Detail of Fig1C_MT-Eg5

(Too many images for preview; see images in SSBD:OMERO Dataset)


Project
Title
Time-lapse confocal images of ATTO647N-labeled microtuble (MT) and GFP-fused Eg5
Description
NA
Release, Updated
2017-10-03,
2018-11-15
License
CC BY
Kind
Image data based on Experiment
File Formats
Data size
1.4 GB

Organism
-
Strain(s)
-
Cell Line
-
Gene symbols
Eg5
Protein tags
GFP

Datatype
microtubule dynamics
Molecular Function (MF)
Biological Process (BP)
-
Cellular Component (CC)
microtubule ( GO:0005874 )
Biological Imaging Method
XYZ Scale
XY: 1.2401 micrometer per pixel, Z: NA
T scale
1 minute for each time interval

Image Acquisition
Experiment type
TimeLapse
Microscope type
ConfocalMicroscope
Acquisition mode
LaserScanningConfocalMicroscopy
Contrast method
Fluorescence
Microscope model
Nikon Eclipse Ti-E Microscope +A1plus confocal system
Detector model
A1-DU4 4 Detector Unit
Objective model
Nikon Plan Apo VC 20x DIC N2
Filter set
-

Summary of Methods
See details in Torisawa et al. (2016) Biophysical Journal, 111(2): 373-385.
Related paper(s)

Takayuki Torisawa, Daisuke Taniguchi, Shuji Ishihara, Kazuhiro Oiwa (2016) Spontaneous Formation of a Globally Connected Contractile Network in a Microtubule-Motor System., Biophysical journal, Volume 111, Number 2, pp. 373-385

Published in 2016 Jul 26

(Abstract) Microtubule (MT) networks play key roles in cell division, intracellular transport, and cell motility. These functions of MT networks occur through interactions between MTs and various associated proteins, notably motor proteins that bundle and slide MTs. Our objective in this study was to address the question of how motors determine the nature of MT networks. We conducted in vitro assays using homotetrameric kinesin Eg5, a motor protein involved in the formation and maintenance of the mitotic spindle. The mixing of Eg5 and MTs produced a range of spatiotemporal dynamics depending on the motor/filament ratio. Low motor/filament ratios produced globally connected static MT networks with sparsely distributed contractile active nodes (motor-accumulating points with radially extending MTs). Increasing the motor/filament ratio facilitated the linking of contractile active nodes and led to a global contraction of the network. When the motor/filament ratio was further increased, densely distributed active nodes formed local clusters and segmented the network into pieces with their strong contractile forces. Altering the properties of the motor through the use of chimeric Eg5, which has kinesin-1 heads, resulted in the generation of many isolated asters. These results suggest that the spatial distribution of contractile active nodes determines the dynamics of MT-motor networks. We then developed a coarse-grained model of MT-motor networks and identified two essential features for reproducing the experimentally observed patterns: an accumulation of motors that form the active nodes necessary to generate contractile forces, and a nonlinear dependency of contractile force on motor densities. Our model also enabled us to characterize the mechanical properties of the contractile network. Our study provides insight into how local motor-MT interactions generate the spatiotemporal dynamics of macroscopic network structures.
(MeSH Terms)

Contact
Kazuhiro Oiwa , National Institute of Information and Communications Technology , Advanced ICT Research Institute
Contributors
Takayuki Torisawa, Daisuke Taniguchi, Shuji Ishihara, Kazuhiro Oiwa

OMERO Dataset
OMERO Project
Source