Ultrastructure and enzyme histochemistry of the marmoset yolk sac and embryonic intestinal epithelium

Development and structure of the placenta and fetal membranes of nonhuman primates

This survey examines placental and fetal membrane structure, function, and development in nonhuman primates. It will focus on these aspects of fetal membranes in species exemplifying the two main types of primate placentation. The chorioallantoic placentas of most strepsirhine primates (e.g., lorises and lemurs), are diffuse, villous and epitheliochorial in structure. Villi are stout, usually unbranched and interdigitate with indentations in the uterine lining. Early in gestation trophoblast cells are columnar but with advancing gestational age considerable thinning of the interhemal membrane occurs. The villous tips have indented regions that appear to be involved in absorption of histotroph. Accessory placental structures known as areolae or chorionic vesicles occur in many strepsirhines. These are cup-shaped specializations that develop opposite the mouths of uterine glands and appear active in absorption of glandular secretions. In addition, most strepsirhines are characterized by a large yolk sac early in gestation, a transient choriovitelline placenta, and most have a large allantoic sac. In strepsirhines, amniogenesis occurs by folding. In contrast, the chorioallantoic placentas of most haplorhines are discoidal, villous, and hemochorial. The species emphasized in the review are macaque monkeys. The placental villi are covered by a layer of syncytiotrophoblast; the latter is active in maternal-fetal transport and hormone synthesis. In some haplorhines, extravillous trophoblast invades deeply into the endometrium and also into spiral arteries supplying the placenta. Other fetal membranes include 1) nonvillous chorion (chorion laeve); there is evidence supporting both an absorptive and synthetic role for trophoblast of the chorion laeve; 2) yolk sac, which is unusual in that a secondary yolk sac is formed. The yolk sac has both synthetic and absorptive functions in early gestation; and 3) amnion; amniogenesis in haplorhines occurs by cavitation.

Cytochemistry of membrane proteases

Membrane proteases that are detectable by cytochemical means are the classified exopeptidases, aminopeptidases A and M (or N), gamma-glutamyl transpeptidase (which also acts as transferase), dipeptidyl peptidase IV and the endopeptidase, enteropeptidase (also known as enterokinase). Not yet classified are the possible exopeptidase, tripeptidyl peptidase and endopeptidases I (Ala-endopeptidase) and II (Arg-endopeptidase). All these membrane proteases can be investigated with either chromogenic or fluorogenic procedures using synthetic peptide substrates. The most useful substrates are 4-methoxy-2-naphthylamine amino acids and peptides for cytochemical localizations at the light and electron microscope levels, for cytophotometric quantification and the study of membrane protease isoenzymes after analytical isoelectric focusing. Amino acid or peptide derivatives of naphthylamine AS can be recommended for light microscopical localization and cytofluorometric quantification, and 7-amino-4-methylcoumarin and 7-amino-4-trifluoromethylcoumarin amino acids and peptides for the development of enzyme bands after isoelectric focusing. Cytochemistry reveals the heterogeneity in the distribution and species differences of membrane proteases in adult cells, tissues and organs and during development. It also reveals some common localizations, such as in small intestinal enterocytes and proximal tubule cells. The species and organ differences are substantiated and extended considerably by isoelectric focusing in combination with methods for the cytochemical detection of proteases. In addition, continuous cytophotometry or cytofluorometry (section and cultured cell biochemistry) allows the kinetic characteristics, initial reaction rates and maximum activities of all membrane proteases to be determined. The physiological functions of the endopeptidases and exopeptidases are still a matter of debate. However, from cytochemical inhibition studies with natural peptide substrates, e.g. peptide hormones, there is increasing evidence that the proteases detected with synthetic peptides play a decisive role in many physiological circumstances, e.g. in endocrine regulation mechanisms or the regulation of blood pressure. In this respect, capillary endothelium-linked surface membrane proteases may be especially important.