Human lymphocyte responses to hepatitis A virus-infected cells: interferon production and lysis of infected cells

Peripheral blood mononuclear cells (PBMC) from nonimmune healthy donors who did not have antibody to hepatitis A virus lysed hepatitis A virus-infected BS-C-1 cells to a greater degree than uninfected BS-C-1 cells. The predominant effector cells were contained in the nonadherent peripheral blood lymphocyte (PBL) fraction, although some lytic activity was associated with adherent cells. Characterization of the PBL with monoclonal antibodies showed that the responsible effector lymphocytes were contained in Leu-11+ and M1+ subsets, but not in the T3+ or T4+ subsets. The phenotypes of the effector cells active in the lysis of hepatitis A virus-infected cells are similar to those of human natural killer cells that lyse K562 cells. Human PBL produced high titers of interferon-alpha (IFN-alpha) when exposed to hepatitis A virus-infected cells. These results imply that hepatitis A virus infection may be controlled by lymphocyte responses in the liver, i.e., by lymphocyte-mediated lysis of the hepatitis A virus-infected cells, and by the production of high titers of IFN-alpha by lymphocytes exposed to hepatitis A virus-infected cells. Furthermore, these results, along with the observations that hepatitis A virus infection results in a persistent noncytocidal infection in vitro, support the hypothesis that lysis of hepatocytes infected with hepatitis A virus is by lymphocyte-mediated cytotoxicity and not by virus-induced destruction of the liver cell.     

In vitro enhancement of natural and antibody-dependent lymphocyte-mediated cytotoxicity against tumor target cells by interferon.

Interferon derived from virus-infected human leukocytes or fibroblasts was found to enhance spontaneous and antibody-dependent lymphocyte cytotoxicity against human target cell lines in vitro. The greater enhancement occurred with spontaneous lymphocyte cytotoxicity. Interferon exerted its effect directly on lymphocytes; no effect on target cells was seen. The mechanism of enhancement was unclear: It did not reflect antibody production or lymphocyte proliferation. Enhancement appeared to be immunologically nonspecific, but clarification of this effect awaits further study.     

Vaccinia virus-specific human CD4+ cytotoxic T-lymphocyte clones.

Vaccinia virus-specific cytotoxic T-lymphocyte (CTL) clones were established from a healthy donor, who had been immunized with vaccinia virus vaccine, by stimulation of peripheral blood lymphocytes with UV-inactivated vaccinia virus antigen. The phenotype of all of the clones established was CD3+ CD4+ CD8- Leu11-. We used a panel of allogenic vaccinia virus-infected B-lymphoblastoid cell lines and demonstrated that some of the clones recognized vaccinia virus epitopes presented by human leukocyte antigen (HLA) class II molecules. Monoclonal antibodies specific for either HLA-DP or HLA-DR determinant reduced the cytotoxicity of specific clones. The HLA-restricted cytotoxicity of the clones is vaccinia virus specific, because vaccinia virus-infected but not influenza virus-infected autologous target cells were lysed. Using vaccinia virus deletion mutants, we found that some of the CTL clones recognize an epitope(s) that lies within the HindIII KF regions of the vaccinia virus genome. These results indicate that heterogeneous CD4+ CTL clones specific for vaccinia virus are induced in response to infection and may be important in recovery from and protection against poxvirus infections.     

Differential cytotoxicity of activated lymphocytes on allogeneic and xenogeneic target cells. II. Activation by phytohemagglutinin

In the preceding paper it has been shown that human or mouse lymphocytes stimulated by a variety of agents, damaged allogeneic target cells while damage of xenogeneic target cells was weak or absent. In this study, the species specificity of the cytotoxicity of PHA activated lymphocytes has been studied in greater detail. Effector cells were purified lymphocytes either from human peripheral blood, or from spleen or lymph nodes of inbred mice. Target cells were ⁵¹Cr-labeled human Chang liver cells or mouse L cells.PHA stimulated human or mouse lymphocytes were significantly more cytotoxic to allogeneic than to xenogeneic target cells. At low PHA doses at which damage of allogeneic target cells was significant, damage of xenogeneic target cells was very weak or absent. At higher PHA doses, damage of xenogeneic target cells became also significant but always remained at a lower level than that of allogeneic target cells.Prestimulation of human lymphocytes with PHA for 3 days increased their cytotoxic efficiency. Furthermore, damage of human Chang cells by human lymphocytes had a dose-response relationship similar to that valid for stimulation of DNA synthesis. However, damage of mouse L cells by human lymphocytes increased at PHA-doses at which stimulation of DNA-synthesis declined. For mouse lymphocytes, these doseresponse relationships were less clear-cut, probably due to differences in origin and survival of the effector cells. This confirms previous observations that cytotoxicity and DNA-synthesis are different but probably interdependent expressions of lymphocyte activation.     

Virus specificity of human influenza virus-immune cytotoxic T cells.

The virus specificity of human in vitro cytotoxic T cell responses to influenza virus was studied with the use of peripheral blood mononuclear leukocytes from normal adult volunteers. Previous natural exposure of these donors to a variety of type A influenza viruses was documented by HI antibody titers. Cells sensitized in vitro with A/HK or A/PR8 were cytotoxic for autologous target cells infected with A/HK, A/PR8, or A/JAP 305 type A influenza viruses, but not for B/HK-infected or uninfected cells. B/HK-sensitized effector cells lysed target cells infected with B/HK but not targets infected with type A viruses. A/HK- and A/PR8-immune effector populations were shown to recognize cross-reactive antigens on A/HK- and A/PR8-infected target cells by cold target competition. Influenza-immune effector cells were cytotoxic for virus-infected autologous targets but much less so for virus-infected allogeneic targets. This self-restriction suggested that the cytotoxicity was largely T cell-mediated and was confirmed by cell separation analysis. Thus, the human secondary cytotoxic T cell response in vitro to influenza viruses is predominantly directed against cross-reactive determinants on cells infected with serologically distinct type A influenza viruses.     

Lymphocyte-mediated cytotoxicity to autologous cells infected with measles virus. II. Specificity of the cytotoxic reaction and characterization of the effector cells involved.

The mechanism of lymphocyte-mediated cytotoxicity to cells infected with measles virus was investigated. Cytotoxicity was measured in a direct assay, immediately after the isolation of lymphocytes from human peripheral blood; mononuclear leukocytes, infected with measles virus in vitro, served as autologous target cells. Virus-specific cytotoxicity required the presence of both IgG antibodies against measles virus and of effector lymphocytes. The effector lymphocytes had Fc receptors and were mainly present in a fraction of non-T lymphocytes. Monocytes were not cytotoxic but rather inhibitory. These results indicate that lysis of virus-infected cells in this direct assay is due to antibody-dependent cellular cytotoxicity (ADCC), caused by K cells. Control experiments showed that the virus-infected target cells were sensitive to incubation with human serum or IgG, resulting in a nonspecific increase of ⁵¹Cr release; however, this did not affect the results of K-cell cytotoxicity. Maximal virus-specific lysis by ADCC did not reach the level obtained by complement-dependent cytotoxicity. Possible explanations for this difference are discussed.     

Spontaneous and lymphokine-induced cytotoxic activity of monkey intestinal mucosal lymphocytes

We determined the capacity of primate (macaque monkey) intestinal mucosal lymphocytes to mediate natural killer cytotoxicity, and characterized the nature of cells mediating this form of cytotoxicity in the intestine. Isolated macaque monkey intestinal mucosal lymphocytes were found to have intermediate levels of spontaneous cytotoxicity against K562 target cells compared to higher values found in lymphocytes of peripheral blood (PBL) and spleen and low values for mesenteric lymph node (MLN) lymphocytes. Intestinal lymphocytes were similar to PBL in having the same range of target cell specificites, in having augmentation of activity by interferon or interleukin 2, and in demonstrating specificity in cold target inhibition studies. Both intestinal and PBL spontaneous cytotoxic function in primates was mediated predominantly by cells bearing antigens cross-reactive with the anti-human monoclonal antibody Leu-11. The percentage of Leu-11+ lymphocytes was significantly lower in isolated intestinal, spleen, and MLN lymphocytes compared to peripheral blood. Furthermore, isolated intestinal lymphocytes differed from PBL in that intestinal Leu-11+ were predominantly Leu-15-, while Leu-11+ PBL were predominantly Leu-15+. These studies demonstrate that the lower spontaneous cytotoxic function of intestinal mucosal lymphocytes compared to PBL is associated with a lower number of effector cells and with effector cells which differ qualitatively in expression of the Leu-15 antigen.     

Ultrastructural changes during lysis of L929 target cells by class II-restricted influenza virus-specific murine cytotoxic T-lymphocyte clones

Lysis of virus-infected L929 target cells transfected with the H-2 class II IAk gene by class II-restricted influenza virus-specific murine cytotoxic T lymphocyte (CTL) clones was studied by electron microscopy and compared with lysis of L929 cells by class I-restricted CTL clones. T lymphocytes predominantly approached the basal surface of target cells grown on a plastic dish and also approached uninfected L929 target cells, although virus maturation exhibited no polarity with respect to the cell surface site. After incubation for 30 min, the target cell nuclei began to change: chromatin became irregularly redistributed and aggregated, and the nuclei appeared swollen. Later, electron-dense and -light areas of nuclei became segregated, and the cytoplasm became disorganized with many vacuoles. The ultrastructural changes of target cells during lysis by class I- and class II-restricted CTL clones appeared to be similar. These findings and other cytotoxicity data of class I and class II CTLs are discussed.     

Cell-mediated cytotoxicity against virus-infected target cells in humans. II. Interferon induction and activation of natural killer cells.

The mechanisms by which human lymphocytes lyse virus-infected allogeneic fibroblast cultures were analyzed with particular consideration of the role of anti-viral antibodies and interferon. Human cells infected with viruses were able to induce high levels of interferon upon contact with human lymphocytes. Interferon, whether produced by lymphocytes after direct infection with virus or induced upon exposure of lymphocytes to virus-infected fibroblasts, appeared to be responsible for enhancing the cytotoxic efficiency of the natural killer cell against the infected target. Activation of cytotoxic lymphocytes occurred as early as 6 hr after addition of interferon and increased up to 24 hr. Antibody-dependent cell-mediated cytotoxicity (Ab-CMC) could be easily induced by sensitization of infected target cells with antiviral antibodies and could be detected at 4 hr from the beginning of the cytotoxic test, before the effect of interferon on the natural killer cell was evident. However, the antibody-dependent effector cell was inactive after 4 hr of incubation. F(ab')2 fragments of rabbit anti-human IgG completely inhibited Ab-CMC but did not at all affect the spontaneous cytotoxic activity of the effector cells against virus-infected target.     

Ultrastructural study of biochemically modulated ADCC in HSV-1 infected and uninfected Chang liver cells

The effect of cytochalasin B, ouabain and 25-OH cholesterol on specific lysis due to antibody dependent cellular cytotoxicity (ADCC) in allogeneic and xenogeneic systems was studied using Herpes simplex I infected Chang liver cells. Cytochalasin B reduced both cytotoxicity and lymphocyte/target (LT) binding in the allogeneic system whereas cytotoxicity but not LT binding was reduced in the xenogeneic system. Ouabain inhibited ADCC in both systems as well as LT binding in the allogeneic system; however, binding in the xenogeneic system was not significantly reduced. The 25-OH cholesterol produced a marked decrease in ADCC in both systems but had no significant effect on LT binding in either system. The biochemical and ultrastructural data suggest that the modulators act at different stages in the ADCC response and that there may be more than one mechanism of ADCC to handle different types of target antigens.     

Mechanism of cell-mediated cytotoxicity at the single cell level. VI. Direct assessment of the cytotoxic potential of human peripheral blood non-lytic effector-target cell conjugates

Single cell cytotoxicity assays reveal that a large percentage of lymphocytes are unable to kill attached targets in a 4- to 18-hr assay. Additional signals (in the form of lectin or anti-target antibody) delivered to target-bound lymphocytes enable these previously non-lytic lymphocytes to kill attached target cells. This finding was obtained by using a modification of the single cell assay, in which lectin or target cell antibody is incorporated into agarose with preformed lymphocyte-target conjugates. Human peripheral blood lymphocytes (PBL) or Percoll density gradient-enriched large granular lymphocytes (LGL) were used as effector cells in natural killer (NK), antibody-dependent cellular cytotoxicity (LDCC) assay systems. The targets used were NK-sensitive K562 and Molt-4 and NK-insensitive Raji. Several findings were made in the modified single cell assay, namely a) the frequency of cytotoxic NK or ADCC effector cells was not augmented, suggesting that the initial trigger was sufficient for lytic expression in these instances. Furthermore, these results showed that the NK-sensitive targets used do not bind nonspecifically to the LDCC effector cells. K562 coated with Con A, however, serve as LDCC targets. b) The frequency of two target conjugate lysis by NK/K effectors was not augmented by Con A. These results suggest that Con A does not potentiate the killing of multiple targets bound to a single cytotoxic lymphocyte. c) Although conjugates formed between LGL or PBL and NK-insensitive Raji are non-lethal, significant lysis was observed when these conjugates were suspended in Con A or antibody agarose. These results demonstrate that Raji bind to cytotoxic NK, K, and LDCC effector cells, but are lysed only when the appropriate trigger is provided. d) The cytotoxic potential of non-lytic conjugates appears to lie within the low density Percoll fraction, although the high density lymphocytes are able to nonlethally bind to targets. Altogether the results demonstrate that target recognition and/or binding by the effector cells is a distinct event from the trigger or lytic process. The implications of these findings are discussed.     

Regulation of the cytotoxic effect of human ‘normal killer cells’ on tumor cell lines by neuraminidase-treated T-lymphocytes

Summary Subpopulations of peripheral blood lymhocytes (PBL) from healthy individuals were separated according to their capacity to form various rosettes and tested for their cytotoxic activity on cell lines of urinary bladder and breast carcinomas. The subpopulation exerting the highest natural cytotoxic activity was characterized by the presence of cell surface Fc-receptors and by the lack of receptors for sheep red blood cells and for C'3 on their surface. Treatment with vibrio cholera neuraminidase (VCN) increased the cytotoxicity of unseparated PBL to a level twice as high as that of untreated PBL. The attachment of T-lymphocytes to tumor monolayers was increased several fold after VCN-treatment, while the attachment of other lymphocyte subpopulations was not. Evidence is presented that the augmentation of the cytotoxicity of PBL following VCN-treatment results from the interaction of VCN-treated T-lymphocytes, attached to target cells, with normal killer cells. It is suggested that augmentation of the activity of killer cells by T-lymphocytes may play a role in antitumor defense mechanisms.Abbreviations CMC Cell-mediated cytolysis - E-rosettes Rosettes formed with sheep red blood cells - EA-rosettes Rosettes formed with red blood cells coated with antibody - EAC'-rosettes Rosettes formed with red blood cells coated with antibody and complement - FCS Heat inactivated fetal calf serum - PBL Peripheral blood lymphocytes - RBC Red blood cells - RF-TAL E-rosette forming, target-attached lymphocytes - SRBC Sheep red blood cells - VCN Vibrio cholera neuraminidase     

Cytotoxic activities of fish leucocytes

Like mammalian leucocytes, white blood cells of fish are able to kill altered (e.g. virus-infected) and foreign (allogeneic or xenogeneic) cells. The existence of natural killer (NK)-like and specific cytotoxic cells in fish was first shown using allogeneic and xenogeneic effector/target cell systems. In addition to in vivo and ex vivo studies, very important contributions were made by in vitro analysis using a number of different long-term cytotoxic cell lines established from channel catfish. In mammals, specific cell-mediated cytotoxicity (CMC) as part of the adaptive immune response requires a number of key molecules expressed on effector leucocytes and target cells. CD8+ T lymphocytes kill infected cells only, if their antigen receptor (TCR) matches the MHC class I with bound peptide of the target cell. Expression patterns of the fish gene homologues for TCR, CD8 and MHC class I, as well as related genes, are in agreement with similar function. Convenient systems for the analysis of specific CMC have only recently become available for fish with the combination of clonal fish with syngeneic or allogeneic but MHC class I matching cell lines. It was demonstrated that both, NK- and cytotoxic T (Tc) cells are involved in the killing of virus infected MHC class I matching and mismatching target cells. Analysis of these lymphocyte subsets is only starting for fish. There is also evidence that the different viral proteins trigger different subsets of killer cells. This review further discusses findings on fish CMC with regard to temperature/seasons and ontogeny.     

Natural cytotoxicity against mouse hepatitis virus-infected cells. II. A cytotoxic effector cell with a B lymphocyte phenotype

The effector cell in mouse spleen which mediates natural cytotoxicity against mouse hepatitis virus (MHV)-infected target cells was characterized. The target cells were MHV-infected BALB/c 3T3, and the assay time was 3 hr. The effector cell, designated virus killer (VK) cell for the purpose of discussion, had the following phenotype: lymphocyte morphology, plastic-nonadherent, nylon wool-adherent, nonphagocytic, cyclophosphamide-sensitive; by antibody plus complement (C) depletion studies, it was asialo GM1-, NK 1.2 alloantigen-negative, Thy-1.2-, Lyt-5-, and macrophage antigen-negative; by rosetting techniques, it was Fc receptor-positive and surface Fab+; by flow cytometry (FACS) analysis, it was Lyt-2-, MAC-1-, Ia+, IgG (gamma)+, IgM (mu)+, IgD (delta)+, and B cell lineage antibody B-220+. NK cells, measured for cytotoxicity on YAC-1 cells, were similarly tested and were found to differ from the VK cell in the following properties: nylon wool-nonadherent, asialo GM1+, NK alloantigen-positive, Lyt-5+, surface Fab-, MAC-1+, Ia-, IgG-, IgM-, IgD-, and B-220-. The VK effector cell had a phenotype highly distinguishable from NK cells, effectors most commonly associated with antiviral natural cytotoxicity. The VK cell had a phenotype identical to that of a B lymphocyte and was identified as such. Although the effector cells displayed cell surface antibody, the antibody did not appear to be involved in lysis, because lysis could not be blocked by F(ab)'2 directed against Fab, mu, or delta. Cytotoxicity was more likely associated with recognition of the B lymphocyte surface by the MHV glycoprotein E2, as shown in the accompanying companion paper. This is the first demonstration that natural cytotoxicity can be mediated by B lymphocytes.     

Target level blocking of T-cell cytotoxicity for human malignant melanoma by monoclonal antibodies

Cytotoxic T lymphocytes (CTL) for autologous malignant melanoma in culture of a patient AV were induced by restimulation of PBL (peripheral blood leukocytes) with AV melanoma cells in vitro and subcultured in interleukin 2 (IL-2) conditioned media. Monoclonal antibodies detecting six antigenic systems on melanoma cell surfaces were tested for blocking activity on the effector function of subcultured cytolytic T lymphocytes for autologous melanoma cells. The monoclonal antibodies R₂₄ (γ3), specific for the G_D3 disialoganglioside on melanoma cell surfaces and I₂₄ (γM), detecting a similar antigenic determinant, blocked autologous T lymphocytotoxicity for malignant melanoma cells on the target level. The effector function of alloantigen activated cytolytic T lymphocytes generated by coculture of allogeneic PBL with Epstein-Barr virus (EBV) transformed AV B lymphocytes, was blocked by monoclonal antibody R₂₄ when tested against AV melanoma targets, but not when tested against AV B lymphocyte targets. It is concluded that blocking by mAb R₂₄ occurs in this system as a nonspecific effect, unrelated to the specific target antigen recognition by cytotoxic T lymphocytes. Steric hindrance or antibody induced membrane changes may account for the blocking effect of monoclonal antibody R₂₄.     

Human lymphocyte cytotoxicity against mumps virus-infected target cells. Requirement for non-T cells.

Subpopulations of human lymphocytes were tested for their capacity to kill mumps virus-infected target cells in a 51-chromium release asaay. Using two different cell fractionation techniques, lymphocytes were fractionated into T cell-enriched (primarily T cells) and T cell-depleted (primarily B cells) subpopulations. Filtration of lymphocytes through columns coated with human immunoglobulin and rabbit anti-human-immunoglobulin (Ig-anti-Ig) rendered the resulting T-cell preparation inactive as effector cells against target cells carrying mumps virus antigens. In the second technique, lymphocytes were fractionated by centrifugation into two fractions according to their ability to form spontaneous rosettes with sheep erythrocytes (E). The E-rosette-forming population (primarily T cells) was shown to lack cytotoxic activity against mumps virus-infected target cells. This activity was present in the nonrosetting population. The results suggest that the effector cells involved in this cytotoxic system are of a non-T variety.     

Effector cell activity in antibody mediated cell dependent immune lysis. II. Evidence for different populations of effector cells for different targets.

Using the adhering property of certain types of cells to glass or plastic in human peripheral blood lymphocyte preparations, two populations of effector cells can be identified in the ABCIL system, each with a selective killing directed toward a different antibody coated target. The adherent cells which are radioresistant functionally, with the morphology of macrophages, exhibit strong cytotoxicity against the antibody-coated erythroid target while lacking any killing effect toward the antibodycoated target lymphocytes. The nonadherent cells which are radiosensitive and with the morphology of small lymphocytes, selectively kill the antibody-coated lymphocyte target without possessing any cytotoxicity against the antibody-coated target erythrocytes.     

Selective response of gamma delta T-cell hybridomas to orthomyxovirus-infected cells.

A gamma delta T-cell hybridoma established from influenza virus-infected mice responded to a reproducible way when cultured with influenza virus-infected stimulators. Subclones of this line responded to cells infected with influenza viruses A/PR/8/34 (H1N1), X-31 (H3N2), and B/HK/8/73 but not to cells infected with vaccinia virus or Sendai virus. This spectrum of response to both type A and type B orthomyxoviruses has never been recognized for the alpha beta T-cell receptor-positive subsets. There was no response to cells infected with a panel of recombinant vaccinia viruses expressing all individual influenza virus proteins, and so it is unlikely that the stimulating antigen is of viral origin. The alternative is that the antigen is a cellular molecule induced in influenza virus-infected cells. Infectious virus was required for stimulation, and immunofluorescence studies showed increased expression of heat shock protein 60 (Hsp60) in influenza virus- but not Sendai virus- or vaccinia virus-infected cells. Both the hybridoma generated from influenza virus-infected mice and an established hybridoma which uses the same gamma delta T-cell receptor combination responded to recombinant Hsp60. Furthermore, the Hsp60-reactive hybridoma, which was obtained from an uninfected mouse, also responded to influenza virus-infected cells, indicating that Hsp60 may indeed be the target antigen.     

Human autologous rosette-forming cells. III. Binding of erythrocytes from different species to the T-cell receptors for autologous red blood cells

Spontaneous rosette formation in humans is restricted to a subpopulation of the circulating T cells. We have previously shown that the interaction between lymphocytes and autologous red blood cells (auto-RBC) is not mediated by a self-recognition mechanism, since allogeneic (allo-) RBC bind to T cells through the same receptors. In this work, we have extended these observations to thymocytes. Using a mixed-rosette assay in which one type of erythrocyte was identified by FITC labeling, we have shown that almost all the thymocytes which attached auto-RBC could also fix allo-RBC. However, as for the peripheral blood lymphocytes (PBL), binding of human RBC to thymocytes occurred with varying affinities according to the erythrocyte's origin. In order to further study the specificity of the erythrocyte to lymphocyte binding in rosette formation, PBL were mixed with auto-RBC and erythrocytes of xenogeneic (xeno-) origin. Although very disparate incidences of rosettes were found according to the species from which the RBC were derived, most of the autorosetting lymphocytes also had receptors for xeno-RBC. In addition, preincubation of PBL with monoclonal antibody OKT11A (directed against the sheep RBC receptors on T cells) completely abrogated rosette formation with all the erythrocytes tested (human auto- and allo-, sheep, pig, and rabbit) except mouse RBC. Taken together these data strongly suggest that human auto- or allo-, as well as sheep or some other xeno-RBC, bind to T lymphocytes by a single receptor and that the combining sites are expressed with different densities or varying affinities depending upon the RBC's origin. Therefore, spontaneous autorosettes may represent T lymphocytes having high-affinity receptors for sheep RBC.