Zebrafish skeleton development: High resolution micro-CT and FIB-SEM block surface serial imaging for phenotype identification

Although bone is one of the most studied living materials, many questions about the manner in which bones form remain unresolved, including fine details of the skeletal structure during development. In this study, we monitored skeleton development of zebrafish larvae, using calcein fluorescence, hig...

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Bibliographic Details
Published in:PloS one 2017-12, Vol.12 (12), p.e0177731-e0177731
Main Authors: Silvent, Jeremie, Akiva, Anat, Brumfeld, Vlad, Reznikov, Natalie, Rechav, Katya, Yaniv, Karina, Addadi, Lia, Weiner, Steve
Format: Article
Language:English
Subjects:
Animal development
Animals
Axial skeleton
Biology
Biology and Life Sciences
Biomedical engineering
Bone Development
Bone growth
Bone imaging
Bones
Calcein
Calcium - metabolism
Calcium carbonate
CAT scans
Computed tomography
Danio rerio
Embryos
Fertilization
Fluorescence
Fluorescence microscopy
Genes
Genetic engineering
High resolution
Image resolution
Larvae
Medicine and Health Sciences
Microscopy, Electron, Scanning - methods
Mineralization
Mutants
Mutation
Nacre
Notochord
Otoliths
Physiological aspects
Research and Analysis Methods
Scanning electron microscopy
Science
Skeleton
Stains & staining
X-Ray Microtomography - methods
Zebrafish
Zebrafish - embryology
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Summary:Although bone is one of the most studied living materials, many questions about the manner in which bones form remain unresolved, including fine details of the skeletal structure during development. In this study, we monitored skeleton development of zebrafish larvae, using calcein fluorescence, high-resolution micro-CT 3D images and FIB-SEM in the block surface serial imaging mode. We compared calcein staining of the skeletons of the wild type and nacre mutants, which are transparent zebrafish, with micro-CT for the first 30 days post fertilization embryos, and identified significant differences. We quantified the bone volumes and mineral contents of bones, including otoliths, during development, and showed that such developmental differences, including otolith development, could be helpful in identifying phenotypes. In addition, high-resolution imaging revealed the presence of mineralized aggregates in the notochord, before the formation of the first bone in the axial skeleton. These structures might play a role in the storage of the mineral. Our results highlight the potential of these high-resolution 3D approaches to characterize the zebrafish skeleton, which in turn could prove invaluable information for better understanding the development and the characterization of skeletal phenotypes.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0177731