TY - JOUR
T1 - Cell-sized confinement controls generation and stability of a protein wave for spatiotemporal regulation in cells
AU - Kohyama, Shunshi
AU - Yoshinaga, Natsuhiko
AU - Yanagisawa, Miho
AU - Fujiwara, Kei
AU - Doi, Nobuhide
N1 - Funding Information:
We thank Ms. A Yoshida (Keio University) for supporting protein purification, and Prof. K Yoshikawa (Doshisha University), Prof. H Kitahata (Chiba University), Prof. T Sakurai (Chiba University), Prof. Karsten Kruse (University of Geneva), and Prof. Toshiyuki Ogawa (Meiji University) for helpful discussion. We are grateful for financial support from JSPS KAKENHI Grant Number JP16H00809, JP26650044, JP15KT0081, JP15H00826, JP18H04565 (to KF), JP26800219, JP16H00793, and JP17K05605 (to NY). We are also grateful for a Ph.D. Program Research Grant at Keio university awarded to SK.
Publisher Copyright:
© Kohyama et al.
PY - 2019/7
Y1 - 2019/7
N2 - The Min system, a system that determines the bacterial cell division plane, uses changes in the localization of proteins (a Min wave) that emerges by reaction-diffusion coupling. Although previous studies have shown that space sizes and boundaries modulate the shape and speed of Min waves, their effects on wave emergence were still elusive. Here, by using a microsized fully confined space to mimic live cells, we revealed that confinement changes the conditions for the emergence of Min waves. In the microsized space, an increased surface-tovolume ratio changed the localization efficiency of proteins on membranes, and therefore, suppression of the localization change was necessary for the stable generation of Min waves. Furthermore, we showed that the cell-sized space strictly limits parameters for wave emergence because confinement inhibits both the instability and excitability of the system. These results show that confinement of reaction-diffusion systems has the potential to control spatiotemporal patterns in live cells.
AB - The Min system, a system that determines the bacterial cell division plane, uses changes in the localization of proteins (a Min wave) that emerges by reaction-diffusion coupling. Although previous studies have shown that space sizes and boundaries modulate the shape and speed of Min waves, their effects on wave emergence were still elusive. Here, by using a microsized fully confined space to mimic live cells, we revealed that confinement changes the conditions for the emergence of Min waves. In the microsized space, an increased surface-tovolume ratio changed the localization efficiency of proteins on membranes, and therefore, suppression of the localization change was necessary for the stable generation of Min waves. Furthermore, we showed that the cell-sized space strictly limits parameters for wave emergence because confinement inhibits both the instability and excitability of the system. These results show that confinement of reaction-diffusion systems has the potential to control spatiotemporal patterns in live cells.
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U2 - 10.7554/eLife.44591
DO - 10.7554/eLife.44591
M3 - Article
C2 - 31358115
AN - SCOPUS:85070791343
SN - 2050-084X
VL - 8
JO - eLife
JF - eLife
M1 - e44591
ER -