A doppler effect in embryonic pattern formation

During embryonic development, temporal and spatial cues are coordinated to generate a segmented body axis. In sequentially segmenting animals, the rhythm of segmentation is reported to be controlled by the time scale of genetic oscillations that periodically trigger new segment formation. However, w...

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Detalles Bibliográficos
Autores principales:	Soroldoni, D., Jörg, D.J., Morelli, L.G., Richmond, D.L., Schindelin, J., Jul̈icher, F., Oates, A.C.
Formato:	JOUR
Materias:	cyprinid Doppler effect embryo embryonic development genetic variation animal experiment article biological rhythm Doppler flowmetry embryo development embryo pattern formation embryo segmentation embryonic structures gene expression genetic analysis germ layer kinematics nonhuman oscillation physical parameters priority journal spike wave steady state tissue level transgenics zebra fish animal animal embryo genetics morphogenesis periodicity physiology prenatal development Animals Body Patterning Doppler Effect Embryo, Nonmammalian Periodicity Zebrafish
Acceso en línea:	http://hdl.handle.net/20.500.12110/paper_00368075_v345_n6193_p222_Soroldoni
Aporte de:	Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires

id	todo:paper_00368075_v345_n6193_p222_Soroldoni
record_format	dspace
spelling	todo:paper_00368075_v345_n6193_p222_Soroldoni2023-10-03T14:47:56Z A doppler effect in embryonic pattern formation Soroldoni, D. Jörg, D.J. Morelli, L.G. Richmond, D.L. Schindelin, J. Jul̈icher, F. Oates, A.C. cyprinid Doppler effect embryo embryonic development genetic variation animal experiment article biological rhythm Doppler flowmetry embryo development embryo pattern formation embryo segmentation embryonic structures gene expression genetic analysis germ layer kinematics nonhuman oscillation physical parameters priority journal spike wave steady state tissue level transgenics zebra fish animal animal embryo genetics morphogenesis periodicity physiology prenatal development Animals Body Patterning Doppler Effect Embryo, Nonmammalian Periodicity Zebrafish During embryonic development, temporal and spatial cues are coordinated to generate a segmented body axis. In sequentially segmenting animals, the rhythm of segmentation is reported to be controlled by the time scale of genetic oscillations that periodically trigger new segment formation. However, we present real-time measurements of genetic oscillations in zebrafish embryos showing that their time scale is not sufficient to explain the temporal period of segmentation. A second time scale, the rate of tissue shortening, contributes to the period of segmentation through a Doppler effect. This contribution is modulated by a gradual change in the oscillation profile across the tissue. We conclude that the rhythm of segmentation is an emergent property controlled by the time scale of genetic oscillations, the change of oscillation profile, and tissue shortening. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_00368075_v345_n6193_p222_Soroldoni
institution	Universidad de Buenos Aires
institution_str	I-28
repository_str	R-134
collection	Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic	cyprinid Doppler effect embryo embryonic development genetic variation animal experiment article biological rhythm Doppler flowmetry embryo development embryo pattern formation embryo segmentation embryonic structures gene expression genetic analysis germ layer kinematics nonhuman oscillation physical parameters priority journal spike wave steady state tissue level transgenics zebra fish animal animal embryo genetics morphogenesis periodicity physiology prenatal development Animals Body Patterning Doppler Effect Embryo, Nonmammalian Periodicity Zebrafish
spellingShingle	cyprinid Doppler effect embryo embryonic development genetic variation animal experiment article biological rhythm Doppler flowmetry embryo development embryo pattern formation embryo segmentation embryonic structures gene expression genetic analysis germ layer kinematics nonhuman oscillation physical parameters priority journal spike wave steady state tissue level transgenics zebra fish animal animal embryo genetics morphogenesis periodicity physiology prenatal development Animals Body Patterning Doppler Effect Embryo, Nonmammalian Periodicity Zebrafish Soroldoni, D. Jörg, D.J. Morelli, L.G. Richmond, D.L. Schindelin, J. Jul̈icher, F. Oates, A.C. A doppler effect in embryonic pattern formation
topic_facet	cyprinid Doppler effect embryo embryonic development genetic variation animal experiment article biological rhythm Doppler flowmetry embryo development embryo pattern formation embryo segmentation embryonic structures gene expression genetic analysis germ layer kinematics nonhuman oscillation physical parameters priority journal spike wave steady state tissue level transgenics zebra fish animal animal embryo genetics morphogenesis periodicity physiology prenatal development Animals Body Patterning Doppler Effect Embryo, Nonmammalian Periodicity Zebrafish
description	During embryonic development, temporal and spatial cues are coordinated to generate a segmented body axis. In sequentially segmenting animals, the rhythm of segmentation is reported to be controlled by the time scale of genetic oscillations that periodically trigger new segment formation. However, we present real-time measurements of genetic oscillations in zebrafish embryos showing that their time scale is not sufficient to explain the temporal period of segmentation. A second time scale, the rate of tissue shortening, contributes to the period of segmentation through a Doppler effect. This contribution is modulated by a gradual change in the oscillation profile across the tissue. We conclude that the rhythm of segmentation is an emergent property controlled by the time scale of genetic oscillations, the change of oscillation profile, and tissue shortening.
format	JOUR
author	Soroldoni, D. Jörg, D.J. Morelli, L.G. Richmond, D.L. Schindelin, J. Jul̈icher, F. Oates, A.C.
author_facet	Soroldoni, D. Jörg, D.J. Morelli, L.G. Richmond, D.L. Schindelin, J. Jul̈icher, F. Oates, A.C.
author_sort	Soroldoni, D.
title	A doppler effect in embryonic pattern formation
title_short	A doppler effect in embryonic pattern formation
title_full	A doppler effect in embryonic pattern formation
title_fullStr	A doppler effect in embryonic pattern formation
title_full_unstemmed	A doppler effect in embryonic pattern formation
title_sort	doppler effect in embryonic pattern formation
url	http://hdl.handle.net/20.500.12110/paper_00368075_v345_n6193_p222_Soroldoni
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A doppler effect in embryonic pattern formation

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