Quantification of gene expression patterns to reveal the origins of abnormal morphogenesis

Martínez‐Abadías, Neus; Estivill, Roger Mateu; Tomas, Jaume Sastre; Perrine, Susan M. Motch; Yoon, Melissa; Robert‐Moreno, Alexandre; Swoger, Jim; Russo, Lucía; Kawasaki, Kazuhiko; Richtsmeier, Joan T.; Sharpe, James

doi:10.1101/246256

Cited by 2 publications

(2 citation statements)

References 39 publications

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“…However, since μCT measures X-ray transmissivity and cannot distinguish colors, it can provide fine structural data, but not suitable gene expression pattern data. Opticalbased 3D imaging systems, such as light sheet fluorescence microscopy (LSFM) and optical projection tomography (OPT), enable the creation of 3D reconstructed images of specific gene expression patterns and 2D optical cutting planar images (Keller, 2013;Martínez-Abadías et al, 2018). Both LSFM and OPT are useful for obtaining 3D gene expression data; however, 2D planar images from these methods are virtual sections and cannot be re-used for various labeling methods, as can be done using the CoMBI method.…”

Section: Discussionmentioning

confidence: 99%

Combined method of whole mount and block‐face imaging: Acquisition of 3D data of gene expression pattern from conventional in situ hybridization

et al. 2022

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Visualization of spatiotemporal expression of a gene of interest is a fundamental technique for analyzing the involvements of genes in organ development. In situ hybridization (ISH) is one of the most popular methods for visualizing gene expression. When conventional ISH is performed on sections or whole‐mount specimens, the gene expression pattern is represented in 2‐dimensional (2D) microscopic images or in the surface view of the specimen. To obtain 3‐dimensional (3D) data of gene expression from conventional ISH, the “serial section method” has traditionally been employed. However, this method requires an extensive amount of time and labor because it requires researchers to collect a tremendous number of sections, label all sections by ISH, and image them before 3D reconstruction. Here, we proposed a rapid and low‐cost 3D imaging method that can create 3D gene expression patterns from conventional ISH‐labeled specimens. Our method consists of a combination of whole‐mount ISH and Correlative Microscopy and Blockface imaging (CoMBI). The whole‐mount ISH‐labeled specimens were sliced using a microtome or cryostat, and all block‐faces were imaged and used to reconstruct 3D images by CoMBI. The 3D data acquired using our method showed sufficient quality to analyze the morphology and gene expression patterns in the developing mouse heart. In addition, 2D microscopic images of the sections can be obtained when needed. Correlating 2D microscopic images and 3D data can help annotate gene expression patterns and understand the anatomy of developing organs. These results indicated that our method can be useful in the field of developmental biology.

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Section: Discussionmentioning

confidence: 99%

Combined method of whole mount and block‐face imaging: Acquisition of 3D data of gene expression pattern from conventional in situ hybridization

et al. 2022

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“…Connecting these mechanisms to 3D change in organismal form requires quantification of cellular processes in whole embryonic structures over developmental time. While three dimensional morphology can be quantified from microCT and optical projection tomography images (Parsons et al, 2008;Boughner et al, 2008;Xu et al, 2015;Martínez-Abadías et al, 2018), cellular dynamics are much less accessible in three dimensions. This is because the vast majority of quantification of cellular dynamics is based on analysis of serial histological sections, with localized sampling rather than whole embryonic structures (Ramaesh and Bard, 2003;Miklius and Hilgenfeldt, 2011;Russ and Dehoff, 2012).…”

Section: Introductionmentioning

confidence: 99%

Quantifying the relationship between cell proliferation and morphology during development of the face

Green

Vercio

Dauter

et al. 2023

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Morphogenesis requires highly coordinated, complex interactions between cellular processes: proliferation, migration, and apoptosis, along with physical tissue interactions. How these cellular and tissue dynamics drive morphogenesis remains elusive. Three dimensional (3D) microscopic imaging poses great promise, and generates beautiful images. However, generating even moderate through-put quantified images is challenging for many reasons. As a result, the association between morphogenesis and cellular processes in 3D developing tissues has not been fully explored. To address this critical gap, we have developed an imaging and image analysis pipeline to enable 3D quantification of cellular dynamics along with 3D morphology for the same individual embryo. Specifically, we focus on how 3D distribution of proliferation relates to morphogenesis during mouse facial development. Our method involves imaging with light-sheet microscopy, automated segmentation of cells and tissues using machine learning-based tools, and quantification of external morphology via geometric morphometrics. Applying this framework, we show that changes in proliferation are tightly correlated to changes in morphology over the course of facial morphogenesis. These analyses illustrate the potential of this pipeline to investigate mechanistic relationships between cellular dynamics and morphogenesis during embryonic development.

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Quantification of gene expression patterns to reveal the origins of abnormal morphogenesis

Cited by 2 publications

References 39 publications

Combined method of whole mount and block‐face imaging: Acquisition of 3D data of gene expression pattern from conventional in situ hybridization

Combined method of whole mount and block‐face imaging: Acquisition of 3D data of gene expression pattern from conventional in situ hybridization

Quantifying the relationship between cell proliferation and morphology during development of the face

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