Effect of cellular rearrangement time delays on the rheology of vertex models for confluent tissues

Autor: M. Lisa Manning, Gonca Erdemci-Tandogan
Rok vydání: 2021
Předmět:
0301 basic medicine
Work (thermodynamics)
Glass Science
01 natural sciences
Cell junction
0302 clinical medicine
Cell Behavior (q-bio.CB)
Relaxation Time
Biomechanics
Tissue mechanics
Biology (General)
Tissues and Organs (q-bio.TO)
Physics
0303 health sciences
Sequence
Ecology
Drosophila Melanogaster
Eukaryota
Classical Mechanics
Animal Models
Structural Relaxation
Condensed Matter Physics
Insects
Intercellular Junctions
Aspect Ratio
Computational Theory and Mathematics
Experimental Organism Systems
Rosette formation
Biological Physics (physics.bio-ph)
Modeling and Simulation
Physical Sciences
Engineering and Technology
Drosophila
Biological system
Rheology
Research Article
Time delays
Tissue Mechanics
Arthropoda
QH301-705.5
Materials Science
Material Properties
Morphogenesis
Biophysics
FOS: Physical sciences
Geometry
Condensed Matter - Soft Condensed Matter
Research and Analysis Methods
Models
Biological
Continuum Mechanics
03 medical and health sciences
Cellular and Molecular Neuroscience
Model Organisms
0103 physical sciences
Genetics
Animals
Physics - Biological Physics
010306 general physics
Molecular Biology
Relaxation (Physics)
Ecology
Evolution
Behavior and Systematics
030304 developmental biology
Convergent extension
Mechanical Engineering
Organisms
Biology and Life Sciences
Quantitative Biology - Tissues and Organs
Invertebrates
Vertex (geometry)
030104 developmental biology
FOS: Biological sciences
Animal Studies
Quantitative Biology - Cell Behavior
Soft Condensed Matter (cond-mat.soft)
Anisotropy
Brakes
Zoology
Entomology
030217 neurology & neurosurgery
Mathematics
Zdroj: PLoS Computational Biology
PLoS Computational Biology, Vol 17, Iss 6, p e1009049 (2021)
ISSN: 1553-7358
Popis: Large-scale tissue deformation during biological processes such as morphogenesis requires cellular rearrangements. The simplest rearrangement in confluent cellular monolayers involves neighbor exchanges among four cells, called a T1 transition, in analogy to foams. But unlike foams, cells must execute a sequence of molecular processes, such as endocytosis of adhesion molecules, to complete a T1 transition. Such processes could take a long time compared to other timescales in the tissue. In this work, we incorporate this idea by augmenting vertex models to require a fixed, finite time for T1 transitions, which we call the “T1 delay time”. We study how variations in T1 delay time affect tissue mechanics, by quantifying the relaxation time of tissues in the presence of T1 delays and comparing that to the cell-shape based timescale that characterizes fluidity in the absence of any T1 delays. We show that the molecular-scale T1 delay timescale dominates over the cell shape-scale collective response timescale when the T1 delay time is the larger of the two. We extend this analysis to tissues that become anisotropic under convergent extension, finding similar results. Moreover, we find that increasing the T1 delay time increases the percentage of higher-fold coordinated vertices and rosettes, and decreases the overall number of successful T1s, contributing to a more elastic-like—and less fluid-like—tissue response. Our work suggests that molecular mechanisms that act as a brake on T1 transitions could stiffen global tissue mechanics and enhance rosette formation during morphogenesis.
Author summary In various morphogenetic events such as embryonic development, tissue repair, or the spread of cancer tumors, cells must move past each other and change neighbors to allow global tissue shape change. In its simplest form, such cell rearrangement events involves neighbor exchanges among four cells, called T1 transitions. During a T1 transition, a sequence of molecular processes must occur over a finite time while cell junctions shrink and new junctions form. In this work, we augment vertex models to require a fixed, finite time for cellular rearrangements, which we call the “T1 delay time”. We show that T1 delay affects tissue mechanics, stiffening the tissue. We also find that increasing the T1 delay time enhances the percentage of higher-fold coordinated vertices and rosettes, which are seen during many developmental processes such as during the body axis elongation of the fruit fly. Our results highlight the important role of a molecular-scale timescale, T1 delay time, on the global tissue response, and suggest that the organisms might utilize specific molecular processes that act as a brake on cellular rearrangements in order to control the global tissue response.
Databáze: OpenAIRE
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