SSBD - SSBD:database - Fig2B_STED_mitochondria

Detail of Fig2B_STED_mitochondria_after

Title

STED images of mitochondria after deconvolution

Description

STED images of mitochondria after deconvolution

Release, Updated

2022-11-23

Organism

Homo sapiens ( NCBITaxon:9606 )

Strain(s)

Cell Line

HeLa cell ( CLO_0003684 )

Molecular Function (MF)

Biological Process (BP)

mitochondrial fusion ( GO:0008053 )

Cellular Component (CC)

mitochondrion ( GO:0005739 ) mitochondrial crista ( GO:0030061 ) mitochondrial inner membrane ( GO:0005743 ) mitochondrial outer membrane ( GO:0005741 ) mitochondrial membrane ( GO:0031966 )

Biological Imaging Method

Stimulation emission depletion ( Fbbi:00000334 )

X scale

0.0142045 micrometer/pixel

Y scale

0.0142045 micrometer/pixel

Z scale

1 micrometer/slice

Image Acquisition

Experiment type

Microscope type

Acquisition mode

Contrast method

Microscope model

Detector model

Objective model

Filter set

Summary of Methods

See details in Wang C, et. al. (2019) Proc Natl Acad Sci U S A., 116(32):15817-15822.

Related paper(s)

Chenguang Wang, Masayasu Taki, Yoshikatsu Sato, Yasushi Tamura, Hideyuki Yaginuma, Yasushi Okada, Shigehiro Yamaguchi (2019) A photostable fluorescent marker for the superresolution live imaging of the dynamic structure of the mitochondrial cristae., Proceedings of the National Academy of Sciences of the United States of America, Volume 116, Number 32, pp. 15817-15822

Published in 2019 Aug 6 (Electronic publication in July 23, 2019, midnight )

doi: 10.1073/pnas.1905924116
pmid: 31337683

(Abstract) Stimulation emission depletion (STED) microscopy enables ultrastructural imaging of organelle dynamics with a high spatiotemporal resolution in living cells. For the visualization of the mitochondrial membrane dynamics in STED microscopy, rationally designed mitochondrial fluorescent markers with enhanced photostability are required. Herein, we report the development of a superphotostable fluorescent labeling reagent with long fluorescence lifetime, whose design is based on a structurally reinforced naphthophosphole fluorophore that is conjugated with an electron-donating diphenylamino group. The combination of long-lived fluorescence and superphotostable features of the fluorophore allowed us to selectively capture the ultrastructures of the mitochondrial cristae with a resolution of approximately 60 nm when depleted at 660 nm. This chemical tool provides morphological information of the cristae, which has so far only been observed in fixed cells using electron microscopy. Moreover, this method gives information about the dynamic ultrastructures such as the intermembrane fusion in different mitochondria as well as the intercristae mergence in a single mitochondrion during the apoptosis-like mitochondrial swelling process.

(MeSH Terms)

Contact

Taki Masayasu, Yasushi Okada, Shigehiro Yamaguchi , Nagoya University, RIKEN, Nagoya University , Institute of Transformative Bio-Molecules, Center for Biosystems Dynamics Research , Institute of Transformative Bio-Molecules , Functional Organic Materials Laboratory, Laboratory for Cell Polarity Regulation , Functional Organic Materials Laboratory