Ly-49 G2+ NK cells are responsible for mediating the rejection of H-2b bone marrow allog rafts in mice

NK cells can mediate the specific rejection of bone marrow butnot solid tissue allografts in lethally irradiated mice. NKcells are also responsible for the phenomenon of ‘hybridresistance’ in which F₁ hybrid H-2 heterozygous mice canreject parental H-2 homozygous bone marrow grafts. Ly-49C andLy-49 G2 are markers identified on subsets of NK cells. WhileLy-49C⁺ NK cells have been demonstrated to mediate the specificrejection of H-2^d bone marrow allografts, the role of the Ly-49G2⁺ NK subset is unclear because depletion of this subset invivo did not affect splenic NK activity against tumor targets.Through bone marrow transplantation typing studies, we demonstratethat Ly-49 G2⁺ NK cells complement Ly-49C⁺ NK cells in thatthey specifically mediate the rejection of H-2^b bone marrowallografts in lethally irradiated mice. In support of this,depletion of the Ly-49C⁺ NK subset in vivo also enhanced theability of the mice to reject H-2^b bone marrow cells suggestingthat the depletion was augmenting the ability of the Ly-49 G2⁺NK cells to reject the marrow allografts. Depletion of Ly-49G2⁺ NK cells in F₁ hybrid mice abrogated their ability to rejectparental H-2^b but not H-2^d bone marrow grafts. Therefore, Ly-49G2 denotes, a subset of NK cells that appears to play a criticalrole in the recognition of H-2^b bone marrow cells in allogeneicand F₁ hybrid mice.     

MHC class I expression protects target cells from lysis by Ly49-deficient fetal NK cells

Using appropriate conditions natural killer (NK) cells can be cultured from the liver and thymus of day 14 fetal mice. These fetal NK cells are phenotypically and functionally indistinguishable from adult NK cells with the exception that they lack measurable expression of all of the Ly49 molecules that can currently be detected with antibodies. Despite this, they preferentially kill tumor cells and blast cells deficient in the expression of major histocompatibility complex class I molecules, although the degree of discrimination is usually weaker than that shown by adult NK cells and varies depending on the particular combination of effector and target cells used. Polymerase chain reaction analysis revealed that although fetal NK cells are severely deficient in the expression of mRNA for Ly49A, B, C, D, G, H, and I they express high levels of Ly49E mRNA, raising the possibility that Ly49E may have an important and special function in the early development of the NK lineage.     

Ly-49D transfected NK cells show reduced interleukin-10 production in response to H-2d and increased lytic activity: implication by interaction using class I MHC alloantigen+ target cells in pregnancy

PROBLEM: Mating of CBA/J (H-2k) with DBA/2 (H-2d) males leads to a high rate of spontaneous resorption (about 40%), which is not seen in other mating combinations, such as CBA/J X BALB/c. The activation of natural killer cells (NK cells) seems to be a key mechanism for the maternal-fetal intolerance in allogeneic pregnancy, and recurrent spontaneous abortion. The effect of expression of the NK cell activating receptor Ly49D recognizing BALB/c or DBA/2 class I MHC was investigated. METHOD OF STUDY: Intracellular interleukin (IL)-100 production was detected and target cell survival rates were calculated after 22 hr coincubation of rat NK cells transfected, or not. with a murine Ly49D receptor, with either male BALB/c or male DBA/2 splenocytes, by using flow cytometry. RESULTS: Ly49D negative rat NK cells produced 13.7% more IL-10 than Ly49D positive rat NK cells, and more splenocytes were killed by Ly49D transfected rat NK cells (survival rate 2.45%) than by Ly49D negative rat NK cells (survival rate 4.36%). CONCLUSION: After physiological stimulation with BALB/c or DBA/2 splenocytes, rat NK cells are able to synthesize IL-10. Recognition of mouse splenocyte major histocompatibility complex (MHC) by Ly49D mice receptor decreased IL-10 production. The observed increase in killing activity might be a result of this phenomenon. NK cell activation via the Ly49D receptor might play an important role in pregnancy failure, but cannot explain why CBA/J X DBA/2 matings are abortion prone, and CBA/J X BALB/c matings are abortion resistant.     

Quantifying the reduction in accessibility of the inhibitory NK cell receptor Ly49A caused by binding MHC class I proteins in cis

Murine natural killer (NK) cells are inhibited by target cell MHC class I molecules via Ly49 receptors. However, Ly49 receptors can be made inaccessible to target cell MHC class I by a cis interaction with its MHC class I ligand within the NK cell membrane. It has recently been demonstrated that MHC class I proteins transfer from the target cells to the NK cell. Here, we establish that the number of transferred MHC class I proteins is proportional to the number of Ly49A receptors at the NK cell surface. Ly49A+ NK cells from mice expressing the Ly49A ligand H-2D(d) showed a 90% reduction in Ly49A accessibility compared to Ly49A+ NK cells from H-2D(d)-negative mice. The reduction was caused both by lower expression of Ly49A and interactions in cis between Ly49A and H-2D(d) at the NK cell surface. Approximately 75% of the Ly49A receptors on H-2D(d)-expressing NK cells were occupied in cis with endogenous H-2D(d) and only 25% were free to interact with H-2D(d) molecules in trans. Thus, H-2D(d) ligands control Ly49A receptor accessibility through interactions both in cis and in trans.     

Location-specific regulation of transgenic Ly49A receptors by major histocompatibility complex class I molecules

Inhibitory receptors expressed on natural killer (NK) cells and T cells specific for major histocompatibility complex (MHC) class I are believed to prevent these cells from responding to normal self tissues. To understand the regulation and function of Ly49 receptor molecules in vivo, we used the CD2 promoter to target Ly49A expression to all thymocytes, T cells, and NK cells. In animals expressing its MHC class I ligand, H-2D^d or H-2D^k, there was a large decrease in the expression of Ly49A on thymocytes, peripheral T cells, and NK1.1⁺ cells. The extent of the down-regulation of Ly49A was dependent on the expression of the MHC ligand for Ly49A and on the site where the cells were located. The level of expression of endogenous Ly49A was similarly found to be dependent upon the organ where the cells resided. Data from bone marrow chimeras indicated that most cell types may regulate Ly49A expression, but the efficacy to regulate receptor expression may vary depending on the cell type.     

α1 / α2 domains of H-2Dd,but not H-2Ld,induce “missing self” reactivity in vivo – No effect of H-2Ld on protection against NK cells expressing the inhibitory receptor Ly49G2

Introduction of the MHC class I transgene H-2D^d on C57BL / 6 (B6) background conveys NK cell-mediated “missing self” reactivity against transgene-negative cells, and down-regulates expression of the inhibitory receptors Ly49A and Ly49G2 in NK cells. We here present an analysis of transgenic mice expressing chimeric H-2D^d / L^d MHC class I transgenes, and show that the α1 / α2 domains of H-2D^d were necessary and sufficient to induce “missing self” recognition and to down-modulate Ly49A and Ly49G2 receptors. In contrast, transgenes containing the α1 / α2 domains of H-2L^d induced none of these changes, suggesting that not all MHC class I alleles in a host necessarily take part in NK cell education. The lack of effect of the α1 / α2 domains of H-2L^d on NK cell specificity was surprising, considering that both H-2L^d and H-2D^d have been reported to interact with Ly49G2. Therefore, the role of H-2L^d for protection against NK cells expressing Ly49G2 was re-investigated in a transfection system. In contradiction to earlier reports, we show that H-2D^d, but not H-2L^d, abolished killing by sorted Ly49G2⁺ NK cells, indicating that H-2L^d does not inhibit NK cells via the Ly49G2 receptor.     

β2 -Microglobulin-deficient NK cells show increased sensitivity to MHC class I-mediated inhibition,but self tolerance does not depend upon target cell expression of H-2Kb and Db heavy chains

Mice lacking β2 -microglobulin (β₂ m− mice) express greatly reduced levels of MHC class I molecules, and cells from β₂ m− mice are therefore highly sensitive NK cells. However, NK cells from β₂ m− mice fail to kill β₂ m− normal cells, showing that they are self tolerant. In a first attempt to understand better the basis of this tolerance, we have analyzed more extensively the target cell specificity of β₂ m− NK cells. In a comparison between several MHC class I-deficient and positive target cell pairs for sensitivity to β₂ m− NK cells, we made the following observations: First, β₂ m− NK cells displayed a close to normal ability to kill a panel of MHC class I-deficient tumor cells, despite their nonresponsiveness to β₂ m− concanavalin A (Con A)-activated T cell blasts. Secondly, β₂ m− NK cells were highly sensitive to MHC class I-mediated inhibition, in fact more so than β₂ m+ NK cells. Third β₂ m− NK cells were not only tolerant to β₂ m− Con A blasts but also to Con A blasts from H-2Kb − /Db − double deficient mice in vitro. We conclude that NK cell tolerance against MHC class I-deficient targets is restricted to nontransformed cells and independent of target cell expression of MHC class I free heavy chains. The enhanced ability of β₂ m− NK cells to distinguish between MHC class I-negative and -positive target cells may be explained by increased expression of Ly49 receptors, as described previously. However, the mechanisms for enhanced inhibition by MHC class I molecules appear to be unrelated to self tolerance in β₂ m− mice, which may instead operate through mechanisms involving triggering pathways.     

The impact of killer cell immunoglobulin-like receptor (KIR) genes and human leukocyte antigen (HLA) class I ligands on predisposition or protection against prostate cancer

Natural killer (NK) cell development largely depends on killer cell immunoglobulin-like receptors (KIRs) and human leukocyte antigen (HLA) class I ligands. In the current study, we investigated the role of KIR genes, HLA ligands, and KIR-HLA combinations in vulnerability or protection against prostate cancer (PC). To analyze the frequency of 16 KIR genes and 5 HLA ligands, polymerase chain reaction with sequence-specific primers (PCR-SSP) was conducted in 150 PC patients and 200 healthy controls (CNs). KIR2DL5 (p = 0.0346, OR = 0.606, CI = 0.3916–0.9336), KIR2DS5 (p = 0.0227, OR = 0.587, CI = 0.3793–0.9139), HLA-B Bw4^Thr80 (p = 0.0401, OR = 0.3552, CI = 0.1466–0.9059), HLA Bw4 (p = 0.0190, OR = 0.4744, CI = 0.2656–0.8521), and T4 gene cluster (including KIR2DS5-2DL5-3DS1-2DS1 genes) (p = 0.0194, OR = 0.5575, CI = 0.3449–0.8938) had a lower frequency in the PC patients compared to the control group. Moreover, a lower frequency of the genotypes contacting activating KIR (aKIR) > inhibitory KIR (iKIR) (p = 0.0298, OR = 0.5291, CI = 0.3056–0.9174) and iKIR + HLA < aKIR + HLA (p = 0.0183, OR = 0.2197, CI = 0.0672–0.7001) in PC patients compared to the CNs implies a protective role for aKIR genes. In the case of KIR-HLA interactions, we detected a significant association between KIR3DS1⁺ + HLA-A Bw4⁺ (p = 0.0113, OR = 0.5093, CI = 0.3124–0.8416) and KIR3DL1^? + HLA-A Bw4⁺ (p = 0.0306, OR = 0.1153, CI = 0.0106–0.6537) combinations and resistance to prostate cancer. In contrast, the presence of KIR3DL1 in the absence of HLA-A Bw4 (p = 0.0040, OR = 2.00, CI = 1.264–3.111), HLA Bw4 (p = 0.0296, OR = 2.066, CI = 1.094–3.906), and HLA-Bw4^Thr80 (p = 0.0071, OR = 2.505, CI = 1.319–4.703) genes probably predisposes to prostate cancer. Carrying the CxT4 genotype in PC patients was positively associated with lower tumor grades (Gleason score ≤ 6) (p = 0.0331, OR = 3.290, and CI = 1.181–8.395). Altogether, our data suggest a protective role for aKIRs, HLA-B Bw4^Thr80, and HLA Bw4 ligands as well as a predisposing role for certain KIR-HLA combinations in prostate cancer. The findings of this study offer new insight into the population's risk assessment for prostate cancer in men. Additionally, predicting immunotherapy response based on KIR-HLA combinations aids in implementing the most effective therapeutic approach in the early stages of the disease.     

Rat interleukin-2-activated natural killer (A-NK) cell-mediated lysis is determined by the presence of CD18 on A-NK cells and the absence of major histocompatibility complex class I on target cells

The precise mechanism by which target cells are recognized and subsequently lysed by interleukin-2-activated natural killer (A-NK) cells is poorly understood. In this study the role of major histocompatibility complex (MHC) class I and adhesion molecules in the recognition and lysis of tumor cells was investigated in a syngeneic Wag rat model. Preincubation of tumor cells with F(ab′)₂ fragments of anti-MHC class I monoclonal antibody (mAb) OX18 strongly enhanced the A-NK cell-mediated lysis. Also normal syngeneic cells such as T cells and A-NK cells became highly sensitive for lysis by A-NK cells after preincubation with mAb OX18. Two other mAb against MHC class I had no effect on lysis of target cells. These data indicate that masking of MHC class I on syngeneic tumor and normal cells by mAb OX18 is sufficient for A-NK cells to recognize target cells as non-self, resulting in lysis. In addition, we found that the presence of mAb against the β2 (CD18)-integrins blocked the lysis of all tumor cell lines by A-NK cells in ⁵¹Cr-release assays, also when target cells were preincubated with mAb OX18. Because of the absence of CD18 on most tumor cells we concluded that a CD18-associated integrin on A-NK cells is essential for lysis of target cells. These results show that in this syngeneic rat model CD18 on A-NK cells together with MHC class I on tumor cells determine A-NK cell-mediated lysis. Furthermore, we hypothesize that the anti-MHC class I OX18 recognizes an epitope on rat MHC class I which is, or is very close to, the restriction element determining A-NK cell-mediated lysis.     

KIR specificity and avidity of standard and unusual C1, C2, Bw4, Bw6 and A3/11 amino acid motifs at entire HLA:KIR interface between NK and target cells,the functional and evolutionary classification of HLA class I molecules

Natural killer (NK) cells make vital contributions to the immune system and the reproductive system. Notably, NK cells of donor origin can recognize and kill residual leukaemic cells and cure malignant patients in hematopoietic stem cell (HSC) transplant setting. NK cell function is regulated by KIRs that recognize cognate HLA class I molecules on target cells, depending on their amino acid residues. In review, we addressed the question of binding capacity and avidity of HLA class I molecules to different killer cell immunoglobulin‐like receptors (KIRs) depending on all interacting amino acid residues both on HLA and KIR side. We searched PubMed database and analysed available HLA:KIR crystallographic data for amino acid residues in HLA molecules, those physically involved in binding KIRs (termed here the “entire KIR interface”). Within entire KIR interface, we selected five functional sequence motifs (14–19, 66–76, 77–84, 88–92 and 142–151) and classified them according to the conservation of their amino acid sequences among 8,942 HLA class I molecules. Although some conserved amino acid motifs were shared by different groups of KIR ligands, the HLA motif combinations were exclusive for the ligand groups. In 135 common HLA class I molecules with known HLA:KIR recognition, we found 54 combinations of five motifs in each of the KIR‐binding interfaces (C1, C2, Bw4, A3/11) and conserved non‐KIR‐binding interfaces. Based on the entire KIR interface, this analysis allowed to classify 8,942 HLA class I molecules into KIR specificity groups. This functional and evolutionary classification of entire KIR interfaces provides a tool for unambiguously predicting HLA:KIR interactions for common and those HLA molecules that have not yet been functionally tested. Considering the entire KIR interface in HLA class I molecules, functional interactions of HLA and KIR can be predicted in immune responses, reproduction and allotransplantation. Further functional studies are needed on the HLA:KIR interaction variations caused by the repertoires of peptides presented by HLA molecules and KIR polymorphisms at allelic level.