Detail of Fig3D_CAHS3-GFP_TFE



Project
Title
Time-lapse confocal images of fibril formation of CAHS3-GFP proteins before and after adding TFE.
Description
Time-lapse confocal images of fibril formation of CAHS3-GFP proteins before and after adding TFE.
Release, Updated
2023-05-11,
2023-05-29
License
CC BY
Kind
Image data
File Formats
.lsm
Data size
242.9 MB

Organism
-
Strain(s)
-
Cell Line
-
Protein names
CAHS3
Protein tags
GFP

Datatype
-
Molecular Function (MF)
Biological Process (BP)
stamen filament development ( GO:0080086 )
Cellular Component (CC)
Biological Imaging Method
time lapse microscopy ( Fbbi:00000249 )
X scale
0.2196470 micrometer/pixel
Y scale
0.2196470 micrometer/pixel
Z scale
-
T scale
4.92 seconds of time interval

Image Acquisition
Experiment type
-
Microscope type
-
Acquisition mode
-
Contrast method
-
Microscope model
-
Detector model
-
Objective model
-
Filter set
-

Summary of Methods
See details in Tanaka A, et. al. (2022) PLoS Biol. Sep 6;20(9):e3001780.
Related paper(s)

Akihiro Tanaka, Tomomi Nakano, Kento Watanabe, Kazutoshi Masuda, Gen Honda, Shuichi Kamata, Reitaro Yasui, Hiroko Kozuka-Hata, Chiho Watanabe, Takumi Chinen, Daiju Kitagawa, Satoshi Sawai, Masaaki Oyama, Miho Yanagisawa, Takekazu Kunieda (2022) Stress-dependent cell stiffening by tardigrade tolerance proteins that reversibly form a filamentous network and gel., PLoS biology, Volume 20, Number 9, pp. e3001780

Published in 2022 Sep (Electronic publication in Sept. 6, 2022, midnight )

(Abstract) Tardigrades are able to tolerate almost complete dehydration by entering a reversible ametabolic state called anhydrobiosis and resume their animation upon rehydration. Dehydrated tardigrades are exceptionally stable and withstand various physical extremes. Although trehalose and late embryogenesis abundant (LEA) proteins have been extensively studied as potent protectants against dehydration in other anhydrobiotic organisms, tardigrades produce high amounts of tardigrade-unique protective proteins. Cytoplasmic-abundant heat-soluble (CAHS) proteins are uniquely invented in the lineage of eutardigrades, a major class of the phylum Tardigrada and are essential for their anhydrobiotic survival. However, the precise mechanisms of their action in this protective role are not fully understood. In the present study, we first postulated the presence of tolerance proteins that form protective condensates via phase separation in a stress-dependent manner and searched for tardigrade proteins that reversibly form condensates upon dehydration-like stress. Through a comprehensive search using a desolvating agent, trifluoroethanol (TFE), we identified 336 proteins, collectively dubbed "TFE-Dependent ReversiblY condensing Proteins (T-DRYPs)." Unexpectedly, we rediscovered CAHS proteins as highly enriched in T-DRYPs, 3 of which were major components of T-DRYPs. We revealed that these CAHS proteins reversibly polymerize into many cytoskeleton-like filaments depending on hyperosmotic stress in cultured cells and undergo reversible gel-transition in vitro. Furthermore, CAHS proteins increased cell stiffness in a hyperosmotic stress-dependent manner and counteract the cell shrinkage caused by osmotic pressure, and even improved the survival against hyperosmotic stress. The conserved putative helical C-terminal region is necessary and sufficient for filament formation by CAHS proteins, and mutations disrupting the secondary structure of this region impaired both the filament formation and the gel transition. On the basis of these results, we propose that CAHS proteins are novel cytoskeleton-like proteins that form filamentous networks and undergo gel-transition in a stress-dependent manner to provide on-demand physical stabilization of cell integrity against deformative forces during dehydration and could contribute to the exceptional physical stability in a dehydrated state.
(MeSH Terms)

Contact
Takekazu Kunieda , The University of Tokyo , Graduate School of Science , Department of Biological Sciences
Contributors

OMERO Dataset
OMERO Project
Source