社论要点。

IF 2 3区 生物学 Q2 ANATOMY & MORPHOLOGY
Paul A. Trainor
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Taken together, changes in epithelial cell shape reflect optimal cell packing and the minimization of surface free energy, but also cell–cell interactions, cell proliferation, and cytoskeletal rearrangements, each of which is critical for normal lung development.</p><p><b>Organogenesis—Cochlea Development</b> “Localization of cadherins in the postnatal cochlear epithelium and their relation to space formation” by Holly Beaulac and Vidhya Munnamalai; <i>Dev Dyn</i> 253:8, pp. 771–780. https://doi.org/10.1002/dvdy.692. The cochlea is a fluid-filled spiral cavity within the inner ear, that contains the organ of Corti. Comprised of three rows of outer hair cells and one row of inner hair cells in humans, the organ of Corti produces nerve impulses in response to sound vibrations. The organ of Corti has therefore been called the “temple of hearing” in the inner ear. The sensory epithelium in the organ of Corti consists of mechanosensory hair cells intercalated by epithelial support cells. 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Furthermore, transient changes in cytoskeletal F-actin influence epithelial morphogenesis, and changes in the strength and properties of cell adhesion drive the formation of fluid-filled spaces in the epithelium that are central for proper hearing.</p><p><b>Neural Development</b> “Requirement of a novel gene, <i>drish</i>, in the zebrafish retinal ganglion cell and primary motor axon development” by Suman Gurung, Nicole Restrepo, Surendra Kumar Anand, Vinoth Sittaramane, and Saulius Sumanas; <i>Dev Dyn</i> 253:8, pp. 750–770. https://doi.org/10.1002/dvdy.694. During nervous system development, a motor neuron's axons traverse the extracellular matrix to make synaptic connections, which are critical for neural circuit function. Zebrafish possess two distinct classes of spinal motor neurons: primary and secondary. This study explores the activity and functional role of a novel putative transmembrane protein, Drish, in zebrafish. Loss-of-function mutant embryos exhibit defects in retinal ganglion cell differentiation, with thinner optic nerves, and abnormal branching of motor neurons. In addition, <i>drish</i> mutant adults exhibit deficiencies in the outer nuclear layer of the retina and consequently display defective light response and locomotory behaviors. Drish may function downstream of Hh signaling, however, the exact role of Drish requires further investigation. 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引用次数: 0

摘要

每种生物都是了解发育、进化、疾病和再生的模式生物,而我们对调控这些生物过程的跨学科遗传、分子、细胞和发育机制的研究才刚刚起步。这些 "亮点 "指出了《发育生物学》最近报道的令人兴奋的进展,这些进展说明了发育生物学的复杂动态。器官发生-肺生物学《出生后内脏胸膜拓扑秩序的演变》(Evolving topological order in the postnatal visceral pleura),作者:Betty Liu、Ali Ali、Stacey Kwan、Jennifer Pan、Willi Wagner、Hassan Khalil、Zi Chen、Maximilian Ackermann 和 Steven Mentzer;《发育生物学》253:8,第 711-721 页。https://doi.org/10.1002/dvdy.688。内脏器官表面由多层上皮细胞构成,为周围环境提供选择性屏障。在这些细胞层中,上皮细胞呈现出复杂的形状,其特征是与相邻细胞相邻的边数,多边形与最佳的细胞排列和最小的自由表面能有关。肺部的正常发育需要在出生后的快速生长期与内脏胸膜和邻近肺泡之间的物理相互作用,肺泡暴露在影响细胞形状和方向的静态和动态力下。在这项研究中,作者对出生后的肺发育进行了调查,发现了网络的高度异质性,其中少数高度连接的节点或枢纽在维持网络结构完整性方面发挥着至关重要的作用。此外,这还有助于在肺快速生长的挑战中实现高效的信息流。总而言之,上皮细胞形状的变化反映了最佳的细胞排列和表面自由能的最小化,同时也反映了细胞-细胞间的相互作用、细胞增殖和细胞骨架的重新排列,其中每一个环节都对肺的正常发育至关重要。器官发生-耳蜗的发育 Holly Beaulac 和 Vidhya Munnamalai 合著:《产后耳蜗上皮中粘连蛋白的定位及其与空间形成的关系》;Dev Dyn 253:8,第 771-780 页。https://doi.org/10.1002/dvdy.692。耳蜗是内耳中一个充满液体的螺旋形空腔,其中包含柯蒂器官。耳蜗器官由三排外毛细胞和人类的一排内毛细胞组成,能对声音振动产生神经冲动。因此,Corti 器官被称为内耳的 "听觉圣殿"。Corti 器官的感觉上皮由机械感觉毛细胞和上皮支持细胞夹层组成。上皮支持细胞坚硬但具有足够的顺应性,能够承受和调节振动对毛细胞的影响,而细胞之间相邻细胞膜的细胞粘附特性具有柔韧性,能够在耳蜗内形成充满液体的空间。这项研究调查了通常与细胞骨架重塑有关的粘附蛋白在耳蜗发育过程中的作用,发现在婴儿出生后第一周内就会发生广泛的F-肌动蛋白重塑。此外,细胞骨架F-肌动蛋白的瞬时变化会影响上皮细胞的形态发生,而细胞粘附强度和特性的变化则会推动上皮细胞内充满液体的空间的形成,而这些空间是正常听力的核心。神经发育》:Suman Gurung、Nicole Restrepo、Surendra Kumar Anand、Vinoth Sittaramane 和 Saulius Sumanas 撰写的《斑马鱼视网膜神经节细胞和初级运动轴突发育对新型基因 drish 的要求》;Dev Dyn 253:8,第 750-770 页。https://doi.org/10.1002/dvdy.694。.在神经系统发育过程中,运动神经元的轴突穿过细胞外基质建立突触连接,这对神经回路功能至关重要。斑马鱼拥有两类不同的脊髓运动神经元:初级和次级。本研究探讨了斑马鱼中一种新型推测跨膜蛋白 Drish 的活性和功能作用。功能缺失突变体胚胎表现出视网膜神经节细胞分化缺陷,视神经变细,运动神经元分支异常。此外,Drish突变体成鱼的视网膜外核层也存在缺陷,因此表现出光反应和运动行为缺陷。Drish可能在Hh信号转导的下游发挥作用,但其确切作用还需要进一步研究。因此,本研究揭示了 drish 在斑马鱼视网膜神经节细胞、视神经和中间神经元发育以及脊髓运动轴突分支中的重要作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Editorial highlights

Every organism is a model organism for understanding development, evolution, disease, and regeneration, and we have only begun to scratch the surface of the interdisciplinary genetic, molecular, cellular, and developmental mechanisms that regulate these biological processes. These “Highlights” denote exciting advances recently reported in Developmental Dynamics that illustrate the complex dynamics of developmental biology.

Organogenesis—Lung Biology “Evolving topological order in the postnatal visceral pleura” by Betty Liu, Ali Ali, Stacey Kwan, Jennifer Pan, Willi Wagner, Hassan Khalil, Zi Chen, Maximilian Ackermann, and Steven Mentzer; Dev Dyn 253:8, pp. 711–721. https://doi.org/10.1002/dvdy.688. The surface of a visceral organ is lined by layers of epithelial cells that provide a selective barrier to the surrounding environment. Within these layers, epithelial cells exhibit complex shapes characterized by the number of sides adjoining neighboring cells, and polygonal shapes are associated with optimal cell packing and minimal free surface energy. Proper development of the lung requires rapid growth during the postnatal period with physical interactions between the visceral pleura and subjacent alveoli, which are exposed to both static and dynamic forces that influence cell shape and orientation. In this study, the authors investigated postnatal lung development discovering a high degree of network heterogeneity in which a small number of highly connected nodes, or hubs, play crucial roles in maintaining the network's structural integrity. Furthermore, this facilitated efficient information flow during the challenges of rapid lung growth. Taken together, changes in epithelial cell shape reflect optimal cell packing and the minimization of surface free energy, but also cell–cell interactions, cell proliferation, and cytoskeletal rearrangements, each of which is critical for normal lung development.

Organogenesis—Cochlea Development “Localization of cadherins in the postnatal cochlear epithelium and their relation to space formation” by Holly Beaulac and Vidhya Munnamalai; Dev Dyn 253:8, pp. 771–780. https://doi.org/10.1002/dvdy.692. The cochlea is a fluid-filled spiral cavity within the inner ear, that contains the organ of Corti. Comprised of three rows of outer hair cells and one row of inner hair cells in humans, the organ of Corti produces nerve impulses in response to sound vibrations. The organ of Corti has therefore been called the “temple of hearing” in the inner ear. The sensory epithelium in the organ of Corti consists of mechanosensory hair cells intercalated by epithelial support cells. The support cells are stiff yet compliant enough to withstand and modulate vibrations to the hair cells, and the cell adhesion properties of adjoining cell membranes between cells are flexible to allow the formation of fluid-filled spaces within the cochlea. This study investigated the role of cadherins, typically associated with cytoskeletal remodeling, in cochlea development and discovered that extensive F-actin remodeling occurs within the first week of birth. Furthermore, transient changes in cytoskeletal F-actin influence epithelial morphogenesis, and changes in the strength and properties of cell adhesion drive the formation of fluid-filled spaces in the epithelium that are central for proper hearing.

Neural Development “Requirement of a novel gene, drish, in the zebrafish retinal ganglion cell and primary motor axon development” by Suman Gurung, Nicole Restrepo, Surendra Kumar Anand, Vinoth Sittaramane, and Saulius Sumanas; Dev Dyn 253:8, pp. 750–770. https://doi.org/10.1002/dvdy.694. During nervous system development, a motor neuron's axons traverse the extracellular matrix to make synaptic connections, which are critical for neural circuit function. Zebrafish possess two distinct classes of spinal motor neurons: primary and secondary. This study explores the activity and functional role of a novel putative transmembrane protein, Drish, in zebrafish. Loss-of-function mutant embryos exhibit defects in retinal ganglion cell differentiation, with thinner optic nerves, and abnormal branching of motor neurons. In addition, drish mutant adults exhibit deficiencies in the outer nuclear layer of the retina and consequently display defective light response and locomotory behaviors. Drish may function downstream of Hh signaling, however, the exact role of Drish requires further investigation. This study therefore reveals the important roles of drish in retinal ganglion cell, optic nerve and interneuron development, and in spinal motor axon branching in zebrafish.

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来源期刊
Developmental Dynamics
Developmental Dynamics 生物-发育生物学
CiteScore
5.10
自引率
8.00%
发文量
116
审稿时长
3-8 weeks
期刊介绍: Developmental Dynamics, is an official publication of the American Association for Anatomy. This peer reviewed journal provides an international forum for publishing novel discoveries, using any model system, that advances our understanding of development, morphology, form and function, evolution, disease, stem cells, repair and regeneration.
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