心脏神经嵴的进化与发育起源:构建分隔的流出道。
Evolutionary and developmental origins of the cardiac neural crest: building a divided outflow tract.
作者信息
Keyte Anna L, Alonzo-Johnsen Martha, Hutson Mary R
机构信息
Brumley Neonatal Perinatal Research Institute, Department of Pediatrics, Duke University, Durham, North Carolina.
出版信息
Birth Defects Res C Embryo Today. 2014 Sep;102(3):309-23. doi: 10.1002/bdrc.21076. Epub 2014 Sep 16.
Abstract
The cardiac neural crest cells (CNCCs) have played an important role in the evolution and development of the vertebrate cardiovascular system: from reinforcement of the developing aortic arch arteries early in vertebrate evolution, to later orchestration of aortic arch artery remodeling into the great arteries of the heart, and finally outflow tract septation in amniotes. A critical element necessary for the evolutionary advent of outflow tract septation was the co-evolution of the cardiac neural crest cells with the second heart field. This review highlights the major transitions in vertebrate circulatory evolution, explores the evolutionary developmental origins of the CNCCs from the third stream cranial neural crest, and explores candidate signaling pathways in CNCC and outflow tract evolution drawn from our knowledge of DiGeorge Syndrome.
摘要
心脏神经嵴细胞(CNCCs)在脊椎动物心血管系统的进化和发育中发挥了重要作用:从脊椎动物进化早期对发育中的主动脉弓动脉的强化,到后来将主动脉弓动脉重塑为心脏大动脉的协调过程,以及最后在羊膜动物中流出道的分隔。流出道分隔进化出现所必需的一个关键因素是心脏神经嵴细胞与第二心脏场的共同进化。本综述重点介绍了脊椎动物循环系统进化中的主要转变,探讨了来自第三流颅神经嵴的CNCCs的进化发育起源,并根据我们对22q11.2缺失综合征的了解,探索了CNCCs和流出道进化中的候选信号通路。
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