K562 cells induced to differentiate by phorbol ester tumor promotors resist NK lysis

The effect of various phorbols and phorbol diesters on the NK sensitivity of the human leukemic K562 cells was studied. A marked decrease in K562 cell susceptibility was achieved by culture in the presence of either 12-O-tetradecanoyl-phorbol-13-acetate (TPA) or beta-phorbol-dibutyrate. The maximum protection against NK lysis was achieved when K562 cells were cultured in the presence of 160 nM TPA for 48 hr (mean percentage inhibition: 61% of specific lysis). As for untreated targets, the residual killing of K562 cells after TPA treatment was mediated through large granular lymphocytes (LGL). The experimental procedures required to achieve maximal NK protection with TPA resulted simultaneously in marked phenotypical changes in K562 cells: erythroid and early myeloid markers decreased, whereas the expression of megakaryocytic markers was increased as shown by staining with antiplatelet monoclonal antibodies and assessment of platelet peroxidase activity. Chemical phorbol analogs which were unable to induce K562 cell differentiation did not affect K562 cell sensitivity to NK lysis. De novo protein synthesis is involved in the TPA-induced NK resistance, since this effect was abolished by pretreatment of K562 cells with actinomycin D or cycloheximide. TPA has been previously demonstrated to reduce NK effector activity. In our data however, the observed TPA effects were not due to release of TPA acting on effector cells during the NK assay since TPA-treated K562 cell supernatants were unable to inhibit NK activity in control assays. Thus, TPA appears to decrease NK killing of malignant cells, both by depressing NK effector cells functions and by reducing the susceptibility to NK lysis of the target cells. In single-cell agarose assays, TPA-treated K562 cells demonstrated reduced NK-binding capacity and reduced sensitivity to lysis after binding. These defects could not be reversed by activation of the NK effector cells with interferon. The results here reported extend the previously suggested relations between the expression of NK-target structures and the differentiation stage of malignant cells.     

Comparative effects of fagaronine,Adriamycin and aclacinomycin on K562 cell sensitivity to natural-killer-mediated lysis

Little is known about membrane target antigens for natural killer (NK) cells. Transferrin receptor and CD15 antigen might be two of these target structures. A novel antileukemic alkaloid, fagaronine, is able to induce hemoglobin synthesis in the K562 cell line. Numerous reports suggest relations between the expression of natural killer target structures and the differentiation stage of malignant cells. Effects of fagaronine on the expression of glycophorin A, transferrin receptor and CD15 antigen and susceptibility to NK-mediated lysis have been investigated in K562 cells and compared to those of two anthracyclines (Adriamycin and aclacinomycin A) known to be erythroid-differentiation inducers. When comparing the balance of differentiating effect and toxicity, the dose and time-dependent effects of the drugs, fagaronine and aclacinomycin, are equivalent on K562 cells. In experimental conditions where fagaronine (3500 nM), Adriamycin (40 nM) and aclacinomycin (15 nM) recruit the same percentage of hemoglobin-containing cells (40%-50%), glycophorin A expression increases and transferrin receptor expression decreases. Only Adriamycin treatment decreases CD15 antigen expression. In addition, Adriamycin and aclacinomycin, but not fagaronine, induce resistance to NK-mediated lysis. These data suggest that (a) it is unlikely that CD15 antigen and transferrin receptor, separately considered, can be unique target structures for NK cells; and (b) fagaronine is a potent erythroid inducer which, in our system, has similar effects to aclacinomycin without induced resistance to NK attack.     

Susceptibility to natural killer cell-mediated cytolysis is independent of the level of target cell class I HLA expression

To test the hypothesis that susceptibility to NK cell-mediated cytolysis varies inversely with the levels of target cell class I HLA expression, NK-susceptible K562 and MOLT-4 target cells have been transfected via electroporation with cloned human class I HLA-A2 and HLA-B7 genes. Stably transfected cells expressing varying levels of cell-surface class I HLA have been selected by fluorescent activated cell sorting and tested for susceptibility to NK-mediated cytolysis by freshly isolated peripheral blood NK cells from nine normal volunteers as well as by cloned human NK effectors and tumor cells from a patient with an NK cell lymphoproliferative disorder. Expression of class I HLA did not alter the susceptibility of K562 or MOLT-4 target cells to NK-mediated cytolysis by any of the effectors tested. In addition, the class I HLA-expressing transfectant cells were identical to mock transfected cells in their ability to compete for lysis in cold target inhibition assays. Treatment of both mock-transfected and class I HLA-transfected K562 cells with IFN-gamma resulted in decreased susceptibility to NK-mediated cytolysis which was independent of the total level of class I HLA expression. These results demonstrate that the level of target cell class I HLA expression is not sufficient to determine susceptibility or resistance to NK-mediated cytolysis of the classical NK targets K562 and MOLT-4.     

Analysis of the mechanisms involved in NK resistance induced by a new tumor factor NK-RIF

The mechanisms involved in susceptibility or resistance of neoplasic cells to lysis by NK cells are not well known. We have recently described a 12-kDa factor (NK-RIF), produced and released by different tumor cell lines, making K562 resistant to NK lysis without affecting the cytotoxic function of NK effector cells. In this paper we further study the mechanism involved in NK resistance of K562 mediated by NK-RIF and its biological implications. The results show that NK-RIF does not affect the binding capacity of target and effector cells nor the levels of HLA class I antigen expression on the target cells, as a proof that resistance to NK-mediated lysis is not always associated with a defect in target effector binding or with an increased MHC class I antigen expression. However NK-RIF-treated K562 loses its capacity to induce NK cell activation and the subsequent capacity to release NKCF and makes K562 resistant to lysis by NKCF. Therefore our results show that induction of resistance to NK cytotoxicity can be the result of the modulation of target structures responsible for inducing effector cell activation without affecting target/effector binding molecules. This indicates that the structures involved in adherence and activation of NK cells have a different nature and that molecules other than HLA participate in NK resistance.     

Tumor cell differentiation modulates susceptibility to natural killer cells

Induced differentiation in three human cell lines altered their sensitivity specifically to human natural killer (NK) cells by affecting their expression of NK target antigens. Differentiation of HL-60, a promyelocytic leukemia cell line, and the erythroleukemic cell line K562 was accompanied by a concomitant decrease in susceptibility to NK-mediated lysis whereas induction of MeWo melanoma cells resulted in an enhanced sensitivity to lysis. Our findings suggest that target cell susceptibility to NK-mediated lysis may in part be dependent on the stage of differentiation of the tumor cell target.     

Long-term killing of natural killer-resistant target cells by interferon-alpha-, interferon-gamma-, and interleukin-2-activated natural killer cells

The sensitivity of target cells to natural killer (NK) cell-mediated cytotoxicity was investigated. Five target cell lines were examined for susceptibility to killing by activated NK cells in a 4-hour cytotoxicity assay: one of them (K562) was highly sensitive, while the other four were resistant. However, the four NK-resistant target cell lines were fully susceptible to lysis when the assay was extended to 24 h. The cytotoxic cells that killed the NK-resistant target cells in a 24-hour assay were plastic- and nylon wool-nonadherent human peripheral blood mononuclear cells (PBMC) and their cytotoxicity was increased by interferon-alpha, interferon-gamma, and interleukin-2. Further, the cytotoxic activity of PBMC in the long-term assay was associated with large granular lymphocytes purified on a Percoll gradient, that killed the NK-sensitive cell line K562 in a 4-hour assay. All of the above are general criteria to qualify the cytotoxic cells as NK cells. Thus, the NK-resistant phenotype may not reflect absolute immunity to NK-mediated lysis, but it may reflect the different rates at which various target cell lines can be killed.     

IFN-gamma treatment of K562 cells inhibits natural killer cell triggering and decreases the susceptibility to lysis by cytoplasmic granules from large granular lymphocytes

Pretreatment of human K562 leukemia cells with rIFN-alpha and rIFN-gamma resulted in decreased susceptibility to lysis by human peripheral blood NK cells. The reduction of NK-susceptibility after IFN treatment was not due to a general effect of IFN on the stability of the cell membrane because the susceptibility of K562 cells to lysis by antibodies plus C, distilled water, or lysolecithin was unaffected. Binding studies with effector cell preparations enriched for NK cells with large granular lymphocyte morphology revealed no difference in binding to control and IFN-gamma-treated target cells. The sensitivity to soluble NK cytotoxic factors was not affected significantly by the IFN treatment. In contrast, the susceptibility of IFN-treated target cells to the cytotoxic activity of purified cytoplasmic granules from a rat large granular lymphocyte tumor was significantly reduced, indicating that the IFN-induced resistance acted at the level of susceptibility to the lytic mechanism of NK cells. However, IFN-alpha was more effective than IFN-gamma in inducing resistance to the cytoplasmic granules although resulting in only a weak resistance in the cell-mediated cytotoxic assay. IFN-gamma but not IFN-alpha caused a reduction in the frequency of effector cells that had reoriented their Golgi apparatus toward their bound target cell. In addition, IFN-gamma treated K562 cells failed to elicit an influx of Ca2+ into effector cells. Taken together, the results suggest that IFN-gamma in addition to an increased resistance to the lytic molecules released by NK cells can also induce changes in the target cells which prevent the triggering and activation of the effector cell.     

Phospholipase C treatment of certain human target cells reduces their susceptibility to NK lysis without affecting binding or sensitivity to lytic granules.

Phosphatidylinositol-specific phospholipase C (PI-PLC) is an enzyme that has the capacity to release glycosyl-phosphatidyl inositol (G-PI)-anchored proteins from the cells surface. Pretreatment of the human T-cell leukemia cell line Molt-4 with PI-PLC resulted in a decrease in the susceptibility to lysis by natural killer (NK) cells. Treatment of the erythroleukemia cell line K562 with PI-PLC had no effect on its NK susceptibility. PI-PLC-treated and untreated Molt-4 bound equally well to lymphocytes in target-binding studies with effector cell preparations enriched for NK cells. Susceptibility to cytolytic granules isolated from rat LGL tumor cells remained the same after treatment of Molt-4 or K562 with PI-PLC. Combined treatment of Molt-4 with PI-PLC and rlFN-alpha or rlFN-gamma resulted in additive reductions of the NK susceptibility, suggesting that PI-PLC and interferons act on different mechanisms to protect cells from NK lysis. When expression of a number of antigens on Molt-4 and K562 was analyzed in flow cytometry, only the expression of CD58 was reduced after PI-PLC treatment. The susceptibility of Con A blasts to MLR derived cytotoxic T-cells was not altered by treatment with phospholipase. These data suggest that PI-PLC treatment reduces the capacity of some target cells to activate NK cells upon contract. The mechanism behind this phenomenon is presently unclear.     

Interferon-gamma is a strong modulator of NK susceptibility and expression of beta 2-microglobulin but not of transferrin receptors of K562 cells

The human cell line K562 was treated with human natural leukocyte interferon (IFN-alpha) and recombinant immune interferon (IFN-gamma). Cell cultures exposed to both types of IFNs displayed a reduced susceptibility to the cytotoxic activity of human PBL (NK activity). While this effect occurred preferentially at high doses of IFN-alpha, as little as 10 U/ml of IFN-gamma caused a marked decrease in susceptibility to NK-cell-mediated lysis. Using a monoclonal antibody against human beta2-microglobulin (beta2M) a low level of specific binding to K562 cells was detected. The binding increased after treatment with IFN-alpha (1.4-fold) and IFN-gamma (1.7-fold). The expression of transferrin receptors (TR) was not changed significantly. A hybrid cell line between K562 and a Burkitt's lymphoma-derived cell line displayed a similar pattern of response to IFN-alpha and IFN-gamma as did K562, when effects on NK susceptibility, beta2M expression, and TR expression were studied. The Burkitt's lymphoma line PUT showed no consistent changes in expression of beta2M and TR. These results demonstrate that IFN-gamma is highly efficient in modulating the NK susceptibility, and the expression of beta2M on K562. The presented data do not support a role for expression of TR as the only property that determines the degree of NK susceptibility, since there was no correlation between NK susceptibility and TR expression among the cell lines tested or when IFN-treated and untreated cells were compared.     

Lymphocyte function-associated antigen 1 (LFA-1) and natural killer (NK) cell activity: LFA-1 is not necessary for all killer: target cell interactions

A panel of five monoclonal antibodies detecting human lymphocyte function-associated antigen 1 (LFA-1) was generated and shown by competitive binding studies to react with at least four distinct epitopes on this molecule. The antibodies were then tested for their ability to inhibit the lytic activity of a variety of different human natural killer (NK) populations on a panel of four NK-susceptible target cells (K562, MOLT-4, HSB-2, and Jurkat). When heterogeneous NK populations derived from fresh peripheral blood and mixed-lymphocyte culture (MLC)-generated lines were used, these anti-LFA-1 monoclonal antibodies (MAbs) inhibited lysis of all four NK targets; this finding supports the notion that LFA-1 molecules play an important role in NK-mediated lysis. When tested on a cloned line of NK cells (NK 3.3), lysis of K562 was inhibited by these MAbs, but lysis of the other three targets was not affected. This represents an instance where a MAb specific for LFA-1 inhibits the lytic activity of NK cells against some but not all targets; thus the LFA-1 molecule cannot be considered under all circumstances to be an absolute requirement in NK-mediated lysis.     

Mechanisms involved in NK resistance induced by interferon-gamma.

Human tumor cell lines were treated with interferon-gamma (IFN-gamma) and then used as target cells in NK assays to measure their ability to form conjugates and stimulate the production of NK cytotoxic factors (NKCF) and to determine their susceptibility to NKCF lysis. K562 and cell lines RS1, RS3, RS7, CAC, and CAP2, obtained from solid brain tumors, were used as targets, and peripheral blood lymphocytes (PBL) from normal donors were used as effector cells. IFN-gamma-treated cell lines had a decreased susceptibility to NKCF lysis and a decreased ability to induce the release of these factors without affecting target-effector cell binding. These results were not due to changes in HLA class I antigen expression, given that the level of HLA class I antigens on the tumor cell lines was not affected, the only exception being K562. In an attempt to further clarify the possible influence of HLA class I expression on K562, IFN-gamma-pretreated K562 cells were separated into HLA class I positive and HLA class I negative subsets for the NK assays. The results showed that both populations behaved similarly upon target-effector conjugate formation, whereas the HLA class I positive population showed a reduced susceptibility to lysis by NK cells and NKCF. Thus, these results establish that NK resistance induced by IFN-gamma is mediated by blocking the target cell's ability to activate NK cell triggering and release of NKCF and by blocking its susceptibility to lysis by these factors. This analysis helps to clarify not only the NK process but also the controversial regulatory effect of IFN in NK lysis.     

Modulation of natural cytotoxicity by alloantibodies. V. The mechanism of a selective augmenting effect of anti-H-2 antisera on the natural killer activity of mouse spleen cells

Treatment of mouse spleen cells with specific anti-H-2 antisera augments their natural killer (NK) activity against K562 cells but not against YAC target tumor cells. The same population of natural killer cells was found to lyse K562 as well as YAC target cells, since (a) depletion of YAC reactive NK cells by absorption on YAC monolayers resulted in a concomitant depletion of anti-K562 NK activity of mouse spleen cells, and (b) both K562 and YAC cells could inhibit their own as well as each others lysis in a cross-competition assay. Anti-H-2 antiserum could not induce anti-K562 NK activity in spleen cells previously depleted of NK cells by absorption on YAC monolayers, indicating that alloantiserum does not act by recruiting otherwise nonreactive cells to become cytotoxic toward K562 target cells. In a target-binding assay, K562 binding of NK cells (T-cell-, B-cell-, and macrophage-depleted spleen cells) increased five- to eightfold in the presence of anti-H-2 antiserum whereas YAC cells binding of NK cells was not increased. H-2 antigens per se did not appear to be involved in the alloantisera effect since anti-NK antiserum directed against a non-H-2 antigen selectively expressed on NK cells, showed a similar selective NK enhancing effect. Protein A, a reagent which binds to the Fc region of immunoglobulin molecules, completely blocked the alloantiserum induced augmentation of anti-K562 NK activity, but did not alter basal NK activity. Moreover, the F(ab)₂ fraction of alloantibodies failed to enhance anti-K562 cytotoxic activity of mouse spleen cells, indicating a crucial role for the Fc portion of the alloantibodies attached to the NK cells, in NK augmentation. Utilization of several target cell lines with or without membrane Fc receptors (FcR) revealed that alloantiserum enhanced the lysis of only FcR⁺ target cells. It is proposed that alloantibody-coated NK cells, as a result of a secondary interaction between attached alloantibody and Fc receptors on target cells, interact more readily with the target cells and thereby cause a higher level of lytic activity.     

Synergistic effects of phorbol ester and interferon-alpha: target cell class I HLA antigen expression and resistance to natural killer and lymphokine-activated killer cell-mediated cytolysis

This study was undertaken to investigate whether target cell class I HLA antigen expression induced by phorbol ester and interferon-alpha (IFN-alpha) was associated with resistance to natural killer (NK) cells and lymphokine-activated killer (LAK) cell-mediated cytotoxicity. Class I antigen expression on the surface of the K562 erythroleukemia cell line was enhanced by either IFN-alpha or phorbol ester (PDBu). Addition of PDBu together with IFN-alpha had a synergistic effect on class I antigen expression on the cells. Furthermore, synergism between IFN-alpha and PDBu was also found in class I antigen expression by MOLT-3 cells. This synergistic effect on class I antigen expression was blocked by the protein synthesis inhibitor (cycloheximide). Pretreatment of K562 cells with PDBu and IFN-alpha made them more resistant to lysis by NK and LAK cells than did either PDBu or IFN-alpha. In contrast to PDBu, 4 alpha PDD, a biologically inactive phorbol analogue, alone or combination with IFN-alpha, had no effect on class I antigen expression and susceptibility to lysis by NK and LAK cells. Kinetic experiments showed an inverse relationship between the expression of class I antigens and susceptibility to NK cell-mediated cytolysis. Using cold target competition analysis, target cells pretreated with PDBu and IFN-alpha clearly competed less effectively than did untreated cells for lysis of untreated target cells. These results demonstrate that target cells pretreated with PDBu and IFN-alpha decrease their sensitivity to natural killer and lymphokine-activated killer cells inversely with target cell class I HLA antigen expression.     

Interferon-gamma-treated K562 target cells distinguish functional NK cells from lymphokine-activated killer (LAK) cells

In vitro incubation of the erythroleukemic cell line K562 with interferon-gamma (IFN-gamma) renders these cells relatively resistant to natural killer (NK) cell lysis. However, such treatment does not alter their sensitivity to LAK cell lysis. Thus, the lytic susceptibility of interferon-gamma-treated K562 (I-K562) cells to LAK cells as opposed to its relative resistance to NK cell lysis provides a functional assay to help distinguish these two types of effector cells. The relative resistance of I-K562 for NK cell-mediated lysis was not secondary to the release of soluble factors or the frequency of Leu-19+, CD3+ T cells, residual IFN-gamma, or expression of MHC Class I molecules. Coincubation of I-K562 cells with NK or LAK cells overnight did not appreciably change the pattern of lytic responses against K562 and I-K562 target cells. However, incubation of PBMC in vitro with I-K562 but not native K562 in the presence of r-IL-2 leads to a marked decrease in the generation of LAK cells. The inhibition of LAK cell generation was not secondary to differences in the consumption of bioactive levels of IL-2. Differences in the lytic capability of NK and LAK effector cells suggest heterogeneity among cells that mediate such non-MHC-restricted lysis. Use was made of cells from a patient with a large granular lymphocyte lymphoproliferative disease (greater than 85% Leu-19+) to determine if such cells could be used to distinguish clonal population of cells which would represent NK or LAK cell function. Of interest was the finding that such cells, even after incubation in vitro with IL-2, showed lytic function representative of NK cells but not LAK cells. Data concerning the inhibition of LAK cell generation by I-K562 cells have important implications for future therapeutic trials of IFN-gamma and IL-2 in the treatment of human malignancies.     

Susceptibility of Adenovirus 2-transformed rat cell lines to natural killer (NK) cells: direct correlation between NK resistance and in vivo tumorigenesis

The susceptibility to natural killer (NK)-mediated cell lysis of Adenovirus type 2 (Ad2)-transformed rat embryo fibroblast cell lines, which differed markedly in tumorigenic potential in vivo (T2C4 greater than F19 greater than F17), was investigated by using NK effector cells from F344 rat or athymic nude rat spleens. A comparison of the degree of NK-mediated lysis obtained with these tumor cell targets suggested a direct relationship between the resistance of a cell to NK cell lysis and its potential to form tumors in vivo. The cells were lysed in the following order of increasing susceptibility: T2C4 less than F4 less than F19 less than F17. Whether T cells or macrophages played a significant role in the observed lytic activity was determined by treating the NK effector cell population with anti-rat T cell serum (alpha T) and complement or by depletion of macrophages after binding to a glass bead column and treatment with carbonyl iron. A series of clonal sublines derived from the parental F17 and F4 cell lines further strengthened this relationship between tumorigenesis and resistance to NK-mediated cell lysis. Tumorigenic subclones from the non-tumorigenic F17 parental cells were demonstrated to be comparatively resistant to NK-mediated lysis. Tumorigenic subclones from tumorigenic F4 parental cell population showed a susceptibility to NK-mediated cell lysis virtually identical to the parental F4 cells. The implication of these results are discussed.     

Tight conjugate formation is not always required for natural killer cell-mediated lysis.

We have utilized several clonal cell lines, derived from the murine lymphoma ASL1w, to investigate the early events in NK-mediated lysis. The studies described here examine the relationship between NK recognition, NK cell:tumor cell conjugate formation, and NK-mediated lysis. The AW4F and AW4D tumor lines were susceptible to NK-mediated lysis and efficiently inhibited NK recognition in competitive inhibition assays, whereas the AW5J tumor, which is relatively resistant to NK-mediated lysis, did not. In contrast, the AW5E tumor was NK resistant but inhibited NK recognition almost as well as the NK-sensitive tumors, suggesting that it was deficient in a postbinding event required for NK-mediated lysis. These findings demonstrate a correlation, with one exception, between the susceptibility of the ASL1w-derived tumor lines to NK-mediated lysis and their ability to inhibit NK recognition. In contrast, there was no apparent correlation between tight conjugate formation, as assessed in three independent target binding assays, and the susceptibility of these tumors to NK-mediated lysis, showing that tight conjugate formation is not required for either efficient NK recognition or lysis.     

Nucleosome-dependent escape of tumor cells from natural-killer-mediated lysis: nucleosomes are taken up by target cells and act at a postconjugation level

 Our previous data suggested that chromatin fragments released from dead cells into the extracellular medium could be involved in the impairment of natural-killer (NK)-mediated cytotoxicity reported in cancer patients. In the present study, an inhibition of the NK-mediated lysis was obtained in vitro by nucleosome addition to different tumor target cells, independently of their sensitivity to NK-mediated lysis. We observed a rapid endocytosis and degradation of nucleosomes by K562 tumor target cells and (although to a much lesser extent) a binding to a subpopulation of lymphocytes. Nucleosomes impaired neither the conjugation step nor the expression of adhesion molecules at the effector (CD11a, CD18, CD2) or target (CD54, CD58) cell surface. On the contrary, flow-cytometry analysis of the conjugation suggested that nucleosomes might stabilize the conjugates. Investigations of the killing process showed that nucleosomes decreased the NK cytotoxic potential without modifying Ca²⁺-dependent lethal-hit-delivery kinetics. The cytotoxic potential was not restored by increasing the available magnesium and calcium concentrations in the extracellular medium. Taken together, the results suggest that the inhibition of NK-mediated lysis by nucleosomes may result from alterations of the NK mechanism at the postconjugation level and after lethal-hit delivery. Hence, the inhibition could involve a delay in the recycling of effector cells, or a resistance of tumor target cells to NK cells. Received: 7 October 1996 / Accepted: 12 November 1996     

Distinct effects of interferon-gamma and MHC class I surface antigen levels on resistance of the K562 tumor cell line to natural killer-mediated lysis

Various investigators have examined the relationship between tumor cell susceptibility to natural killer (NK) cell lysis and the expression of HLA class I antigens on the tumor cell. There is controversy as to whether or not an inverse relationship exists, and if so, the basis of the relationship between these two phenomena remains undefined. To address these questions, the genomic clones for two HLA antigens were transfected into the erythroleukemia cell line K562, a cell line that is used as the standard to assess human NK and major histocompatibility complex (MHC) nonrestricted cytolysis. Susceptibility to NK lysis was not affected by the de novo expression of HLA antigens on the K562 after DNA mediated gene transfer. Interferon-gamma (IFN-gamma) treatment of K562 induced levels of MHC class I antigen surface expression comparable to those found on the transfected cells; however, the IFN-gamma-treated cells were resistant to NK lysis. When very high levels of surface HLA antigens were induced on the transfectants, a potential effect of class I MHC expression on K562 lysis could be discerned that was distinct from the resistance to NK lysis induced by IFN-gamma-treatment.     

Autophagic degradation of GZMB/granzyme B

The crucial issue for defining successful natural killer (NK)-based anticancer therapy is the ability of tumor cells to activate resistance mechanisms leading to escape from NK-mediated killing. It is now well established that such mechanisms are likely evolved under hypoxia in the tumor microenvironment. Here, we show that hypoxia-induced autophagy impairs breast cancer cell susceptibility to NK-mediated lysis and that this impairment is reverted by targeting autophagy. We provide evidence that activation of autophagy in hypoxic cells is involved in selective degradation of the pro-apoptotic NK-derived serine protease GZMB/granzyme B, thereby blocking NK-mediated target cell apoptosis. Our in vivo data validate the concept that targeting autophagy in cancer cells promotes tumor regression by facilitating their elimination by NK cells. This study provides a cutting-edge advance in our understanding of how hypoxia-induced autophagy impairs NK-mediated lysis and might pave the way for formulating more effective NK-based antitumor therapy by combining autophagy inhibitors.     

Commentary: Autophagic degradation of GZMB/granzyme B: A new mechanism of hypoxic tumor cell escape from natural killer cell-mediated lysis

The crucial issue for defining successful natural killer (NK)-based anticancer therapy is the ability of tumor cells to activate resistance mechanisms leading to escape from NK-mediated killing. It is now well established that such mechanisms are likely evolved under hypoxia in the tumor microenvironment. Here, we show that hypoxia-induced autophagy impairs breast cancer cell susceptibility to NK-mediated lysis and that this impairment is reverted by targeting autophagy. We provide evidence that activation of autophagy in hypoxic cells is involved in selective degradation of the pro-apoptotic NK-derived serine protease GZMB/granzyme B, thereby blocking NK-mediated target cell apoptosis. Our in vivo data validate the concept that targeting autophagy in cancer cells promotes tumor regression by facilitating their elimination by NK cells. This study provides a cutting-edge advance in our understanding of how hypoxia-induced autophagy impairs NK-mediated lysis and might pave the way for formulating more effective NK-based antitumor therapy by combining autophagy inhibitors.