Perforin--a primary or auxiliary lytic mechanism?

DNA immunization: mechanistic studies

DNA immunization works, as has been amply demonstrated in a variety of microbial and tumor models. However, the mechanisms which underpin its success remain unclear. Using intramuscular delivery of DNA, we wish to precisely define how DNA-encoded antigens induce CD8+ T-cells (most cytotoxic T-cells; CTL), CD4+ T-cells (mostly helper cells) and antibodies; and to use the accrued knowledge to rationally manipulate DNA vaccines, thus enabling us to optimize each of the above three types of immune response. We consider it likely that different mechanisms operate in each case. We have designed a DNA vaccine which induces CTL, but not antibodies. We will present evidence that CTL are induced by endogenously-synthesized protein, not by protein released from cells; and that in the absence of release of intact protein, antibodies are not induced, while CTL induction remains strong. We have used plasmid-encoded minigenes and have found that these short sequences also induce CTL; this, too, argues that CTL are induced by antigens presented following endogenous synthesis. We are attempting to determine how antigens are released from transfected cells, to interact with B-cells and induce antibodies, and are currently evaluating the CD4 responses induced by DNA vaccines.

The Induction of Nitric Oxide by Interleukin-12 and Tumor Necrosis Factor- in Human Natural Killer Cells: Relationship With the Regulation of Lytic Activity

We have investigated the interleukin-12 (IL-12) and tumor necrosis factor- (TNF)-induced regulation of human natural killer (NK) cell function and their relationship with nitric oxide (NO) generation. We demonstrate that both cytokines were efficient to trigger the transcription of the inducible nitric oxide synthase (iNOS) mRNA, as detected by reverse transcriptase-polymerase chain reaction (RT-PCR). Western blot analysis and intracytoplasmic fluorescence showed that iNOS protein was also induced by both cytokines. However, our data indicate that NO does not play a significant role in the effector phase of the cytotoxic activity mediated by NK-stimulated cells, inasmuch as the lytic activity was not affected in the presence of specific NO synthase inhibitors. When aminoguanidine (AMG), an inhibitor of iNOS, was added during the afferent phase of NK stimulation with IL-12 and TNF, a subsequent increase in the lytic potential of the effector cells towards the NK-sensitive target cells (K562) and lymphokine-activated killer (LAK) target cells (Daudi) was observed. Conversely, the addition of chemical NO donors during the afferent step resulted in a dose-dependent inhibition of the NK and LAK cytotoxicity. Our data suggest that the enhancement of NK-cell cytotoxic activity resulting from iNOS inhibition may be correlated, at least in part, to an increase in interferon-γ production and granzyme B expression.

© 1998 by The American Society of Hematology.

The Induction of Nitric Oxide by Interleukin-12 and Tumor Necrosis Factor- in Human Natural Killer Cells: Relationship With the Regulation of Lytic Activity

We have investigated the interleukin-12 (IL-12) and tumor necrosis factor- (TNF)-induced regulation of human natural killer (NK) cell function and their relationship with nitric oxide (NO) generation. We demonstrate that both cytokines were efficient to trigger the transcription of the inducible nitric oxide synthase (iNOS) mRNA, as detected by reverse transcriptase-polymerase chain reaction (RT-PCR). Western blot analysis and intracytoplasmic fluorescence showed that iNOS protein was also induced by both cytokines. However, our data indicate that NO does not play a significant role in the effector phase of the cytotoxic activity mediated by NK-stimulated cells, inasmuch as the lytic activity was not affected in the presence of specific NO synthase inhibitors. When aminoguanidine (AMG), an inhibitor of iNOS, was added during the afferent phase of NK stimulation with IL-12 and TNF, a subsequent increase in the lytic potential of the effector cells towards the NK-sensitive target cells (K562) and lymphokine-activated killer (LAK) target cells (Daudi) was observed. Conversely, the addition of chemical NO donors during the afferent step resulted in a dose-dependent inhibition of the NK and LAK cytotoxicity. Our data suggest that the enhancement of NK-cell cytotoxic activity resulting from iNOS inhibition may be correlated, at least in part, to an increase in interferon-γ production and granzyme B expression.

© 1998 by The American Society of Hematology.

Different pathways of the release of cytotoxic proteins in LAK cells

Human LAK cells were shown to release cytotoxic proteins by both Ca(2+)-dependent and Ca(2+)-independent mechanisms. CD3+ CD8+ CD16- and CD16+ CD8+ CD3- LAK cells were co-incubated with target cells in the presence of 4 mM EGTA. Although EGTA inhibited the exocytosis of cytolytic granules, supernatants obtained were cytotoxic for target cells. Cytotoxicity of CD3+ LAK cells and CD16+ LAK cells was due to cytotoxic proteins with MW 75 (p75), 35 (p35) and 22 (p22) kDa. LAK cells were also shown to release cytotoxic proteins by way of continuous secretion. After co-incubation in the absence of target cells LAK cells can secrete cytotoxic proteins with MW 75 (p75), 55 (p55), 38 (p38), 35 (p35), 25 (p25), 22 (p22) and 17 (p17) kDa.

Molecular mechanisms of lymphocyte-mediated cytotoxicity and their role in immunological protection and pathogenesis in vivo

Studies with perforin-deficient mice have demonstrated that two independent mechanisms account for T cell-mediated cytotoxicity: A main pathway is mediated by the secretion of the pore-forming protein perforin by the cytotoxic T cell, whereas an alternative nonsecretory pathway relies on the interaction of the Fas ligand that is upregulated during T cell activation with the apoptosis-inducing Fas molecule on the target cell. NK cells use the former pathway exclusively. The protective role of the perforin-dependent pathway has been shown for infection with the noncytopathic lymphocytic choriomeningitis virus, for infection with Listeria monocytogenes, and for the elimination of tumor cells by T cells and NK cells. In contrast, perforin-dependent cytotoxicity is not involved in protection against the cytopathic vaccinia virus and vesicular stomatitis virus. LCMV-induced immunopathology and autoimmune diabetes have been found to require perforin-expression. A contribution of perforin-dependent cytotoxicity to the rejection of MHC class I-disparate heart grafts has also been observed. Its absence is efficiently compensated in rejection of fully allogeneic organ or skin grafts. So far, evidence for a role of Fas-dependent cytotoxicity as a T cell effector mechanism in vivo is lacking. Current data suggest that the main function of Fas may be in regulation of the immune response and apparently less at the level of an effector mechanism in host defense. Further analysis is necessary, however, to settle this point finally.

Nitric oxide synthase pathway may mediate human natural killer cell cytotoxicity

The present study provides evidence that the human natural killer (NK) cell effector mechanism causing target cytolysis has a requirement for L-arginine. In a deficient medium (DM) containing only salts, buffer system and glucose, NK cell-mediated cytotoxicity was found to decrease by 70% as compared to that obtained in a complete medium (CM). However, adding L-arginine to such DM could restore the activity of NK cells to the normal level. Many other components of CM, such as serum, glutamine and vitamins did not improve NK cell-mediated killing in DM. When all amino acids except L-arginine were added to DM only a partial recovery of NK cell functional cytolysis was seen. L-arginine enhanced the NK cell activity in a dose-dependent manner. Additionally, the inhibitor of both inducible and constitutive nitric oxide synthase, N-monomethyl-L-arginine (L-NMMA) inhibited NK cytolytic activity in DM supplemented with L-arginine indicating participation of nitric oxide (NO). The results also show that the stimulatory effect of L-arginine on human NK cell-mediated cytotoxicity was accompanied by an increase in NO formation as determined by accumulation of nitrite and citrulline. L-NMMA gave a dose-dependent reduction in NO generation as well. The nitrite and citrulline production dose-dependently correlated with not only the concentration of L-arginine in the cultivation medium, but also the enhanced NK cell-mediated cytolysis. Taken together, these findings could define a L-arginine/NO-linked effector mechanism in human NK cells. Nitrite and citrulline were not formed when NK cell-mediated target cell killing took place in a L-arginine-free DM supplemented with additives. Thus, it appears as if human NK cells may cause target cell killing via both NO-dependent and -independent processes.

Cell-mediated cytotoxicity in perforin-less mice

We have used a perforin-less (PO) mouse to explore alternate CTL-mediated lytic pathways. PO mice are unable to overcome an infection with LCMV in vivo. Nevertheless, splenocytes from infected mice show vigorous, antigen-specific cytotoxicity that requires the presence of the Fas antigen on target cells. The Fas lytic pathway is virtually indistinguishable, in terms of kinetics and magnitude of cytotoxicity, from perforin/granzyme-mediated lysis. It is rapidly induced in CTL upon occupation of the TcR, and requires protein synthesis for full expression. Upon removal of the activating signal, the capacity for fas-mediated lysis rapidly disappears. PO mice infected with LCMV also undergo what appears to be a CD8-mediated immunopathology, and rarely live beyond one month. The precise basis of this pathology is unknown at present. Given the widespread distribution of Fas in mice, particularly on inflamed tissues, the complete failure to clear virus from any tissue or organ is surprising.

Mechanisms of immune-mediated myocyte injury

Much progress has been made in defining the mechanisms by which altered systolic and diastolic function of the heart may be produced by components of the immune system activated during allograft rejection and myocarditis and in patients with dilated cardiomyopathy. It is clear that injury of the vascular bed can occur via both humoral and cellular mediators and probably accounts for the acute alterations in ventricular compliance that occur during allograft rejection, as well as the accelerated development of graft atherosclerosis. Altered myocyte function and lysis can be produced by CTL in vitro, but the importance of this injury process in vivo remains uncertain. Other cells present in the inflammatory infiltrate can also affect myocyte function and survival. Neutrophils may cause lysis of myocytes, and cytokines produced by infiltrating macrophages and HtL may reach a sufficient concentration in the interstitial microenvironment to decrease myocyte catecholamine responsiveness and/or directly depress myocyte contractility. Humoral antibodies to myocyte cell surface antigens may cause cell damage by an antibody-dependent cytotoxic cell mechanism or by directly binding to and altering sarcolemmal receptor and/or ion channel function. Further elucidation of the extent of involvement of these different mechanisms in specific clinical settings may provide a basis for improved therapy of immune-mediated cardiac injury and dysfunction.

Changes in actin organization during the cytotoxic process

Changes in organization of F-actin during the cytotoxic process between NK and K562 cells have been observed and studied using confocal laser scanning microscopy and quantitative fluorescence microscopy. An increase in F-actin content and orientation of F-actin towards the target cell have been observed in conjugated NK cells. The increase in F-actin content probably reflects activation of the NK cell for the killing process. An increase in F-actin content in the conjugated K562 cell, occurring simultaneously with the appearance of filamentous actin structures that often originated/ended at the contact place with the NK cell, was also observed. These changes were delayed compared to the increase in F-actin content in the NK cell and were accompanied by increasing cytotoxic activity. This indicates that they were results of the interaction of the K562 cell with the activated NK cell. The possible role of target cell microfilaments in the cytotoxic process is addressed.

Adoptive immunotherapy of cancer: biological response modifiers and cytotoxic cell therapy

Immunotherapy has been developed for the treatment of metastatic cancers refractory to conventional therapies. Immunotherapy utilizes immune cells and/or biological response modifiers (BRMs) to induce an anti-tumor response mediated by the patient's immune system. BRMs, including lymphokines and cytokines, are used as single agents or in combination for cancer therapy. Some BRMs, particularly interleukin 2 (IL-2), can activate and expand in vitro lymphocytes with anti-tumor reactivity which will be adoptively transferred to the patient. To enhance the therapeutic effect of immunotherapy, gene therapy is currently under investigation and involves the insertion of cytokine genes in immune cells or in tumor cells. The development and future of cancer immunotherapy will be discussed in this review.

How do CTL control virus infections? Evidence for prelytic halt of herpes simplex

Cytotoxic T lymphocytes (CTL) induce in target cells a rapid, prelytic fragmentation of target cell DNA, accompanied by apoptosis. In contrast, complement and (with a few exceptions) chemical and physical means of inducing cytolysis induce necrosis, without DNA fragmentation. The function of the unusual DNA fragmentation induced by CTL remains to be elucidated. The major recognized function of CTL is in halting virus infections. Earlier, we proposed that CTL might halt virus infections prelytically, by fragmenting viral and cellular nucleic acids, and that in this case, cytolysis per se might be a less important function of CTL. We report here experiments designed to detect prelytic halt of virus replication. We employed in vivo-like conditions: fibroblast targets (difficult to lyse) were infected with herpes simplex virus (HSV), then incubated at low E/T cell ratios overnight. At the highest E/T ratios which produced less than 10% CTL-induced lysis, plaque-forming unit yield was reduced by about 50%. At higher E/T ratios which lysed 1/6 to 1/3 of the infected target cells, 3/4 to 9/10 of the virus production was prevented. The discrepancy between the level of lysis and the reduction in virus yield is evidence for significant CTL-induced prelytic halt of HSV replication. At present, it is unclear whether the antiviral effect observed involves an activity of CTL distinct from their lytic ability, such as their DNA fragmenting ability.

Effector mechanisms in organ-specific autoimmunity. I. Characterization of a CD8+ T cell line that mediates murine interstitial nephritis

To further investigate mechanisms of cell-mediated tissue destruction in an organ-specific autoimmune disease, we have established and characterized a nephritogenic CD8+ T cell line. This target antigen-specific effector T cell line, M52, was derived from bulk populations of CD8+ T cells isolated from susceptible animals immunized to produce anti-tubular basement membrane (alpha TBM) disease. Our studies show that M52 retains the phenotypic and functional characteristics of nephritogenic T cells induced in vivo. M52 mediates antigen-specific delayed-type hypersensitivity (DTH) responses to the target antigen 3M-1, it is cytotoxic to 3M-1-expressing renal tubular epithelial cells in vitro, and it adoptively transfers interstitial nephritis to naive syngeneic recipients. Clonal analysis of these nephritogenic CD8+ T cells reveals distinct functional phenotypes within the M52 cell line. We have isolated a cytotoxic CD8+ clone, M52.26, which is not DTH-reactive to 3M-1, and multiple DTH-reactive clones which mediate less efficient cytotoxicity to 3M-1-expressing target cells. Cytofluorographic analysis of four randomly selected clones reveals alpha beta T cell receptor expression. Further characterization of these functionally distinct CD8+ T cell clones will help to define their respective roles in mediating tubular epithelial cell injury and the inflammatory lesion of autoimmune interstitial nephritis.

Cyclosporin A renders target cells resistant to immune cytolysis

Exposure of cytolytically susceptible human target cells with therapeutic concentrations of the immunosuppressive drug cyclosporin A renders these cells highly resistant to T cell-mediated, natural killer (NK) cell-mediated, and complement-mediated cytolysis. The resistance is dose dependent, time dependent and reversible. The resistance is accompanied by target cell growth inhibition as measured by thymidine uptake. Surprisingly, target cell growth inhibition induced by serum depletion is associated with cell-mediated cytolytic resistance. These data suggest that cyclosporin A (CsA) may block some target cell biochemical pathway(s) important in the suicidal cytolytic process which is (are) linked to some G0/G1 cell cycle events. In addition, these results suggest that the increased risk of Epstein-Barr virus (EBV)-associated lymphoproliferative disease in human organ transplant recipients may be contributed to by CsA-induced resistance of EBV-transformed B lymphocytes to immune cytolysis. In the post-transplant setting, CsA probably blocks T cell-dependent responses to EBV-transformed B lymphocytes (Bird, A.G., McLachlan, S.M. and Britton, S., Nature 1981, 289: 300) yet leaving the NK cell and antibody-dependent responses intact (Shao-Hsien, C. et al. Transplantation 1983. 35: 127). However, given the direct effect of CsA upon EBV-transformed B lymphocytes, these cells would be rendered resistant to nearly all forms of cytolytic immune control (cytotoxic T lymphocyte, natural killer, antibody-dependent cell-mediated cytotoxicity, complement). Unregulated EBV-transformed B lymphocytes may then proliferate in the CsA-treated host thus leading to a polyclonal B cell hyperplasia. Our data would suggest that this early pre-malignant process is likely to be reversible following CsA dose reduction. Indeed, EBV-dependent polyclonal B cell hyperplasia is seen in early post-transplant lymphoproliferative disorders (Hanto, D.W., et al., Transplantation 1989, 47: 458). Furthermore, in some cases CsA dose reduction does lead to disease regression (Starzl, T., et al., Lancet 1984. i: 583). However, further progression of the disease probably occurs following chromosomal changes leading to oncogene activation and might be resistant to CsA dose reduction.

Novel putative promoter/enhancer sequences are shared by the mouse and human perforin (Pfp) genes

This report describes the organization of the mouse pore-forming protein (perforin) gene (Pfp), which is highly analogous to that of the corresponding human gene. Pfp comprises three exons, the first of which consists entirely of 5' non-coding sequence, separated by an intron of 1.94 kb from the two polypeptide-coding exons. The promoter region of the gene shows strong similarity to that in humans, with six stretches of high homology noted within 0.7 kb of the mRNA cap site. However, many of the sequences of the human gene with similarity to previously described promoter/enhancer elements are poorly conserved in the mouse, suggesting that these motifs may be of no functional significance, and that control mechanisms for expression of Pfp may be highly specific to killer cells.

Differential effects of protein synthesis inhibition on CTL and targets in cell-mediated cytotoxicity

The reactions that lead to target cell lysis by cytotoxic T cells (CTL) are despite intensive investigations poorly understood. To examine the relative roles effectors and targets play in the lytic reaction, protein synthesis in either CTL or targets was inhibited before assay of lysis. We show, in agreement with previous results, that de novo protein synthesis is not necessary in either effectors or targets during the cytolytic reaction. However, activation of CTL requires protein synthesis. Activated CTL respond to protein synthesis inhibitors with a cycling of activity, a result that is interpreted to be consistent with a stimulus secretion mechanism. Treatment of targets with protein synthesis inhibitors prior to incubation with CTL leads to a very rapid and irreversible loss of lytic susceptibility. It is shown that the decrease in lysability is not due to lack of proper CTL target interaction: MHC class I antigens are expressed on drug-treated targets and these cells serve as cold targets in competitive inhibition experiments. Moreover, drug-treated targets trigger transient Ca2+ mobilization and generation of inositol phosphates in CTL. It is therefore concluded that drug-treated targets are able to trigger CTL function but lack a component that is required for their successful lysis.

Monoclonal antibodies detecting discrete epitopes of human perforin

Perforin is a cytolytic protein of natural killer (NK) cells and cytotoxic T cells (CTL). Purified perforin has been shown to cause cell lysis and to form stable pores in the target cell membrane, but its relevance to cytolysis in vivo is not clear. The gene for human perforin has been cloned, but monoclonal antibodies (mabs) have not been available. In order to study further its role in cytotoxicity, we have generated mabs to different regions of human perforin. Four mabs were produced from mice immunized with hybrid proteins comprising E. coli TrpE protein at the N-terminus and different regions of human perforin at the C-terminus. These proteins were made using the pATH expression plasmids into which fragments of perforin cDNA were subcloned. Monoclonal antibody PA1 was made from a mouse immunized with a hybrid protein containing the C-terminal 240 amino acids (AA) of perforin, PE1 - the N-terminal 118 AA, and PB1 and PB2 - the central 199 AA. The three plasmid constructs contained non-overlapping cDNA segments which covered the entire sequence of perforin. All mabs reacted with the immunizing hybrid protein, but not with the other hybrid proteins, indicating that at least three epitopes are recognized by this set of mabs. All mabs immunoprecipitated a molecule of about 68 kd from lysates of metabolically-labelled cytolytic large granular lymphocytic leukemia cells, but not from control lysates of non-cytolytic promyelocytic U937 cells. These mabs should be of use in determining structure-function relationships for perforin.

Cytopathic action of Naegleria fowleri amoebae on rat neuroblastoma target cells

The axenically cultured, weakly pathogenic Naegleria fowleri LEE and the highly pathogenic, mouse passaged N. fowleri LEEmp are cytopathic for B103 rat nerve cells in culture. Cytopathogenicity was measured by release of radiolabeled rubidium or radiolabeled chromium from B103 target cells. Cytopathogenicity was time-dependent for up to 18 h and dependent upon amoebae effector to nerve cell target ratios of less than 1:1. Release of 51Cr from B103 cells by either LEE or LEEmp amoebae was enhanced by addition of calcium or magnesium to medium free of these divalent cations but the ion-channel inhibitor, verapamil, or the ionophore A23187 and phorbol myristate acetate did not alter release of 51Cr from B103 cells cocultured with the amoebae. Cycloheximide or actinomycin D impaired release of 51Cr from B103 target cells injured by either LEE or LEEmp amoebae. Both strains of amoebae were fractionated by glass bead disruption and high speed centrifugation into membrane and soluble fractions. Each fraction was incubated with either 86Rb or 51Cr labeled nerve cells. The membrane fraction from LEEmp was more active than the soluble fraction in facilitating rubidium and chromium release. In contrast, the soluble fraction from LEE was more active than the membrane fraction in facilitating rubidium release from radiolabeled target cells. The sequential release of 86Rb and 51Cr from target cells rather than the simultaneous release of the two isotopes indicates that target cell death is due to the release of ions followed later by the release of large macromolecules. The results indicate that N. fowleri amoebae injure nerve cells by two alternate mechanisms, trogocytosis or contact-dependent lysis.

Genomic organization of the mouse pore-forming protein (perforin) gene and localization to chromosome 10. Similarities to and differences from C9

Genomic clones encompassing the entire coding region of the mouse lymphocyte pore-forming protein gene (Pfp) have been isolated and used to determine its intron-exon organization. In contrast to C9, Pfp has a simple structure, consisting of only three exons (two of which encode polypeptide), a large 5' intron, and a single, smaller intron that is situated approximately one-third of the way through the protein-coding portions of the gene. The regions encoding the homologous domains of PFP and C9 are encoded on exons 7, 8, 9, and 10 of C9, but form only approximately half of the open reading frame of exon III in Pfp. Although encoding polypeptides with related functions, the two genes possess such sharply contrasting structures as to suggest that their analogous regions may have risen independently, by a process of convergent evolution. Using a panel of somatic cell hybrid cell lines, Pfp has been mapped to chromosome 10.

Evidence that protein kinase C activation is essential for killing by IL-2-activated lymphocytes

Previous pharmacological evidence has suggested that activation of protein kinase C (PKC) is necessary for T and natural killer (NK) killing of different target cells. In the present study we find, using interleukin 2 (IL-2)-activated lymphocytes (LAK cells), that phosphorylation of a well-characterized 80-kDa PKC substrate increases during conjugation to target cells. Furthermore, down-regulation of PKC by pretreatment with the active phorbol esters PDB (24 h) or PMA (2 h), but not with the inactive phorbolester PDD, simultaneously inhibits killing by LAK cells. H-7, an inhibitor of PKC, also inhibited LAK-cell killing without affecting the target-effector cell conjugate formation. We also demonstrate that pretreatment of target cells with phorbol ester (PMA) decreases killing, suggesting that PKC activation in the target cell population may also influence killing although the effect may vary depending on the particular target cell used. We conclude that PKC activation is essential for triggering of lysis in LAK cells.

Interaction of lymphokine-activated killer cells with susceptible targets does not induce second messenger generation and cytolytic granule exocytosis

CTL activation by specific targets leads to a rapid rise of inositol phosphates (InsPs) and of cytoplasmic-free Ca2+ concentration ([Ca2+]i). While these events are considered necessary to trigger granule secretion, Ca2+-independent cytolytic mechanisms have been recently proposed in addition or as an alternative to the classical Ca2+-dependent exocytosis model. We observed that lymphokine-activated killer (LAK) cells, obtained after stimulation with supraoptimal concentrations of IL-2 in short- or long-term cultures, kill susceptible targets in the absence of a [Ca2+]i rise and InsP3 formation. Moreover, LAK cell-mediated lysis was not associated with an increase in cytotoxic granule exocytosis, as evaluated by BLT-esterase release into the culture supernatant. Furthermore, using an antigen-specific CTL clone, which acquires LAK-like activity when cultured in medium containing high IL-2 doses, second messenger generation and cytolytic granule content secretion were not detected during lysis of unrelated target cells, while killing of specific targets triggered both these processes. These findings suggest that two lytic pathways may coexist in the same effector cells: a second messenger-dependent pathway involving degranulation, which is activated after TCR interaction with specific targets, and another pathway, independent of any known second messenger generation, responsible for unrelated target cell lysis.

Natural killer cells and cytotoxic T cells induce DNA fragmentation in both human and murine target cells in vitro

DNA fragmentation induced by cytolytic lymphocytes in human erythromyeloid cell line K562 and murine T lymphoma cell line YAC-1 was investigated by means of agarose gel electrophoresis. Murine natural killer (NK) and cytotoxic T (Tc) cells induced DNA fragmentation in YAC-1 cells, with the fragments being approximately multiples of 180 bp. More significantly, murine NK cells can induce a similar pattern of DNA fragmentation in human K562 cells. Therefore, cytolytic lymphocytes can induce apoptosis or programmed cell death in human target cells.

Detection of perforin and granzyme A mRNA in infiltrating cells during infection of mice with lymphocytic choriomeningitis virus

The analysis of gene expression in cytotoxic T cells by in situ hybridization of serial liver and brain sections from mice infected with lymphocytic choriomeningitis virus (LCMV) and immunostaining with T cell marker- and virus-specific antibodies revealed a close histological association of infiltrating lymphocytes expressing the perforin and granzyme A genes with virally infected cells. Maximal frequency of perforin and granzyme A mRNA-containing cells on liver sections preceded by about 2 days maximal LCMV-specific cytotoxicity of the lymphoid liver infiltrating cells. These results are most consistent with an involvement of perforin and granzyme A in cell-mediated cytotoxicity in vivo.

In vivo expression of perforin by CD8+ lymphocytes during an acute viral infection

CTL and NK cells cultured in vitro have been shown to contain a cytolytic pore-forming protein (PFP/perforin/cytolysin). To date, it has not been determined whether perforin is expressed by CTL that have been primed in vivo. Here, we have infected mice with two strains of lymphocytic choriomeningitis virus (LCMV), one of which mainly produces choriomeningitis and, the other, hepatitis. Brain and liver cryostat sections obtained from LCMV-infected mice were stained for various lymphocyte markers, including perforin. We were able to detect a large accumulation of perforin antigen in CD8+/Thy-1+/asialo GM1+/CD4- lymphocytes, which in fact represent the main infiltrating cell type found in brain and liver sections obtained during the late acute stage of LCMV infection. Perforin was also detected in a smaller population of CD8-/asialo GM1+/NK 1.1+/F480- cells, presumably corresponding to NK cells. Perforin-positive cells were found to have the morphology of blasts or large granular lymphocytes (LGL). These observations, together with in vitro studies performed in the past, indicate that perforin may be associated exclusively with LGL-like CTL blasts and NK cells. Our results demonstrate for the first time the presence of perforin in CTL that have been primed in vivo and suggest that perforin-positive CTL may be directly involved in producing the immunopathology associated with the LCMV infection.

Generation and partial characterization of melanoma sublines resistant to lymphokine activated killer (LAK) cells. Relevance to doxorubicin resistance

To see whether a tumor cell population may contain cells resistant to lymphokine-activated killer (LAK) lymphocytes, cells from a LAK-sensitive melanoma line (Me 665/2) were co-cultured with LAKs. Three sublines were obtained after 1, 2 or 3 immunoselection cycles. Immunoselected (IS) sublines show reduced proliferation, decreased reactivity to the monoclonal antibody (MAb) R24 and appeared morphologically more differentiated in comparison with the parental Me 665/2 line. A progressively reduced sensitivity to LAKs was observed in IS sublines with a more than 8-fold reduction in LAK susceptibility. A reduced complement (C)-mediated lysis was also observed in IS sublines. Since we have previously shown that LAK sensitivity of melanoma cells may be associated with Doxorubicin (Dx) resistance, the sensitivity to Dx was tested in these lines. An augmented sensitivity to Dx was noted in IS sublines as compared with Me 665/2. The differences in LAK susceptibility between the IS sublines and the parental Me 665/2 line remained stable for 2 weeks but declined and disappeared thereafter. These results indicate that (1) a LAK-sensitive tumor line may contain a subpopulation of cells which are significantly less lysed by LAKs; (2) a correlation between LAK sensitivity and susceptibility to C-mediated lysis is also present; and (3) increased sensitivity to Dx is evident in the IS sublines.

Function and regulation of lymphocyte-mediated immune responses: relevance to bovine mastitis

Bovine mastitis is one of the most costly diseases to the dairy industry. Prospects for effective vaccines are limited by the variety of microorganisms capable of causing mastitis. An understanding of the physiologic and immunologic factors controlling the susceptibility of the cow to disease will lead to more rational approaches to prevention and control. In this paper, we describe the basic components of the immune system, drawing upon information derived from studies with rodents and humans. Some of these findings have been confirmed in the bovine and other domestic species, and it is likely that further study will reveal additional similarities between the immune systems of laboratory animals, humans, and domestic animals. Some important differences have already been identified, such as altered lymphocyte circulation patterns in ruminant versus non-ruminant species. These differences are discussed. We describe the structural and functional properties of major histocompatibility complex antigens and their role in regulation of immune responses. Finally, we discuss the consequences of antigen-induced activation of T-lymphocytes and the role of these cells in response to disease-causing microorganisms.

CTL: virus control cells first and cytolytic cells second? DNA fragmentation, apoptosis and the prelytic halt hypothesis

It is usually presumed that cytotoxic T lymphocytes (CTL) stop viral replication by lysing infected cells before a full virus yield has been assembled. Unlike complement-mediated lysis, however, CTL induce apoptosis, including fragmentation of target cell DNA. Why should CTL do this? Here, Eric Martz and Donna Howell suggest that since the major function of CTL appears to be control of viruses, CTL may be able to halt viral replication without inducing rapid lysis. It may be more useful to think of CTL as virus control cells rather than as cytolytic cells.

Susceptibility of human and murine drug-resistant tumor cells to the lytic activity of rIL2-activated lymphocytes (LAK)

This article surveys the available data on the sensitivity of drug-resistant tumor cells to recombinant interleukin 2 (rIL2)-activated lymphocytes (LAK). In our own study, three different experimental systems were used: 1. in vitro treatment of tumor cells with an anticancer drug followed by the use of surviving cells as targets of LAK; 2. use of pairs of drug-resistant and drug-sensitive cell sublines; 3. analysis of several tumor clones obtained from the same tumor. The antitumor activity of LAK was evaluated both by the 51Cr release and the human tumor clonogenic assay (HTCA). In all the experimental systems used, drug-resistant tumor cells were found to be significantly lysed by LAK, with a consistent trend towards a higher susceptibility than their drug-sensitive counterparts. A positive correlation between the sensitivity to LAK and the ID50 for doxorubicin (Dx) was found in 44 melanoma clones analyzed, suggesting that spontaneously drug-resistant clones have a higher sensitivity to LAK than the drug-sensitive clones. Drug-resistant cells were also more sensitive to antibody and complement-mediated lysis, whereas the higher lysis of drug-resistant tumor cells exerted by LAK was maintained in a lectin dependent cytotoxicity assay. These data offer a rationale for combining chemotherapy with adoptive immunotherapy in the treatment of cancer. Moreover, studying the reasons for the higher LAK sensitivity of drug-resistant tumor cells may provide insights into the mechanisms by which tumor cells can resist LAK action.