COMPARATIVE ASPECTS OF PLACENTAL LACTOGENS - STRUCTURE AND FUNCTION

Removal of the pituitary from pregnant rats provided early evidence th at the placenta was the source of prolactin-like bioactivity. After mi d-pregnancy the placenta was able to support progesterone production b y the corpus luteum (luteotrophic activity) and continued development of the mammary gland (mammotrophic activity). Three groups of mammals, the rodents, the ruminant artiodactyls and the primates are now known to produce from fetal placenta a remarkable variety of proteins which are related in structure to pituitary prolactin and growth hormone. P rolactin and growth hormone are themselves structurally related and ar e thought to have arisen from a common ancestral gene by gene duplicat ion and evolutionary divergence. The receptors with which they interac t also form a family of homologous proteins. Surprisingly the placenta l lactogens appear to have arisen more than once in evolution since in primates they are structurally closely related to growth hormone, whi le in rodents and ruminants they have closer similarity to prolactin. There is suggestive evidence that there may be specific receptors for placental lactogens in some fetal and maternal tissues. In humans a fi ve-gene cluster on chromosome 17 contains two growth hormone (GH) and three placental lactogen (PL) genes. Two human PL genes encode identic al proteins that are expressed in the placenta. One of the human GH ge nes is also placentally expressed. In mice, chromosome 13 carries the genes for mouse prolactin, for placental lactogen-I and -II (PL-I and PL-II) and for two other prolactin-related proteins, the proliferins. Rats also express PL-I and PL-II, together with at least three other p lacental prolactin-like proteins different from proliferins. In sheep, goat and cow, placental lactogens with about 50% sequence homology wi th their homologous prolactins occur. The bovine placenta has also yie lded cDNA clones predicting proteins related to prolactin but distinct from FL. The physiological role of most of these known or predicted p roteins is poorly understood. Each, however, appears to show a rather specific pattern of expression with regard to tissue, cell and time of appearance. Placental lactogens may reach very high concentrations in maternal plasma and their roles are thought to include luteotrophic e ffects in rodents and in all species metabolic effects to divert nutri ents to the fetus as well as effects on mammary development. They may also have important roles in the fetus exerting growth-promoting and m etabolic actions.