生物电信号作为发育和再生的独特调节剂。
Bioelectric signaling as a unique regulator of development and regeneration.
机构信息
Department of Genetics, Harvard Medical School, Department of Orthopaedics, Boston Children's Hospital, 300 Longwood Avenue Enders 260, Boston MA 02115, USA.
出版信息
Development. 2021 May 15;148(10). doi: 10.1242/dev.180794. Epub 2021 May 17.
Abstract
It is well known that electrical signals are deeply associated with living entities. Much of our understanding of excitable tissues is derived from studies of specialized cells of neurons or myocytes. However, electric potential is present in all cell types and results from the differential partitioning of ions across membranes. This electrical potential correlates with cell behavior and tissue organization. In recent years, there has been exciting, and broadly unexpected, evidence linking the regulation of development to bioelectric signals. However, experimental modulation of electrical potential can have multifaceted and pleiotropic effects, which makes dissecting the role of electrical signals in development difficult. Here, I review evidence that bioelectric cues play defined instructional roles in orchestrating development and regeneration, and further outline key areas in which to refine our understanding of this signaling mechanism.
摘要
众所周知,电信号与生物体密切相关。我们对兴奋组织的认识在很大程度上来源于对神经元或心肌细胞等特殊细胞的研究。然而,所有细胞类型都存在电势,这是由于离子在膜上的差异分布所致。这种电势能与细胞行为和组织组织有关。近年来,有令人兴奋的、广泛出乎意料的证据表明,发育的调节与生物电信号有关。然而,电势能的实验调节可能具有多方面和多效性的影响,这使得电信号在发育中的作用难以解析。在这里,我回顾了生物电线索在协调发育和再生中发挥明确指令作用的证据,并进一步概述了在这一信号机制方面需要进一步研究的关键领域。
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