Cytotoxic mechanisms of murine lymphokine-activated killer cells: functional and biochemical characterization of homogeneous populations of spleen LAK cells

Nonlymphoid cultured cells possess a system controlling cellular compatibility

We show that various nonlymphoid cultured cells can activate the production of cytotoxic factors in response to direct contact with cells of a different kind. Accumulation of cytotoxic factors in the medium was detected 1 h after contact of K562 and L929 cells or after contact of L929 cells with purified membranes of K562 cells. TNF-alpha or immunologically related proteins, or both, but not Fas-ligand or lymphotoxin, were also accumulated in membranes of K562 and L929 cells shortly after these cells had been allowed to contact each other. The cytotoxic factors expressed by nonlymphoid cells trigger apoptosis of target cells. These observations strongly suggest that nonlymphoid cells possess molecular mechanisms controlling cellular compatibility.

Cytolytic effector mechanisms of human CD4+ cytotoxic T lymphocytes

To elucidate mechanisms by which human CD4+ cells mediated cytolytic activity, we studied the expression of cytolytic proteins and the effects of inhibitors and mAbs on T-cell clones. Of seven cytolytic CD4+ clones, three were specific for the HLA-DR17, while four recognized DR18. Anti-HLA-DR mAb and anti-CD4 mAb blocked lysis. In addition, N alpha-p-tosyl-L-lysine chloromethylketone (TLCK), a serine esterase inhibitor, as well as cytochalasin B and monensin, antagonists of secretory pathways, inhibited CD4+ CTLs, whereas the absence of extracellular Ca+2 or the presence of Ca+2 channel blockers partially inhibited cytotoxicity. CD4+ CTLs induced apoptosis of target cell nuclei and membrane damage simultaneously. The CD4+ clones synthesized perforin and granzyme B and expressed the granule-associated protein TIA-1. Our studies indicate that two distinct mechanisms may contribute to cytolysis by CD4+ clones: (1) a Ca+2-dependent mechanism associated with the cytotoxic granules and (2) a Ca+2-insensitive mechanism.

Ethanol consumption reduces the cytolytic activity of lymphokine-activated killer cells

Ethanol (20% w/v) given to female C57BL/6 mice in their drinking water reduces splenic natural killer (NK) cell cytolytic activity after 2, 4, and 10 weeks of consumption. This reduction is transient because the levels of NK cell cytotoxicity from ethanol-consuming mice are nearly equal to those of water-drinking mice after splenocytes were incubated in 1000 IU/ml of recombinant interleukin-2 (rIL2) for 16-18 hr. In this study, mice were given 20% w/v ethanol in the drinking water for 2 weeks. Splenic NK cells were enriched up to 88% by negative selection based on surface expression of NK1.1. Enriched NK cells were expanded in rIL2 for 6 days. Lymphokine-activated killer (LAK) cells from both ethanol-consuming and water-drinking mice were > 95% NK1.1+. LAK cell cytolytic activity was significantly lower against NK-insensitive P815 mastocytoma [6.67 +/- 2.18 vs. 17.21 +/- 1.8 lytic units (LUs), p < 0.01], moderately NK-sensitive B16 melanoma (25.3 +/- 6.6 vs. 66.2 +/- 14.2 LU, p < 0.05), and NK-sensitive YAC-1 lymphoma targets (80.5 +/- 34.7 vs. 177.0 +/- 43.6 LU, p < 0.005) in cells from ethanol-consuming mice compared with water-drinking controls. Ethanol consumption did not affect the morphology or phenotype of LAK cells with respect to surface expression of NK1.1, B220, CD3, CD25, CD11a, CD54, CD45RB, or class I major histocompatibility complex.

Membrane-associated lymphotoxin expression and functional analysis of lymphokine-activated killer cells derived from tumor-infiltrating lymphocytes

The expression of a membrane-associated lymphotoxin molecule (mLT) on lymphokine-activated killer (LAK) cells obtained from 18 patients with malignant tumors and its role in the tumor cell killing mechanisms were investigated. LAK cells from tumor-infiltrating lymphocytes (TIL-LAK cells) were mainly composed of CD3-positive cells, whereas LAK cells from peripheral blood lymphocytes (PBL-LAK cells) were mainly composed of CD16- and CD56-positive cells. However, mLT was found to be expressed on TIL-LAK cells as well as PBL-LAK cells. The degree of mLT expression correlated with the killing activity of LAK cells towards L929 cells (r = 0.806, P < 0.01, n = 15), but not with that towards Daudi or K562 cells. Although the degree of mLT expression correlated with the amount of secreted lymphotoxin (LT) in the supernatant of LAK cell culture, the secreted LT itself could not account for the tumor cell killing activity of LAK cells. Polyclonal rabbit anti-LT antibody partially inhibited the killing activities of LAK cells towards L929 cells and this inhibition was found in the combination of autologous tumor cells and PBL-LAK cells. These findings suggest the possibility that the mLT-related cytotoxicity is involved in the tumor cell killing mechanisms of TIL-LAK cells as well as PBL-LAK cells.

Time-dependent changes of LAK cell phenotypes correlate with the secretion of different cytotoxic proteins

Human lymphokine-activated killer (LAK) cells were generated from peripheral blood lymphocytes (PBL) of normal volunteers by interleukin-2 (IL-2) stimulation for 1-8 days. During the first 3 days the surface marker CD16 characteristic for natural killer (NK) cells was expressed and later the CD3 marker characteristic for cytotoxic T cells became predominant. The conditioned media of LAK cells collected after interaction of LAK cells with K562 target cells was chromatographically separated into two cytotoxic fractions: F1 and F2. It was demonstrated that fraction F1 contained cytotoxic proteins having molecular weights of 30 and 40 kDa, and fraction F2 contained cytotoxic proteins having molecular weights of 22, 38 and 75 kDa. The presence of the proteins in each of these two fractions correlated with the phenotype changes of LAK cells: the F2 cytotoxic proteins were characteristic for NK-like cells, and the F1 proteins for cytotoxic T-lymphocyte (CTL)-like phenotypes.

Correlation between killing activity towards the murine L929 cell line and expression of membrane-associated lymphotoxin-related molecule of human lymphokine-activated killer cells

Human lymphokine-activated killer (LAK) cells expressed a membrane-associated lymphotoxin-related molecule (mLT) which was detected by flow cytometric analysis with anti-lymphotoxin antibody. Upon removal of exogenous interleukin-2 from LAK cell culture medium and another 24 h cultivation, the expression of mLT was decreased. Corresponding to the decrease of mLT expression, the killing activity of LAK cells towards L929 cells was remarkably reduced and killing of MIA PaCa-2 and U937 cells was moderately reduced, whereas killing of Daudi and K562 cells was fully restored. The supernatant of mLT-expressing LAK cells had no cytotoxic activity towards L929 cells in the absence of actinomycin D. Moreover, not only the killing of L929 cells but also that of human tumor cell lines (MIA PaCa-2, U937) by mLT-expressing LAK cells was partially inhibited in the presence of anti-lymphotoxin antibody. These results suggest an involvement of mLT in the killing of some tumor target cells by LAK cells.

Different signaling pathways induced by alpha-CD3 monoclonal antibody versus alloantigen on the basis of differential ornithine sensitivity

Previously we reported that 10 mM ornithine (Orn) selectively inhibits the development of CD8+ CTL in MLC. Herein we show that induction by alpha-CD3 mAb of CD8+ killer cells which manifest antibody-redirected cytotoxicity (ARC) of FcR+ targets is not Orn sensitive. Orn resistance was independent of activation kinetics or alpha-CD3 mAb concentration. alpha-CD3 mAb added to the cytotoxicity assay did not reveal a cytolytic potential in CTL from an Orn-treated MLC when the target cells bore both the inducing alloantigen and FcR. Addition of alpha-CD3 mAb to MLC failed to overcome Orn inhibition of CTL and yet induced ARC activity in the same culture. Expression of mRNA for pore-forming proteins (PFP) and granzyme B was inhibited by Orn in CTL but not in ARC killer cells. Our results demonstrate differences in the T cell activation process stimulated by alloantigen or alpha-CD3 mAb.

Programmed cell death: concept, mechanism and control

Programmed cell death or apoptosis occurs under physiological conditions as a result of physiological effectors. It is a relatively slower process and requires active participation of the cell in the suicidal mechanism. Apoptosis is controlled by precise intrinsic genetic programme and may be induced by almost all those stimuli causing necrosis. The role played by the intensity in determining the death process and the underlying mechanism is imperfectly understood. Morphologically apoptotic cells appear as small condensed body. The chromatin is dense and fragmented, packed into compact membrane-bound bodies together with randomly distributed cell organelles. The plasma membrane loses its characteristic architecture and shows extensive blebbing. It buds off projections so that the whole cell may split into several membrane-bound apoptotic bodies. Significant chemical changes take place in the plasma membrane. This helps in recognition of the apoptotic bodies by phagocytes. At this moment it is unclear if all cells can undergo apoptosis or it is a characteristic of only some tissues which are predisposed to apoptotic death being directly under the control of hormones or growth factors. Experimental studies aimed at comparison of induction of apoptosis in cells of different origin are warranted to elucidate this point. Biochemically a pre-commitment step for induction of death programmation through macromolecular synthesis is essential for most systems. The double-stranded linker DNA between nucleosomes is cleaved at regular inter-nucleosomal sites through the action of a Ca2+, Mg(2+)-sensitive neutral endonuclease. Zinc is a potent inhibitor of the enzyme. Calcium probably plays a key controlling role in activation of the enzyme since prevention of Ca2+ increase prevents endonuclease activation. It is becoming evident that signal transduction through appropriate receptors control the Ca2+ flux in the cells. Most apoptotic cells require synthesis of RNA and proteins. Delay or abrogation of apoptosis by inhibition of macromolecular synthesis is well known. The dying cells show high mRNA levels for several enzymes. Several degradative enzymes become active. Regulatory proteins maintain control over the apoptotic cascade. At the molecular level, search has been initiated for the mammalian equivalents of the cell death (ced) gene. Activation of several specific genes is indicated. Specific expression of cell death-associated gene products (e.g. TRPM-2/SGP-2) has been reported in several unrelated apoptotic cell systems. Sequential induction of c-fos, c-myc and 70 kDa heat shock protein is reported. Studies demonstrate that certain genes must remain in a transcriptionally active demethylated state during programmed cell death. Recent evidences clearly indicate that apoptosis may be positively or negatively modulated by certain genes.(ABSTRACT TRUNCATED AT 400 WORDS)

Expression and utilization of chymotrypsin-like but not trypsin-like serine protease enzymes by nonspecific T killer cells activated by anti-CD3 monoclonal antibody

Coculture of purified murine T cells with anti-CD3 monoclonal antibody (145-2C11) results in the induction of nonspecific cytotoxic T lymphocytes (CTL) with MHC-unrestricted cytolytic activity against a range of tumor targets. Serine proteases associated with effector cell granules are among the molecules postulated to play a role in cell-mediated cytolysis. The present study examines the ability of exogenous serine protease substrates to inhibit anti-CD3-activated cytotoxic T (ACT) cell-mediated killing of P815 mastocytoma and YAC1.2 lymphoma target cells. The chymotrypsin substrate N-acetyl-L-tyrosine ethyl ester (ATEE) was found to significantly inhibit ACT cell-mediated cytolysis. In contrast, the trypsin substrate N-benzoyl-L-arginine ethyl ester (BAEE) had little, if any, effect on ACT cell-mediated cytolysis. These effects were observed with both target cell populations. Conjugate inhibition studies performed with ATEE indicated that a chymotrypsin-like serine protease is involved in a postbinding event during cytolysis. Pretreatment of either target or effector cells with ATEE prior to cytolytic assay revealed that the chymotrypsin-like serine protease involved in cytotoxicity is of effector cell origin. Northern blot analysis of total RNA extracted from ACT cells revealed the presence of transcripts coding for CCP1 and CCP2 serine proteases known to be involved in antigen-specific CTL function, but little or no expression of the HF serine protease which has also been implicated in antigen-specific CTL killing. CCP2 exhibits chymotrypsin-like activity while HF displays trypsin-like activity. On the other hand, the CCP1 gene product has protease activity which resembles neither chymase nor tryptase activities. Thus, the level of mRNA expression for these serine proteases is consistent with our earlier observations, using the serine protease substrates, that a chymotrypsin-like serine protease but not a trypsin-like serine protease is involved in ACT cell-mediated cytolysis. "Lymphocyte panning" of ACT cells revealed abundant CCP1 and moderate CCP2 mRNA expression in CD4- and CD8+ anti-CD3-activated T cells with strong tumoricidal activity. CD8- anti-CD3-activated T cells with moderate cytolytic activity also expressed substantial levels of CCP1 and CCP2 mRNA, suggesting that both CD4- CD8- and CD4- CD8+ ACT cells participate in killing tumor targets. In contrast, CD4+ anti-CD3-activated T cells lacked both cytolytic activity and significant CCP1 and CCP2 mRNA expression. These findings are consistent with the involvement of chymotrypsin-like, as well as other, serine proteases in CTL-mediated lysis.

CD4+ T cell-mediated killing of major histocompatibility complex class II-positive antigen-presenting cells (APC) III. CD4+ cytotoxic T cells induce apoptosis of APC

A subset of CD4+ T cells, belonging to the T helper type 1 (Th1) cells, kills antigen-presenting cells (APC) in an antigen-specific and major histocompatibility (MHC) class II-restricted way. Evidence is presented that CD4+ cytotoxic T lymphocytes (CTL) induce apoptosis or programmed cell death within susceptible APC as witnessed by quantitative DNA fragmentation. Apoptosis is more reliable to determine cell death than the 51Cr-release assay, because some cells demonstrate resistance to CD4-mediated lysis in the 51Cr-release assay. Apoptosis becomes manifest after 2 to 4 h of incubation preceding the disintegration of the target cells which is detectable between 12 and 24 h as measured by the 51Cr-release assay. Unstimulated B cells, which are not killed, but function as APC, do not undergo apoptosis, whereas lipopolysaccharide or anti-mu-activated B cell blasts show apoptosis and are efficiently lysed. Several CD4+ Th2-type cells tested, which did not demonstrate killing of APC as measured by the 51Cr-release assay, are unable to mediate programmed cell death of appropriate APC. Actinomycin D or cycloheximide, inhibitors of transcription and translation, respectively, fail to prevent apoptosis of APC excluding the involvement of newly synthesized soluble products as mediators of killing. Pretreatment of CD4+ CTL, but not of APC with 4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid, a specific inhibitor of the anion transport, efficiently prevents apoptosis of APC, although the secretion of interleukins is not affected. We propose, that upon contact of the CD4+ CTL with APC, molecules of yet undefined nature are activated and released in a polar fashion at the contact site and induce the endogenous pathway of programmed cell death.

Expression of perforin and granzymes in vivo: potential diagnostic markers for activated cytotoxic cells

Perforin and granzymes are considered to be instrumental in cell-mediated cytolysis by cytotoxic T cells and natural killer cells. Here, Gillian Griffiths and Christoph Mueller describe the expression of perforin and granzymes, emphasizing studies in vivo, and discuss the possibility that these proteins are useful diagnostic markers for immune responses involving cytolytic cells.

Plasma membrane-associated proteins with the ability to partially inhibit perforin-mediated lysis

Cytolytic lymphocytes have previously been reported to be resistant to the lytic effects of perforin. In this work, plasma membrane proteins from a CTL cell line were fractionated by HPLC, and the eluted fractions were collected based on their ability to inhibit perforin-mediated hemolysis. Three proteins with inhibitory activity were thus purified, the serine esterase MCSP-3/granzyme F and the histones H2B and H3. A commercial source of H2B was able to potently inhibit perforin-mediated lysis, and it was confirmed by FACS analysis that H2B is in fact present on the surface of cytolytic cells. However, H2B was also found on the surface of perforin-susceptible tumor cell lines, indicating that the histones may partially inhibit perforin-mediated lysis in vitro, but that they do not represent the factor conferring specific resistance on cytolytic lymphocytes. The origin of the surface histones and the possible role of the surface MCSP-3/granzyme F are discussed.

Functional importance of CD4+ and CD8+ cells in cytotoxic lymphocytes activity and associated gene expression. Impact on the age-related decline in lytic activity

Previously we found that the age-related decline in cytotoxic lymphocyte (CTL) activity in a murine allogeneic system is associated with declining expression of the perforin and two serine esterase genes by senescent CTL. To identify the cell subsets responsible for the age-related decrement in the generation of CTL, splenic T cells, subsets, and mixtures of subsets from aging and young BALB/c female mice were analyzed for their allo-responsiveness to C57BL/6 spleen cells. Depletion studies revealed that CD8+ cells expressed both the lytic activity and the CTL-associated genes, although both CD8+ and CD4+ cells were required for generation of optimal lytic and proliferative responses. Mixture experiments demonstrated that the reduced lytic activity generated by CD8+ cells from the spleens of old mice is a consequence of alterations in both CD8+ and CD4+ cells. The results of experiments in which CD4+ cells from young and old mice were mixed revealed that the alteration in CD4+ cells is consistent with a loss of function. These findings show that (a) the expression of the perforin and serine esterase genes in primary CTL is associated with CD8+ T cells in old and young mice, and exhibits an age-related decrement consistent with that for lytic activity, and (b) the senescent decline in CTL activity is a consequence of aging decreasing activity in both the CD4+ and CD8+ subsets.

A high molecular weight cytotoxic lymphokine in supernatants of lymphokine-activated killer cells cross-reacts with transforming growth factor beta

Supernatants of lymphokine-activated killer (LAK) cells were highly cytotoxic for melanoma A375 cells. A high-molecular-weight fraction was isolated from such supernatants by gel filtration on an S-300 Sephacryl column (Fraction 1; Fr1). The cytotoxic activity in Fr1 was heat- and acid-resistant and was completely abolished by a rabbit antibody against TGF-beta. We conclude that Fr1 contains TGF-beta or a cross-reactive molecule, associated with a high-molecular-weight carrier.