Yung Wai Loke

Human Decidual Natural Killer Cells Express the Receptor for and Respond to the Cytokine Interleukin 15

Abstract The natural killer (NK) cells that are present in the uterine mucosa (decidua) during early pregnancy have a distinctive phenotype, CD56bright CD16−. These cells have previously been shown to proliferate and be activated by interleukin (IL)-2. However, IL-2 is absent from the decidua and placenta, and we have therefore investigated whether IL-15 is present in the uterus and can act on decidual NK cells. Both IL-15 mRNA and protein were found in a variety of cells but particularly in decidual macrophages. IL-15 induced a proliferative response in decidual NK cells that was blocked by anti-IL-15 and was augmented by stem cell factor. The cytolytic activity of decidual NK cells against K562 was augmented. Interestingly, in contrast to IL-2, although activation with IL-15 resulted in some killing of JEG-3 choriocarcinoma cells, normal trophoblast cells remained resistant to lysis. These findings suggest that IL-15 is a candidate cytokine responsible for NK cell proliferation in vivo in the progesterone-dominated secretory endometrium and early decidua.

Nonclassical HLA-G molecules are classical peptide presenters

BACKGROUND The physiological functions of the classical HLA (human leukocyte antigen) molecules, HLA-A, HLA-B and HLA-C, are to present peptides to T cells and to inhibit the activity of natural killer cells. In contrast, the functions of nonclassical HLA-molecules, such as HLA-E, HLA-F and HLA-G, remain to be established. The expression of HLA-G is largely limited to the placental trophoblast, where it might mediate protection of the fetus from rejection by the mother. Achieving the aim of understanding the function of HLA-G should be facilitated by information on the biochemical properties of HLA-G molecules, especially on their potential ability to act as peptide receptors. RESULTS To study peptide presentation by HLA-G, we used stably transfected LCL721.221 cells as a source of HLA-G molecules and analysed the spectrum of extracted peptides by individual and pool sequencing. Our results indicate that HLA-G molecules, like classical HLA molecules, are associated with a wide array of peptides derived from cellular proteins. Peptides presented by HLA-G usually consisted of 9 amino acids, and adhered to a specific sequence motif, with anchor residues at position 2 (isoleucine or leucine), position 3 (proline) and the carboxy-terminal position 9 (leucine). Thus, the HLA-G peptide ligand motif follows the principles of classical HLA motifs, although it displays its own unique features. Peptide-binding assays indicated that two of the three anchor residues were sufficient for binding, and that the three natural HLA-G ligands that we identified bound, not only to HLA-G, but also to HLA-A2. This was not surprising, because the binding pockets of HLA-A2 and HLA-G overlap in their ability to recognize anchor residues at positions 2 and 9. Likewise, some, but not all, HLA-A2 peptide ligands could also bind to HLA-G. CONCLUSIONS Nonclassical HLA-G molecules present peptides essentially in the same way as classical HLA molecules do. We determined the peptide motif that is specifically recognized by HLA-G; its basic features are described by the sequence XI/LPXXXXXL: This information should help to elucidate the physiological role of HLA-G molecules at the fetal-maternal interface. Most likely, this role is to protect fetal cells from lysis by natural killer cells, and possibly to present foreign peptides to a class of T cells that has not yet been identified.

Human uterine NK cells have a similar repertoire of killer inhibitory and activatory receptors to those found in blood, as demonstrated by RT-PCR and sequencing.

The expression of natural killer (NK) cell receptors specific for HLA class I molecules has been studied in CD56bright, CD3- NK cells isolated from the pregnant uterine mucosa, the decidua. RT-PCR was performed on cDNA from uterine NK cells with primers designed to amplify members of the killer inhibitory receptor (KIR)/killer activatory receptor (KAR) gene family. Sequencing of the PCR products revealed that uterine NK cells express KIR/KAR which have two or three extracellular immunoglobulin superfamily (Ig-SF) domains. NK receptors for both groups of HLA-C alleles were found. KIR, characterised by a long cytoplasmic tail containing the immune receptor tyrosine-based inhibitory motif (ITIM), and KAR, characterised by a short cytoplasmic domain with a transmembrane region containing a charged lysine, were both identified. Different individuals appear to have a distinct but overlapping repertoire of KIR/KAR. No new members of this NK receptor gene family were identified in the uterine CD56bright NK cells. Similar findings were obtained from non-pregnant endometrial tissues representative of different stages of the menstrual cycle. Immunohistology confirmed that the KIR protein products were expressed by decidual NK cells. These results reveal that NK receptors for trophoblast HLA class I molecules are present in maternal uterine NK cells. Fetal trophoblast cells infiltrating the decidua express HLA-G and HLA-C gene products. This suggests that maternal recognition of the fetus may be mediated by an NK allorecognition system.

In situ hybridization and northern blot demonstration of HLA-G mRNA in human trophoblast populations by locus-specific oligonucleotide

Trophoblast cells from normal first trimester pregnancies have been shown to express the nonclassical class I molecule, HLA-G, which is nonpolymorphic and has a heavy chain of 40 kD. In this study, in situ hybridization experiments were performed using a biotinylated HLA-G specific oligonucleotide on sections of normal placenta including the implantation site. HLA-G mRNA was identified in all extravillous trophoblast populations including the cytotrophoblast cell columns, interstitial trophoblast, endovascular trophoblast, and placental bed giant cells. In addition, villous cytotrophoblast and villous mesenchymal cells also contained HLA-G transcripts, but villous syncytiotrophoblast was always negative.

The full length HLA-G1 and no other alternative form of HLA-G is expressed at the cell surface of transfected cells

In contrast to HLA class Ia, the HLA-G class Ib transcripts can be alternativeley spliced to yield several isoforms including four potentially membrane-bound variants, namely HLA-G1, -G2, -G3 and G4. It is so far unclear whether each of these splice variants lacking one or two external domains is properly translated and expressed at the cell surface. We used targeted Enhanced Green Fluorescence Protein (EGFP)-HLA-G fusion cDNA to track HLA-G isoform expression in living murine (L-human beta2m) and human (JAR) transiently transfected cells. It was demonstrated that the four HLA-G1, -G2, -G3, and -G4 isoforms were translated in these transfectants by the means of (i) Western blotting analysis, using an anti-EGFP mAb; (ii) intracellular double labeling flow cytometry analysis, using the EGFP natural fluorescence and phycoerythrin-labeled HCA2 anti-HLA-G mAb; and (iii) immunocytochemistry on isolated acetone fixed transfectants with the use of different anti-HLA-G mAbs. Cell surface flow cytometry analysis using the HCA2 mAb revealed that only the HLA-G1 isoform was expressed as a membrane-bound protein. Two color confocal microscopy performed on fixed, permeabilized cells further showed that the EGFP green fluorescence co-localized with anti-calnexin rhodamine fluorescence in the four HLA-G isoform transfectants but only in HLA-G1 transfectant was the green EGFP fluorescence also detectable at the outer part of the cells, suggesting that the HLA-G2, -G3, and G4 were retained in the endoplasmic reticulum. Such intracellular retention of the three shorter forms of HLA-G suggest that they may play a role in regulating cell surface expression either of the full length HLA-G1 form or of HLA-E.

Immunology of human implantation: an evolutionary perspective

The concept of the fetus as an allograft, which has been much cherished by reproductive immunologists, is in need of re-appraisal. We speculate that the relationship between the allogeneic conceptus and mother is not governed by the laws of classical transplantation immunity. Instead, this relationship is more akin to the allorecognition system seen in invertebrates.

Human extravillous trophoblast MHC Class I expression is resistant to regulation by interferon-α

We have shown that MHC Class I antigen expression by first trimester human extravillous trophoblast cells is resistant to upregulation by IFN-alpha while embryonic fibroblasts of the same gestational age are responsive. This is in contrast to our previous finding that IFN-gamma increases both Class I mRNA and surface expression in these trophoblast cells. It would appear that human trophoblast has differential susceptibility to the effects of the two classes of IFN.