Mechanism of target cell recognition by CD3- LGL. I. Development of a monoclonal antibody to a K562-associated target cell antigen.

In an attempt to identify the target recognition molecule(s) involved in the interaction between CD3- large granular lymphocyte (LGL) and a tumor cell target, monoclonal antibodies (mAb) to NK-susceptible K562 tumor cell membrane glycoproteins were developed. After screening by ELISA for reactivity to K562 membrane glycoproteins, two monoclonal antibodies were identified (mAb 35 and mAb 36). One of the monoclonal antibodies (mAb 36) was found to inhibit conjugation between LGL and K562 target cells and also to inhibit lysis of K562 by LGL. Upon further testing, mAb 36 also inhibited the binding between LGL and other NK-susceptible target cells, e.g., Daudi and Molt 4. In contrast, mAb 35, even though binding to K562, did not inhibit the binding of LGL to tumor targets and therefore was used as an isotype control. When mAb 36 was utilized as an affinity matrix, bound proteins specifically inhibited CD3- LGL-K562 conjugation. Experiments involving tunicamycin treatment of tumor target cells demonstrated that mAb 36 recognized a carbohydrate moiety rather than the protein core. Therefore, these data suggested that the target cell recognition molecule which is recognized by mAb 36 appears to be a membrane carbohydrate-associated molecule.     

F1 hybrid anti-parental H-2k cell-mediated lympholysis. I. Stimulator and target determinants controlled by the H-2K region.

H-2k-heterozygous F1 hybrid mouse spleen cells cultured with irradiated H-2k-homozygous stimulator cells generated specific anti-parent cytolytic effectors. The parental antigenic determinants recognized by responder cells during induction (afferent arm) and by effector cells during cytolysis (efferent arm) were coded for, or regulated by, the H-2K-Hh3 region of the MHC, according to recombinant analysis. There were no detectable influences by other linked or unlinked genes on the phenotypic expression of parental antigens; however, the anti-parent responsiveness was modulated by background genes of responder cells. These experiments establish that the K end of H-2 controls determinants of F1 anti-parental H-2k CML, like the D end controls those of F1 anti-parental H-2b CML, thus confirming the basic symmetry of the H-2 complex. The relationship of this primary in vitro cell-mediated response with natural in vivo resistance to parental and allogeneic bone marrow grafts is discussed.     

Characterization by monoclonal antibodies of a target cell antigen complex recognized by nonspecific cytotoxic cells

Fish nonspecific cytotoxic cells (NCC)3 recognize and lyse a large variety of human and mouse transformed cells. In an effort to determine the Ag recognized by NCC on these targets, mAb were raised against NC-37 target cells. Four anti-NC-37 mAb were chosen for further characterization based on their effects on NCC lysis of target cells. Purified mAb 18C2 and 1E7 (IgM isotype) inhibited NCC killing of the following targets: U937, MOLT-4, K562, HL-60, DAUDI, NC-37, P815, and YAC-1. The dose-dependent inhibitory activity occurred at the target cell level and ranged from 50 to 70% at a concentration of 50 micrograms/well when compared to noninhibitory mAb 7C6 and 1D4 (IgG isotype). Similarly, mAb 18C2 protected the fish parasite Tetrahymena pyriformis from lysis by NCC when compared to mAb 7C6. Adsorption experiments demonstrated that the inhibitory effect on NC-37 lysis by NCC could be removed in a titratable fashion by incubation of mAb 1E7 with any one of the other target cell lines, but it could not be removed by incubation with effector cells. The inhibitory activity of mAb 1E7 and 18C2 was shown to be caused by the inhibition of conjugate formation between effector and NC-37 target cells. The relative membrane concentration of the antigenic determinants recognized by these mAb on the target cells was studied by flow cytometry using FITC-labeled mAb. These experiments showed that all four mAb bound to the surface of the cells tested. Biochemical analysis with Western blots and immunoprecipitation showed that mAb 18C2 and 1E7 recognize two Ag in NC-37 lysates: a larger protein of around 80 kDa and a smaller one of 42 kDa.     

A monoclonal antibody-purified soluble target cell antigen inhibits nonspecific cytotoxic cell activity.

We have previously reported the characterization of mAb derived against NC-37 target cells. mAb 18C2 and 1E7 inhibit fish cytotoxicity by binding to target cells and thus preventing the formation of conjugates with fish nonspecific cytotoxic cells (NCC). It was therefore presumed that these inhibitory mAb were specific for the target cell Ag necessary for effector cell recognition. mAb 1D4 and 7C6 bind to NC-37 cells but do not inhibit fish cytotoxic activity. We now report the isolation and purification of the Ag recognized by mAb 18C2 (inhibitor) and 1D4 (noninhibitor) by affinity chromatography of solubilized NC-37 target cell extracts. The 18C2-purified soluble target Ag (STAg) caused inhibition of cytotoxicity when preincubated with fish NCC. This inhibitory activity was reversible and dose-dependent ranging from 20 to 70% inhibition with 25 to 100 micrograms 18C2 purified STAg/10(6) NCC. STAg purified by 1D4 affinity chromatography had no effect on fish cytotoxicity. mAb 18C2 and 1E7 preabsorbed with 18C2 STAg lost their inhibitory activity when tested in the fish NCC cytotoxicity assay. Preabsorption of the same mAb with 1D4 STAg had no effect on their activity.     

Antibody-dependent cell-mediated cytotoxicity in humans. I. Characterization of the effector cell.

Mononuclear cells from human peripheral blood are able to destroy alloantibody-coated target cells of a human lymphoblastoid line. The effector cell is a nonadherent, non-phagocytic, medium sized lymphoid cell. The cell is not detectable in early human fetuses. Its activity is destroyed by x-ray treatment in vitro but is not inhibited by anti-immunoglobulin sera. Its efficiency in antibody-dependent cell-mediated cytotoxicity is rapidly lost in culture and this loss is prevented by stimulation with allogeneic cells.     

The Qa-2 antigen on lymphocyte subpopulations. Mixed lymphocyte culture and cell-mediated lympholysis.

Treatments of spleen cells from Qa-2+ strains with Qa-2 antiserum plus complement (C) have revealed that the Qa-2 antigen is present on restricted functional lymphocyte subpopulations. Anti-Qa-2 plus C reduced the mixed lymphocyte culture response and inhibited the generation of cytolytic effector cells. This treatment, however, did not affect cytolytic effector cells once they were generated.     

Characterization of a renal tubular epithelial cell line which secretes the autologous target antigen of autoimmune experimental interstitial nephritis

Proximal tubular epithelial cells from mice which develop autoimmune interstitial nephritis were found to express the nephritogenic target antigen, 3M-1. Anti-3M-1 mAbs (alpha 3M-1-Ab) were used to positively select for 3M-1-secreting tubular epithelium and, after stabilization in culture, this new cell line (MCT) was examined for the production of several moieties important to either immune interactions or to the development of extracellular matrix. Alkaline phosphatase-staining MCT cells also express epithelial growth factor receptors with a Kd of 0.87 nM and an epithelial growth factor receptor constant (Ro) of 2.1 X 10(4) receptors/cell. MCT culture supernatants contain greater amounts of laminin, and types IV and V procollagens compared to types I and III procollagens, and growing MCT cells on type I collagen matrix causes them to preferentially secrete even more type IV and V procollagen. The 30,000-Mr 3M-1 antigen could be immunoprecipitated from biosynthetically labeled MCT cell supernatants with alpha 3M-1-Ab. An identical-sized moiety was isolated by immunoaffinity chromatography from collagenase-solubilized mouse kidney tubular basement membranes. The 3M-1 antigen can be found on the MCT cell surface by radioimmunoassay, or deposited in a linear array in the extracellular matrix surrounding the MCT cells in culture by immunofluorescence. Mature messenger RNA species for both class I and class II major histocompatibility complex (MHC) molecules were detected by Northern hybridization, and their corresponding cell surface gene products were detected by cytofluorography of MCT cells stained with haplotype-specific antibodies. Both the cell surface 3M-1 and the small amounts of detected class II MHC molecules appear to be biologically functional, as MCT cells can support the proliferation of 3M-1-specific, class II MHC-restricted helper T cells in culture. These findings suggest that MCT cells provide all the necessary biological parameters for interfacing both as the target of a nephritogenic immune response, and as a potential source for new extracellular matrix which develops as a fibrogenic response to interstitial nephritis.     

The murine Kupffer cell. I. Characterization of the cell serving accessory function in antigen-specific T cell proliferation.

Murine Kupffer cells, the tissue macrophages of the liver, were isolated by collagenase digestion, differential sedimentation over Metrizamide, and glass adherence. The resultant cell population was more than 86% phagocytic, and 95% of cells stained positively for alpha-naphthyl butyrate esterase activity. The cells also had cell surface receptors for complement (C) and the Fc portion of IgG. In addition, a large proportion of Kupffer cells was shown to bear Ia antigens: about half of the cells bore I-A subregion-encoded antigens and about half bore I-BJE or I-EC subregion-encoded antigens. Kupffer cell populations were capable of reconstituting antigen-stimulated proliferative responses of antigen-primed, macrophage-depleted, lymph node T cells. The ability to reconstitute proliferation was enriched in the adherent population and was resistant to radiation and treatment with an anti-Thy antiserum and C. We conclude that isolated murine Kupffer cells bear the Ia phenotype of accessory cells that function in antigen presentation and that Kupffer cells can participate in the induction of antigen-specific immune responses. These data suggest that Kupffer cells may play a role in modulating responses to enterically derived antigens.     

The interaction of nominal antigen with T cell antigen receptors. I. Specific binding of multivalent nominal antigen to cytolytic T cell clones

In this report, we describe an experimental strategy for analyzing the interaction of nominal antigen with antigen-specific T cell clones. Our approach was based on the notion that low affinity interactions between nominal antigen and T cell antigen receptors might be detected by using a highly multivalent form of the antigen in which a large number of identical, appropriately spaced epitopes are attached to a polymer backbone. Antigens of this kind should be capable of multivalent binding to receptors on the T cell, resulting in a marked enhancement of the overall avidity of the interaction. To examine this possibility, we established a series of murine cytolytic T cell (Tc) clones specific for the readily detectable hapten fluorescein isothiocyanate (FL). These clones lysed FL-conjugated target cells in an antigen-specific fashion and also showed specificity for target cell MHC gene products. The interaction of these clones with the nominal antigen FL was assessed by flow cytometry, using a series of water-soluble FL-conjugated polymers varying in polymer backbone and FL isomer. High m.w. (600 to 2000 Kd) polymers of acrylamide, dextran, or Ficoll conjugated with 300 to 800 FL groups/molecule bound specifically to anti-FL Tc clones. There was little binding to syngeneic spleen cells, thymocytes, noncytolytic T cell clones, or T cell clones specific for other haptens such as NIP. Polymer concentrations in the 1 to 10 micrograms/ml range produced readily detectable binding within minutes at 20 degrees C, and the binding approached plateau levels at polymer concentrations of between 100 and 300 micrograms/ml. Studies with closely related FL isomers showed that the same antigen fine specificity was operative in both lysis of FL-conjugated target cells and in binding of FL-conjugated polymers. The functional significance of the observed binding was assessed by measuring the effect of FL-conjugated polymers on lymphokine secretion by the clones. High m.w. FL-conjugated polymers caused a dose-dependent increase in the production of macrophage activation factor (MAF) by anti-FL Tc clones, but did not increase MAF production by an NIP-specific clone. In contrast, concanavalin A induced MAF production by both FL-specific and NIP-specific clones. Thus, the observed binding is both specific and functionally significant. These results suggest that soluble nominal antigen, in an appropriately multivalent form, can bind specifically to antigen receptors on Tc clones.     

Genetics of cell-mediated lympholysis in man.

Cell-mediated lympholysis (CML) was studied in a family containing two siblings in who genetic recombinaiton had occurred in the HLA comples. In one sibling, recombination occurred between the HLA-A locus and the HLA-B locus. In the second sibling recombination occurred between the HLA-B locus and the HLA-D locus. Strong CML activity was generated in mixed lymphocyte cultures (MLC) when stimulator and responder cells differed in HLA-A, B, and D antigens. MLC involving HLA-D differences alone did not generate CML. Weak, but definite CML activity was generated during MLC with cells differing at HLA-A and HLA-B but sharing HLA-D. HLA-B antigens were good targets for lysis in all combinations studied. HLA-A antigens were poor targets in some but not in all combinations. However, combinations where HLA-A antigens seemed to be good targets could have involved HLA-B differences due to polymorphism of HLA-B7 antigens each inherited from a different parent. HLA-D antigens did not serve as targets for lysis. In three cell experiments, excellent CML activity was generated when responder cells were stimulated by HLA-D antigens and by HLA-A and B antigens present on separate stimulator cells.     

Characterization of Epstein-Barr virus antigens. I. Biochemical analysis of the complement-fixing soluble antigen and relationship with Epstein-Barr virus-associated nuclear antigen.

The Epstein-Barr virus-soluble (S) antigen extracted from RAJI cells was characterized by sucrose gradient centrifugation, gel filtration, and ion-exchange chromatography. The sedimentation coefficient was estimated to be 8.5S corresponding to a molecular weight of 180,000. The S antigen binds to DEAE-A25 ion exchanger from which it can be eluted with 0.3 M NaCl in Tris buffer (pH 7.2). All fractions which contained complement-fixing S antigen also inhibited the anticomplement immunofluorescence reaction as used to detect the Epstein-Barr virus-associated nuclear antigen. These results are consistent with the hypothesis that the S and Epstein-Barr virus-associated nuclear antigens are either a single antigen or that both activities are present on the same molecule.     

T cell epitope mapping of the Smith antigen reveals that highly conserved Smith antigen motifs are the dominant target of T cell immunity in systemic lupus erythematosus.

B cell and T cell immunity to the Smith Ag (Sm) is a characteristic feature of systemic lupus erythematosus (SLE). We have shown that T cell immunity against Sm can be detected in SLE patients, and that T and B cell immunity against Sm are linked in vivo. TCR usage by Sm-reactive T cells is highly restricted and characteristic of an Ag-driven immune response. Sm is a well-characterized complex Ag consisting of proteins B1, B2, D1, D2, D3, E, F, and G. A unique feature of all Sm proteins is the presence of homologous motifs, Sm motif 1 and Sm motif 2. We used limiting dilution cloning and synthetic peptide Ags to characterize the human T cell immune response against Sm in seven SLE patients. We sought to determine the precise antigenic peptides recognized, the common features of antigenic structure recognized, and the evolution of the T cell response against Sm. We found there was a highly restricted set of Sm self-peptides recognized by T cells, with three epitopes on Sm-B and two epitopes on Sm-D. We found that T cell immunity against Sm-B and Sm-D was encoded within the highly conserved Sm motif 1 and Sm motif 2, and that immunity against these epitopes appeared stable. The present study supports the concept that T cell immunity to Sm is an Ag-driven immune response directed against a highly restricted set of self-peptides, encoded within Sm motif 1 and Sm motif 2, that is shared among all Sm proteins.     

Characterization of the carbohydrate component of fraction I in the Neurospora crassa cell wall.

The carbohydrate portion of fraction I of the Neurospora crassa cell wall has been analyzed for sugar composition by gas-liquid chromatography and colorimetric methods. The analysis was performed comparatively in a wild-type strain (RL 3-8A) and three morphological mutants: scumbo (FGSC 49), peak-2a (a mutant known to be allelic to biscuit), and ragged (FGSC 296). Fraction I of all strains studied contains glucose, mannose, and galactose as the main sugars. Uronic acids and amino sugars are also present in small amounts. The glycosidic linkages binding the neutral sugars were analyzed by Lindberg's combined gas chromatography-mass spectrometry techniques for identification of the partially methylated alditol acitate sugar derivatives. The main polymeric portion of fraction I seems to be a linear glucan with the glucose residues linked by 1 leads to 3 and 1 leads to 4 bonds. A mannan portion with a branched configuration is also present, with galactose as the sugar residue which serves as branches in the molecule(s). The branched mannan portion appears to increase in amount in correlation with more drastic morphological changes of the mycelia. In this respect, the mutant ragged has the lowest mycelial growth rate and the largest amount of mannan. The importance of the polysaccharide structure of fraction I on the colonial morphology of the mycelia is discussed.     

The genetics of cell-mediated lympholysis.

The role of HLA antigens in the generation of cytotoxic cells in CML has been investigated. Cytotoxic effector cells were generated in MLC among HLA-A or HLA-A and HLA-B disparate, HLA-D identical siblings, and among HLA-A and HLA-B disparate, MLC identical (%RR less than or equal to 2 3.6) unrelated individual. The data indicate that HLA-D differences and poliferative MLC responses as measured by 3H-thymidine incorporation are not requisite for the in vitro generation of cytotoxic cells and suggest the existence of a CML-S locus (loci) distinct from HLA-A, HLA-B and HLA-D. The degree of cytotoxicity generated in a proliferative versus a "nonproliferative" MLC was comparable. In addition, these studies demonstrate that antigens other than the currently definable HLA-A, HLA-B, HLA-C, and HLA-D can serve as target determinants in cell-mediated lympholysis.     

Adherent cell function in murine T lymphocyte antigen recognition. I. A. macrophage-dependent T cell proliferation assay in the mouse.

The data in this report describe a T cell proliferation assay with nylon wool column-purified murine lymph node lymphocyte from animals immunized by footpad injection of antigen in CFA. It was found that the in vitro immune response of sensitized T cells to soluble protein antigens was functionally dependent on the presence of adherent cells, more specifically macrophages, at all concentrations of in vitro antigen challenge. The response was due to T cells in that cytotoxic treatment of the immune lymphocyte cells with anti-Thy 1.2 serum and complement effectively eliminated the antigen-specific DNA synthetic responses. The antigen-specific proliferation of murine lymphocytes depleted of adhereent cells could not be reconstituted with either guinea pig macrophages nor murine fibroblasts, indicating the existence of species and cell type specificity. In contrast to previous observations in the guinea pig, soluble products of cultured adherent cells could at least partially replace the function of intact macrophages in the response to antigen.