A dynamical model of ommatidial crystal formation

Lubensky, David K.; Pennington, Matthew W.; Shraiman, Boris I.; Baker, Nicholas E.

doi:10.1073/pnas.1015302108

Cited by 64 publications

(104 citation statements)

References 53 publications

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“…Therefore, the conditions at the wavefront are expected to have relevant consequences for the final pattern of neuronal differentiation. Although the importance of static boundary conditions at the borders of a pattern-forming tissue have received some theoretical notice (Honda et al, 1990;Collier et al, 1996;Murciano et al, 2002;Meir et al, 2002;Plahte, 2001), moving wavefronts of lateral inhibition have only recently come to attention (Owen, 2002;Plahte and Øyehaug, 2007;Pennington and Lubensky, 2010;O'Dea and King, 2011;Lubensky et al, 2011). These studies show how a neurogenic wavefront can sweep across a field of identical cells and leave behind a pattern of different cell types.…”

Section: Introductionmentioning

confidence: 99%

Regulation of neuronal differentiation at the neurogenic wavefront

et al. 2012

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SUMMARYSignaling mediated by the Delta/Notch system controls the process of lateral inhibition, known to regulate neurogenesis in metazoans. Lateral inhibition takes place in equivalence groups formed by cells having equal capacity to differentiate, and it results in the singling out of precursors, which subsequently become neurons. During normal development, areas of active neurogenesis spread through non-neurogenic regions in response to specific morphogens, giving rise to neurogenic wavefronts. Close contact of these wavefronts with non-neurogenic cells is expected to affect lateral inhibition. Therefore, a mechanism should exist in these regions to prevent disturbances of the lateral inhibitory process. Focusing on the developing chick retina, we show that Dll1 is widely expressed by non-neurogenic precursors located at the periphery of this tissue, a region lacking Notch1, lFng, and differentiation-related gene expression. We investigated the role of this Dll1 expression through mathematical modeling. Our analysis predicts that the absence of Dll1 ahead of the neurogenic wavefront results in reduced robustness of the lateral inhibition process, often linked to enhanced neurogenesis and the presence of morphological alterations of the wavefront itself. These predictions are consistent with previous observations in the retina of mice in which Dll1 is conditionally mutated. The predictive capacity of our mathematical model was confirmed further by mimicking published results on the perturbation of morphogenetic furrow progression in the eye imaginal disc of Drosophila. Altogether, we propose that Notch-independent Delta expression ahead of the neurogenic wavefront is required to avoid perturbations in lateral inhibition and wavefront progression, thus optimizing the neurogenic process.

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Section: Introductionmentioning

confidence: 99%

Regulation of neuronal differentiation at the neurogenic wavefront

et al. 2012

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“…Although we cannot exclude this possibility, the above results suggest that the fourcomponent model with Notch-mediated lateral inhibition is essentially consistent with proneural wave progression in silico and in vivo and that the wave acceleration phenotype is equivalent to the classical neurogenic phenotype of Notch mutant clones (2). Although nonlinear regulations of Notch signaling were implemented in the previous models (5,6,(17)(18)(19), the equation for N in the four-component model was sufficient to reproduce all of the experimental conditions described above. feedback (Fig.…”

Section: Salt and Pepper Pattern Formation Requires A Higher Notch Acmentioning

confidence: 99%

“…Therefore, many of the theoretical studies regard the mode of Notch action during wave propagation as lateral inhibition. Previous mathematical modeling has revealed essential roles for Notch signaling in the formation of a salt and pepper pattern of photoreceptor neurons (17)(18)(19)(20). Although it was suggested that Dl restricts wave propagation during eye development (17), Notch signaling is also required for undifferentiated cells to acquire a proneural state before the wave progression in Significance Notch-mediated lateral inhibition regulates binary cell fate choice, resulting in salt and pepper patterns during various developmental processes.…”

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confidence: 99%

Notch-mediated lateral inhibition regulates proneural wave propagation when combined with EGF-mediated reaction diffusion

Sato

Yasugi

Minami

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Notch-mediated lateral inhibition regulates binary cell fate choice, resulting in salt and pepper patterns during various developmental processes. However, how Notch signaling behaves in combination with other signaling systems remains elusive. The wave of differentiation in the Drosophila visual center or “proneural wave” accompanies Notch activity that is propagated without the formation of a salt and pepper pattern, implying that Notch does not form a feedback loop of lateral inhibition during this process. However, mathematical modeling and genetic analysis clearly showed that Notch-mediated lateral inhibition is implemented within the proneural wave. Because partial reduction in EGF signaling causes the formation of the salt and pepper pattern, it is most likely that EGF diffusion cancels salt and pepper pattern formation in silico and in vivo. Moreover, the combination of Notch-mediated lateral inhibition and EGF-mediated reaction diffusion enables a function of Notch signaling that regulates propagation of the wave of differentiation.

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“…Such self-regulated progression ensures patterning is occurring in a small moving region, in between non-neurogenic tissue and already patterned tissue. From a theoretical point of view, moving wavefronts of lateral inhibition are receiving increasing attention (Owen, 2002;Plahte and Øyehaug, 2007;Pennington and Lubensky, 2010;Lubensky et al, 2011;O'Dea and King, 2011;O'Dea and King, 2012;Formosa-Jordan et al, 2012;Simakov and Pismen, 2013). The advantage of a moving wavefront versus a neurogenic region surrounded by a fixed boundary remains to be elucidated.…”

Section: Perspectivesmentioning

confidence: 99%

Lateral inhibition and neurogenesis: novel aspects in motion

Formosa-Jordan¹,

Ibañes²,

Ares³

et al. 2013

Int. J. Dev. Biol.

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Neuronal production in metazoans is tightly controlled by Delta/Notch-dependent signals regulating lateral inhibition. It is currently thought that lateral inhibition takes place in clusters of precursors with equal capacity to trigger and receive Notch-dependent inhibitory signals. However, this view neglects crucial dynamical aspects of the process. In this review, we discuss two of these dynamic factors, whose alterations yield dysfunctions in neurogenesis. First, precursors show variable neurogenic capacity as they go through the cell cycle. Second, differentiating precursors are in direct contact with non-neurogenic cells at the wavefront of expanding neurogenic domains. We discuss the mechanisms adopted by Metazoa to prevent these dysfunctions in the lateral inhibitory process, which include cell cycle synchronization occurring in the invertebrate neural epithelium and during primary neurogenesis in anamniotes, interkinetic nuclear movement in the vertebrate neuroepithelium and generalized Delta expression ahead of the neurogenic wavefront. The emerging concept is that lateral inhibition during neurogenesis occurs in dynamic clusters of precursors and requires specific mechanisms to avoid distortions resulting from the interaction between neurogenic and non-neurogenic precursors. The advance in visualizing Notch dynamics with real-time imaging at cellular and subcellular levels will notably contribute to our understanding of these novel "aspects of motion" in neurogenesis.

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A dynamical model of ommatidial crystal formation

Cited by 64 publications

References 53 publications

Regulation of neuronal differentiation at the neurogenic wavefront

Regulation of neuronal differentiation at the neurogenic wavefront

Notch-mediated lateral inhibition regulates proneural wave propagation when combined with EGF-mediated reaction diffusion

Lateral inhibition and neurogenesis: novel aspects in motion

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