Expression of indoleamine 2,3-dioxygenase in the rhesus monkey and common marmoset.

Indoleamine 2,3-dioxygenase (IDO) catalyzes the initial and rate-limiting step of tryptophan degradation along the kynurenine pathway, and is hypothesized to limit tryptophan availability at embryo implantation and prevent maternal T cell activation at the maternal-fetal interface. To determine if nonhuman primates are suitable models for investigating the role of IDO during pregnancy, we defined the expression of IDO in the rhesus monkey and common marmoset with particular attention to the female reproductive tract and placenta. IDO mRNA was detected by RT-PCR in the rhesus monkey term placenta, lung, small intestine, spleen, lymph node and nonpregnant uterus, and also in the common marmoset placenta. Immunohistochemical analysis of rhesus monkey tissues localized IDO to glandular epithelium of nonpregnant endometrium and first trimester decidua, vessel endothelium of nonpregnant myometrium, first trimester decidua and term decidua, and villous vessel endothelium and syncytiotrophoblast of term placenta. Western blot analysis confirmed IDO in rhesus monkey term placenta. In the common marmoset, IDO was detected in glandular epithelium of the nonpregnant uterus and in the decidua at day 60 and day 128 of gestation. IDO activity was higher in rhesus monkey and common marmoset decidua and placentas than in other tissues. Confirmation of IDO expression in rhesus monkey and common marmoset uterine and placental tissues supports the hypothesis that this enzyme regulates immune activation at the maternal-fetal interface and demonstrates that nonhuman primates may provide models with distinct similarities to human placentation to study the role of IDO in maternal-fetal immune dialogue.

Immune and trophoblast cells at the rhesus monkey maternal-fetal interface.

To promote the use of the nonhuman primate model for the study of the cellular and molecular biology of maternal-fetal interactions and placental development during early pregnancy, we have developed protocols for the isolation and characterization of placental trophoblasts and decidual immune cells from the rhesus monkey. In this chapter, we provide protocols for trophoblast and decidual immune cell isolation, phenotyping of isolated cells by flow cytometry, and analysis of placental and decidual tissues by immunohistochemistry. Information on antibodies for these analyses are also provided, which is an important consideration when attempting to use anti-human antibodies for the study of nonhuman primates.

On the role of placental Major Histocompatibility Complex and decidual leukocytes in implantation and pregnancy success using non-human primate models.

While there is broad agreement that interactions of the human maternal immune system with the tissues and cells of the implanting embryo are likely to be critical contributors to pregnancy success, there remains a dearth of information which directly confirms this expectation. Although animal models of reproductive function often provide opportunities for confirming such hypotheses, progress in this area has been sporadic due to limitations of traditional laboratory or agricultural animal models, such as rodents, sheep, pigs and cattle. Many of these limitations derive from divergent modes of implantation and placentation across mammalian species. Over the past decade there has been progress in the development of the nonhuman primate as a model in which to address questions of pregnancy success in the area of immunology. The purpose of this review is to compare available model species, summarize current knowledge and recent progress with an emphasis on experimental in vivo manipulations, and suggest areas available for additional study and growth.

Characterization of decidual leukocyte populations in cynomolgus and vervet monkeys.

The objective of this study was the phenotypic and functional evaluation of decidual immune cells in the cynomolgus and vervet monkeys. Early pregnancy (days 36-42) deciduas were obtained by fetectomy for histological evaluation and decidual mononuclear leukocyte (MNL) isolation. While peripheral NK (pNK) cells in these species do not express CD56, CD56(+) NK cells were abundant in decidual samples. The majority of decidual NK (dNK) cells (>80%) had high light-scatter characteristics and were CD56(bright)CD16(+) cells with no or very low levels of natural cytotoxicity receptors (NKp46, NKp30) and NKG2A, while a minor population were small CD56(dim)CD16(-) lymphocytes also expressing less NKp46, NKp30 and NKG2A than pNK cells. All dNK cells were found to be perforin(+); however, their cytotoxic potential was low and cynomolgus dNK cells showed strongly reduced cytotoxicity against target cells compared with pNK cells. Macrophages and T cells together comprised approximately 25-30% of decidual MNL. Decidual T cells contained a higher proportion of the minor T cell subtypes (gammadeltaT cells, CD56(+) T cells) compared with peripheral blood. A subset of DC-SIGN(+) macrophages, with a distribution adjacent to areas of placental attachment in contrast to the widespread setting of general CD68(+) cells, was identified in both species. Together, these results demonstrate that the maternal-fetal interface in both cynomolgus and vervet monkeys is very rich in immune cells that have similar phenotypes to those seen in humans, indicating that both species are excellent models to study the contributions of distinct immune cell populations to pregnancy support.

Passive immunization against the MHC class I molecule Mamu-AG disrupts rhesus placental development and endometrial responses.

The unique MHC phenotype of the human and nonhuman primate placenta has suggested a potential role in maternal-fetal immune tolerance, pregnancy success, and maternal as well as fetal well-being. In the rhesus monkey (Macaca mulatta) a nonclassical MHC class I molecule, Mamu-AG, is a putative homologue of HLA-G and is hypothesized to play a role in maternal-fetal immune interactions during pregnancy. Rhesus monkeys were passively immunized during the second week after implantation with a mAb against Mamu-AG. Passive immunization altered the growth and vascularization of the fetal placenta, the placental modification of maternal endometrial vessels, the maternal leukocyte response to implantation, and the differentiation of epithelial and stromal cells in the endometrium. These data are the first to demonstrate in vivo the importance of MHC class I molecules expressed on primate trophoblasts in establishing an important environment for pregnancy success through coordinated interactions between endometrial and fetal tissues.

Vitamin A deficiency in the late gastrula stage rat embryo results in a one to two vertebral anteriorization that extends throughout the axial skeleton.

Vitamin A and its metabolites are known to be involved in patterning the vertebrate embryo. Study of the effect of vitamin A on axial skeletal patterning has been hindered by the fact that deficient embryos do not survive past midgestation. In this study, pregnant vitamin A-deficient rats were maintained on a purified diet containing limiting amounts of all-trans retinoic acid (12 microg atRA/g diet) and given a daily oral bolus dose of retinol starting at embryonic day 0.5, 8.25, 8.5, 8.75, 9.25, 9.5, 9.75, or 10.5. Embryos were recovered at E21.5 for analysis of the skeleton and at earlier times for analysis of select mRNAs. Normal axial skeletal development and patterning were observed in embryos from pregnant animals receiving retinol starting on or before E8.75. Delay of retinol supplementation to E9.5 or later resulted in a marked increase in both occurrence and severity of skeletal malformations, extending from the craniocervical to sacral regions. Embryos from the groups receiving retinol starting at E9.5 and E9.75 had one-vertebral anterior transformations of the cervical, thoracic, lumbar, and sacral vertebrae. Few embryos survived in the E10.5 group, but these embryos yielded the most severe and extensive anteriorization events. The skeletal alterations seen in vitamin A deficiency are associated with posterior shifts in the mesodermal expression of Hoxa-4, Hoxb-3, Hoxd-3, Hoxd-4, and Hoxa-9 mRNAs, whereas the anterior domains of Hoxb-4 and Cdx2 expression are unaltered. This work defines a critical window of development in the late gastrula-stage embryo when vitamin A is essential for normal axial skeletal patterning and shows that vitamin A deficiency causes anterior homeotic transformations extending from the cervical to lumbosacral regions.