Sources for comparative studies of placentation. II. Genomic resources

Review: The evolving placenta: different developmental paths to a hemochorial relationship

The way in which maternal blood is associated with trophoblast prior to the formation of the different types of hemochorial placenta may be conveniently grouped into four main patterns: a transitory endotheliochorial condition; maternal blood released into a mass of trophoblast; maternal blood confined to lacunae; and fetal villi entering preexisting maternal blood sinuses. Although it might be considered logical that developing placentas would pass through an endotheliochorial stage to become hemochorial, this developmental pattern is seen only as a transient stage in several species of bats and sciuromorph rodents. More commonly a mass of trophoblast at the junction with the endometrium serves as a meshwork through which maternal blood passes, with subsequent organization of a labyrinth when the fetal vascular component is organized. The initial trophoblast meshwork may be cellular or syncytial, often leading to a similar relationship in the spongy zone and labyrinth. Old World monkeys, apes and humans have a lacunar stage prior to establishing a villous hemochorial condition. New World monkeys lack a true lacunar stage, retaining portions of maternal vessels for some time and initially forming a trabecular arrangement similar to though differently arrived at than that in the tarsier. In armadillos, preexisting maternal venous sinuses are converted into an intervillous blood space by intruding fetal villi. Variations from the major patterns of development also occur. The way in which the definitive placental form is achieved developmentally should be considered when using placental structure to extrapolate evolution of placentation.

Reasons for diversity of placental structure

Many early embryonic stages are nearly indistinguishable in different Eutheria. However, implantation stages and placental morphological types vary tremendously. A number of factors favor this conflicting diversity. 1. Whereas embryo development takes place in the isolation of the amniotic cavity, the extraembryonic membranes of the conceptus develop in close association with the uterus of a genetically different organism. 2. Early conditions for the developing conceptus are anaerobic whereas later in development efficient aerobic conditions are essential for continued growth of the fetus. 3. Developing extraembryonic membranes have the potential to form two partially sequential placentas. The yolk sac can participate in forming a choriovitelline placenta, including an interhemal region, and can be adapted to various non-respiratory functions as gestation proceeds. Development of the chorioallantoic placenta begins later than the choriovitelline placenta but can overlap with this before supplanting it. The original development of the extraembryonic membranes occurs when the conceptus is sufficiently small that neither its nutritional requirements nor its respiratory needs are the burden to the maternal organism that they are later in gestation. Despite these developmental factors promoting different methods of forming the definitive placenta, the placental type is consistent within most families indicating that the divergence in placental structure accompanied evolution of differences between groups.