Trafficking of circulating pro-NK cells to the decidualizing uterus: regulatory mechanisms in the mouse and human.

Natural Killer (NK) lymphocytes, strongly expressing CD56, become abundant in the human uterus three to five days after the mid-menstrual cycle surge in pituitary-derived luteinizing hormone (LH). The primary functions of LH are to initiate final oocyte maturation/ovulation and to contribute to decidualization of the uterine stroma. Decidualization is the transformation of estrogen-primed uterine stromal fibroblasts into large hormone-producing cells under the influence of progesterone (P4). Decidual CD56bright (dNK) cells are a distinct, transient, tissue-specific NK cell subset that undergoes proliferation, terminal differentiation, and then death prior to menses. If pregnancy occurs, dNK cells increase during first trimester, then decline and are virtually absent in late pregnancy. In mouse models, pregnancy-associated uterine NK (uNK) cells appear coincident with onset of decidualization during embryonic implantation. Murine uNK cells traffic from the circulation to the antimesometrial side of the uterus and migrate to the mesometrial side of each implantation site. Here they proliferate and are implicated in regulation of midgestation structural changes to major arteries supplying the placenta, before dying in late gestation. Emerging data indicate that interactions between lymphocytes and endothelial cells within the uterine microenvironment are mediated by classical molecules associated with lymphocyte trafficking in immune surveillance and in response to inflammation. Here, we review factors influencing NK cell trafficking to decidualizing murine and human uteri and the differentiation and functions of these cells within the uterus.

Coordinate regulation of lymphocyte-endothelial interactions by pregnancy-associated hormones.

Precursors of uterine NK cells home to the uterus during early pregnancy from multiple lymphohemopoietic sources. In mouse uterine tissue, pregnancy markedly up-regulates both L-selectin- and alpha(4) integrin-dependent adhesion pathways for circulating human CD56(bright) cells, the phenotype of human uterine NK cells. Based on roles for these adhesion molecules in lymphocyte homing, we examined effects of pregnancy or the steroid hormones 17beta-estradiol or progesterone on lymphocyte-endothelial interactions in secondary lymphoid tissues and in uterus. From preimplantation gestation day 3, specialized high endothelial venules in peripheral lymph nodes and Peyer's patches supported elevated L-selectin and alpha(4)beta(7) integrin-dependent lymphocyte adhesion under shear throughout pregnancy, as compared with high endothelial venules of virgin or postpartum donors. Squamous endothelium from nonlymphoid tissue was not affected. Pregnancy-equivalent endothelial responses were observed in lymph nodes and Peyer's patches from ovariectomized mice receiving 17beta-estradiol and/or progesterone replacement therapy. Adhesion of human CD56(bright) cells to uteri from pregnant or hormone-treated ovariectomized mice was enhanced through L-selectin- and alpha(4) integrin-dependent mechanisms and involved multiple vascular adhesion molecules including mucosal addressin cell adhesion molecule-1, VCAM-1, and peripheral lymph node addressin. Analysis of Tie2-green fluorescence protein transgenic mice demonstrated that CD56(bright) cells adhered primarily to vascular endothelium within the decidua basalis. Microdomain localization of adhesion involving large clusters of lymphocytes was induced on uteri from natural matings, but not pseudopregnancy. Steroid hormones also had independent effects on L-selectin function in splenic lymphocytes that mimicked physiological stimulation induced by pregnancy or fever-range temperatures. These results provide the first evidence for coordinated, organ-specific, steroid hormone-induced changes in lymphocyte homing mechanisms that could contribute to local and systemic immune responses during pregnancy.

Update on pathways regulating the activation of uterine Natural Killer cells, their interactions with decidual spiral arteries and homing of their precursors to the uterus.

Virgin adult C57Bl/6J mouse uterus contains a population of small, non-granulated Natural Killer (NK) cells with balanced expression of NK cell activating and inhibiting LY49 receptors. Coincident with blastocyst implantation and decidualization, uterine (u)NK cells become activated. The surface glycoslyation of uNK changes, the cells proliferate and they induce production of interferon (IFN)gamma, perforin, serine esterases and other molecules, including angiogenic factors. Mouse strains genetically ablated in uNK cells fail to undergo modification of spiral artery segments that branch from the uterine artery and feed into the placenta and these mice do not sustain a robust decidualization response. IFN-gamma is thought, from bone marrow transplantation and therapeutic studies, to be the key uNK-cell derived mediator regulating gene expression in vascular and decidual tissues. Here, we review recent studies showing that IL-15 is the critical cytokine controlling uNK cell differentiation and that uNK cells are activated by either IL-12 or IL-18 and by other factors when both IL-12 and IL-18 are genetically absent from implantation sites. We address possible roles of the IFN-gamma regulated gene alpha2-macroglobulin (alpha2-M) in regulation of the position of fetal trophoblast within the walls of the spiral arteries, and we discuss approaches that have been successful in evaluating mechanisms involved in homing of mouse uNK cell precursors to the uterus. These approaches maybe applicable to studies in women. Our studies show that complex immuno-physiological events contribute to spiral artery modification by mid-gestation in mice.

Uterine natural killer cells: insights into their cellular and molecular biology from mouse modelling.

In primates, including women, and in rodents, natural killer lymphocytes (NK cells) have a unique relationship with the decidualizing uterus. Implantation sites from genetically modified and transplanted mice have proven useful models for understanding potential mechanisms involved in the recruitment, activation and functions of human CD56(bright) uterine (u)NK cells. Key findings are reviewed in this article. In mice, uNK precursor cells are recruited from secondary lymphoid tissues and are activated coincident with their uterine arrival. uNK cells proliferate, produce cytokines (interferon gamma (IFN-gamma) and interleukin 18 (IL-18) and IL-27), and terminally differentiate into granulated lymphocytes. Many uNK cells proliferate within the myometrium at each implantation site forming a structure, the mesometrial lymphoid aggregate of pregnancy (MLAp) that surrounds blood vessels servicing each placenta. Post-mitotic uNK cells are abundant within decidua basalis; frequently (<25%) associating with spiral arteries, intramurally and intraluminally. From mid-gestation, numbers of uNK cells decline. Studies of implantation sites in mice lacking uNK cells, IFN-gamma, components of IFN-gamma-induction and -signalling pathways or IFN-gamma-regulated genes indicate that uNK cell-derived IFN-gamma is essential in triggering pregnancy-induced spiral artery modification. Decidual maintenance and uNK cell death are additional effects of uNK cell-derived IFN-gamma. Thus, during the first half of gestation, uNK cells contribute to and sustain important changes in the maternal placental bed.

Neither lymphotoxin alpha nor lymphotoxin beta receptor expression is required for biogenesis of lymphoid aggregates or differentiation of natural killer cells in the pregnant mouse uterus.

Gene ablation studies in mice indicate that lymphotoxin (LT)alpha, LTbeta and LTbetaR are essential for the genesis of lymph nodes (LN), normal structural development of peripheral lymphoid tissues and the differentiation of natural killer (NK) cells. LTbetaR binds to the heterotrimeric cytokines LTalpha1beta2 and LIGHT. LTs also regulate stromal cell expression of lymphocyte homing chemokines. Uterine decidualization in normal (+/+) mice is accompanied by the appearance and maturation of large numbers of uterine NK (uNK) cells that differentiate from precursors mobilized to the uterus from secondary lymphoid tissues. uNK cells accumulate in a transient, lymphocyte-rich region known as the metrial gland or, more recently, the mesometrial lymphoid aggregrate of pregnancy (MLAp). To determine if LTs contribute to development of the MLAp, and to the differentiation and/or localization of uNK cells, a histological study was undertaken of implantation sites from LTalpha null, LTbetaR null and gestation day-matched, normal mice. Implantation sites from the gene-ablated mice contained abundant numbers of uNK cells that localized appropriately. This indicates that the stromally derived molecules supporting NK cell differentiation in the uterus differ from those used in secondary lymphoid organs.

Decidual natural killer cells: key regulators of placental development (a review).

Establishment of pregnancy initiates a dynamic and predictable series of changes in the uterus. In rodents, the trophectoderm of the blastocyst develops through the stage of an ectoplacental cone to become the placenta. The inner cell mass becomes the fetus and its associated extra-embryonic ectoderm and mesoderm. Maternal changes support development of the conceptus. These begin in the uterine stroma, which undergoes a process known as decidualization, and progress to include dilation and elongation of the uteroplacental arteries and activation and proliferation of specialized large granulated lymphocytes in the decidua basalis. This review focuses on these pregnancy-associated lymphocytes, known as uterine Natural Killer (uNK) cells and on their interactions with the other tissues that form the mesometrial aspect of the mouse maternal-fetal interface. Analogous lymphocytes are present in the decidualized human uterus. Understanding of uNK cell biology has advanced significantly through histological studies of implantation sites in immune deficient mice. Here, we summarize the key studies in lymphocyte-, cytokine- and cytokine receptor-deficient mice and in four enhanced models of gestation in these mice that incorporate transplantation or therapy with biologically active molecules.

Contributions from self-renewal and trafficking to the uterine NK cell population of early pregnancy.

Uterine NK (uNK) cells are abundant in human and murine uteri during decidualization. It is unclear whether precursors of uNK (pre-uNK) cells self-renew or are recruited from other sites. To assess self-renewal of pre-uNK cells, uterine segments from NK cell-competent mice were grafted orthotopically into NK/uNK cell-deficient or wild-type mice. Only in wild-type recipients did decidualized grafts contain uNK cells, indicating that pre-uNK cells do not self-renew in uterus. To identify pre-uNK cell sources, thymus, bone marrow, lymph node, or spleen cells were grafted from virgin or pregnant NK cell-competent donors into mated NK/uNK cell-deficient recipients. Cells from secondary lymphoid tissues of pregnant donors gave high level uNK cell reconstitution, which was independent of chemokine receptors CCR2 or CCR5. Pregnancy-induced changes to lymphocyte-endothelial cell interactions were documented using adhesion of human lymphocytes to frozen mouse tissue sections under shear. A dynamic increase was observed in L-selectin- and alpha(4) integrin-dependent adhesion of CD56(bright) NK cells to decidualizing uterus and in human PBL adhesion to lymph node endothelium. These data support a model that attributes the dramatic increases in human and murine uNK cells during decidualization to precursor cell recruitment.