— Presentation transcript:

1 How Myosin Generates Force on Actin Filaments
Anne Houdusse, H. Lee Sweeney  Trends in Biochemical Sciences  Volume 41, Issue 12, Pages (December 2016) DOI: /j.tibs Copyright © 2016 Elsevier Ltd Terms and Conditions

2 Figure 1 Key Figure: Myosin Force Generation on Actin Filaments
Several structural states of the motor allow this molecular machine to generate force upon ATP hydrolysis. This scheme provides a unifying view of the current available structural and functional data available for this motor. The myosin heads are shown in red for states of the motor that produce force. This cycle describes the structural transitions during the powerstroke that actin promotes in the motor to sequentially release the hydrolysis products while directing a nanometer-long conformational change in the lever arm coupled to the swing of the converter (green). Trends in Biochemical Sciences  , DOI: ( /j.tibs ) Copyright © 2016 Elsevier Ltd Terms and Conditions

3 Figure 2 Myosin Motor Domain. A ribbon diagram of the myosin V motor illustrates components of the myosin motor domain, including the four subdomains (U50, L50, N-term., and converter) that move relative to each other during the structural transitions of the myosin force-generating cycle on actin. The subdomains are linked by flexible connectors (Switch II, Relay, SH1 helix, and strut). ATP is bound to the switch elements (Switch I and Switch II) and P-loop of the active site. The actin-binding site comprises actin-binding loops (such as the HCM loop and activation loop) from both the upper (U50) and lower (L50) 50-KDa subdomains that are separated by the actin-binding cleft, as well as a helix–loop–helix region of the lower 50-KDa (L50) subdomain. The Switch II connector (orange), situated close to the position where the γ-phosphate of ATP is bound, is found at the other end of this actin-binding cleft compared with the actin-binding site. The central beta sheet has a critical role in closing the cleft during the powerstroke on actin and is part of the transducer region (cyan). A switch II (orange) movement creates a tunnel to release phosphate at the beginning of the powerstroke. Trends in Biochemical Sciences  , DOI: ( /j.tibs ) Copyright © 2016 Elsevier Ltd Terms and Conditions

Download ppt "How Myosin Generates Force on Actin Filaments"

Similar presentations

Motor Proteins - Introduction Part 2 Biochemistry 4000 Dr. Ute Kothe.

Motor Proteins - Introduction Part 2 Biochemistry 4000 Dr. Ute Kothe.
The magic of the sugar code Hans-Joachim Gabius Trends in Biochemical Sciences Volume 40, Issue 7, (July 2015) DOI: 10.1016/j.tibs.2015.04.003 Copyright.

The magic of the sugar code Hans-Joachim Gabius Trends in Biochemical Sciences Volume 40, Issue 7, (July 2015) DOI: /j.tibs Copyright.
Outline: The Lymn-Taylor cycle PCA method (theory & applications) Individual involvement coefficient (theory & applications) Summary Future work.

Outline: The Lymn-Taylor cycle PCA method (theory & applications) Individual involvement coefficient (theory & applications) Summary Future work.
Cytoskeltal Motors. Network of long protein strands located in the cytosol not surrounded by membranes Consist of microtubules and microfilaments Microfilaments.

Cytoskeltal Motors. Network of long protein strands located in the cytosol not surrounded by membranes Consist of microtubules and microfilaments Microfilaments.
RLC ELC Myopathy Loop Actin-Binding Loop Helix- Loop- Helix Motor Domain Lever-Arm 50 kD Cleft Active Site Crystal Structure of Myosin S1 Lever Arm.

RLC ELC Myopathy Loop Actin-Binding Loop Helix- Loop- Helix Motor Domain Lever-Arm 50 kD Cleft Active Site Crystal Structure of Myosin S1 Lever Arm.
Two views of brain function Marcus E. Raichle Trends in Cognitive Sciences Volume 14, Issue 4, Pages 180-190 (April 2010) DOI: 10.1016/j.tics.2010.01.008.

Two views of brain function Marcus E. Raichle Trends in Cognitive Sciences Volume 14, Issue 4, Pages (April 2010) DOI: /j.tics
KRAS: feeding pancreatic cancer proliferation Kirsten L. Bryant, Joseph D. Mancias, Alec C. Kimmelman, Channing J. Der Trends in Biochemical Sciences Volume.

KRAS: feeding pancreatic cancer proliferation Kirsten L. Bryant, Joseph D. Mancias, Alec C. Kimmelman, Channing J. Der Trends in Biochemical Sciences Volume.
Michael A. Geeves, Sherwin S. Lehrer  Biophysical Journal 

Michael A. Geeves, Sherwin S. Lehrer  Biophysical Journal 
Paper Introduction 29th September 2015.

Paper Introduction 29th September 2015.
Sampath Koppole, Jeremy C. Smith, Stefan Fischer  Structure 

Sampath Koppole, Jeremy C. Smith, Stefan Fischer  Structure 
Volume 18, Issue 6, Pages (June 2010)

Volume 18, Issue 6, Pages (June 2010)
How Actin Initiates the Motor Activity of Myosin

How Actin Initiates the Motor Activity of Myosin
Sonja Schmid, Thorsten Hugel  Molecular Cell 

Sonja Schmid, Thorsten Hugel  Molecular Cell 
Volume 11, Issue 12, Pages (December 2003)

Volume 11, Issue 12, Pages (December 2003)
Volume 10, Issue 5, Pages R177-R179 (March 2000)

Volume 10, Issue 5, Pages R177-R179 (March 2000)
Deubiquitination of Lys63-Linkage by a CYLD UBP

Deubiquitination of Lys63-Linkage by a CYLD UBP
ZNF217/ZFP217 Meets Chromatin and RNA

ZNF217/ZFP217 Meets Chromatin and RNA
Erratum: NAD+ metabolism in health and disease

Erratum: NAD+ metabolism in health and disease
Volume 21, Issue 3, Pages (February 2006)

Volume 21, Issue 3, Pages (February 2006)
Volume 52, Issue 6, Pages (December 2013)

Volume 52, Issue 6, Pages (December 2013)

Similar presentations

Ads by Google