Killer cells of feline leukemia virus- and feline sarcoma virus-infected transformed cells: the role of NK, ADCC, and in vitro generated cytotoxic cells

Feline white blood cells (WBC) manifested a primary in vitro mixed lymphocyte tumor cell culture (MLTC) proliferative response to feline leukemia virus-feline sarcoma virus (FeLV-FeSV)-infected transformed target cells, which reached a peak at Day 15. Furthermore, primary in vitro MLTC cultures generated cytotoxic killer cells capable of killing a variety of targets in non-major histocompatibility gene complex restricted fashion, and effector cells were capable of killing targets introduced repeatedly into cultures over a 49-day period. The presence of feline fibrosarcoma (f-sarc) stimulators was the primary driving force for proliferation and generation of killing because exogenous IL-2 conditioned medium did not appreciably increase the yield of killer cells generated in vitro. WBC cultured without f-sarc stimulators with or without IL-2 supplementation also generated killer (K) cells but at a low level. The killer cell population was composed of approximately 50% lymphocytes and 50% monocytes. Cats had K cells functional in antibody-dependent cell-mediated cytotoxicity against FeLV-coated chicken red blood cells but not against any FeLV-FeSV-infected transformed targets tested. Natural killer (NK) cell activity to any targets tested was not found. Although no evidence was found for K or NK cell activity against FeLV-FeSV-infected transformed cells, feline WBC were readily able to generate killer cells in vitro and it is probable that this cell-mediated immune potential is functionally important in vivo.     

Mechanisms of granule-dependent killing

Cytotoxic T lymphocyte and natural killer cell-initiated cell death is one of the primary mechanisms used by higher organisms to eliminate viruses and transformed cells. In this context, target cell death is rapid and efficient and initiated via two main pathways, involving either the ligation of death receptors or through the granule-exocytosis pathway. The granule-exocytosis pathway has attracted much attention over the past 10 years and consequently, a mechanism for granule-dependent killing has become reasonably well established. In the granule-dependent pathway, several proteolytic enzymes called granzymes are delivered to the target cell, promoting the activation of a family of death-inducing proteases called caspases. If caspases are inhibited by viral proteins or are inactivated through mutation, granzyme-mediated proteolysis of other cellular substrates ensures the timely death of infected or transformed cells. Here, we examine the findings that have shaped our current understanding of the mechanics of granule-dependent killing and discuss recent insights that have clarified some long-standing discrepancies in the granzyme literature.     

Vesicle-associated membrane protein 7 (VAMP-7) is essential for target cell killing in a natural killer cell line

Natural killer cells recognize and induce apoptosis in foreign, transformed or virus-infected cells through the release of perforin and granzymes from secretory lysosomes. Clinically, NK-cell mediated killing is a major limitation to successful allo- and xenotransplantation. The molecular mechanisms that regulate the fusion of granzyme B-containing secretory lysosomes to the plasma membrane in activated NK cells, prior to target cell killing, are not fully understood. Using the NK cell line YT-Indy as a model, we have investigated the expression of SNAP REceptors (SNAREs), both target (t-) and vesicular (v-) SNAREs, and their function in granzyme B-mediated target cell killing. Our data showed that YT-Indy cells express VAMP-7 and SNAP-23, but not VAMP-2. VAMP-7 was associated with granzyme B-containing lysosomal granules. Using VAMP-7 small interfering RNA (siRNA), we successfully knocked down the expression of VAMP-7 protein in YT-Indy to less than 10% of untreated cells in 24 h. VAMP7-deficient YT-Indy cells activated via co-culture with Jurkat cells released <1 ng/mL of granzyme B, compared to 1.5-2.5 μg/mL from controls. Using Jurkat cells as targets, we showed a 7-fold reduction in NK cell-mediated killing by VAMP-7 deficient YT-Indy cells. Our results show that VAMP-7 is a crucial component of granzyme B release and target cell killing in the NK cell line YT-Indy. Thus, targeting VAMP-7 expression specifically with siRNA, following transplantation, may be a viable strategy for preventing NK cell-mediated transplant rejection, in vivo.     

Selective killing of transformed rat cells by minute virus of mice does not require infectious virus production.

Fischer rat fibroblasts, naturally resistant to killing by the fibrotropic strain of minute virus of mice [(parvovirus MVM(p)], became sensitive to MVM when transformed by polyomavirus. This sensitization did not involve an increase in the percentage of cells which synthesized viral capsid antigens or in the percentage of cells which produced infectious virus. The addition of anti-MVM antiserum to the growth medium of MVM-infected cells had only a small effect on their survival rates, indicating that the majority of the killing effect of MVM occurs in a single cycle of infection. The data indicate that cell killing by MVM is independent of infectious virus production and thus support the notion that the preferential cytolytic effect is affected by viral cytotoxic gene products which accumulate to intolerable levels in transformed cells but not in normal ones. Finally, using cells transformed with polyomavirus and genomic and subgenomic clones of polyomavirus, we showed that the extent of sensitization to killing by MVM depended on the transforming agent used.     

Sodium butyrate affects expression of fibronectin on CHO cells: Specific increase in antibody-complement-mediated cytotoxicity

Cellular fibronectin is expressed only at very low levels on the surface of the spontaneously transformed Chinese Hamster Ovary (CHO) cell line, as detected by immunofluorescence studies and confirmed by resistance of CHO cells to complement-mediated lysis in the presence of anti-fibronectin antibody. Treatment of CHO cells with sodium butyrate results in a marked susceptibility to anti-fibronectin complement-mediated killing. Using selected complement-containing sera from rabbits, it is possible to demonstrate that killing of butyrate-treated CHO cells is absolutely and specifically dependent on the presence of antibody to fibronectin. The increased susceptibility of butyrate-treated cells to complement-mediated killing correlates with an increase in cell surface fibronectin detected by immunofluorescence studies. This increased antigen expression should allow the isolation of mutants with altered regulation of fibronectin expression in a cell line of proven value for somatic cell genetic studies.     

Effects of human interferon-alpha on UV-induced DNA-repair synthesis and cell killing

Cells of a human transformed cell line, RSb, which have unusually high sensitivity to UV killing and low DNA-repair capacity and which can be induced into antiviral states by human interferon (HuIFN)-alpha (Suzuki et al., 1982), acquired increased levels of DNA-repair synthesis and cell survival when pretreated with HuIFN-alpha before UV irradiation. The increased effects of HuIFN-alpha were also observed in other transformed VA13 cells and AK fibroblast cells.     

Establishment and functional characterization of novel natural killer cell lines derived from a temperature-sensitive SV40 large T antigen transgenic mouse

Natural killer (NK) cells belong to an important lymphocyte population that eliminates transformed cells and invading pathogens without any prior sensitization. NK cells possess not only natural killing activity against non-self and altered-self cells but also exhibit cytokine production and antibody-dependent cell-mediated cytotoxicity (ADCC). Despite their important roles in the innate immune system, little is known about the details of NK cell biology. In spite of that several murine NK cell clones have been established, studies have mainly focused on their natural killing activity but not their cytokine production or ADCC. In this study, we established and characterized eight novel, immortalized murine NK cell clones derived from a temperature-sensitive SV40 large-T antigen transgenic mouse. These NK cell lines continuously proliferated for more than 30 months in a culture medium supplemented with interleukin 2. All cell lines contained azurophilic granules in the cytoplasm, and a few clones retained the NK cell functions, such as natural killing activity, cytokine production, and ADCC. In addition, one clone could serve as a host for transient as well as stable gene transfection. Taken together, these findings indicate that the cell lines could constitute useful tools for detailed analysis of murine NK cell biology.     

Apoptin nucleocytoplasmic shuttling is required for cell type-specific localization, apoptosis, and recruitment of the anaphase-promoting complex/cyclosome to PML bodies

The chicken anemia virus protein Apoptin selectively induces apoptosis in transformed cells while leaving normal cells intact. This selectivity is thought to be largely due to cell type-specific localization: Apoptin is cytoplasmic in primary cells and nuclear in transformed cells. The basis of Apoptin cell type-specific localization and activity remains to be determined. Here we show that Apoptin is a nucleocytoplasmic shuttling protein whose localization is mediated by an N-terminal nuclear export signal (NES) and a C-terminal nuclear localization signal (NLS). Both signals are required for cell type-specific localization, since Apoptin fragments containing either the NES or the NLS fail to differentially localize in transformed and primary cells. Significantly, cell type-specific localization can be conferred in trans by coexpression of the two separate fragments, which interact through an Apoptin multimerization domain. We have previously shown that Apoptin interacts with the APC1 subunit of the anaphase-promoting complex/cyclosome (APC/C), resulting in G(2)/M cell cycle arrest and apoptosis in transformed cells. We found that the nucleocytoplasmic shuttling activity is critical for efficient APC1 association and induction of apoptosis in transformed cells. Interestingly, both Apoptin multimerization and APC1 interaction are mediated by domains that overlap with the NES and NLS sequences, respectively. Apoptin expression in transformed cells induces the formation of PML nuclear bodies and recruits APC/C to these subnuclear structures. Our results reveal a mechanism for the selective killing of transformed cells by Apoptin.     

CD4+ T cell-mediated killing of MHC class II-positive antigen-presenting cells. I. Characterization of target cell recognition by in vivo or in vitro activated CD4+ killer T cells

Ag-specific as well as Ia-restricted killing of certain APC by CD4+ T cells was investigated. The CD4-mediated killing is not only a characteristic of in vitro long term cultured T cell lines or clones, but is also manifest after in vivo priming. Thus, CD4+ killer T cells are generated in vivo as well. CD4+ killer T cells are detected in the Th1, but not in the Th2 subset, and they do not appear to lyse Ia+ APC or bystander cells by a pathway mediated by secreted T cell factors. The latter observation is demonstrated by cold target inhibition experiments as well as by the failure of puromycin to inhibit killing, if applied in doses which completely block lymphokine secretion. Ia+ APC differ in their susceptibility to lysis. Transformed APC are usually better lysed than nontransformed APC. Unstimulated B cells are not killed, while LPS-stimulated B cell blasts are killed. The results of cold target inhibition and bystander killing experiments suggest that CD4+ killer T cells are activated by the common pathway, i.e., by Ag presented in the context of Ia, but killing requires the recognition of additional determinant(s) on APC. It is proposed that these killing-inducing determinants are continuously expressed on most transformed Ia+ cells and on nontransformed but stimulated APC.     

Differential sensitivities of transformed and untransformed murine cell lines to DNA cross-linking agents relative to repair of O6-methylguanine

Sensitivities of several murine cell strains to killing by the DNA cross-linking agents 1-(2-chloroethyl)-1-nitrosourea (CNU), cis-diamminedichloroplatinum (II) (Cis-Pt) and mitomycin C (MMC) were measured by post-treatment colony-formation. Virally-transformed murine cells were usually more sensitive to cell killing by these agents than were the parental 3T3 cell strains. The hypersensitivity to CNU of some virally-transformed murine cell strains correlated well with the reduced ability to repair O6-methylguanine (O6mGua), a phenomenon similar to that in human cells. The loss of ability to repair O6mGua, as well as the increased sensitivity of transformed strains to cell killing, may not be due to a mutation but rather due to a change of gene expression associated with transformation by viruses or activation of oncogenes.     

Ethanolamine base exchange enzymatic activities in spontaneous transformed glial cell lines. Effect of dibutyryl cyclic AMP treatment

Cultured astrocytes derived from neonatal rats (normal cells) displayed maximal ethanolamine base exchange enzymatic activity (EBEE) when cultures reached confluency and cells almost ceased to divide. At this stage, ethanolamine phosphotransferase (EPT) and choline base exchange enzyme (CBEE) activities reached a plateau. In spontaneously transformed glial cells, no differential activity variation either between EPT and CBEE, or between EPT and EBEE was observed. The EBEE activity was mainly localized in the microsomal fraction and was completely absent from plasma membranes. Dibutyryl cyclic AMP (db-cAMP) treatment of the transformed cells reversed the pattern of these activities to that of normal cells. Moreover, treatment of the transformed cells with medium conditioned by normal astroblasts markedly increased EBEE activity. This study demonstrates that (i) variation of EBEE activity during cell growth differs in normal and in transformed cultured glial cells. (ii) EBEE activity may be modulated via both db-cAMP and normal cell conditioned medium. Our findings suggest a possible implication of EBEE in the maturation and contact inhibition of cell growth.     

Chemical and immunological studies of cell surfaces from normal and transformed cells

Immunological and chemical studies of cell surfaces from normal and transformed BALB/c fibroblasts have shown alterations associated with transformation. The cells studied include normal lines which do not cause tumors when injected into BALB/c mice, viral transformants, and spontaneous transformants which cause tumors that either regress or grow progressively, killing the host. The spontaneously transformed progressors include cell lines which are immunogenic and nonimmunogenic as determined by the ability of tumor excision to protect an animal from subsequent rechallenge by tumor cells. Tumor-bearing mice produce lymphocytes which are nonspecifically cytotoxic for all the normal and transformed lines. Some of the cell lines induce specific antibody formation in BALB/c hosts. Antisera have been prepared in rabbits which are specific for the transformed cell lines. These antisera can be used to determine specific surface changes on the transformed cells. Chemical studies have shown glycolipid alterations between the normal cells and some, but not all, of the transformants. Glycoproteins labeled by lactoperoxidase-¹²⁵ I or [³H] glucosamine were compared by SDS gel electrophoresis. Results from these studies do not show changes associated with malignancy. Individual glycoprotein regions from gels were treated with pronase, and the glycopeptides compared by Sephadex G-50 chromatography. Alterations in glycopeptides from several cellular glycoproteins are the only changes which appear to be associated with malignancy.     

In vivo studies of repair of 2-aminopurine in Escherichia coli.

The repair of the base analog 2-aminopurine has been studied in vivo by using a temperature-sensitive mutant of the cloned mutH gene of Escherichia coli. Our results suggest that the lethal event in killing of dam mutants by 2-aminopurine does not result simply from incorporation of 2-aminopurine into the DNA and its subsequent repair. Furthermore, a 10-fold increase in the level of 2-aminopurine incorporated into the DNA of a dam mutH double mutant has little effect on the mutation frequency of this strain. An alternative mechanism for the mutagenicity of 2-aminopurine in E. coli is proposed.     

Macrophage binding of cells resistant and sensitive to contact-dependent cytotoxicity

We compared macrophage binding and killing of F5b cells to the binding and killing of P815 mastocytoma cells and to several other nontransformed and transformed cell lines. Formalin fixation of elicited or activated macrophages did not affect binding of F5b or 3T3 cells but did abrogate binding of P815 cells. However, formalin fixation abrogated resident macrophage binding of F5b and 3T3 cells. Therefore, depending on the type of macrophage or target cell, formalin fixation may affect binding. Only the binding of P815 cells was dependent upon activation; macrophage binding of target cells F5b and 3T3 was not. Even though macrophages bound F5b and 3T3 cells, macrophages only mediated contact-dependent cytotoxicity against F5b cells. Macrophages did not kill 3T3 cells. Experiments also compared macrophage binding and killing of the uv-light-induced tumor cell lines 1422, 2237, and 2237a46. Only the cell line 2237a46 was susceptible to contact-dependent killing. Both 1422 and 2237 cells were resistant. In contrast, cell lines 2237a46 and 1422 were bound by activated macrophages while 2237 cells were bound poorly.     

Systematic comparison of antibody-mediated mechanisms of keratinocyte lysis in vitro

We have conducted a systematic comparison of lysis of TNP-coated keratinocyte targets by TNP-specific antibody, by antibody plus complement, by antibody-dependent cellular cytotoxicity (ADCC), and by natural killing with the use of monocyte, lymphocyte, and neutrophil effectors. With chromium-release assays, human keratinocytes, HEp-2 cells (transformed human keratinocytes), PAM 212 cells (transformed mouse keratinocytes), and RSC (transformed rabbit keratinocytes) were all susceptible to monocyte- and lymphocyte-mediated ADCC (p less than 0.01 to p less than 0.02). All trypsinized keratinocyte targets were also susceptible to natural killing by monocyte or lymphocyte effectors (p = 0.05 to p less than 0.001). Antibody and antibody plus complement were poor mediators of keratinocyte lysis. If protein and complex lipid synthesis of keratinocytes were inhibited by 16-hr cycloheximide preincubation, then keratinocytes were susceptible to complement-mediated lysis, implying that the resistance of these cells to complement may be due to repair of transmembrane pores. Comparison of chromium-release assays with fluorescein diacetate dye uptake viability assays showed that human keratinocytes were still susceptible to monocyte and lymphocyte ADCC but not to antibody, antibody plus complement, or natural killing. The reproducible and uniform susceptibility of normal and transformed keratinocyte targets from three different species to monocyte and lymphocyte ADCC supports the hypothesis that this mechanism of cellular lysis may be important in antibody-associated diseases of epidermal cytotoxicity.     

Subcellular action of Neocarzinostatin. Intracellular incorporation, DNA breakdown and cytotoxicity

The subcellular site of action of a proteinaceous antitumor antibiotic neocarzinostatin (NCS) was studied using normal human lymphocytes, Epstein-Barr virus transformed lymphoblastoid cells, osmotically burst lymphoblastoid cells, and colicin E1 plasmid DNA. The rate of DNA strand break in these different types of DNA was found to be in the following order: Colicin DNA > burst cell DNA > lymphoblastoid cell DNA > normal lymphocyte DNA. Furthermore, fluorescence microscopy revealed that lymphoblastoid cells incorporated more fluorescein isothiocyanate labeled NCS than normal cells. High uptake of NCS in lymphoblastoid cells coincided with a high killing rate; low uptake of NCS in lymphocytes resulted in very little cell killing. Uptake velocity using fluorescein diacetate (FDA) also showed that the lymphoblastoid cells exhibited a higher uptake of FDA coinciding with a higher killing rate. The cell killing activity of NCS appears to be closely associated with the rate of intracellular uptake of NCS and subsequent direct degradation of DNA by the drug. This notion is reinforced by the reported finding that the dose required for DNA strand scission is only about 1/100 of that for the inhibition of cap formation. Thus DNA strand scission, rather than the cell membrane, appears to be the primary target of NCS. Enhanced incorporation of many substances is commonly observed upon transformation of cells by viruses, and our present results may provide an important clue toward the explanation of the selective toxicity toward tumor cells of NCS.     

Analysis of sera from SV40-immunized and tumor-bearing hosts for blocking activity and antibody-dependent cellular cytotoxicity.

The role of serum factors in tumor immunity to cells transformed by PARA-(defective SV40)-adenovirus 7 was investigated. It was found that sera from SV40-sensitized hosts did not block the specific cytotoxicity of SV40-sensitized spleen cells for PARA-7 cells. However, such sera could collaborate with nonsensitized spleen cells to produce specific killing. This activity could be absorbed out by PARA-7 cells but not by cells transformed by cytomegalovirus. The activity of sera from hamsters bearing tumor isografts depended upon when, after transplantation, the specimens were obtained. Sera collected greater than or equal to 10 days after grafting completely blocked immune spleen cell cytotoxicity and did not mediate target cell killing in the presence of normal spleen cells. Sera obtained at an earlier time, i.e., 3 to 6 days after transplantation, consistently were active in the antibody-dependent cellular cytotoxicity test and exhibited reduced or no blocking of antibody-independent cellular cytotoxicity. Thus, there appears to be an inverse correlation in the capacity of serum from tumor bearing hosts to block effector cell cytotoxicity and mediate antibody-dependent cellular cytotoxicity.     

Induction of entosis by epithelial cadherin expression

Cell engulfment typically targets dead or dying cells for clearance from metazoan tissues. However, recent evidence demonstrates that live cells can also be targeted and that engulfment can cause cell death. Entosis is one mechanism proposed to mediate the engulfment and killing of live tumor cells by their neighbors, an activity often referred to as cell cannibalism. Here we report that the expression of exogenous epithelial cadherin proteins (E- or P-cadherin) in human breast tumor cells lacking endogenous expression of epithelial cadherins induces entosis and inhibits transformed growth. Entosis induced by cadherin expression is associated with the polarized distribution of Rho and Rho-kinase (ROCK) activity within entotic cells, which is dependent on p190A RhoGAP activity. ROCK inhibition or downregulation of p190A RhoGAP expression reduces entosis and increases the transformed growth of epithelial cadherin-expressing tumor cells. These data define new cell systems for the study of entosis, and identify entosis as a mechanism of cell cannibalism that is induced by the establishment of epithelial adhesion and inhibits transformed growth.     

Ultraviolet mutagenesis in human lymphocytes: The effect of cellular transformation

We have assessed the role of cellular transformation in ultraviolet (uv)-induced mutagenic events in human cells. To maintain uniformity of genetic background and to eliminate the effect of DNA repair, primary nontransformed lymphocytes (T-cells) and Epstein-Barr virus-transformed lymphocytes (B-cells) from one patient (XP12Be) with the DNA repair-deficient disorder xeroderma pigmentosum (group A) were transfected with the mutagenesis shuttle vector pZ189. Parallel control experiments were performed with primary, nontransformed lymphocytes from a normal individual and with a repair-proficient Epstein-Barr virus-transformed lymphocyte line (KR6058). pZ189 was treated with uv and introduced into the four cell lines by electroporation. Plasmid survival and mutations inactivating the marker supF suppressor tRNA gene in the recovered pZ189 were scored by transforming an indicator strain of Escherichia coli. Plasmid survival was reduced and mutation frequency elevated equally with both XP-A cell lines compared to both normal cell lines. Base sequence analysis of more than 250 independent plasmids showed that while the G:C----A:T base substitution mutation was found in at least 60% of plasmids with single or tandem mutations with all four cell lines, the frequency with the transformed XP-A (93%) cells was significantly higher (P less than 0.01) than that with the nontransformed XP-A cells (77%). In addition, with the transformed XP-A cells, there were significantly fewer plasmids with transversions and with mutations at a transversion hotspot (base pair 134) than with plasmids recovered from nontransformed XP-A cells. Interleukin-2 and phytohemagglutinin (used to maintain growth of the nontransformed lymphocytes) treatment of transformed XP12Be cells did not change overall plasmid survival or mutation frequency, but increased the transversion frequency and induced a mutational hotspot (at base pair 159), while another mutational hotspot (at base pair 123) disappeared. Thus we have demonstrated that in repair-deficient human cells, cellular transformation, while not affecting overall postuv plasmid survival and mutation frequency, does increase the susceptibility to G:C----A:T transition mutations, a type of mutation associated with uv-induced neoplasia.     

Recovery of yeast cells after exposure to ionizing radiation and hyperthermia

Quantitative regularities of recovery of wild-type diploid yeast cells irradiated with gamma-rays (60Co) simultaneously with exposure to high temperatures were studied. It was shown that in conditions of such a combined action the constant of recovery did not depend on the temperature at which the irradiation was carried out. However, with an increase of acting temperature an augmentation in the portion of irreversible component was registered. The analysis of cell inactivation revealed that the augmentation of the irreversible component was accompanied by a continuous increase of cell killing without any postirradiation division after which cells are incapable of recovery. The reproductive death was mainly exerted after ionizing radiation applied alone while in conditions of simultaneous thermoradiation action the interphase killing (cell death without division) predominated. It is concluded on this base that the mechanism of synergistic interaction of ionizing radiation and hyperthermia may be related with cardinal change in mechanisms of cell killing.