Activator-inhibitor dynamics of vertebrate limb pattern formation

Activator-inhibitor dynamics of vertebrate limb pattern formation

The development of the vertebrate limb depends on an interplay of cellular differentiation, pattern formation, and tissue morphogenesis on multiple spatial and temporal scales. While numerous gene products have been described that participate in, and influence, the generation of the limb skeletal pa...

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Published in:Birth defects research. Part C. Embryo today Vol. 81; no. 4; pp. 305 - 319
Main Authors: Newman, Stuart A., Bhat, Ramray
Format: Journal Article
Language:English
Published: Hoboken Wiley Subscription Services, Inc., A Wiley Company 01-12-2007
Subjects:
Animals
Body Patterning - genetics
Body Patterning - physiology
Extremities - embryology
Fibroblast Growth Factors - genetics
Gene Expression Regulation, Developmental
Humans
Mesoderm - embryology
Models, Biological
Transforming Growth Factor beta - genetics
Vertebrates - embryology
Vertebrates - genetics
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Summary:The development of the vertebrate limb depends on an interplay of cellular differentiation, pattern formation, and tissue morphogenesis on multiple spatial and temporal scales. While numerous gene products have been described that participate in, and influence, the generation of the limb skeletal pattern, an understanding of the most salient feature of the developing limb—its quasiperiodic arrangement of bones, requires additional organizational principles. We review several such principles, drawing on concepts of physics and chemical dynamics along with molecular genetics and cell biology. First, a “core mechanism” for precartilage mesenchymal condensation is described, based on positive autoregulation of the morphogen transforming growth factor (TGF)‐β, induction of the extracellular matrix (ECM) protein fibronectin, and focal accumulation of cells via haptotaxis. This core mechanism is shown to be part of a local autoactivation‐lateral inhibition (LALI) system that ensures that the condensations will be regularly spaced. Next, a “bare‐bones” model for limb development is described in which the LALI‐core mechanism is placed in a growing geometric framework with predifferentiated “apical,” differentiating “active,” and irreversibly differentiated “frozen” zones defined by distance from an apical source of a fibroblast growth factor (FGF)‐type morphogen. This model is shown to account for classic features of the developing limb, including the proximodistal (PD) emergence over time of increasing numbers of bones. We review earlier and recent work suggesting that the inhibitory component of the LALI system for condensation may not be a diffusible morphogen, and propose an alternative mechanism for lateral inhibition, based on synchronization of oscillations of a Hes mediator of the Notch signaling pathway. Finally, we discuss how viewing development as an interplay between molecular‐genetic and dynamic physical processes can provide new insight into the origin of congenital anomalies. Birth Defects Research (Part C) 81:305–319, 2007. © 2008 Wiley‐Liss, Inc.
Bibliography:istex:AE0E523F3FA4CF1E0061F7123AC4823B66D9D6E8
ark:/67375/WNG-LMJ4D1N8-N
ArticleID:BDRC20112
National Science Foundation
ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-3
content type line 23
ObjectType-Review-1
ISSN:1542-975X
1542-9768
DOI:10.1002/bdrc.20112