Flamme I
Department of Developmental Biology, Ruhr-University Bochum, Federal Republic of Germany.
Anat Embryol (Berl). 1989;180(3):259-72. doi: 10.1007/BF00315884.
The area vasculosa of the chick embryo is subdivided into two concentric zones: the inner transparent area pellucida vasculosa (AVP) and the less transparent surrounding area opaca vasculosa (AOV). The different optical properties of these zones are caused by the different morphology of the endoderm, which consists of flat cells in the APV and of high-prismatic cells containing large yolk vacuoles in the AOV. The present study describes how this endodermal subdivision of the area vasculosa is related to the development of the extraembryonic vascular pattern. By injection of ink into the vascular system of chick embryos at stages 12 to 20 (Hamburger and Hamilton 1951 "HH"), it has been demonstrated that the vascular net of the area vasculosa from stage 14 (HH) onwards develops into different patterns in APV and AOV. The small loops of uniform capillary vessels of stage 13 (HH) are widened due to the rapid expansion of the extraembryonic mesoderm. In the AOV from stage 14 (HH) onwards numerous small blood vessels sprout into the enlarged intervascular spaces. This process is maximal at stage 17 (HH). In contrast, the blood vessels of the APV remain largely unbranched. These findings suggest that the development of the extraembryonic vascular pattern is controlled by the endodermal pattern. To test this hypothesis, both zones (APV and AOV) were examined by light microscopy, transmission and scanning electron microscopy, in vivo observations and by treatment with bromodeoxyuridine (BrdU). TEM examinations show that the ultrastructural organization of the APV mesoderm is different from that of the AOV: The splanchnopleuric cells of the APV form a continuous cover around the endothelial cells connected by numerous desmosomes, whereas the splanchnopleuric cells of the AOV are frequently separated by gaps. The largest gaps are seen in the small blood vessels at stage 17 (HH). These results should be considered in relation to the dynamic changes in the vascular pattern of the AOV. The endodermal cells of APV and AOV are two different populations. In vivo observation of the endodermal transition from APV to AOV detected no transformations of APV cells into AOV cells or vice versa. The borderline between the zones is stable. The AOV endoderm, having been overgrown by the expanding mesoderm, stops proliferating almost completely, whereas the proliferation of the APV endoderm is unaffected by contact with the mesoderm. The rate of its proliferation is approximately as high as that of the AOV prior to contact with the expanding mesoderm (results after treatment with BrdU).(ABSTRACT TRUNCATED AT 400 WORDS)
内部较透明的明区血管区(AVP)和周围不太透明的暗区血管区(AOV)。这些区域不同的光学特性是由内胚层不同的形态所致,AVP中的内胚层由扁平细胞组成,而AOV中的内胚层由含有大卵黄泡的高柱状细胞组成。本研究描述了血管区的这种内胚层细分与胚外血管模式发育之间的关系。通过在第12至20阶段(Hamburger和Hamilton,1951年“HH”)向鸡胚的血管系统中注入墨水,已证明从第14阶段(HH)开始,血管区的血管网在AVP和AOV中发育成不同的模式。第13阶段(HH)均匀毛细血管的小环由于胚外中胚层的快速扩张而变宽。从第14阶段(HH)开始,在AOV中,许多小血管向扩大的血管间隙中芽生。这个过程在第17阶段(HH)达到最大值。相比之下,AVP的血管在很大程度上保持无分支状态。这些发现表明胚外血管模式的发育受内胚层模式的控制。为了验证这一假设,通过光学显微镜、透射和扫描电子显微镜、体内观察以及用溴脱氧尿苷(BrdU)处理对这两个区域(AVP和AOV)进行了检查。透射电镜检查表明,AVP中胚层的超微结构组织与AOV不同:AVP的脏壁细胞围绕通过众多桥粒连接的内皮细胞形成连续覆盖,而AOV的脏壁细胞经常被间隙隔开。在第17阶段(HH)的小血管中可见最大的间隙。这些结果应结合AOV血管模式的动态变化来考虑。AVP和AOV的内胚层细胞是两个不同的群体。对从AVP到AOV的内胚层转变进行的体内观察未检测到AVP细胞向AOV细胞或反之的转化。区域之间的边界是稳定的。被扩张的中胚层覆盖的AOV内胚层几乎完全停止增殖,而AVP内胚层的增殖不受与中胚层接触的影响。其增殖速率与在与扩张的中胚层接触之前的AOV大致相同(用BrdU处理后的结果)。(摘要截取自400字)
