Utility of quantitative micro-computed tomographic analysis in zebrafish to define gene function during skeletogenesis

Charles, Julia F.; Sury, M.; Tsang, Kelly; Urso, Katia; Henke, Katrin; Huang, Yue; Russell, R.; Duryea, J.; Harris, Matthew P.

doi:10.1016/j.bone.2017.05.001

Cited by 44 publications

(51 citation statements)

References 35 publications

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“…The three‐dimensional (3D)‐high‐resolution micro‐computed tomography has become established as a powerful method to assess bone morphology and microstructure in zebrafish . Using a 5 μm voxel size, bone structure indices as vertebral bone volume, thickness, and eccentricity can be characterized .…”

Section: Phenotypingmentioning

confidence: 99%

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Zebrafish: An Emerging Model for Orthopedic Research

Busse

Galloway

Gray

et al. 2019

Journal Orthopaedic Research

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Advances in next-generation sequencing have transformed our ability to identify genetic variants associated with clinical disorders of the musculoskeletal system. However, the means to functionally validate and analyze the physiological repercussions of genetic variation have lagged behind the rate of genetic discovery. The zebrafish provides an efficient model to leverage genetic analysis in an in vivo context. Its utility for orthopedic research is becoming evident in regard to both candidate gene validation as well as therapeutic discovery in tissues such as bone, tendon, muscle, and cartilage. With the development of new genetic and analytical tools to better assay aspects of skeletal tissue morphology, mineralization, composition, and biomechanics, researchers are emboldened to systematically approach how the skeleton develops and to identify the root causes, and potential treatments, of skeletal disease.

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Section: Phenotypingmentioning

confidence: 99%

“…Using a 5 μm voxel size, bone structure indices as vertebral bone volume, thickness, and eccentricity can be characterized . Neural arch area, which reflects modeling arising from osteoblast and osteoclast activity, can also be captured . Because of their small size, whole body, high‐resolution scans are readily acquired .…”

Section: Phenotypingmentioning

confidence: 99%

Zebrafish: An Emerging Model for Orthopedic Research

Busse

Galloway

Gray

et al. 2019

Journal Orthopaedic Research

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“…We complemented this functional analysis with ex-vivo µ-CT imaging to examine the morphology of the adult zebrafish heart in fine detail. With a few exceptions (Descamps et al, 2014;Vagberg et al, 2015;Babaei et al, 2016;Weinhardt et al, 2018;Ding et al, 2019), this technique has been mainly used for ex-vivo samples focusing on the skeleton (Charles et al, 2017;Hur et al, 2017;Silvent et al, 2017;C. J. Watson et al, 2020).…”

Section: Optimization Of Preclinical Cardiac Imaging Analysismentioning

confidence: 99%

Integration of multiple imaging platforms to uncover cardiac defects in adult zebrafish

Bensimon-Brito

Boezio

Cardeira-da-Silva

et al. 2020

Preprint

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Mammalian models have been instrumental to investigate adult heart function and human disease. However, electrophysiological differences with human hearts and high costs emphasize the need for additional models. The zebrafish is a well-established genetic model to study cardiac development and function; however, analysis of cardiac phenotypes in adult specimens is particularly challenging as they are opaque. Here, we optimized and combined multiple imaging techniques including echocardiography, magnetic resonance imaging and micro-computed tomography to identify and analyze cardiac phenotypes in adult zebrafish. Using alk5a/tgfbr1a mutants as a case study, we observed morphological and functional cardiac defects, which were undetected with conventional approaches. Correlation analysis of multiple parameters revealed an association between hemodynamic defects and structural alterations of the heart, as observed clinically. Thus, we report a comprehensive and sensitive platform to identify otherwise indiscernible cardiac phenotypes in adult zebrafish, a model with clear advantages to study cardiac function and disease.

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“…BMP1 is a secreted enzyme that functions in the cleavage of C-propeptides from procollagen precursors (28). We and others previously showed that zebrafish germline loss-of-function mutants for plod2 and bmp1a exhibit severe skeletal abnormalities as adults, reminiscent of OI phenotypes (1,27,29,30).…”

Section: Somatic Mutants For Plod2 and Bmp1a Exhibit Differences In Vmentioning

confidence: 99%

Decoding G0 somatic mutants through deep phenotyping and mosaic pattern analysis in the zebrafish skeleton

Watson

Monstad-Rios

Bhimani

et al. 2018

Preprint

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Genetic mosaicism manifests as spatially variable phenotypes, whose detection and interpretation remains challenging. This study identifies biological factors influencing spatial phenotypic patterns in the skeletons of somatic mutant zebrafish, and tests methods for their analysis using deep phenotyping. We explore characteristics of loss-offunction clusters in the skeleton of CRISPR-edited G0 ("crispant") zebrafish, and identify a distinctive size distribution shown to arise from clonal fragmentation and merger events. Using microCT-based phenomics, we describe diverse phenotypic manifestations in somatic mutants for genes implicated in monogenic (plod2 and bmp1a) and polygenic (wnt16) bone diseases, each showing convergence with germline mutant phenomes. Finally, we describe statistical frameworks for phenomic analysis which confers heightened sensitivity in discriminating somatic mutant populations, and quantifies spatial phenotypic variation. Our studies provide strategies for decoding spatially variable phenotypes which, paired with CRISPR-based screens, can identify genes contributing to skeletal disease.

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Utility of quantitative micro-computed tomographic analysis in zebrafish to define gene function during skeletogenesis

Cited by 44 publications

References 35 publications

Zebrafish: An Emerging Model for Orthopedic Research

Zebrafish: An Emerging Model for Orthopedic Research

Integration of multiple imaging platforms to uncover cardiac defects in adult zebrafish

Decoding G0 somatic mutants through deep phenotyping and mosaic pattern analysis in the zebrafish skeleton

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