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

Autor: Jim Swoger, Jaume Sastre Tomas, James Sharpe, Alexandre Robert-Moreno, Lucia Russo, Roger Mateu Estivill, Neus Martínez-Abadías, Susan M. Motch Perrine, Melissa Yoon, Kazuhiko Kawasaki, Joan T. Richtsmeier
Přispěvatelé: Universitat de Barcelona
Jazyk: angličtina
Rok vydání: 2018
Předmět:
0301 basic medicine
0106 biological sciences
Mouse
Whole‐mount‐in‐situ hybridization (WMISH)
regulación de la expresión génica
medicine.disease_cause
01 natural sciences
Mice
biometría
Gene expression
Morphogenesis
Optical Projection Tomography (OPT)
Biology (General)
Tomography
Limb development
Organ system
0303 health sciences
Mutation
whole‐mount‐in‐situ hybridization (WMISH)
General Neuroscience
Morfogènesi
Gene Expression Regulation
Developmental
General Medicine
Phenotype
3. Good health
Medicine
Developmental defects
Research Article
Biometry
Limb defects
QH301-705.5
Science
Mutation
Missense
Apert syndrome
Biology
010603 evolutionary biology
General Biochemistry
Genetics and Molecular Biology
tomografía
03 medical and health sciences
Developmental biology
medicine
Animals
Receptor
Fibroblast Growth Factor
Type 2
perfiles de expresión génica
mutación
030304 developmental biology
Congenital diseases
General Immunology and Microbiology
Gene Expression Profiling
Geometric Morphometrics (GM)
Acrocephalosyndactylia
medicine.disease
Expressió gènica
Mice
Inbred C57BL
Disease Models
Animal
030104 developmental biology
acrocefalosindactilia
Gene Expression Regulation
Evolutionary biology
limb development
animales
Tomography
X-Ray Computed
ratones
developmental defects
Developmental Biology
Zdroj: eLife, Vol 7 (2018)
Recercat. Dipósit de la Recerca de Catalunya
instname
eLife
Dipòsit Digital de la UB
Universidad de Barcelona
Popis: The earliest developmental origins of dysmorphologies are poorly understood in many congenital diseases. They often remain elusive because the first signs of genetic misregulation may initiate as subtle changes in gene expression, which are hard to detect and can be obscured later in development by secondary effects. Here, we develop a method to trace back the origins of phenotypic abnormalities by accurately quantifying the 3D spatial distribution of gene expression domains in developing organs. By applying Geometric Morphometrics to 3D gene expression data obtained by Optical Projection Tomography, we determined that our approach is sensitive enough to find regulatory abnormalities that have never been detected previously. We identified subtle but significant differences in the gene expression of a downstream target of a Fgfr2 mutation associated with Apert syndrome, demonstrating that these mouse models can further our understanding of limb defects in the human condition. Our method can be applied to different organ systems and models to investigate the etiology of malformations.
eLife digest Our development in the womb is complex. Genes need to switch on and off in a precise order, controlling the activity of millions of cells as they work together to form different tissues. For everything to happen smoothly, cells must use instructions provided by each gene exactly at the correct moment and in the correct place. In this biological assembly line, the slightest change can lead to a defect. Certain genetic mutations can change when and where cells use particular genes, and this can cause errors in development. These kinds of mutations are a common cause of birth defects, but we cannot always pinpoint how they begin. For example, a single mutation in a gene called FGFR2 causes malformations in the head, the heart and the limbs in a rare disease called Apert syndrome. The first signs that development has gone wrong can be subtle changes in the use of certain genes, impossible to detect with standard methods. As development continues, other processes can mask the impact of problems with certain genes. Ultimately, changes alter the shape of the developing embryo. Genetically engineered mouse models can mimic the gene defects that cause disease in humans. But current methods are not sensitive enough to detect the very first signs of defects. Now, Martínez-Abadías et al. developed a new method to detect these subtle changes and reveal the precise moment when development starts to go wrong. In mice, a specific mutation in the FGFR2 gene affects the activity of a series of other genes. To track the levels of one of these genes, Martínez-Abadías et al. marked mouse embryos using a chemical label. Scanning the embryos then revealed the pattern of the cells using the gene during the earliest stages of development. In mice carrying a mutation in the FGFR2 gene, subtle changes in gene expression began just a few hours after their limbs start to develop. But it took another half a day to see the effects of these changes on the shape and size of the growing limbs. This approach revealed changes in gene expression before any problems with development were visible by eye. Tracking subtle changes in the way cells use genes could allow us to detect the origins of embryo malformations before they appear, pointing at the best moment to start a treatment. With further development, the model could extend to other genes, proteins, animal models and diseases.
Databáze: OpenAIRE
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