Alloreactivity and Association of Human Natural Killer Cells with the Major Histocompatibility Complex

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Clinical and Diagnostic Laboratory Immunology, March 1999, p. 254-259, Vol. 6, No. 2
1071-412X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Alloreactivity and Association of Human Natural Killer Cells with the Major Histocompatibility Complex

Elie Mavoungou,¹^,^* Aicha Sall,¹ Virginie Poaty-Mavoungou,² Fousseyni S. Toure,³ Philippe Yaba,¹ Andre Delicat,¹ and Joseph Lansoud-Soukate¹

Unit of Emerging and Re-Emerging Diseases,¹ Retrovirology,² and Parasitology,³ International Center for Medical Research (CIRMF), Franceville, Gabon

Received 28 July 1998/Returned for modification 5 October 1998/Accepted 17 December 1998

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

All NK cells potentially lytic for autologous cells but not expressing self-major histocompatibility complex (MHC)-reactivereceptors could be eliminated by a negative selection mechanismduring ontogeny. This idea is based on the existence of a NK cellsubset expressing a specific inhibitory receptor for allogeneicMHC alleles. As ancestral haplotypes of the MHC appear to defineidentical MHC haplotypes in unrelated individuals, unrelated individualshaving the same ancestral haplotype should also have the sameNK-defined allospecificities that have been shown to map to thehuman MHC. To test this prediction, multiple cell lines from unrelatedindividuals having the same ancestral haplotypes were tested forthe NK-defined allospecificities. It was found that cells havingthe same ancestral haplotypes do have the same NK-defined specificities.Furthermore, the NK-defined phenotype of cells that possess twodifferent ancestral haplotypes can be predicted from the NK-definedphenotypes of unrelated cells that are homozygous for the ancestralhaplotypes concerned. Although the group 1 and 2 NK-defined allospecificitiescan be explained to some extent by HLA-C alleles, evidence ispresented that additional genes may modify the phenotype conferredby HLA-C.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

With the expanding use of bone marrow transplantation, an increasing number of patients lack HLA genotypically identical siblingdonors. Unrelated donors identified from large panels are beingused. Current strategies for donor-recipient matching involvedetailed matching for alleles at HLA class I and II loci, butthis approach is evidently inadequate. Graft rejection can occurdespite apparently good matching, and the outcome can be successfuldespite mismatches at these loci (3). Current methods may notallow adequate matching of the class I and II alleles, as hasbeen demonstrated in a case report of T-cell rejection involvingmismatching at HLA-B (24). In addition, however, other polymorphicnon-HLA genes within the major histocompatibility complex (MHC)may be involved, and matching for HLA alone does not ensure matchingfor these genes. There is direct evidence in the mouse for thepresence of at least one set of such genes (45).

The hemopoietic histocompatibility system in mice has been shown to determine F1 hybrid resistance to a bone marrow graftfrom either parent with graft rejection mediated by radio-resistantNK cells (4). Unlike classical MHC antigens, hemopoietic histocompatibilityantigens are inherited in a recessive fashion (4). It has beensuggested that the major hematopoietic histocompatibility locus(Hh-1) maps within the H-2 complex between H2-S and H2-D and canbe dissociated from class I genes (5). However, class I MHCantigens may play a role in the function or expression of Hh-1antigens (41). One model suggests that two genetic loci, Hh-1rand Hh-1s, control the expression of Hh-1 antigens. The Hh-1sgenes encode the structural antigen, whereas the Hh-1r gene downregulatesexpression of the Hh-1s genes. Complex Hh-1 haplotypes have beensuggested previously (50). Compatibility between the donor andrecipient at Hh-1 is required to prevent NK-mediated graftrejection.

There is evidence that the equivalent of the Hh-1 system exists in humans. A series of studies has demonstrated that NK cellscan mediate specific allogeneic target cell lysis (11); NK clonesderived from single donors can recognize different allospecificities(12), and five different allospecificities have been defined(14). Susceptibility to lysis by NK clones recognizing specificities1, 2, and 3 and probably specificities 4 and 5 has been shownto be inherited in an autosomal recessive manner, whereas resistanceto lysis is a dominant genetic trait (15). Segregation studiesand mapping with families with recombinant haplotypes have shownthat the genes controlling susceptibility or resistance to lysisare localized within the MHC between complement factor Bf andthe HLA-A locus (13). The nature of the target molecules isuncertain. However, in another series of studies, Ciccone et al.have provided evidence that HLA-Cw3 can provide specific protectionof target cells against lysis mediated by group 2-reactive NKclones (14) and evidence that group 1 and 2 specificities arereciprocally associated with homozygosity for a diallelic polymorphismat amino acid positions 77 and 80 on HLA-C (15). Killer inhibitoryreceptors (KIRs) are transmembrane glycoproteins, expressed onNK cells and a small subset of T cells, that inhibit cell-mediatedcytotoxicity upon binding to polymorphic MHC class I determinanton target cells. A member of the KIR cDNA family was recentlydiscovered (24). The aqueous humor inhibits NK cell-mediatedcytotoxicity in vitro but does not affect cytotoxic T lymphocyte-mediatedlysis (1). The existence of human inhibitory NK cell receptorsfor polymorphic MHC class I molecules was predicted based on theobservation that NK cells killed HLA class I-deficient B lymphoblastoidcell lines but did not lyse these target cells when transfectedwith certain HLA class I genes (43, 44). Membrane glycoproteinson NK cells involved in the recognition of HLA-A (24, 40),HLA-B (30), and HLA-C (36) were subsequently identified byusing monoclonal antibodies that disrupted interactions betweenthe inhibitory receptors on the NK cells and their class I ligandson targets. Cloning of the cDNAs encoding these receptors (18,19, 48) revealed the existence of a family of genes, designatedKIR (31), on human chromosome 19 q13.4 (2). Unlike the Ly49or CD94/NKG2A receptors, KIRs are type I glycoproteins relatedto the immunoglobulin superfamily (18, 20, 48). Like Ly49,KIRs recognize a region in the $alpha$ 1 domain of the HLA class I heavychain (6, 33). The three-immunoglobulin domain KIR designatedNKB1 recognizes the HLA-Bw4 motif, which is conferred by aminoacids 77 to 83 in the $alpha$ 1 domain of certain HLA-B heavy chains(27). Other three-immunoglobulin domain KIRs, recognized bythe 5.133 and Q66 monoclonal antibodies (MAbs), recognize HLA-A3,although the structural properties of this specificity have notbeen well characterized (24, 40). The two-immunoglobulin domainKIRs recognize a polymorphism at positions 77 and 80 of the HLA-Cheavy chain (17). KIRs reactive with the EB6 (36) or HP-3E4(28) MAbs recognize HLA-Cw4 and related alleles, whereas KIRsdetected with the GL183 MAb (36) bind HLA-Cw3 and relatedalleles.

Given the existence of the human equivalent of Hh-1, NK allorecognition is likely to be involved in human bone marrow graftrejection. Therefore, a simple means of matching for these determinantsand of retrospectively analyzing cases for such matching is required.It is increasingly evident that these ancestral haplotypes (AH)have been maintained as a whole from remote ancestors and thateach haplotype defines a continuous specific sequence of DNA (52).It follows, therefore, that AH provide markers for alleles atunknown genes as well as at known genes in the MHC. We thereforepredicted that each AH would be associated with particular setsof NK-defined determinants (NK haplotypes). Consequently, theidentification of AH should provide an effective means of matchingfor the NK-defined specificities before bone marrow transplantation.It has been shown that HLA-E, a nonclassical molecule, is involvedin regulating NK cell-mediated cytotoxicity both positively andnegatively (9). Therefore, in this study we determined theNK-defined specificities present on target cells carrying variousAH and related the findings to the unknown alleles present onthesehaplotypes.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Target cells for NK allorecognition. A panel of 34 Epstein-Barr virus-transformed lymphoblastoid cell lines (LCLs) served as targets. These cells were selectedfrom an extensive local panel of LCLs based on their homozygosityor heterozygosity for the AH listed in Table 1. Several of thesecells were included in the 10th International HistocompatibilityWorkshop cell panel held in Princeton, N.J., and New York, N.Y.,1987. Each cell was characterized by using all the MHC markerslisted in Table 2 to confirm the presence of the particular AH.HLA-A, -B, and -C and DR, DQ serological typing was performedby a complement-mediated microlymphocytotoxicity assay with apanel of antisera extensively characterized against standard cellsincluded in previous International Histocompatibility Workshops.DNA-based HLA class II typing was performed according to the methodsdetailed in the 11th International Histocompatibility Workshopsheld in Yokohama, Japan, in 1991 by using a series of sequence-specificoligonucleotide probes labeled with derivatized horseradish peroxidasesuitable for detection by enhanced chemiluminescence (49). Complementcomponents C4 and Bf allotyping was performed by immunofixationwith appropriate antisera after electrophoresis described previously(51). Methods for the typing of the alleles at tumor necrosisfactor (TNF) (21), BAT3 (22), and XYV (49) have been describedpreviously.

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TABLE 1. Haplotype specificity

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TABLE 2. MHC alleles and restriction fragment length polymorphism markers

Isolation of NK clones and evaluation of NK cytotoxicity. NK alloreactivity against the LCL target cells was evaluated by using previously described methods (14). In brief, peripheralblood lymphocytes from normal donors were isolated on Ficoll-Hypaquegradients, and NK cells were enriched after the depletion of Tcells by using a mixture of MAbs against CD3, CD4, and CD8 (11,12). The viable cells were then separated on a Ficoll-Hypaquegradient. These viable NK-enriched cells were then cloned underlimiting dilution conditions in the presence of irradiated feedercells, 0.1% phytohemagglutinin, and recombinant interleukin-2.The NK-defined specificities present on the LCL target cells weredetermined in a 4-h ⁵¹Cr release assay by using cloned NK effector cells reacting specificallywith group 1 (ES2 or ES10), group 2 (AM25, Mauro P), group 3 (A51-8),and group 5 (OA64) specifities. Target cells were used at 5 ×10³/well, for a final effector/target cell ratio of 10:1. The percentspecific lysis was determined as described previously (11, 12).

The use of this assay cytotoxicity is usually clearly bimodal. Indeed, it was previously demonstrated that GL183 and EB6 MAbsrecognize two triggering molecules with common biochemical andfunctional properties on the surface of human NK cells. Targetcells considered negative for a specificity give <10% lysis, whereastargets considered positive give >20% lysis with the specificNK clone (14).

HLA-C alleles and sequencing. All target cells were HLA typed for the presence of Cw antigenes 1 to 7. The Cw allele associated with each AH has been previouslyestablished based on typing of many examples of each AH. The presenceof the amino acids at residues 77 and 80 on the $alpha$ chain of theCw molecule present on each AH was established by review of publishednucleotide sequences (23), and that for Cw4 was establishedby review of a sequence submitted to GenBank (sequence no. M84386).This sequence was derived from an HLA-B35-positive cell and hastherefore been provisionally assigned to the 35.1 and 35.4AH.

The HLA-C allele on the 44.2 AH was sequenced by the following method. HLA-C was specifically amplified by PCR with primersand conditions described previously (16). The resulting PCRproduct was diluted 1:25 in distilled water and reamplified withnested degenerate primer CACAGAAGTACAA(C/G)CGCCAGG (5', nucleotides189 to 209, exon 2) and the same 3' primers used in the originalPCR. The nested PCR was performed by a standard PCR, with 25 µlof diluted product in 50 µl of final reaction mix, with 1-minsteps at 94, 60, and 72°C for 30 cycles with 2-s increments everycycle. The resulting PCR product was purified by column centrifugation(Filtron 30 microconcentrator; Polylabo, Strasbourg, France) andsequenced by using fluorescence-labeled dideoxy termination reactionmixtures on an automated DNA sequencer (model ALF express; PharmaciaBiotech S.A., St- Quentin en Yvelines, France) with the primersused to produce the nested PCRproduct.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

NK group 1 and 2 specificities are associated with specific AH. The cytotoxicity of the NK clones defining group 1 and 2 specificities against the 34 LCL target cells are shown in Table3. Several points are evident. The specific lysis is bimodal,with most target cells being clearly positive (>20% lysis) ornegative (<10%). All cells homozygous for an AH express eithergroup 1 or 2 specificity, and these specificities behave as allelesat a single locus. The results for cells heterozygous for twoAH are predictable from the results obtained with the cells thatare homozygous for these AH and a recessive model of susceptibilityto lysis. For example, both the 8.1 and 7.1 AH carry the group1 specificity, and cells R7/17219 and Q9/20920, which are heterozygousfor these two AH, are group 1 positive. On the other hand, cellQ6/8187 is heterozygous for AH 8.1 and 57.1, which possess group1 and 2 specificity, respectively, and expresses neither group1 nor group 2 specificity. Cell R6/12336, which is homozygousfor the 44.2 AH, gave indeterminate cytotoxicity of 14% with thegroup 1 cone. This cell has been considered group 1 positive.This classification is supported by the results of two other cells(R8/5618 and Q5/7952) that are heterozygous for 44.2 and anotherAH which is clearly group 1 positive based on the results forhomozygous cells. Both these cells are group 1 positive (37 and27% cytotoxicity, respectively), indicating that the 44.2 AH mustalso be group 1 positive under a recessive model of susceptibilityto lysis. However, the cytotoxicities of both these cells andthat of the homozygous cell are lower than those of most of theother group 1-positive cells. These data suggest that the Cw allelepresent on the 44.2 AH is different from the other group 1 alleles.

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TABLE 3. Cytotoxicities of NK clones defining group 1 and 2 specificities against the 34 LCL target cells

The results for the 68 haplotypes present on the 34 cells, summarized in Table 3, indicated that all AH tested carry eithergroup 1 or group 2 specificity. All examples of the same AH fromunrelated individuals possess the same NK-defined specificity,i.e., these specificities are AH haplotypic. Therefore, AH identifiesspecificity, and the NK-defined phenotype of a cell can be predictedbyAH.

NK-defined haplotypes occur and are associated with specific AH. Having shown that the group 1 and 2 determinants are AH haplotypic, we examined whether more-complex NK-defined haplotypesare also associated with specific AH. A subset of 12 of the 34target cells was therefore tested against NK clones defining group3 and 5 specificities. This subset included cells homozygous for7.1, 8.1, 18.2, 60.1, 57.1, and 44.1 AH and three heterozygouscells. All 12 cells were positive for group 3 specificity, sothe nature of the group 3 inheritance could not be determined.The 7.1, 8.1, and 44.1 homozygous cells were all positive, andthe 18.2 and 57.1 homozygous cells were negative for group 5 specificity.However, the results for the three heterozygous cells cannot beexplained by the same genetic model as group 1 and 2specificities.

From the results obtained above, several points are evident as follows. (i) Target cells homozygous for an AH can encode severalspecificities. (ii) Sets of NK-defined specificities (i.e, NK-definedhaplotypes) occur. (iii) Unrelated individuals homozygous forthe same AH express the same NK-defined haplotype, i.e., NK-definedhaplotypes are AH haplotypic; and (iv) the same NK-defined haplotypecan be common to several differentAH.

Residues 77 to 80 on the HLA-C molecule do account for NK-defined specificities. Having demonstrated that NK specificities associate with specific AH, we determined whether these associations could be accountedfor by the two alternate epitopes at amino acid residues 77 and80 on HLA-C associated with group 1 and 2 specificities (15,16). Therefore, the HLA-C allele and the epitope present oneach AH was examined. These results are summarized in Table 4.In all cases for which data are available, the results fit thehypothesis that the alternative epitopes defined at residues 77to 80 are associated with the NK-defined group 1 and 2 specificities.However, the NK specificity associated with the 44.2 AH is unusualin expressing group 1 target relatively weakly. In view of thedifferent phenotype of the 44.2 AH, the HLA-C allele of this cellwas sequenced from nucleotides 190 to 269 of exon 2, with theexpectation that this allele would possess a different epitopefrom those shown to correspond to groups 1 and 2. Surprisingly,this cell carries the S--N epitope expected for group 1-positivecells. However, its sequence apparently describes a new HLA-Cwallele. This new allele is identical to Cw1 and HLA-Cw*1401 inthis region, except that it has an A at nucleotide 267.

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TABLE 4. HLA-C allele and epitope present on AH

It is also evident that the group 3 and 5 specificities are not associated with any particular C allele or with either ofthe two alternative Cw epitopes at residues 77 and80.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

In this study we utilized cells that are homozygous or heterozygous for specific AH as target cells for NK clones definingspecificities 1, 2, 3, and 5. We have shown that all cells homozygousfor an AH express either a group 1 or 2 determinant and that thephenotypes of heterozygous cells can be predicted from the resultsin the homozygous cells and a recessive model of inheritance forsusceptibility to lysis. Homozygous cells carry several NK-definedspecificities, suggesting the presence of NK-defined haplotypes.Without exception, all examples of the same AH possessed the samegroup 1 or 2 specificity, and the more limited panel of cellstested possessed the same NK-defined haplotype, i.e, the NK-definedspecificities are AH haplotypic. Therefore, the identificationof AH will allow the identification of the associated NK specificitiesand provide a simple means of identifying the presence of thesespecificities in an individual. The NK-defined phenotype of anindividual can be predicted based on the particular combinationof AHpresent.

Whereas AH provide an excellent means of identifying the presence of a particular NK-defined haplotype, the relevant genesmay be encoded anywhere along the haplotype. Elsewhere we haveprovided evidence that AH consist of several blocks of severalhundred kilobases of DNA. Recombination occurs preferentiallybetween these blocks but has not been observed within them. Infact, there appear to be at least four distinct blocks of polymorphismwithin the MHC interval, viz. (i) the $alpha$ block, which carries HLA-A;(ii) the $beta$ block, which carries HLA-C, HLA-B, and CL (18); (iii)the $gamma$ block, which carries complementary component genes Cyp21and Bf and C2 and C4; and (iv) the $delta$ block, which carries theDR and DQ gene clusters. Mapping studies in both humans (12)and mice (41) and examination of several cells bearing recombinantAH suggest that the genes encoding group 1 and 2 NK-defined allospecificitiesare carried on the $beta$ block.

The nature of the target molecules for NK allorecognition has not been determined. It has been recently suggested that HLAclass I molecules are the targets or ligands for NK receptors(32). HLA-Cw3 provides protection against lysis mediated bygroup 2-reactive clones. This resistance to lysis was inheritedin a dominant manner and was specific for group 2 specificity.Two alternative epitopes defined by polymorphism of amino acidresidues 77 and 80 on HLA-C have been shown to be associated withprotection against group 1 and group 2 specificities (12). Thepresent data support this hypothesis but also show that theseepitopes are not associated with the group 3 or 5 specificity.HLA-C is included within the $beta$ block. In all cases for which dataare available, the group 1- and 2-associated AH carry the predictedHLA-Cw epitope. However, cytotoxicity by group 1-reactive NK clonesagainst the 44.2 AH homozygous cells are weak, and the two cellsheterozygous for this AH exhibited considerably less cytotoxicitythan did the other susceptible cells. We have shown that thisAH carries a new HLA-C allele which may behave similarly to HLA-Cw*1401,as reported by Colonna et al. (16).

Two possible models to account for NK recognition have been suggested previously (35, 37). These involve either effectorinhibition, during which an MHC class I molecule provides an inactivatingsignal that blocks the NK cell ability to lyse, or target interference,during which an appropriate class I molecule masks a putativeself-epitope that is actually a molecular target for NK recognitionleading to cell lysis. HLA-C may be one such class I molecule,but there is evidence that other class I molecules may also beinvolved (28, 45). The phenotype conferred by HLA-Cw*1401and the HLA-Cw allele carried on the 44.2 AH support the involvementof additional genes. Indeed, cellular responses are often controlledby the opposing actions of tyrosine kinases activating signalingand tyrosine phosphatases terminating signaling (46). For example,coligation of the immunoglobulin receptor and Fc $gamma$ RIIB on B cellsstimulates the tyrosine kinases that phosphorylate the intracytoplasmicportion of Fc $gamma$ RIIB, which in turn recruits the SHP-1 phosphatasethat terminates immunoglobulin signal transduction (19). Molecularanalysis of several membrane receptors with inhibitory functionrevealed a common sequence, I/VxYxxL/V (the immune receptor tyrosine-basedinhibitory motif [ITIM]), which binds the SHP-1 tyrosine phosphataseand halts positive signals transduced via other receptors (42).The two-immunoglobulin domain and three-immunoglobulin domainKIR isoforms with a long cytoplasmic tail possess two ITIMs, separatedby 26 to 28 amino acids (18, 20, 48). Studies from severalgroups have recently demonstrated that activation of NK cellsresults in tyrosine phosphorylation of the KIR ITIMs, recruitmentof SHP-1 and possibly SHP-2, and inhibition of NK cell-mediatedcytotoxicity (7, 9, 10, 39). Like the way they functionin NK cells, KIR can negatively regulate signals initiated inT cells via the T-cell receptor by recruitment of SHP-1 (26).

Our findings have important practical implications. NK allorecognition is likely to be involved in bone marrow graft rejectionin humans, given the mouse model and the inadequacy of currentmatching. It has been shown that bone marrow from an HLA-A, -B,DR-, DQ-matched. MLC-nonreactive unrelated donor who was mismatchedwith the recipient for the NK-defined group 1 specificity wasrejected (47). Also, there is evidence that mismatching withinthe $beta$ block, as with mismatching for the CL region, is associatedwith graft rejection (34). Matching for NK-defined allospecificitiesis therefore likely to be an important factor for successful bonemarrow engraftment. Ultimately, the relevant target moleculesneed to be identified, and their genes must be mapped and characterized.It will be necessary to identify a marker specific for the MHCblocks associated with each of the approximately 40 AH presentin each major racial group. Matching for these blocks will resultin matching for all the NK allospecificities present within theseblocks. We have data that the polymorphic CL region provides sucha haplospecific marker for the $beta$ block. Cross-matching donor andrecipient at CL would therefore match for the NK-defined specificities.Work is in progress to confirm the validity of thisapproach.

	ACKNOWLEDGMENTS

The Centre International de Recherches Médicales de Franceville (CIRMF) is supported by the state of Gabon and by funds providedby ELF Gabon and the French CooperationMinistry.

	FOOTNOTES

^* Corresponding author. Mailing address: Emerging and Re-Emerging Diseases Unit, Centre International de Recherches Médicalesde Franceville CIRMF, B.P. 769, Franceville, Gabon. Phone: (241)67 70 92. Fax: (241) 67 72 95. E-mail: emavoung{at}cirmf.sci.ga.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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24. Dohring, C., D. Scheidegger, J. Samaridis, M. Cella, and M. Colonna. 1996. A human killer inhibitory receptor specific for HLA-A'. J. Immunol. 156:3098-3101[Abstract].

25. Fleischhauer, D., N. A. Kernan, R. J. O'Reilly, B. Dupont, and S. Y. Yang. 1990. Bone marrow-allogreaft rejection by T lymphocytes recognizing a single amino acid difference in HLA-B44. N. Engl. J. Med. 323:1818-1822[Medline].

26. Fry, A., L. L. Lanier, and A. Weiss. 1996. Phosphotyrosines in the KIR motif of NKB1 are required for negative signaling and for association with PTP1C. J. Exp. Med. 184:295-300[Abstract/Free Full Text].

27. Gumperz, J. E., V. Letwin, J. H. Phillips, L. L. Lanier, and P. Parham. 1995. The Bw4 public epitope of HLA-B molecules confers reactivity with NK cell clones that express NKB1, a putative HLA receptor. J. Exp. Med. 181:1133-1144[Abstract/Free Full Text].

28. Lanier, L. L., J. E. Gumperz, P. Parham, I. Melero, M. Lopez-Botet, and J. H. Phillips. 1995. The NKB1 and HP-3E4 NK cells receptors are structurally distinct glycoproteins and independently recognize polymorphic HLA-C molecules. J. Immunol. 154:3320-3327[Abstract].

29. Leelayuwat, C., L. J. Abraham, H. Tabarias, F. T. Christiansen, and R. L. Dawkins. 1992. Genomic organization of a polymorphic duplicated region centromeric of HLA-B. Immunogenetics 36:208-212[Medline].

30. Letwin, V., J. Gumperz, P. Parham, J. H. Phillips, and L. L. Lanier. 1994. NKB1: an NK cell receptor involved in the recognition of polymorphic HLA-B molecules. J. Exp. Med. 180:537-543[Abstract/Free Full Text].

31. Long, E. O., D. N. Burshtyn, W. P. Clark, M. Peruzzi, S. Rajagopalan, S. Rojo, N. Wagtmann, and C. C. Winter. 1997. Killer cell inhibitory receptors: diversity, specificity, and function. Immunol. Rev. 155:135-144[Medline].

32. Manalti, M. S., M. Peruzzi, K. C. Parker, W. E. Biddison, E. Ciccone, A. Moretta, and E. O. Long. 1995. Peptide specificity in the recognition of MHC class I by natural killer cell clones. Science 267:1016-1018[Abstract/Free Full Text].

33. Mandelboim, O., H. T. Reyburn, M. Vales-Gomez, L. Pazmany, M. Colonna, G. Borsellino, and J. L. Strominger. 1996. Protection from lysis by natural killer cells of group 1 and 2 specificity is mediated by residue 80 in human histocompatibility leukocyte antigen C alleles and also occurs with empty major histocompatibility complex molecules. J. Exp. Med. 184:913-922[Abstract/Free Full Text].

34. Marshall, B., G. Tay, J. Marley, L. J. Abraham, and R. L. Dawkins. 1993. Analysis of MHC genomic structure and gene content between HLA-B and TNF using yeast artificial chromosomes. Genomics 17:435-441[Medline].

35. Moretta, L., E. Ciccone, A. Moretta, P. Hoglund, C. Ohlen, and K. Karre. 1992. Allorecognition by NK cells: nonself or no self. Immunol. Today 13:300-306[Medline].

36. Moretta, A., M. Vitale, C. Bottino, A. M. Orengo, L. Morelli, R. Augugliaro, M. Barbaresi, E. Ciccone, and L. Moretta. 1993. p58 molecules as putative receptors for major histocompatibility complex (MHC) class I molecules in human natural killer (NK) cells: anti-p58 antibodies reconstitute lysis of MHC class I-protected cells in NK clones displaying different specificities. J. Exp. Med. 178:597-604[Abstract/Free Full Text].

37. Napper, C., J. T. Vaage, D. Lambracht, G. Lovick, G. W. Butcher, K. Wonigeit, and B. Rolstad. 1995. Alloreactive natural killer cells in the rat: complex genetics for major histocompatibility complex control. Eur. J. Immunol. 25:1249-1256[Medline].

38. Ohlen, C., P. Hoglund, C. L. Sentman, E. Carbone, H. G. Ljunggren, B. Koller, B. Karre, and K. Karre. 1995. Inhibition of natural killer cell-mediated bone marrow graft rejection by allogeneic major histocompatibility complex class I, but not class II molecules. Eur. J. Immunol. 25:1286-1291[Medline].

39. Olcese, L., P. Lang, F. Vely, A. Cambiaggi, D. Marguet, M. Blery, K. L. Hippen, R. Biassoni, L. Moretta, J. C. Cambier, and E. Vivier. 1996. Human and mouse killer-cell inhibitory receptors recruit PTP1C and PTP1D protein tyrosine phosphatases. J. Immunol. 156:4531-4534[Abstract].

40. Pende, D., R. Biassoni, C. Cantoni, S. Verdiani, M. Falco, C. DiDonato, O. Accame, C. Bottino, A. Moretta, and L. Moretta. 1996. The natural killer cell receptor specific for HLA-A allotypes: a novel member of the p58/p70 family of inhibitor receptors that is characterized by three immunoglobulin-like domains and is expressed as a 140-kD disulphide-linked dimer. J. Exp. Med. 184:505-518[Abstract/Free Full Text].

41. Rembecki, R. M., V. Kumar, C. S. David, and M. Benett. 1990. Hemopoietic histocompatibility (Hh-1) regulatory and structural genes of the f haplotype map to H 2. Transplantation 49:633-638[Medline].

42. Scharenberg, A. M., and J. P. Kinet. 1996. The emerging field of receptor-mediated inhibitory signaling: SHP or SHIP? Immunity 87:961-964.

43. Shimizu, Y., and R. DeMars. 1989. Demonstration by class I gene transfer that reduced susceptibility of human cells to natural killer cell-mediated lysis is inversely correlated with HLA class I antigen expression. Eur. J. Immunol. 19:447-451[Medline].

44. Storkus, W. J., J. Alexander, J. A. Payne, J. R. Dawson, and P. Cresswell. 1989. Reversal of natural killing susceptibility in target cells expressing transfected class I HLA genes. Proc. Natl. Acad. Sci. USA 86:2361-2364[Abstract/Free Full Text].

45. Storkus, W. J., R. D. Salter, J. Alexander, F. E. Ward, R. E. Rutz, P. Cresswell, and J. R. Dawson. 1991. Class I-induced resistance to natural killing: identification of nonpermissive residues in HLA-A2. Proc. Natl. Acad. Sci. USA 88:5989-5992[Abstract/Free Full Text].

46. Thomas, M. L. 1995. Of ITIMS and ITIMs: turning on and off the B cell antigen receptor. J. Exp. Med. 181:1953-1956[Free Full Text].

47. Thomsen, M., C. S. Witt, M. A. Degli-Esposito, and F. T. Christiansen. 1993. Typing of 4AOHW cells by allospecific natural killer cells. Hum. Immunol. 38:52-56[Medline].

48. Wagtmann, N., R. Biassoni, C. Cantoni, S. Verdiani, M. S. Malnati, M. Vitale, C. Bottino, A. Moretta, and E. O. Long. 1995. Molecular clones of the p58 natural killer cell receptor reveal Ig-related molecules with diversity in both the extra- and intracellular domains. Immunity 2:439-449[Medline].

49. Wu, X., W. J. Zhang, C. S. Witt, L. J. Abraham, F. T. Chrsitiansen, and R. L. Dawkins. 1992. Haplospecific polymorphism between HLA B and tumor necrosis factor. Hum. Immunol. 33:89-97[Medline].

50. Yu, Y. Y., V. Kumar, and M. Benett. 1992. Murine natural killer cells and marrow graft rejection. Annu. Rev. Immunol. 10:189-213[Medline].

51. Zhang, W. J., P. H. Kay, T. J. Cobain, and R. L. Dawkins. 1988. C4 allotyping on plasma or serum: application to routine laboratories. Hum. Immunol. 21:165-171[Medline].

52. Zhang, W. J., M. A. Degli-Esposito, T. J. Cobain, F. T. Cameron, Christiansen, and R. L. Dawkins. 1990. Differences in gene copy number carried by different MHC ancestral haplotypes. J. Exp. Med. 171:2101-2114[Abstract/Free Full Text].

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24.	Dohring, C., D. Scheidegger, J. Samaridis, M. Cella, and M. Colonna. 1996. A human killer inhibitory receptor specific for HLA-A'. J. Immunol. 156:3098-3101[Abstract].
25.	Fleischhauer, D., N. A. Kernan, R. J. O'Reilly, B. Dupont, and S. Y. Yang. 1990. Bone marrow-allogreaft rejection by T lymphocytes recognizing a single amino acid difference in HLA-B44. N. Engl. J. Med. 323:1818-1822[Medline].
26.	Fry, A., L. L. Lanier, and A. Weiss. 1996. Phosphotyrosines in the KIR motif of NKB1 are required for negative signaling and for association with PTP1C. J. Exp. Med. 184:295-300[Abstract/Free Full Text].
27.	Gumperz, J. E., V. Letwin, J. H. Phillips, L. L. Lanier, and P. Parham. 1995. The Bw4 public epitope of HLA-B molecules confers reactivity with NK cell clones that express NKB1, a putative HLA receptor. J. Exp. Med. 181:1133-1144[Abstract/Free Full Text].
28.	Lanier, L. L., J. E. Gumperz, P. Parham, I. Melero, M. Lopez-Botet, and J. H. Phillips. 1995. The NKB1 and HP-3E4 NK cells receptors are structurally distinct glycoproteins and independently recognize polymorphic HLA-C molecules. J. Immunol. 154:3320-3327[Abstract].
29.	Leelayuwat, C., L. J. Abraham, H. Tabarias, F. T. Christiansen, and R. L. Dawkins. 1992. Genomic organization of a polymorphic duplicated region centromeric of HLA-B. Immunogenetics 36:208-212[Medline].
30.	Letwin, V., J. Gumperz, P. Parham, J. H. Phillips, and L. L. Lanier. 1994. NKB1: an NK cell receptor involved in the recognition of polymorphic HLA-B molecules. J. Exp. Med. 180:537-543[Abstract/Free Full Text].
31.	Long, E. O., D. N. Burshtyn, W. P. Clark, M. Peruzzi, S. Rajagopalan, S. Rojo, N. Wagtmann, and C. C. Winter. 1997. Killer cell inhibitory receptors: diversity, specificity, and function. Immunol. Rev. 155:135-144[Medline].
32.	Manalti, M. S., M. Peruzzi, K. C. Parker, W. E. Biddison, E. Ciccone, A. Moretta, and E. O. Long. 1995. Peptide specificity in the recognition of MHC class I by natural killer cell clones. Science 267:1016-1018[Abstract/Free Full Text].
33.	Mandelboim, O., H. T. Reyburn, M. Vales-Gomez, L. Pazmany, M. Colonna, G. Borsellino, and J. L. Strominger. 1996. Protection from lysis by natural killer cells of group 1 and 2 specificity is mediated by residue 80 in human histocompatibility leukocyte antigen C alleles and also occurs with empty major histocompatibility complex molecules. J. Exp. Med. 184:913-922[Abstract/Free Full Text].
34.	Marshall, B., G. Tay, J. Marley, L. J. Abraham, and R. L. Dawkins. 1993. Analysis of MHC genomic structure and gene content between HLA-B and TNF using yeast artificial chromosomes. Genomics 17:435-441[Medline].
35.	Moretta, L., E. Ciccone, A. Moretta, P. Hoglund, C. Ohlen, and K. Karre. 1992. Allorecognition by NK cells: nonself or no self. Immunol. Today 13:300-306[Medline].
36.	Moretta, A., M. Vitale, C. Bottino, A. M. Orengo, L. Morelli, R. Augugliaro, M. Barbaresi, E. Ciccone, and L. Moretta. 1993. p58 molecules as putative receptors for major histocompatibility complex (MHC) class I molecules in human natural killer (NK) cells: anti-p58 antibodies reconstitute lysis of MHC class I-protected cells in NK clones displaying different specificities. J. Exp. Med. 178:597-604[Abstract/Free Full Text].
37.	Napper, C., J. T. Vaage, D. Lambracht, G. Lovick, G. W. Butcher, K. Wonigeit, and B. Rolstad. 1995. Alloreactive natural killer cells in the rat: complex genetics for major histocompatibility complex control. Eur. J. Immunol. 25:1249-1256[Medline].
38.	Ohlen, C., P. Hoglund, C. L. Sentman, E. Carbone, H. G. Ljunggren, B. Koller, B. Karre, and K. Karre. 1995. Inhibition of natural killer cell-mediated bone marrow graft rejection by allogeneic major histocompatibility complex class I, but not class II molecules. Eur. J. Immunol. 25:1286-1291[Medline].
39.	Olcese, L., P. Lang, F. Vely, A. Cambiaggi, D. Marguet, M. Blery, K. L. Hippen, R. Biassoni, L. Moretta, J. C. Cambier, and E. Vivier. 1996. Human and mouse killer-cell inhibitory receptors recruit PTP1C and PTP1D protein tyrosine phosphatases. J. Immunol. 156:4531-4534[Abstract].
40.	Pende, D., R. Biassoni, C. Cantoni, S. Verdiani, M. Falco, C. DiDonato, O. Accame, C. Bottino, A. Moretta, and L. Moretta. 1996. The natural killer cell receptor specific for HLA-A allotypes: a novel member of the p58/p70 family of inhibitor receptors that is characterized by three immunoglobulin-like domains and is expressed as a 140-kD disulphide-linked dimer. J. Exp. Med. 184:505-518[Abstract/Free Full Text].
41.	Rembecki, R. M., V. Kumar, C. S. David, and M. Benett. 1990. Hemopoietic histocompatibility (Hh-1) regulatory and structural genes of the f haplotype map to H 2. Transplantation 49:633-638[Medline].
42.	Scharenberg, A. M., and J. P. Kinet. 1996. The emerging field of receptor-mediated inhibitory signaling: SHP or SHIP? Immunity 87:961-964.
43.	Shimizu, Y., and R. DeMars. 1989. Demonstration by class I gene transfer that reduced susceptibility of human cells to natural killer cell-mediated lysis is inversely correlated with HLA class I antigen expression. Eur. J. Immunol. 19:447-451[Medline].
44.	Storkus, W. J., J. Alexander, J. A. Payne, J. R. Dawson, and P. Cresswell. 1989. Reversal of natural killing susceptibility in target cells expressing transfected class I HLA genes. Proc. Natl. Acad. Sci. USA 86:2361-2364[Abstract/Free Full Text].
45.	Storkus, W. J., R. D. Salter, J. Alexander, F. E. Ward, R. E. Rutz, P. Cresswell, and J. R. Dawson. 1991. Class I-induced resistance to natural killing: identification of nonpermissive residues in HLA-A2. Proc. Natl. Acad. Sci. USA 88:5989-5992[Abstract/Free Full Text].
46.	Thomas, M. L. 1995. Of ITIMS and ITIMs: turning on and off the B cell antigen receptor. J. Exp. Med. 181:1953-1956[Free Full Text].
47.	Thomsen, M., C. S. Witt, M. A. Degli-Esposito, and F. T. Christiansen. 1993. Typing of 4AOHW cells by allospecific natural killer cells. Hum. Immunol. 38:52-56[Medline].
48.	Wagtmann, N., R. Biassoni, C. Cantoni, S. Verdiani, M. S. Malnati, M. Vitale, C. Bottino, A. Moretta, and E. O. Long. 1995. Molecular clones of the p58 natural killer cell receptor reveal Ig-related molecules with diversity in both the extra- and intracellular domains. Immunity 2:439-449[Medline].
49.	Wu, X., W. J. Zhang, C. S. Witt, L. J. Abraham, F. T. Chrsitiansen, and R. L. Dawkins. 1992. Haplospecific polymorphism between HLA B and tumor necrosis factor. Hum. Immunol. 33:89-97[Medline].
50.	Yu, Y. Y., V. Kumar, and M. Benett. 1992. Murine natural killer cells and marrow graft rejection. Annu. Rev. Immunol. 10:189-213[Medline].
51.	Zhang, W. J., P. H. Kay, T. J. Cobain, and R. L. Dawkins. 1988. C4 allotyping on plasma or serum: application to routine laboratories. Hum. Immunol. 21:165-171[Medline].
52.	Zhang, W. J., M. A. Degli-Esposito, T. J. Cobain, F. T. Cameron, Christiansen, and R. L. Dawkins. 1990. Differences in gene copy number carried by different MHC ancestral haplotypes. J. Exp. Med. 171:2101-2114[Abstract/Free Full Text].