Departamento de Biología Animal, Facultad de Ciencias, Universidad de Málaga, Málaga, Spain; Instituto de Investigación Biomédica de Málaga (IBIMA), Málaga, Spain.
Departamento de Biología Animal, Facultad de Ciencias, Universidad de Málaga, Málaga, Spain; Instituto de Investigación Biomédica de Málaga (IBIMA), Málaga, Spain; CIBERCV Enfermedades Cardiovasculares, Málaga, Spain.
Prog Cardiovasc Dis. 2020 Jul-Aug;63(4):407-418. doi: 10.1016/j.pcad.2020.06.008. Epub 2020 Jun 25.
Bicuspid aortic valve (BAV) is the most common congenital cardiac malformation, frequently associated with aortopathies and valvulopathies. The congenital origin of BAV is suspected to impact the development of the disease in the adult life. During the last decade, a number of studies dealing with the embryonic development of congenital heart disease have significantly improved our knowledge on BAV etiology. They describe the developmental defects, at the molecular, cellular and morphological levels, leading to congenital cardiac malformations, including BAV, in animal models. These models consist of a spontaneous hamster and several mouse models with different genetic manipulations in genes belonging to a variety of pathways. In this review paper, we aim to gather information on the developmental defects leading to BAV formation in these animal models, in order to tentatively explain the morphogenetic origin of the spectrum of valve morphologies that characterizes human BAV. BAV may be the only defect resulting from gene manipulation in mice, but usually it appears as the less severe defect of a spectrum of malformations, most frequently affecting the cardiac outflow tract. The genes whose alterations cause BAV belong to different genetic pathways, but many of them are direct or indirectly associated with the NOTCH pathway. These molecular alterations affect three basic cellular mechanisms during heart development, i.e., endocardial-to-mesenchymal transformation, cardiac neural crest (CNC) cell behavior and valve cushion mesenchymal cell differentiation. The defective cellular functions affect three possible morphogenetic mechanisms, i.e., outflow tract endocardial cushion formation, outflow tract septation and valve cushion excavation. While endocardial cushion abnormalities usually lead to latero-lateral BAVs and septation defects to antero-posterior BAVs, alterations in cushion excavation may give rise to both BAV types. The severity of the original defect most probably determines the specific aortic valve phenotype, which includes commissural fusions and raphes. Based on current knowledge on the developmental mechanisms of the cardiac outflow tract, we propose a unified hypothesis of BAV formation, based on the inductive role of CNC cells in the three mechanisms of BAV development. Alterations of CNC cell behavior in three possible alternative key valvulogenic processes may lead to the whole spectrum of BAV.
二叶式主动脉瓣(BAV)是最常见的先天性心脏畸形,常与主动脉病变和瓣叶病变相关。BAV 的先天性起源被怀疑会影响成人期疾病的发展。在过去的十年中,许多研究先天性心脏病胚胎发育的研究显著提高了我们对 BAV 病因的认识。它们描述了在动物模型中导致先天性心脏畸形(包括 BAV)的分子、细胞和形态水平的发育缺陷。这些模型包括自发的仓鼠和几种具有不同基因操作的小鼠模型,这些基因操作涉及多种途径的基因。在这篇综述文章中,我们旨在收集导致这些动物模型中 BAV 形成的发育缺陷信息,以便初步解释导致人类 BAV 瓣膜形态谱的形态发生起源。BAV 可能是小鼠基因操作唯一导致的缺陷,但通常它是心脏流出道畸形谱中较轻的缺陷。导致 BAV 的基因改变属于不同的遗传途径,但其中许多基因直接或间接地与 NOTCH 途径相关。这些分子改变影响心脏发育过程中的三个基本细胞机制,即心内膜向间质转化、心脏神经嵴(CNC)细胞行为和瓣膜垫间充质细胞分化。有缺陷的细胞功能影响三种可能的形态发生机制,即流出道心内膜垫形成、流出道间隔和瓣膜垫挖掘。虽然心内膜垫异常通常导致侧向 BAV,间隔缺陷导致前向后 BAV,但瓣膜垫挖掘的改变可能导致两种 BAV 类型。原始缺陷的严重程度很可能决定了特定的主动脉瓣表型,包括联合融合和嵴。基于心脏流出道发育的发育机制的现有知识,我们提出了一个基于 CNC 细胞在 BAV 发育的三个机制中的诱导作用的 BAV 形成的统一假设。在三个可能的替代关键瓣膜发生过程中 CNC 细胞行为的改变可能导致整个 BAV 谱。
