脉动动力学在发育中果蝇眼睛中传播晶体秩序

bioRxiv Pub Date : 2024-07-16 DOI:10.1101/2024.07.11.603179
L. Couturier, Juan C. Luna-Escalante, Khallil Mazouni, Claire Mestdagh, Minh-Son Phan, J. Tinevez, François Schweisguth, Francis Corson
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引用次数: 0

摘要

发育中组织的模式形成通常涉及位置信息引导下的自组织。然而,在大多数组织中,其动态以及内在逻辑仍然未知。通过研究蝇眼的自组织模式化,我们结合实验和建模阐明了成排的光接收单元是如何在行进的分化前沿后出现并形成晶体状阵列的。绒毛因子阿托纳尔的实时成像揭示了前沿处意想不到的振荡,这种振荡是由两个不同的增强子相继激活产生的,并与脉冲式 Notch 信号有关。我们的观察结果与目前的眼睛模式化模型不一致,根据该模型,每一排分化细胞都为下一排细胞提供了一个负模板。相反,它们为一个新的中继模型提供了信息,在这个模型中,来自分化细胞的瞬时 Notch 信号为前面两行的分化提供了一个正模板,传递时间和空间信息以传播振荡和晶体状秩序。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Pulsatile dynamics propagate crystalline order in the developing Drosophila eye
Pattern formation in developing tissues often involves self-organization guided by positional information. In most tissues, however, its dynamics, and therefore the underlying logic, remain unknown. Examining self-organized patterning of the fly eye, we combine experiments and modeling to elucidate how rows of light-receiving units emerge in the wake of a traveling differentiation front to form a crystal-like array. Live imaging of the proneural factor Atonal reveals unanticipated oscillations at the front, which are produced by the successive activation of two distinct enhancers and associated with pulsatile Notch signaling. Our observations are inconsistent with current models of eye patterning, whereby each row of differentiating cells provides a negative template for the next. Instead, they inform a new relay model in which transient Notch signaling from differentiating cells provides a positive template for the onset of differentiation two rows ahead, conveying both temporal and spatial information to propagate oscillations and crystal-like order.
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