Geometric theory predicts bifurcations in minimal wiring cost trees in biology are flat

Autor: Jaap A. Kaandorp, Erik De Schutter, Robert Sinclair, Nol Chindapol, Yihwa Kim
Přispěvatelé: Computational Science Lab (IVI, FNWI)
Jazyk: angličtina
Rok vydání: 2012
Předmět:
Models
Anatomic

Anatomy and Physiology
Plant Science
Cardiovascular System
Steiner tree problem
Trees
0302 clinical medicine
Bifurcation theory
Morphogenesis
lcsh:QH301-705.5
0303 health sciences
Ecology
Plants
Anthozoa
Mathematical theory
Tree structure
Computational Theory and Mathematics
Geometric group theory
Modeling and Simulation
Corals
symbols
Medicine
Research Article
Geometry
Marine Biology
Topology
Models
Biological

03 medical and health sciences
Cellular and Molecular Neuroscience
symbols.namesake
Euclidean geometry
Genetics
Animals
Computer Simulation
Biology
Theoretical Biology
Molecular Biology
Ecology
Evolution
Behavior and Systematics

030304 developmental biology
Computational Neuroscience
Computational Biology
Function (mathematics)
Tree (graph theory)
Neuroanatomy
lcsh:Biology (General)
Euclidean Geometry
Cardiovascular Anatomy
Mathematics
030217 neurology & neurosurgery
Neuroscience
Zdroj: PLoS Computational Biology, Vol 8, Iss 4, p e1002474 (2012)
PLoS Computational Biology
PLoS Computational Biology, 8(4). Public Library of Science
ISSN: 1553-7358
1553-734X
Popis: The complex three-dimensional shapes of tree-like structures in biology are constrained by optimization principles, but the actual costs being minimized can be difficult to discern. We show that despite quite variable morphologies and functions, bifurcations in the scleractinian coral Madracis and in many different mammalian neuron types tend to be planar. We prove that in fact bifurcations embedded in a spatial tree that minimizes wiring cost should lie on planes. This biologically motivated generalization of the classical mathematical theory of Euclidean Steiner trees is compatible with many different assumptions about the type of cost function. Since the geometric proof does not require any correlation between consecutive planes, we predict that, in an environment without directional biases, consecutive planes would be oriented independently of each other. We confirm this is true for many branching corals and neuron types. We conclude that planar bifurcations are characteristic of wiring cost optimization in any type of biological spatial tree structure.
Author Summary Morphology is constrained by function and vice-versa. Often, intricate morphology can be explained by optimization of a cost. However, in biology, the exact form of the cost function is seldom clear. Previously, for many different natural trees authors have reported that most bifurcations are planar and we confirm this here for branching corals and mammalian neurons. In a three-dimensional space, where bifurcations can have many shapes, it is not clear why they are mostly planar. We show, using a geometric proof, that bifurcations that are part of an optimal wiring cost tree should be planar. We demonstrate this by proving that a bifurcation that is not planar cannot be part of an optimal wiring cost tree, using a very general form of wiring cost which applies even when the exact form of the cost function is not known. We conclude that nature selects for developmental mechanisms which produce planar bifurcations.
Databáze: OpenAIRE