Resistance of normal, unstimulated, CD8+ T cells to lysis by cytotoxic granules from cloned T cell lines

Previous work has shown that both long-term cloned cytotoxic T lymphocyte (CTL) lines and primary CD8+ CTL are resistant to lysis by the toxic granules purified from long-term cloned CTL cell lines. We show here that normal, unstimulated CD8+ spleen and thymus cells are also relatively resistant to lysis by these granules. Using flow cytometric analysis we demonstrate that CD8+ T cells in normal spleen and thymus cell populations are enriched by subjecting the total cell population to lysis by cytolytic granules. Similar enrichment was not seen when the total cell populations were subjected to lysis by melittin, an unrelated, cytolytic, pore-forming polypeptide.

Perforin mRNA in primary peritoneal exudate cytotoxic T lymphocytes

Considerable evidence indicates that cloned CTL cell lines kill target cells by releasing toxic granules that contain a cytolytic protein, called perforin, and several serine esterases (granzymes A to F). However, primary CTL, such as the highly cytolytic peritoneal exudate lymphocyte (PEL) cell population, have been found by a hemolytic assay to have no perforin, or perhaps only borderline levels of that protein, suggesting that these cells use a different lytic mechanism. To determine whether or not primary CTL express the perforin gene, we have here compared mRNA from PEL CTL and from a cloned CTL cell line, 2C, by Northern blot analysis using a perforin cDNA probe. CD8+ PEL CTL contain approximately 30% of the amount of perforin message present in 2C. Moreover, depletion of CD8+ T cells from the total peritoneal exudate cell population removes both cytolytic activity and perforin message. We have previously shown that PEL CTL elicit the same changes in target cells as cloned CTL cell lines and are resistant to lysis by the toxic granules purified from these cells lines. Taken together these results are consistent with the view that primary CTL, as well as long term cloned CTL cell lines, exercise their cytolytic activity by means of perforin.

Perforin mRNA in primary peritoneal exudate cytotoxic T lymphocytes

Considerable evidence indicates that cloned CTL cell lines kill target cells by releasing toxic granules that contain a cytolytic protein, called perforin, and several serine esterases (granzymes A to F). However, primary CTL, such as the highly cytolytic peritoneal exudate lymphocyte (PEL) cell population, have been found by a hemolytic assay to have no perforin, or perhaps only borderline levels of that protein, suggesting that these cells use a different lytic mechanism. To determine whether or not primary CTL express the perforin gene, we have here compared mRNA from PEL CTL and from a cloned CTL cell line, 2C, by Northern blot analysis using a perforin cDNA probe. CD8+ PEL CTL contain approximately 30% of the amount of perforin message present in 2C. Moreover, depletion of CD8+ T cells from the total peritoneal exudate cell population removes both cytolytic activity and perforin message. We have previously shown that PEL CTL elicit the same changes in target cells as cloned CTL cell lines and are resistant to lysis by the toxic granules purified from these cells lines. Taken together these results are consistent with the view that primary CTL, as well as long term cloned CTL cell lines, exercise their cytolytic activity by means of perforin.

Target cell lysis by cytotoxic T lymphocytes that lack detectable hemolytic perforin activity

When mouse target cells are subjected to cytolytic attack by mouse CTL cell lines that have been cultured for many months in high levels of IL-2, and have abundant perforin-rich secretory granules, they exhibit two prominent changes: 1) rapid and massive increase (greater than 10-fold) in intracellular Ca2+ concentration and 2) fragmentation of DNA into nucleosome-sized fragments. We show here that when the same target cells are subjected to cytolytic attack by perforin-deficient CTL, either human CTL or primary mouse CTL from peritoneal exudates, the same changes are observed, suggesting that perforin-rich and perforin-deficient CTL kill their target cells by similar (if not identical) mechanisms. It is possible that perforin-deficient CTL produce enough perforin to destroy target cells but not enough to be detected by currently available methods.

Resistance of primary CD8+ cytotoxic T lymphocytes to lysis by cytotoxic granules from cloned T cell lines

Recent evidence has shown that cloned, murine CTL cell lines are resistant to the cytotoxic components of the toxic granules they release upon specific interaction with their target cells. Inasmuch as the resistance might be due to selection in culture over many months by repeated exposure to these cytolytic components (which are released repeatedly as a result of the cultured CTL being periodically stimulated by target cells), we asked whether primary CTL are also resistant. The primary CTL were elicited in vivo by i.p. injection of allogeneic tumor cells or in vitro by 5- to 6-day MLC or by 48-h exposure to the lectin Con A. The responding cells were separated into purified CD8+ (i.e., CD4-, CD8+) and purified CD4+ (i.e., CD4+, CD8-) T cell populations that were analyzed for cytolytic activity and for resistance to lysis by toxic secretory granules derived from cloned CTL cell lines. The CD8+ T cells were highly cytolytic and relatively resistant; they retained their cytolytic activity and were lysed to a minimal extent (0 to 10%) by quantities of isolated granules that lysed 80 to 90% of the P815 tumor cell line (tested as a representative standard cell line). The CD4+ T cells, in contrast, had only minimal cytolytic activity and were far more susceptible to granule-mediated lysis. Although the resistance of primary CD8+ T cells is impressive, it is not as pronounced as the resistance of the cloned CTL cell lines, indicating that during long-term culture there is some selection for increased resistance to granule-mediated lysis. In contrast to T cells (especially CD8+ T cells), Ia+ macrophages, isolated from primary immune peritoneal exudates, were highly susceptible to granule-mediated lysis.

Resistance of primary CD8+ cytotoxic T lymphocytes to lysis by cytotoxic granules from cloned T cell lines

Recent evidence has shown that cloned, murine CTL cell lines are resistant to the cytotoxic components of the toxic granules they release upon specific interaction with their target cells. Inasmuch as the resistance might be due to selection in culture over many months by repeated exposure to these cytolytic components (which are released repeatedly as a result of the cultured CTL being periodically stimulated by target cells), we asked whether primary CTL are also resistant. The primary CTL were elicited in vivo by i.p. injection of allogeneic tumor cells or in vitro by 5- to 6-day MLC or by 48-h exposure to the lectin Con A. The responding cells were separated into purified CD8+ (i.e., CD4-, CD8+) and purified CD4+ (i.e., CD4+, CD8-) T cell populations that were analyzed for cytolytic activity and for resistance to lysis by toxic secretory granules derived from cloned CTL cell lines. The CD8+ T cells were highly cytolytic and relatively resistant; they retained their cytolytic activity and were lysed to a minimal extent (0 to 10%) by quantities of isolated granules that lysed 80 to 90% of the P815 tumor cell line (tested as a representative standard cell line). The CD4+ T cells, in contrast, had only minimal cytolytic activity and were far more susceptible to granule-mediated lysis. Although the resistance of primary CD8+ T cells is impressive, it is not as pronounced as the resistance of the cloned CTL cell lines, indicating that during long-term culture there is some selection for increased resistance to granule-mediated lysis. In contrast to T cells (especially CD8+ T cells), Ia+ macrophages, isolated from primary immune peritoneal exudates, were highly susceptible to granule-mediated lysis.

Target cell lysis by cytotoxic T lymphocytes that lack detectable hemolytic perforin activity

When mouse target cells are subjected to cytolytic attack by mouse CTL cell lines that have been cultured for many months in high levels of IL-2, and have abundant perforin-rich secretory granules, they exhibit two prominent changes: 1) rapid and massive increase (greater than 10-fold) in intracellular Ca2+ concentration and 2) fragmentation of DNA into nucleosome-sized fragments. We show here that when the same target cells are subjected to cytolytic attack by perforin-deficient CTL, either human CTL or primary mouse CTL from peritoneal exudates, the same changes are observed, suggesting that perforin-rich and perforin-deficient CTL kill their target cells by similar (if not identical) mechanisms. It is possible that perforin-deficient CTL produce enough perforin to destroy target cells but not enough to be detected by currently available methods.

Allorecognition of purified major histocompatibility complex glycoproteins by cytotoxic T lymphocytes

To investigate how T cells recognize allogeneic class I proteins encoded by the major histocompatibility complex (MHC), we examined the human cytotoxic T lymphocytes (CTL) elicited in a mixed lymphocyte reaction against a lymphoblastoid B-cell line (JY) whose MHC-class I proteins are HLA-A2 and -B7. By panning the responding T cells on plates that were coated with purified HLA-A2, an essentially pure population of CD8+ anti-HLA-A2 CTL was isolated in a single step and established as a cell line designated A2p. In addition to lysing HLA-A2+ target cells, the A2p cells lysed HLA-A2- cells, including mouse cells (P815), when purified native HLA-A2 was attached to them, but not when denatured HLA-A2 was attached. Thus, contrary to the general rule that T cells recognize sequential antigenic determinants in denatured protein antigens, the alloreactive CTLs appear to recognize determinants that depend upon the native configuration of HLA-A2; however, the possibility that these T cells recognize a peptide adduct persistently associated with purified, soluble HLA-A2 has not been ruled out.

A comparison of the cytolytic properties of murine primary CD8+ cytotoxic T lymphocytes and cloned cytotoxic T cell lines

Lysates of many highly cytolytic murine primary CD8+ cytotoxic T lymphocytes (CTLs) have no detectable hemolytic activity and only traces of serine esterase activity, indicating a striking paucity or absence of the perforin-rich secretory granules that are abundant in the cytoplasm of murine cloned CTL cell lines. Nevertheless, the primary CTLs are almost as resistant to granule-mediated lysis as CTL cell lines. Moreover, target cells that are lysed by all CTLs so far tested, whether primary or cell lines, show similar rapid and marked increases in intracellular calcium and breakdown of DNA into nucleosome-sized fragments. A parsimonious explanation for all of these findings is that primary CTLs, like the CTL cell lines, exercise their cytolytic activity by means of perforin, but the amounts needed are extremely small and below the level of detection by the current relatively insensitive hemolytic assays.

Serine esterase and hemolytic activity in human cloned cytotoxic T lymphocytes

Target cell lysis by most murine cytotoxic T lymphocytes appears to be mediated by a complement (C9)-like protein called perforin, contained in high-density cytoplasmic granules. These granules also contain high levels of serine esterase activity, which may also play a role in cytolysis. Analysis of 17 cloned human cytotoxic T lymphocytes revealed the presence of serine esterase that is very similar to its murine counterpart in substrate and inhibitor specificities, pH optimum, and molecular mass; dot blot hybridization with synthetic oligonucleotides corresponding to the active sites of two known murine CTL esterases suggests homology to the murine enzyme HF. However, serine esterase was present at only approximately 10% of the level found in murine CTLs, and was not secreted during CTL-target cell interaction; moreover, hemolytic activity could not be detected in any of the seven cell lines tested. The results suggest that the human CTLs examined here kill their target cells by a mechanism different from that used by most cloned murine CTLs.

Calcium ion concentrations and DNA fragmentation in target cell destruction by murine cloned cytotoxic T lymphocytes

To investigate the destruction of target cells by murine CTLs, we examined intracellular Ca2+ concentrations ([Ca2+]i) and DNA fragmentation in target cells. Changes in [Ca2+]i were followed by flow cytometry by loading the cells with indo-1, a Ca2+-binding fluorescent dye, and determining the ration of fluorescence intensities at 405 nm (emission maximum for Ca2+-bound dye) over 480 nm (emission maximum for the free dye). Within minutes after interacting with the cytolytic granule fraction that had been isolated from CTLs, [Ca2+]i in target cells was strikingly increased. A pronounced increase in [Ca2+]i was also observed in target cells when they were specifically recognized by intact CTLs. Since ionomycin, a Ca2+ ionophore, caused a similar increase in [Ca2+]i and lysed cells (provided that extracellular Ca2+ was present), it appears that a sustained high level of [Ca2+]i is cytolytic. In contrast with other cells, CTLs, which have been shown to be refractory to granule-mediated lysis and to be poor targets for other CTLs, did not manifest an elevation in [Ca2+]i when they were similarly loaded with indo-1 and treated with isolated granules. The characteristic cleavage of target cell DNA into nucleosome-sized fragments was also induced by isolated granules as well as by valinomycin, a K+ ionophore, but not by ionomycin. The results support the view that lysis of most target cells by cloned CTLs is due primarily to target cell membrane changes that are fundamentally equivalent to the formation of nonspecific ion channels. The resulting large increase in [Ca2+]i is probably responsible for target cell lysis; and changes in intracellular ion concentrations also appear to be responsible for DNA fragmentation, probably by activating endogenous target cell endonucleases.

Hormone conjugated with antibody to CD3 mediates cytotoxic T cell lysis of human melanoma cells

Cytotoxic T lymphocytes can be activated by antibodies to their antigen-specific receptor complex (TCR-CD3) to destroy target cells, regardless of the specificity of the cytotoxic T cells. A novel hormone-antibody conjugate, consisting of an analog of melanocyte-stimulating hormone chemically coupled to a monoclonal antibody to CD3, the invariant component of the T cell receptor complex, was used to target human melanoma cells for destruction by human cytotoxic T lymphocytes that bear no specificity for the tumor cells. As targeting components of such anti-CD3 conjugates, hormones or growth factors are expected to prove more effective than antibodies to tumor-associated antigens in focusing the destructive activity of cytotoxic T cells on tumor target cells.

Resistance of cytotoxic T lymphocytes to the lytic effects of their toxic granules

A cytotoxic T lymphocyte (CTL) characteristically kills target cells one after the other by releasing toxic granules that contain one or more cytolytic components. To determine how CTLs avoid destroying themselves when they release granules and lyse target cells, 7 murine CD8+ CTL cell lines were compared with 19 other cell lines for susceptibility to lysis by the isolated toxic granules. Murine CD8+ CTLs were clearly the most resistant cells: granules did not lyse them even after they were exposed to azide, cyanide, and 2-deoxyglucose, conditions that were found to enhance the susceptibility of all the other cells tested, including other T cells. Thus, resistance of CD8+ CTLs to cytotoxic granules appears to be independent of cellular ATP. To reconcile these findings with other observations that, under some circumstances, CTLs can be lysed by other CTLs, we suggest a model in which a CTL releases only a limited proportion of its toxic granules at each antigen-specific encounter with a target cell; the amount released is sufficient to kill most target cells but to leave the CTL undamaged and with enough granules to attack other target cells.

Tissue-specific expression of functionally rearranged lambda 1 Ig gene through a retrovirus vector

To explore the potential use of retrovirus vectors for the transfer of genomic DNA sequences into mammalian cells, recombinant retroviral genomes were constructed that encode a functionally rearranged murine lambda 1 immunoglobulin gene. Several of these genomes could be transmitted intact to recipient cells by viral infection, although successful transmission depended both on the orientation of the lambda 1 sequences and on their specific placement within vector sequences. The lambda 1 gene transduced by viral infection was expressed in a cell lineage-specific manner, albeit at lower levels than endogenous lambda 1 gene expression in cells from the B-lymphocyte lineage. Vectors yielding integrated proviruses that lacked viral transcriptional enhancer sequences were used to show that neither viral transcription nor the viral transcriptional sequences themselves had any effect on the tissue specificity of lambda 1 gene expression or the absolute amount of lambda 1 transcription. Vector transcription did, however, dramatically decrease the amount of lambda 1 protein that could be detected in tranduced cells. These results suggest that retrovirus vectors may be useful reagents not only for the expression of complementary DNA sequences but also for studies of tissue-specific transcription in mammalian cells.

Resistance of cytotoxic T lymphocytes to lysis by a clone of cytotoxic T lymphocytes

To investigate how cytotoxic T lymphocytes (CTL) avoid killing themselves when they destroy target cells, we compared 20 different cell lines as target cells, including several CTL cell lines, for their susceptibility to lysis by CTL. Variations in recognition of this diverse set of target cells was circumvented by attaching to all of them a monoclonal antibody to the antigen-specific receptor of a cloned CTL cell line (clone 2C) and using the 2C cell line as the standard aggressor or effector cell. All of the nine tumor cell lines and the four noncytolytic T-helper cell lines tested as targets were highly susceptible to lysis by the aggressor CTL, but seven cytotoxic T-cell lines (six CTL and one T-helper cell line with cytotoxic activity) were largely resistant. These results, and the use of the lectin Con A as an alternative means for triggering CTL activity, point clearly to a level of resistance that could enable CTL to avoid their own destruction when they lyse target cells. The resistance of the cytolytic T cells did not appear to be accompanied by a similar resistance to complement-mediated lysis, indicating that mechanisms of CTL-mediated and complement-mediated lysis are not identical.

Recognition and lysis of target cells by cytotoxic T lymphocytes

A single cytotoxic T lymphocyte (CTL) is capable of performing the two most fundamental functions of an immune response, recognition and elimination of foreign antigens. It is now clear that in a CTL these two functions are linked via the antigen-specific, heterodimeric receptor. We review here some experimental approaches that justify this conclusion and provide the means for further examination of the mechanisms by which CTLs lyse their target cells. When antireceptor antibodies serving as antigen substitutes are attached to various cells, they trigger the lytic activity of particular CTLs, which results in lysis of the antibody-modified cell. In the process, a novel serine esterase, which is located within cytolytic granules of the CTL, is released. The presence of this enzyme and a complement-like protein, perforin, in granules of a CTL has led to the suggestion that CTLs and complement have similar cytolytic mechanisms. However, the resistance of some CTLs to lysis by other CTLs, but not to lysis by antibody-activated complement, suggests fundamental differences between cytolytic mechanisms of CTLs and complement.

A phosphorylated, disulfide-linked membrane protein in murine cytotoxic T lymphocytes

The previously determined sequence of the murine T-cell gamma gene and its transcription in cloned T lymphocytes suggests that the polypeptide encoded by this gene is generally present in cytotoxic T cells as a 33-kDa monomer in a disulfide-bonded dimer. The gamma chain is also expected to be phosphorylated because a sequence in its cytoplasmic domain is homologous to an active site for serine phosphorylation in the regulatory subunit of cAMP-dependent protein kinase. We describe here a cytotoxic-T-cell-associated phosphorylated protein, many of whose properties suggest that it may be the product of the T-cell gamma gene. Its phosphorylation is greatly enhanced by interleukin 2 stimulation.

Serine esterase in cytolytic T lymphocytes

The mechanisms that enable cytotoxic T lymphocytes (Tc cells) to destroy target cells are only vaguely understood. However, recent studies have identified in Tc cells and natural killer cells cytoplasmic granules that contain perforin, a cytolytic protein that resembles the ninth component of complement (C9). Antigen-specific lysis of target cells, traditionally ascribed solely to Tc cells, has now also been demonstrated in some T-helper cell (Th cell) lines, referred to here as T helper-killer or Th/c cells. We recently found a novel serine esterase that is present at greatly elevated levels in cloned murine Tc cell lines and one Th/c cell line, but not in two non-cytolytic Th cell lines. These findings suggest that the serine esterase is involved in cytolytic activity and that a variety of effector cells share a common cytolytic mechanism. To explore the role of the serine esterase in this process, we have been studying additional properties of the enzyme in murine T cells. We show here that it is a membrane-associated, disulphide-linked dimer, it has trypsin-like properties but is not a general protease, in density gradient centrifugation it sediments with perforin, it is secreted by Tc cells during their cytolytic attack on target cells, and antiserum to Tc-cell serine esterase reacts with the enzyme in Th/c cells.

A functional gamma gene formed from known gamma-gene segments is not necessary for antigen-specific responses of murine cytotoxic T lymphocytes

Structural similarities between surface immunoglobulins (s Ig) on B cells and antigen-specific receptors on T cells suggest that a T cell, like a B cell, should express only two immunoglobulin-like genes, one for each subunit of the disulphide-linked, heterodimeric, antigen-specific (alpha beta) T-cell receptor. However, cytotoxic T lymphocytes (Tc cells) and immature thymocytes also contain RNA transcripts of a third immunoglobulin-like gene, called gamma (refs 1-4). A polypeptide corresponding to the gamma gene has not yet been identified and the function of this gene remains an enigma. Judging from its nucleotide sequence, the rearranged gamma gene is expected to encode an integral membrane polypeptide chain, and gamma complementary DNAs from two cloned Tc cell lines have previously been found to have different sequences around the V-J (variable region-joining region) junction, suggesting that, in these cells, the gamma-gene product is a clonally diverse surface structure that may form part of an as yet unidentified, antigen-specific receptor. To analyse further the extent of diversity of the gamma-gene product, we have determined the partial sequences of 11 gamma cDNA clones from three other cloned Tc cell lines, and report here that the sequences are indeed clonally diverse, but in all instances they are out-of-phase in the region of the V-J junction. This finding and the pattern of gamma-gene rearrangements in these cell lines indicate that a polypeptide product of the previously reported gamma gene, V2J2-C2, is not expressed in them and is, therefore, not necessary for the antigen-specific cytotoxic and proliferative responses of these mature T cells.

Glycosylation of the T-cell antigen-specific receptor and its potential role in lectin-mediated cytotoxicity

Cytotoxic T lymphocytes (CTLs) normally destroy only those cells ("target cells") whose surface antigens they recognize. However, in the presence of lectins such as Con A, CTLs destroy virtually any cell, regardless of its antigens. The oligosaccharides of the T-cell antigen-specific receptor, a dimeric surface glycoprotein composed of disulfide-linked alpha and beta subunits, are of interest because of their potential involvement in this lectin-dependent cytotoxic activity. We report here that three or four asparagine-linked oligosaccharides could be enzymatically removed from each of the receptor subunits expressed by a cloned line of murine CTLs (clone 2C), consistent with the presence of glycosylation sites deduced from cDNA sequences of the alpha and beta genes expressed in this clone. All the N-linked glycans on the alpha subunit were of the complex type (i.e., resistant to endoglycosidase H), but the beta subunit carried two or three endoglycosidase H-sensitive (high-mannose) oligosaccharides. High-mannose glycans can bind tightly to Con A and, indeed, this lectin was found to bind specifically to solubilized 2C T-cell receptor. The Con A-dependent cytotoxic activity of clone 2C, but not of other CTL clones, was inhibited by a monoclonal antibody (1B2) that is specific for the T-cell receptor of clone 2C. Antibody 1B2 also inhibited clone 2C cytotoxicity mediated by phytohemagglutinin, lentil-lectin, and wheat-germ agglutinin. These results suggest that, although lectin-dependent lysis of target cells by CTLs is antigen nonspecific, the cytolytic activity can be triggered by binding of the lectin to the T-cell antigen-specific receptor.

Secondary, tertiary, and quaternary structure of T-cell-specific immunoglobulin-like polypeptide chains

To explore the possibility that the difference in antigen recognition between B and T cells derives from a structural difference in their respective antigen-specific receptors (immunoglobulins on B cells and immunoglobulin-like molecules on T cells), we compared the extracellular segments of the T-cell receptor alpha, beta, and gamma polypeptide chains and the N-terminal segment of the T-cell T8 (Lyt-2) antigen chain with the corresponding regions of immunoglobulins whose three-dimensional structures are known. The results indicate that the four T-cell polypeptide chains are organized into immunoglobulin-like domains consisting of multistranded antiparallel beta-sheet bilayers. Invariant amino acid side chains that are conserved in diverse immunoglobulins, including those that mediate domain-domain interactions and form a constant scaffold for antibody binding sites, are also conserved in the chains encoded by the T-cell receptor genes and in the N-terminal domain of T8 (Lyt-2). It appears that the binding sites of the antigen-specific T-cell alpha beta-chain receptors and of antibodies are very similar in their overall dimensions and geometry: a T-cell alpha beta receptor molecule probably has an antigen-specific binding site that is fundamentally no different than the conventional binding site of an antibody.

Heteroantibody duplexes target cells for lysis by cytotoxic T lymphocytes

Antibodies to the clonally unique variable-region determinants (idiotype) of the antigen-specific alpha beta heterodimeric receptor of a clone of cytotoxic T cells (CTLs) were shown previously to render diverse cells, regardless of their own surface antigens, susceptible to lysis by that clone of CTLs. To extend these findings, we have sought to develop a general means for targeting cells for destruction by any CTL, without regard to its alpha beta idiotype and specificity for antigen. We explored the use of heteroantibody duplexes formed by joining covalently an antibody to the T3 complex (anti-T3), which is associated with the alpha beta receptors on all human mature T cells, and a second antibody, specific for an antigen on the intended target cell. The second antibody selected in this study was specific for the idiotype (Id) of the surface immunoglobulin of a human B-lymphoma (anti-Ig Id). In the presence of the anti-T3/anti-Ig Id heteroantibody duplex the B-lymphoma cells were lysed by a clone of human T8+ CTLs (of unrelated specificity) but not by a noncytotoxic clone of human T4+ helper T cells, and lysis by the CTLs was specifically blocked by the uncoupled anti-T3 or the uncoupled anti-Ig Id antibodies. The extent of the heteroantibody-dependent cytolysis depended both on the heteroantibody concentration and on whether the intended target cells or the CTL effectors were initially preincubated with the heteroantibody. Under optimal conditions, heteroantibody-dependent lysis of the surrogate target (B-lymphoma) cells by the CTLs compared favorably with lysis of their natural target cells by the same CTLs. Overall, our findings suggest that heteroantibody duplexes containing anti-T3 antibody may be capable of targeting selected cells, such as tumor cells, for destruction in vivo by the body's CTLs.