Reconstitution of H-2 class I expression by gene transfection decreases susceptibility to natural killer cells of an EL4 class I loss variant

Several reports have suggested that an inverse correlation exists between major histocompatibility complex class I expression and the susceptibility to natural killer (NK)-mediated lysis. For example, the increased class I expression induced by interferon-gamma was always accompanied by an increased resistance to NK lysis. Likewise, class I loss variants were often more NK susceptible than their normal counterparts. To investigate whether the inverse correlation between class I expression and NK susceptibility was fortuitous or whether the class I molecules were directly responsible for this effect we resorted to gene transfection studies. From the murine thymoma line EL4 and H-2Db- and Kb-negative variant S3 was selected. This variant was highly susceptible to NK lysis. S3 was found to have a defect in beta 2-microglobulin gene expression. Therefore, restoration of Db and Kb expression could be achieved by transfection with the beta 2-microglobulin gene. This resulted in a strong decrease in susceptibility to NK lysis to the level of the H-2+ parental EL4. Transfection with class II genes had no effect. Blocking of the class I molecules on the H-2+ cells with anti-H-2b F(ab')2 fragments increased the susceptibility to NK cells to the level of the H-2- variant S3. These data demonstrate that the class I molecules on the targets are directly responsible for regulation of NK susceptibility but the mechanism is not clear. Possibly the class I molecules interfere with the unknown NK target structures.     

H-2Kb transfection of B16 melanoma cells results in reduced tumourigenicity and metastatic competence

The metastatic B16 mouse melanoma shows a low cell surface expression of H-2Kb and H-2Db class I antigens on cells of both the high-metastatic line B16-F10 and the low-metastatic line B16-F1. Similarly, newly generated clones of these lines, having different metastatic properties, all express low levels of major histocompatibility antigens. One of these clones, the high-metastatic F10.9, was transfected with H-2Kb genes to generate H-2Kb-expressing transfectants. The resulting clones showed reduced tumourigenicity and a low metastatic phenotype. Unlike the parental cells, H-2Kb-positive transfectants are potent inducers and sensitive targets of H-2Kb-restricted syngeneic cytotoxic T cells. Immunization of mice with H-2Kb-positive transfectants conferred protection against a subsequent challenge with Kb-positive transfectants but had only a small effect on growth and metastatic spread of parental cells.     

A human-mouse hybrid cell line expressing both human leukocyte and histocompatibility-2 antigens

Clone-1d, a sub-line of mouse L cells, was transfected with E. coli neo gene cloned in pSV2 vector (pSV2 neo) to obtain C1-1d neo cells. These cells are able to survive in the presence of geneticin (G418) but are killed by the medium containing hypoxanthine, aminopterin, and thymidine (HAT) because of the deficiency of thymidine kinase (TK) gene. By using these cells, it became possible to produce stable hybrid cells between these neo cells and any other cells since the hybrid cells are selected in the culture medium containing both G418 and HAT. We produced such hybrid cells by fusing C1-1d neo and A431 human epidermoidal carcinoma cells and studied the expression of human leucocyte antigens (HLA) and histocompatibility-2 antigens (H-2) in three hybrid cell lines. We found that one out of three hybrid cell lines expresses both HLA and human beta 2 microglobulin besides H-2 antigens, whereas the other two express only H-2 antigens; this indicated better stability of mouse genes than of human genes.     

以pMSEx-1作为共转染质粒观察人NF-IL6过量表达对NIH3T3细胞成瘤性的影响

我们曾以ｐＳＶ２ｎｅｏ作为共转染质粒观察到ＮＦＩＬ６具有转化基因活性。本文以ｐＭＥＳｘ１（含ｎｅｏ抗性基因）质粒作为共转染质粒，发现能表达有义ＮＦＩＬ６的ＮＩＨ３Ｔ３转染子，可同时出现转化形态的克隆和扁平形态的克隆，二者比例６∶４，且ＮＦＩＬ６的表达状态相似。我们提出，ＮＦＩＬ６在ＮＩＨ３Ｔ３细胞表现为转化基因活性时，作用方式具有随机性。本文还提出，ｐＳＶｎｅｏ可能是ＮＩＨ３Ｔ３细胞内在不稳定性的促进因素     

Gene transfer experiments imply instructive role of major histocompatibility complex class I molecules in cellular peptide processing.

DBA/2-derived mouse tumor cells were transfected with the H-2 Kb gene. Naturally processed minor histocompatibility (H) peptides were extracted from both transfected and non-transfected cells by acid elution, and were separated by high-performance liquid chromatography. Kb-restricted minor H epitopes corresponding to H-4b and mapki, both encoded by non-major histocompatibility complex genes of DBA/2, were readily detected by the respective cytotoxic T lymphocyte in peptides extracted from Kb-transfected, but not from non-transfected or Db-transfected cells. Titration experiments indicated at least 3000-fold less copies of correctly processed Kb-restricted epitopes in cells without Kb as compared to cells with Kb. Since we estimate the copy number of Kb-restricted H-4b epitopes in Kb-expressing transfectants to be less than 1000 per cell, the pool size of H-4b epitopes correctly processed in the absence of Kb should be less than 1/3 copy per cell.     

The conformational flexibility of class I H-2 molecules as revealed by anti-peptide antibodies specific for intracytoplasmic determinants: differential reactivity of beta 2-microglobulin "bound" and "free" H-2Kb heavy chains.

Immunoprecipitation experiments using anti-peptide antisera prepared against exon 6, exon 7 and exon 8-encoded intracytoplasmic regions of the H-2Kb gene product indicated that approximately 1/3 of the H-2Kb heavy chains in a cell surface-labelled glycoprotein fraction from EL-4 cells, or H-2b spleen cells, is not associated with beta 2-microglobulin (beta 2-m). This population of "free" H-2Kb heavy chains failed to react with alloantisera or monoclonal antibodies specific for conventional H-2Kb serological determinants, suggesting that significant conformational alterations were induced in the extracellular domains upon dissociation of beta 2-m. In addition, although antibodies to intracytoplasmic peptide 8 were able to react with both "free" and beta 2-m "bound" heavy chains, the determinants seen by anti-peptide 6 and anti-peptide 7 were only recognized in the "free" heavy chain. These data suggest that the conformational perturbation of the extracellular domains induced by beta 2-m dissociation can be "transmitted" to the intracytoplasmic region of the heavy chain. These results indicate the potential for a class I heavy chain-mediated transmembrane signalling event, and suggest that the "free" class I heavy chain might have a role to play in the major histocompatibility complex (MHC)-restricted presentation of T-cell determinants to cytotoxic T-lymphocytes.     

A viral peptide can mimic an endogenous peptide for allorecognition of a major histocompatibility complex class I product.

Alloreactive class I-restricted T cells may recognize the class I structure alone, in association with a specific peptide, or with any stabilizing peptide. We have tested the role of endogenous peptides in the recognition of H-2Kb molecules by two alloreactive cytolytic T lymphocyte (CTL) clones using the mutant tumor line RMA-S, which expresses its surface H-2b molecules devoid of peptides and is not lysed by these two CTL clones. Empty H-2b molecules on RMA-S cells can be stabilized by binding exogenously added peptides. H-2Kb-specific recognition of the RMA-S cells by one of the CTL clones was restored by endogenous peptide extracts which only minimally stabilized H-2Kb on the surface of RMA-S cells, indicating the requirement for a specific peptide on a limited number of H-2Kb molecules. In addition, one out of three peptides which greatly enhance the expression of H-2Kb, the nucleoprotein peptide 52-59 from vesicular stomatitis virus (VSV), was also able to restore the lysis of RMA-S cells by the clone. The recognition of a common motif by an alloreactive clone (H-2k anti-H-2Kb) and virus-specific Kb-restricted clones suggests that both H-2k and H-2b thymic environments allow selection of T cells capable of recognizing H-2Kb+VSV and that tolerance to self, as would be the case in the (H-2k x H-2b)F1 mice, would partially delete the repertoire of antiviral T cells.     

Different Expressions of Ly-49 Receptors on Mouse NK and NK T Cells

NK T cells are a unique T cell lineage and are reported to express Ly-49 molecules which are inhibitory receptors specific for class I molecules. In this study, we examined the expression of activation and inhibitory receptors on NK T cells in different organs of beta2-microgloblin knock out (beta2mKO), C57BL/6 (B6; H-2b), C57BL/10 (B10; H-2b) and B10.D2 (H-2d) mice. The low level expression of inhibitory receptors Ly-49A and G2 on NKT cells as well as NK cells, which are specific for Dd antigen, were observed in B10.D2 mice, but not in beta2mKO, B6, or B10 mice. The small percentage of inhibitory receptor Ly-49C positive NK and NKT cells, which is specific for Kb and Dd antigens, was observed in BMC, LMC and SC of B6, B10 and B10.D2 mice compared to beta2mKO mice. On the contrary, the large percentage of Ly-49C positive NK T cells was observed in thymocytes of B6, B10 and B10.D2 mice compared to beta2mKO mice. Interestingly, Ly-49D activation receptor was hardly detectable on NK T cells in any organs of the 4 strains of mice whereas it was clearly detectable on NK cells. These findings suggest that the unique characteristics of NK T cells may mediate regulatory function in MHC class I antigen-restricted immunity.     

T-Cell Activation. III. Attempts to Activate MHC Class I-Negative and Class I-Transfected EL4 T-Lymphoma Cells by Immobilized Anti-CD3 Antibody

The aim of this study was to examine whether the unresponsiveness of MHC class I-negative subclones of the EL4 thymoma to CD3 cross-linking can be restored by transfection of class I genes into the H-2-negative cells. Cell activation experiments with selected MHC class I-negative subclones and H-2b- and H-2Ld-positive transfectants showed that these cells are equally capable of secreting interleukin 2 (IL-2) after exposure to the phorbol ester phorbol 12-myristate 13-acetate (PMA) and ionomycin. In contrast, only the parental H-2-positive EL4 cells are capable of responding to treatment with immobilized anti-CD3 antibody with IL-2 secretion and IL-2 receptor expression. Measurements of intracellular free Ca2+ (Ca2+i) following anti-CD3 antibody-induced cross-linking of parental EL4 cells and H-2-negative and H-2b gene-transfected subclones showed that the parental cells and two of the class I transfectants, one H-2-positive and one H-2-negative, responded with a slow rise in Ca2+i, whereas one H-2-positive transfected cell clone was completely refractory to CD3 cross-linking. Modulation experiments using parental EL4 cells, H-2-negative subclones and H-2-positive transfectants demonstrated that the CD3 and class I molecules of these different cells are modulated to the same extent after exposure to specific antibodies. The present findings thus indicate that the unresponsiveness of H-2-negative EL4 subclone cells to CD3 cross-linking is not functionally associated with a lack of class I surface expression.     

The in vivo clearance of Ha-ras transformants by natural killer cells

The experiments in this study were designed to test the hypothesis that natural killer (NK) cells play a role in host surveillance against early neoplastic changes in the malignant process. C3H 10T1/2 mouse fibroblasts were transfected with a pSV2-neo plasmid vector which contains EJ, the mutated c-Ha-ras, regulated by its own promoter. Control cells were transfected with pSV2-neo alone and did not contain the ras gene. Oncogene-transfected cells were compared with control cells for lung colony formation following tail vein injection into C3H mice. Intravenous injection of ras-transfected 10T1/2 cells induced marked lung colony formation in vivo, whereas C3H 10T1/2 parental lines or 10T1/2 cells transfected with pSV2-neo alone induced no lung colonies in C3H mice. The colonising potential of ras transfectants could be decreased by augmentation of NK activity by injection of polyinosinic cytidylic acid and increased by depletion of NK effectors with anti-asialo GM₁. Experiments with beige mice demonstrated that the mortality of syngeneic, NK-deficient C3H-bg/bg mice injected with ras tranfectants was significantly greater than similarly treated NK-normal C3H-+/bg littermate controls. The results support the view that NK cells are capable in vivo of recognizing early defined stages in the neoplastic process initiated by oncogenes.     

Structure of the Ly49 family of natural killer (NK) cell receptors and their interaction with MHC class I molecules

Natural killer (NK) cells are an essential component of the innate immunity toward tumors and virally infected cells. The function of NK cells is regulated by a precise balance between inhibitory and activating signals. These signals are mediated by NK cell receptors that bind either classical MHC class I molecules or their structural relatives such as MICA, ULBP, RAE-1, and H-60. Two separate families of NK cell receptors have been identified: the immunoglobulin-like family (KIR, LIR) and C-type lectin-like family (Ly49, NKG2D, and CD94/NKG2). Here we summarize the structure of Ly49 C-type lectin-like proteins hitherto solved (Ly49A, Ly49C and Ly49I) and their interaction with MHC class I molecules as determined by the co-crystal structure of Ly49A/H-2Dd and Ly49C/H-2Kb.     

MHC class I molecules on adenovirus E1A-expressing tumor cells inhibit NK cell killing but not NK cell-mediated tumor rejection

Expression of adenovirus E1A gene products in tumor cells enhances NK cell lysis in vitro and NK-mediated rejection in vivo, despite increasing class I molecules on tumor cells. It is unclear why the increased expression of MHC class I molecules does not appear to confer resistance to killing by NK cells. One possibility is the unique capacity of E1A to sensitize cells to multiple NK cell killing mechanisms including perforin/granzyme, Fas ligand, tumor necrosis factor-alpha and TRAIL. To examine this issue, MCA-102-E1A tumor cells (H-2(b)) that express E1A and are NK sensitive were transfected with H-2D(d), the ligand for the NK inhibitory receptor, Ly49A. Expression of H-2D(d) molecules by MCA-102-E1A cells protected them from lysis by a Ly49A(+) NK cell clone and Ly49A(+) NK cells isolated from C57BL/6 nude mice. In contrast, NK cell-mediated rejection of MCA-102-E1A tumor cells was not inhibited by the expression of H-2D(d) molecules, nor was killing by polyclonal populations of NK cells isolated from C57BL/6-nude mice. H-2D(d) interacts with several inhibitory Ly49 receptors that are non-clonally expressed on NK cells in C57BL/6 mice: Ly49A (20% of NK cells), Ly49G2 (54% of NK cells) and Ly49C/I (47% of NK cells). Our data indicate that while E1A sensitizes cells to NK cell killing, it does not interfere with signal transduction by inhibitory NK receptors. Therefore, a small population of NK cells that do not express Ly49A, Ly49G2 or Ly49C/I inhibitory receptors are likely responsible for the rejection of MCA-102-E1A-D(d) tumor cells in vivo.     

Cytotoxic T lymphocyte recognition of the H-2-erbB hybrid gene product lacking the complete H-2 domain structure.

The chimeric mouse MHC class I gene derived from a recombinant H-2Kb gene, in which the coding region for a large part of alpha 1 and alpha 2 extracellular domains was replaced with a partial avian erythroblastosis virus erbB gene segment encoding the kinase domain, was successfully introduced into a mouse mastocytoma line P1.HTR (H-2d) and transcribed to mRNA. The transfectant cells expressed the chimeric gene product, which was reactive to a phosphotyrosine-specific antibody. When the chimeric gene transfectant was inoculated into CDF1(H-2d) or BDF1(H-2d/b) mice, it grew at an early time but regressed thereafter. Transfectant-specific as well as parental P1.HTR-specific antibody activities were demonstrated in the sera of these mice. Transfectant-specific cytotoxic T lymphocytes (CTL) were generated in the antigen-sensitized culture of spleen cells from the transfectant-immune mice. The CTL-mediated lysis of target chimeric gene transfectant cells was poorly inhibited by anti-H-2d antiserum, which blocked the lysis of parental P1.HTR cells by anti-tumor CTL developed in parallel. The former was, however, inhibited by either anti-transfectant antiserum or anti-phosphotyrosine antibody, which was ineffective for blocking the latter. Target cell lysis by either anti-transfectant or anti-tumor CTL was blocked by anti-CD8 monoclonal antibody but not by anti-CD4 antibody. It was suggested from these results that the H-2K-erbB hybrid gene product, which lacks complete three-domain class I structure, was recognized by CTL in a manner that was endogenous H-2 class I-independent but CD8-dependent.     

Receptor/ligand avidity determines the capacity of Ly49 inhibitory receptors to interfere with T-cell receptor-mediated activation

The specificity and the relative affinity of many Ly49 receptors for major histocompatibility complex class I ligands have been studied in detail in various adhesion and binding assays. However, how the level of cell surface expression of a given Ly49 receptor and its ligand affinity influence the strength of the inhibition signal is not well documented. To address this issue, we developed a series of human Jurkat T-cell transfectants expressing the whole range of Ly49A and Ly49C levels found in vivo on natural killer and T cells and evaluated their capacity to alter superantigen-induced NF-AT activation and interleukin-2 production. We show that the strength of the inhibition induced by Ly49A/H-2Dd interaction correlates with Ly49A density up to a certain level after which increasing expression does not further inhibit significantly the T-cell receptor-induced activation. This system also represents a valuable tool for the determination of the relative strength of the inhibitory signals of Ly49 receptors following their interactions with different ligands. Even at high levels of expression there was no evidence that engagement of Ly49A with H-2b class I molecules provided an inhibitory signal. Moreover, we showed that functional inhibitory interactions of Ly49C with H-2b class I molecules were only the result of H-2Kb and that H-2d represent lower affinity ligands for Ly49C than H-2b. Therefore, depending on the relative affinity of Ly49 receptors for their ligands, the modulation of their expression level will be determinant for the functional outcome of activated T cells.     

Differential effect of adenovirus 2 E3/19K glycoprotein on the expression of H-2Kb and H-2Db class I antigens and H-2Kb- and H-2Db-restricted SV40-specific CTL-mediated lysis

The E3/19-kDa glycoprotein (E3/19K) coded by adenovirus type 2 (Ad2) is known to inhibit the cell-surface expression of major histocompatibility complex (MHC) class I antigens by binding to the MHC antigens intracellularly, and thus reduces recognition of antigens by MHC-restricted cytotoxic T lymphocytes (CTL). We have studied the effect of the E3/19K expression in SV40-infected monkey cells, TC-7/H-2Kb and TC-7/H-2Db expressing transfected H-2Kb and H-2Db antigens, respectively, on the cell-surface H-2 class I antigens and on lysis of the cells by SV40 large tumor (T)-antigen-specific H-2Kb- and H-2Db-restricted CTL clones. H-2Db antigen expression on TC-7/H-2Db cells was drastically reduced by infection with Ad2 but not with an E3/19K-negative SV40-Ad2 hybrid virus, Ad2+ND1, as early as 12 hr postinfection. However, H-2Kb antigen expression on Ad2-infected TC7/H-2Kb cells remained unaltered, even at 24 hr postinfection. Specific lysis of SV40-infected TC-7/H-2Db cells by H-2Db-restricted SV40 T-antigen-specific CTL clones, Y-1 and Y-3, was strongly reduced by coinfection of the target cells with Ad2 but not with Ad2+ND1. Lysis of SV40-infected TC-7/H-2Kb cells by a H-2Kb-restricted SV40 T-antigen-specific CTL clone Y-4 was also reduced significantly by Ad2 infection, but not Ad2+ND1. These results indicate that the E3/19K protein affects cell-surface expression of H-2Db antigen but not H-2Kb antigen.     

Role of Qa-1(b)-binding receptors in the specificity of developing NK cells

NK cells acquire the ability to recognize MHC class I molecules during development. Studies with Qa-1(b) tetramers (Qa-1 tetramers) showed that nearly all NK1.1(+) cells from newborn C57BL/6 mice express Qa-1-binding receptors. Cytotoxic activity of these cells is fully inhibited by Qa-1 ligands on target cells. In contrast, neither receptors for H-2K(b) nor H-2D(b) were observed on NK1.1(+) cells from newborn mice. After birth, frequencies of Qa-1 tetramer(+)/ NK1.1(+) cells gradually decrease as the number of Ly49(+) /NK1.1(+) cells increases. Cell transfer studies showed that Qa-1 tetramer(+) cells from newborn mice do not lose expression of Qa-1 receptors, but that they further acquire expression of Ly49 molecules. Acquisition of Qa-1-binding receptors appears largely independent of host MHC class I molecules, as observed in studies using beta2-microglobulin-deficient (beta2m(-/-)) mice as well as K(b)/ D(b-/-) and K(b)/D(b)/beta2m(-/-) mice. The present results suggest that Qa-1-binding receptors play an important role in the specificity of developing NK cells, and suggest that these cells rely mainly on inhibitory receptors specific for non-classical MHC class I molecules to maintain self tolerance during the first weeks of life.     

Generation of metastatic variants by transfection of a nonmetastatic rat mammary epithelial cell line with DNA from a metastatic rat mammary cell line

Transfection of rat mammary (Rama) 37 epithelial cells, which yield nonmetastasizing adenomas in syngeneic Wistar-Furth rats, with HindIII-fragmented cellular DNA and the drug-resistance plasmids pSV2gpt or pSV2neo yields drug-resistant transformants with a frequency of 10(-4)-10(-5). Transformant cell lines transfected with the following, pSV2gpt alone, pSV2gpt and Rama 37 DNA, pSV2gpt and DNA from a metastasizing cell line Rama 800 (CT set), pSV2neo and salmon sperm DNA, pSV2neo and Rama 800 DNA (C set), all yield tumors when injected subcutaneously into syngeneic rats. A few transformants obtained by cotransfection with DNA from Rama 800 cells produce metastases in lungs and/or lymph nodes. The incidence of such metastases for two transfectants, termed CT4-41 and C18P, is significant at 20 and 24%, respectively, but only half (48%) that achieved with Rama 800 cells. Reintroduction into rats of cells cultured from a metastatic tumor of CT4-41 and of C18P, and from their lung or lymph node metastases, produces either a similar incidence (20-24%) or a significantly higher (48-52%) incidence of metastasis than that of the original transfectants. Cells cultured from nonmetastatic tumors fail to produce any metastatic lesions. When [32P]-labeled gpt or neo DNAs are hybridized to EcoRI-digested cellular DNA of the CT4-41 or C18P series of cell lines, tumors or metastases, gpt binds to one major fragment of 3,800 basepairs, and neo to two major fragments of 5,700 and 4,200 basepairs. The same cell lines produce hybridizing mRNAs of 1,500 and 1,900 bases for the CT4-41 series and 2,000-2,400 bases for the C18P series. It is suggested that transfection of DNA from the metastatic cells causes the nonmetastatic cells to become metastatic, in a genetically dominant manner, but additional steps are required for this process to become established and expressed at a level equivalent to that of the original, metastasizing donor cells.