Mesodermal cell displacements during avian gastrulation are due to both individual cell-autonomous and convective tissue movements

Gastrulation is a fundamental process in early development that results in the formation of three primary germ layers. During avian gastrulation, presumptive mesodermal cells in the dorsal epiblast ingress through a furrow called the primitive streak (PS), and subsequently move away from the PS and form adult tissues. The biophysical mechanisms driving mesodermal cell movements during gastrulation in amniotes, notably warm-blooded embryos, are not understood. Until now, a major challenge has been distinguishing local individual cell-autonomous (active) displacements from convective displacements caused by large-scale (bulk) morphogenetic tissue movements. To address this problem, we used multiscale, time-lapse microscopy and a particle image velocimetry method for computing tissue displacement fields. Immunolabeled fibronectin was used as an in situ marker for quantifying tissue displacements. By imaging fluorescently labeled mesodermal cells and surrounding extracellular matrix simultaneously, we were able to separate directly the active and passive components of cell displacement during gastrulation. Our results reveal the following: (i) Convective tissue motion contributes significantly to total cell displacement and must be subtracted to measure true cell-autonomous displacement; (ii) Cell-autonomous displacement decreases gradually after egression from the PS; and (iii) There is an increasing cranial-to-caudal (head-to-tail) cell-autonomous motility gradient, with caudal cells actively moving away from the PS faster than cranial cells. These studies show that, in some regions of the embryo, total mesodermal cell displacements are mostly due to convective tissue movements; thus, the data have profound implications for understanding cell guidance mechanisms and tissue morphogenesis in warm-blooded embryos.

[1]  E. Sanders,et al.  Guidance of filopodial extension by fibronectin-rich extracellular matrix fibrils during avian gastrulation. A study using confocal microscopy. , 1994, The International journal of developmental biology.

[2]  R. Gordon,et al.  Appendix: dialogue on embryonic induction and differentiation waves. , 1994, International review of cytology.

[3]  V. Hamburger,et al.  A series of normal stages in the development of the chick embryo. 1951. , 2012, Developmental dynamics : an official publication of the American Association of Anatomists.

[4]  R. Keller,et al.  Assembly and remodeling of the fibrillar fibronectin extracellular matrix during gastrulation and neurulation in Xenopus laevis , 2004, Developmental dynamics : an official publication of the American Association of Anatomists.

[5]  C. Little,et al.  Antibodies to β1‐integrins cause alterations of aortic vasculogenesis, in vivo , 1992 .

[6]  András Czirók,et al.  A Digital Image-Based Method for Computational Tissue Fate Mapping During Early Avian Morphogenesis , 2005, Annals of Biomedical Engineering.

[7]  Max A. Viergever,et al.  Quantitative evaluation of convolution-based methods for medical image interpolation , 2001, Medical Image Anal..

[8]  M. Kiskowski,et al.  Initiation of convergence and extension movements of lateral mesoderm during zebrafish gastrulation , 2005, Developmental dynamics : an official publication of the American Association of Anatomists.

[9]  C. Little,et al.  Whole-Mount Immunolabeling of Embryos by Microinjection , 2000 .

[10]  O. Pourquié,et al.  The vertebrate segmentation clock , 2001, Journal of anatomy.

[11]  Ray Keller,et al.  Cell migration during gastrulation. , 2005, Current opinion in cell biology.

[12]  John Philip Trinkaus,et al.  Cells into Organs: The Forces That Shape the Embryo , 1984 .

[13]  A. Czirók,et al.  Multi‐field 3D scanning light microscopy of early embryogenesis , 2002, Journal of microscopy.

[14]  A. Czirók,et al.  Extracellular matrix dynamics during vertebrate axis formation. , 2004, Developmental biology.

[15]  D. Fambrough,et al.  Fibronectin expression during myogenesis , 1983, The Journal of cell biology.

[16]  R. Eils,et al.  Quantitative motion analysis and visualization of cellular structures. , 2003, Methods.

[17]  D. Wiens An alternative model for cell sheet migration on fibronectin during heart formation. , 1996, Journal of theoretical biology.

[18]  L. Lourenço Particle Image Velocimetry , 1989 .

[19]  Ray Keller,et al.  How we are shaped: the biomechanics of gastrulation. , 2003, Differentiation; research in biological diversity.

[20]  A. Czirók,et al.  Culturing of avian embryos for time-lapse imaging. , 2003, BioTechniques.