NKR-P1, an activating molecule on rat natural killer cells, stimulates phosphoinositide turnover and a rise in intracellular calcium

NKR-P1 is a 60-kDa homodimer expressed on all rat NK cells. Previous studies by others suggest that NKR-P1 may play a role in NK cell activation because antibody to NKR-P1 stimulates the release of granules from NK cells, and anti-NKR-P1 causes redirected lysis by activated NK cells against targets that express FcR. To examine the mechanism of transmembrane signaling by NKR-P1, we studied the rat NK cell line, RNK-16. We here demonstrate that F(ab')2 antibody to NKR-P1 stimulates phosphoinositide turnover and a rise in intracellular calcium within RNK-16 cells. The response is augmented by cross-linking the F(ab')2 antibody. The phosphoinositide/calcium pathway is also stimulated by NKR-P1 in activated rat NK cells, although no response is detectable in polymorphonuclear cells, which also express NKR-P1. We also demonstrate that RNK-16 cells kill the anti-NKR-P1 (3.2.3) hybridoma and that exposure to the hybridoma target cells stimulates phosphoinositide turnover in RNK-16 cells. Both killing and phosphoinositide turnover are inhibited by F(ab')2 anti-NKR-P1, implicating NKR-P1 in both responses. In contrast, neither cytotoxicity nor phosphoinositide turnover is appreciably blocked by F(ab')2 anti-NKR-P1 in response to YAC-1 targets. Thus, with either target, killing is linked to phosphoinositide turnover, but killing of YAC-1 involves pathways that differ from those that direct killing of the anti-NKR-P1 hybridoma. Our studies support the hypothesis that NKR-P1 may serve as an activating cell-surface receptor on NK cells, and they clarify the mechanisms by which it activates NK cells.     

小脑顶核损毁对淋巴细胞功能的影响

目的：研究小脑顶核对淋巴细胞功能的调节作用,并初步探讨介导这种调节的中枢途径。方法：用海人酸（KA）毁损大鼠双侧小脑顶核,于术后第8d,取动物肠系膜淋巴结细胞和脾脏自然杀伤（NK）细胞进行体外培养,分别用四甲基偶氮唑（MTT）比色法检测由刀豆蛋白A（Con A）诱导的淋巴细胞的增殖反应,用流式细胞术测定NK细胞杀伤YAC-1肿瘤细胞的活性。同时用高效液相色谱法检测下丘脑中兴奋性神经递质谷氨酸的含量。结果：小脑双侧顶核注入KA后的第8d,小脑切片经Nissl染色,可见顶核内神经元胞体被有效破坏。此时,淋巴细胞对Con A诱导的增殖反应较双侧顶核注入生理盐水的对照组明显增强;而且NK细胞对YAC-1靶细胞的杀伤活性也明显高于对照组;同时下丘脑中谷氨酸含量较对照组明显减少。结论：小脑双侧顶核毁损可导致T和NK淋巴细胞功能明显增强,且下丘脑中谷氨酸含量显著下降,提示小脑顶核对淋巴细胞功能具有调节作用,小脑-下丘脑的谷氨酸能神经投射可能介导小脑顶核的免疫调节作用。     

Characterization of a monoclonal antibody enhancing porcine natural killer cell activity (PNK-E)

A monoclonal antibody, termed PNK-E, that functionally enhances porcine natural killer (NK) cell activity but not antibody-dependent cellular cytotoxicity (ADCC) is investigated in this report. When PNK-E and K562 target cells were simultaneously added to effector cells, killing of target cells could be detected as early as 30 min, and a dramatic enhancement of killing activity was observed in short term 51Cr-release assays. When a panel of five NK-sensitive targets were tested, PNK-E enhanced the killing of K562, MOLT-4, and U937 cells, but not the killing of CEM and YAC-1. F(ab)'2 fragments of PNK-E did not enhance NK activity, indicating a requirement for the Fc portion of PNK-E to elicit enhancement of NK. Immunofluorescence analysis shows that PNK-E antigen is expressed on approximately 15% of peripheral blood lymphocytes with a relatively dull fluorescence staining pattern. PNK-E-positive sorted cells were enriched for large granular lymphocytes (LGL) and contained all detectable NK activity as compared to the PNK-E-negative sorted cells. When analyzed by polyacrylamide gel electrophoresis, PNK-E antibody immunoprecipitated a protein from 125I-labeled peripheral blood lymphocyte (PBL) cell lysates that resolved as a single band of approximately 205 kDa under nonreducing conditions and as two bands of approximately 50 kDa and 47 kDa under reducing conditions. The present data demonstrate a functional association between PNK-E antigen and NK cell activation.     

A triggering structure recognized by G7 monoclonal antibody on porcine lymphocytes and granulocytes.

Monoclonal antibody (mAb) G7 has been developed and appears to recognize a triggering structure on porcine natural killer (NK) cells and granulocytes. G7 mAb binds to approximately 13% of lymphocytes, 70% of monocytes, and greater than 95% of granulocytes. G7 mAb does not react with B cells. G7 mAb immunoprecipitates a heterodispersed molecule of approximately 40 kDa. Functionally, whole but not F(ab')2 fragments of G7 mAb enhance NK killing of Fc receptor positive K562, U937, and MOLT-4 targets but not Fc receptor negative CEM, WEHI-164, or YAC-1 targets. Both whole and F(ab')2 fragments of G7 mAb inhibit lymphocyte-mediated antibody-dependent cellular cytotoxicity. Interestingly, G7 mAb induces dramatic levels of granulocyte killing against nucleated K562 targets. These results suggest that G7 mAb recognizes a trigger molecule involved in porcine cellular cytotoxicity.     

Analysis of rat natural killer cytotoxic factor (NKCF) produced by rat NK cell lines and the production of a murine monoclonal antibody that neutralizes NKCF

Natural killer cytotoxic factor (NKCF) is produced as a result of the interaction of murine, rat, or human natural killer (NK) cells with NK-susceptible targets. This factor has been linked to the target cell lysis mediated by the NK effector cell. In the present results, culture supernatants from rat large granular lymphocyte (LGL) tumors exhibited NKCF activity which lysed the susceptible targets, MBL-2 and YAC-1. NKCF production from these rat tumor lines was spontaneous and was not significantly increased by co-incubation of the LGL tumors with target cells, target cell membranes, or by preincubation of the LGL tumor cells with interferon or interleukin 2. In addition to NKCF activity, the supernatants lysed L929, indicating the presence of tumor necrosis factor (TNF) in these preparations. The presence of this latter cytokine was verified using specific antibodies to recombinant murine TNF which neutralized the L929 activity while not affecting the NKCF activity against MBL-2 or YAC-1. Mouse monoclonal antibodies (mAb) A0287, A0462, and A0316) which significantly inhibit the NKCF cytolytic activity of these LGL-derived supernatants were also produced. These antibodies were shown to cross-react with human NKCF in a manner similar to that seen in the rat. Interestingly these same mAb demonstrated no inhibition of L929 cytotoxicity from either LGL-derived supernatants or by recombinant murine or human TNF. To examine further the specificity of these antibodies, they were chemically linked to Sepharose 4B and found to remove a significant proportion of the NKCF cytolytic activity from LGL supernatants, while not affecting the TNF reactivities in these preparations. In addition, these antibodies demonstrated significant inhibition of cell-mediated cytotoxicity by rat LGL against YAC-1 target cells. Biochemical analysis of labeled NKCF-containing supernatants indicated the major protein recognized by these anti-NKCF mAb to be approximately 12,000 m.w. The use of these mAb against NKCF should be very useful in further purification and biochemical characterization of NKCF and in studying its role in a variety of cell-mediated cytotoxicity assays.     

Surrogate receptor-mediated cellular cytotoxicity. A method for "custom designing" killer cells of desired target specificity

Palmitate-derivatized antibody molecules can function as surrogate receptors when incorporated into the plasma membranes of nylon wool non-adherent spleen cells. Surrogate receptor molecules are attached to the membranes by insertion of the palmitate hydrocarbon chains into the phospholipid bilayer. This mode of attachment precludes interactions between surrogate receptors and intracellular and intramembranous structures. Despite these limitations, surrogate receptors consisting of either palmitate-derivatized intact antibody molecules or their corresponding F(ab')2 fragments specific for Ag on syngeneic B lymphocytes or hapten-modified EL-4 lymphoma cells can direct cell-mediated cytotoxic activity against the appropriate target. Treatment of the surrogate receptor-decorated effector cell populations with anti-asialo GM1 plus C eliminated the observed target cell lysis, suggesting a role for NK cells in this cytolytic process. The efficiency of this surrogate receptor-mediated cellular cytotoxicity parallels that of natural receptor-mediated target cell lysis and is not limited by inherent resistance of a target cell to NK cell-mediated cytotoxicity. Application of this technology to study the requirements for productive lytic interactions between effector and target cells may provide valuable insights into the mechanism of cell-mediated cytotoxicity. Furthermore, these results provide the rationale for future studies designed to evaluate the ability of surrogate receptors to focus cytotoxic cell activity onto a specified target in situ, in an attempted elimination of diseased cells.     

Selective inhibition of natural killer activity by the monoclonal antibodies OKT10 and VEP10 at the single cell level

The monoclonal antibodies, VEP10 and OKT10, which have been shown to recognize determinants on human natural killer (NK) cells, inhibit large granular lymphocyte (LGL) NK activity against K562, MOLT4, and CEM tumor target cells in the single cell conjugate agarose assay. Inhibition of NK activity by monoclonal antibodies was expressed independently of effector-target cell binding, as inhibitory activity could be demonstrated when the monoclonal antibodies VEP10 and OKT10 were added to preformed conjugates or to the LGLs and targets prior to the binding event. In addition, this inhibition was exerted on the effector cell and not the target cell since VEP10 and OKT10 did not react with determinants on K562 target cells. Furthermore, the 4F2 monoclonal antibody, which reacted with determinants on the LGL and all of the targets used, effected no inhibition of NK activity. Inhibition of killing by OKT10 and VEP10 was specific to endogenous NK activity since the same antibodies did not inhibit antibody-dependent cellular cytotoxicity (ADCC), mixed lymphocyte-generated NK, or cytotoxic T lymphocyte (CTL) activities.     

Natural anti-bacterial activity against Salmonella typhi by human T4+ lymphocytes armed with IgA antibodies

Peripheral blood mononuclear cells from normal volunteers possess natural anti-bacterial (NA) activity against S. typhi that can be measured in a 2-hr in vitro assay. Employing fractionation on nylon wool columns, Percoll gradients, plastic adherence, and E rosetting, the effector cell of NA activity appeared to be a lymphocyte of the T lineage rather than a macrophage, a B lymphocyte, or a large granular cell. Moreover, complement-dependent killing with monoclonal antibodies such as OKM1, OKB7, OKT8, 5.9 and the anti-natural killer cells AB8.28 did not reduce NA activity. On the contrary, this was completely inhibited when OKT3, OKT11, or OKT4 antibodies and complement were used to pretreat the effector lymphocytes. Indeed, T4+ cells sorted with a FACS displayed an extremely high NA activity against S. typhi. By pretreatment of peripheral lymphocytes with F(ab')2 fragments against human IgA, the NA activity was blocked. It is therefore suggested that NA activity by human cells might be a mechanism of defense against infections, acting as antibody-dependent cellular cytotoxicity expressed by T4+ lymphocytes coated with preexisting anti-Salmonella IgA antibodies.     

Lysis of uninfected and virus-infected cells in vivo: a rejection mechanism in addition to that mediated by natural killer cells

To examine the lysis of virus-infected cells in vivo, uninfected and lymphocytic choriomeningitis virus (LCMV)-infected L-929 cells were labeled in vitro with [125I]-iododeoxyuridine and implanted intravenously into mice. Natural cytotoxicity against both uninfected and virus-infected cells was demonstrated in normal uninfected mice, but LCMV-infected cells were cleared from the lungs and whole bodies more rapidly than uninfected cells. Treatment of L-929 cells with defective interfering LCMV inhibited standard virus synthesis and protected the target cells from enhanced in vivo rejection. The in vivo rejection was apparently mediated by a cellular constituent of the host immune response and not simply a result of virus-induced cytopathic effects on the target cell, as hydrocortisone acetate and cyclophosphamide each reduced rejection of both target cell types and eliminated the enhanced rejection of LCMV-infected cells. The enhanced rejection of LCMV-infected cells was not restricted by histocompatibility antigens, indicating that classic T-cell recognition was not involved in the lysis, and since the enhanced rejection of LCMV-infected cells was mediated by mice treated with cobra venom factor, complement was also not involved in the lysis. Although moderate levels of interferon (102 U/ml) were present in the sera and although there was a modest activation of natural killer (NK) cells in the lungs of LCMV-infected cell recipients but not uninfected cell recipients, the enhanced rejection of virus-infected cells did not appear to be NK cell mediated. Normal mice and mice depleted of NK cell activity by in vivo treatment with antibody to asialo ganglio-n-tetraosylceramide ( AGM1 ) rejected uninfected and LCMV-infected L-929 cells similarly. This antibody markedly inhibited the rejection of NK-sensitive YAC-1 cells. In addition to the natural cytotoxicity directed against virus-infected cells, a second nonspecific rejection mechanism appeared in response to treatment protocols which induced interferon. Polyinosinic-polycytidylic acid and infection with LCMV augmented in vivo rejection of both uninfected and LCMV-infected L-929 cells but eliminated the differential rejection of the virus-infected cells. Infection with LCMV also augmented the in vivo rejection of the NK-sensitive target cell, YAC-1. In vivo treatments with anti- AGM1 sera only moderately inhibited the elevated rejection of uninfected and LCMV-infected L-929 cells, indicating that the enhanced rejection of these target cells was predominantly mediated by a mechanism other than that mediated by NK cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Analysis of rat natural killer cytotoxic factor (NKCF): mechanism of action and relationship to other cytotoxic/cytostatic factors

Natural killer cytotoxic factor (NKCF) has been proposed as one of the factors that mediates lysis induced by natural killer (NK) cells. Recently, an excellent source of NKCF has been found to be the rat large granular lymphocyte (LGL) tumor (RNK) cell line. In this study, the kinetics of lysis of the NK-sensitive, tumor target YAC-1 by the RNK-NKCF was analyzed and found to parallel that seen with NK cell-mediated killing. RNK-NKCF was also capable of killing the NK-resistant target cell, MBL-2, over a longer time period. This study utilized monoclonal antibodies (mAbs) prepared against granule protein, previously termed "anti-NKCF mAbs." These mAbs established the nature of RNK-NKCF as compared to other known cytotoxic factors in combination with studies that show that RNK-NKCF causes both 51Cr release and nuclear degradation. Antibody inhibition experiments have verified that RNK-NKCF is unique from tumor necrosis factor (TNF), leukoregulin, or complement. Anti-NKCF mAbs were capable, however, of neutralizing the RNK cell granule activity against YAC-1 tumor target cells. Based on these results, the ability of anti-NKCF mAbs to neutralize the cytolytic function of pore-forming protein (PFP), a component of these granules, was analyzed. In these experiments, the antibodies were found to inhibit the hemolytic activity of granules. Interestingly, the antibodies were effective in inhibiting the activity of unbound granule proteins as well as those bound to sheep red blood cell (SRBC) targets. Further studies to examine the target lysis requirements demonstrated that in contrast to PFP, the RNK-NKCF was able to lyse the tumor target in the absence of calcium. In addition, treatment of targets with RNA and protein synthesis inhibitors indicated that the mechanism of lysis of NKCF is quite unique from other defined cytotoxic moieties.     

Decay-accelerating factor expression on either effector or target cells inhibits cytotoxicity by human natural killer cells.

Previous studies have shown that freshly isolated CD16+ NK cells are deficient in the expression of decay-accelerating factor (DAF), or CD55, a membrane regulator of C3 activation. In this study we investigated the significance, for NK cell-mediated lysis, of DAF expression on the target and effector cells. The effect of DAF expression on the susceptibility of NK cell targets was investigated by several means: first, DAF- cell lines were cloned from K562; second, the cloned DAF- cells were reconstituted with exogenous purified DAF; and third, anti-DAF F(ab')2 was used to block DAF function on the DAF+ K562 cells. Consistently, the presence of DAF in the target cell membrane, either naturally occurring or experimentally incorporated, afforded the target cell protection against lysis, and this protection could be blocked with anti-DAF. Similarly, targets for antibody-dependent cell-mediated cytotoxicity with exogenous DAF incorporated in their plasma membrane became less sensitive to antibody-dependent cell-mediated cytotoxicity by NK cells compared with the same target cells without incorporated DAF in their membranes. DAF incorporated in the plasma membranes of the effector NK cells made the NK cells less effective at killing K562 targets. The known function of DAF is to regulate C3 activation, and we were able to demonstrate that the isolated NK cell is capable of releasing C3. It is also possible that the participation of DAF in NK cell function represents a new, noncomplement-dependent function for DAF.     

Natural cytotoxicity against mouse hepatitis virus-infected cells. II. A cytotoxic effector cell with a B lymphocyte phenotype

The effector cell in mouse spleen which mediates natural cytotoxicity against mouse hepatitis virus (MHV)-infected target cells was characterized. The target cells were MHV-infected BALB/c 3T3, and the assay time was 3 hr. The effector cell, designated virus killer (VK) cell for the purpose of discussion, had the following phenotype: lymphocyte morphology, plastic-nonadherent, nylon wool-adherent, nonphagocytic, cyclophosphamide-sensitive; by antibody plus complement (C) depletion studies, it was asialo GM1-, NK 1.2 alloantigen-negative, Thy-1.2-, Lyt-5-, and macrophage antigen-negative; by rosetting techniques, it was Fc receptor-positive and surface Fab+; by flow cytometry (FACS) analysis, it was Lyt-2-, MAC-1-, Ia+, IgG (gamma)+, IgM (mu)+, IgD (delta)+, and B cell lineage antibody B-220+. NK cells, measured for cytotoxicity on YAC-1 cells, were similarly tested and were found to differ from the VK cell in the following properties: nylon wool-nonadherent, asialo GM1+, NK alloantigen-positive, Lyt-5+, surface Fab-, MAC-1+, Ia-, IgG-, IgM-, IgD-, and B-220-. The VK effector cell had a phenotype highly distinguishable from NK cells, effectors most commonly associated with antiviral natural cytotoxicity. The VK cell had a phenotype identical to that of a B lymphocyte and was identified as such. Although the effector cells displayed cell surface antibody, the antibody did not appear to be involved in lysis, because lysis could not be blocked by F(ab)'2 directed against Fab, mu, or delta. Cytotoxicity was more likely associated with recognition of the B lymphocyte surface by the MHV glycoprotein E2, as shown in the accompanying companion paper. This is the first demonstration that natural cytotoxicity can be mediated by B lymphocytes.     

Activation of cloned human natural killer cells via Fc gamma RIII

The Fc gamma RIII (CD16) Ag on human NK cells involved in antibody-dependent cellular cytotoxicity has been demonstrated to be an important activation structure. The present studies were carried out to further characterize the functional role of the CD16 Ag and the mechanisms whereby cytotoxicity is activated by using human NK clones. In phenotypic studies Fc gamma RIII was found to be expressed heterogeneously on various human cloned NK cells. Expression on CD3- and CD3+ clones varied with the donor and mAb used for detection. Functional data demonstrated that cytotoxicity against NK-resistant target cells can be induced in CD3-CD16+ NK clones and CD3+CD16+ clones with NK activity when various CD16 mAb were used. CD16 antibodies but not reactive isotype control antibodies induced cytotoxicity. In contrast to complete CD16 antibodies F(ab')2 fragments were not able to activate the cytotoxic mechanism. Both an antibody against FcR on the target cell (Fc gamma RII) and a CD11a antibody blocked induction of cytotoxicity. These results suggest that three steps are critical for activation of CD16+ cells via Fc gamma RIII: 1) specific binding of CD16 antibodies to Fc gamma RIII on effector cells irrespective of the epitope recognized; 2) cross-linking of effector cell CD16 Ag through binding of the Fc site of CD16 antibodies via corresponding FcR on the target cell membrane; and 3) interaction of CD11a/18 molecules with the target cell membrane.     

Inhibition of human antibody-dependent cellular cytotoxicity, cell-mediated cytotoxicity, and natural killing by a xenogeneic antiserum prepared against "activated" alloimmune human lymphocytes

Xenogeneic antiserum (RH1) was prepared in Lewis rats by hyperimmunization with concanavalin A- (Con A) activated alloimmune human lymphocytes. The antiserum RH1 effectively inhibited human antibody-dependent cellular cytotoxicity (ADCC), cell-mediated cytotoxicity (CMC), and natural killing (NK) in the absence of complement (C). Inhibition by RH1 was dependent on the dilution of antiserum employed and the number of cytotoxic lymphocytes present during cytolysis. Pretreatment of lymphocytes with RH1 or the presence of RH1 in culture did not inhibit lymphocyte proliferation stimulated by Con A, phytohemagglutinin, or allogeneic cells; lymphokine production as measured by leukocyte-inhibiting factor production; antibody-dependent C lysis; or CMC mediated by murine cytotoxic T lymphocytes. Analysis of the mechanism of inhibition of cytotoxicity by RH1 revealed that 1) RH1 was not cytotoxic for human lymphocytes at 37 degrees C in the absence of C; 2) purified F(ab')2 fragments were equally inhibitory as whole serum; 3) pretreatment of lymphocytes with RH1 effectively inhibited their capacity to mediate ADCC, CMC, or NK, and this effect was reversible by culturing the cells overnight at 37 degrees C; 4) RH1 did not inhibit target cell binding by K cells, effector cells of ADCC, or alloimmune T cells, but did inhibit binding by NK cells; and finally, 5) the addition of RH1 to preformed lymphocyte-target conjugates in a single cell cytotoxicity assay inhibited killing of the bound target cells in all three systems without disrupting the conjugates. Collectively, these findings suggest that RH1 antiserum interacts with structures present on the surfaces of cytotoxic lymphocytes that are involved in the activation of the lytic mechanism(s) or with the actual lytic molecule or molecules themselves. Furthermore, the ability of RH1 to inhibit ADCC, CMC, and NK during the post-binding cytolytic phase of these reactions indicates that binding and cytolysis are distinct and separate events in all types of cell-mediated cytolysis.     

In vivo administration of anti-CD3 monoclonal antibodies or immunotoxins in murine recipients of allogeneic T cell-depleted marrow for the promotion of engraftment.

The role of host anti-donor cells in rejection of fully allogeneic donor T cell-depleted marrow was investigated by using mAb or immunotoxins directed against T cell or NK cell determinants. Immunotoxins consisting of mAb conjugated to a low oligosaccharide-containing fraction of purified ricin toxin A chain (RTA) facilitated in vivo-depletion of target cell populations. BALB/c and DBA/1 donors were selected based upon their expression (BALB/c) or lack of (DBA/1) hemopoietic histocompatibility (Hh1) Ag, which may serve as targets for donor rejection in C57BL/6 hosts. When studies directed toward eliminating CD3+ cells were performed in both systems, injections of intact anti-CD3 mAb or anti-CD3-RTA reproducibly produced the highest engraftment values. The fact that engraftment values obtained with anti-CD3 or anti-CD3-RTA therapy in allogeneic systems were substantially higher than in syngeneic controls suggested that engraftment stimulatory proteins were released upon TCR engagement. Elevated levels of cytokines and a high mortality rate in allogeneic recipients confirmed that this was the case. Nonstimulatory preparations of anti-CD3F(ab')2 fragments and anti-CD3F(ab')2-RTA promoted engraftment of both types of allogeneic marrow, as measured by short term 125I-IUdR assays, suggesting that stimulation was not a prerequisite for engraftment. Recipients of anti-CD3F(ab')2 or anti-CD3F(ab')2-RTA showed a marked reduction of host CD3+ cells as measured by immunofluorescence and flow cytometry. In long term chimerism studies, recipients of Hh1-disparate marrow and anti-CD3F(ab')2 had a dramatic increase in donor cell engraftment as compared to controls, indicating that positive effects on engraftment were long lived. Studies further showed that BALB/c donor cells exhibiting an Hh1 disparity were rejected by host cells expressing NK1.1 or Ly-1 (NK cells and T cells). In contrast, DBA/1 donor cells that were not Hh1-disparate were rejected by cells expressing Ly-1, but not NK1.1 (T cells only). These studies provide definitive data that CD3+ cells participate in the rejection of either Hh1+ or Hh1null T cell-depleted allografts and offer new strategies for alloengraftment using regimens containing nonmitogenic anti-CD3.     

GP120 specific cellular cytotoxicity in HIV-1 seropositive individuals. Evidence for circulating CD16+ effector cells armed in vivo with cytophilic antibody

Fresh circulating PBMC from HIV-1 seropositive individuals have been found to mediate specific, non-MHC restricted lysis of targets expressing the major envelope glycoprotein of HIV-1, gp120, in 6-h 51Cr release assays. This gp120 specific cell-mediated cytotoxicity (CMC) is broadly reactive against target cells infected with a wide range of viral isolates, is IL-2 augmentable, and is mediated by a CD16+, Leu-7+, CD15-, CD3- population of NK/K cells. The presence of FcR (CD16) on these cells suggested that the lytic specificity for gp120 might be directed by cytophilic antibody bound to the cell surface. Affinity purified F(ab')2 antibody fragments specific for the Fc and F(ab')2 portions of human IgG were used in attempts to block gp120 specific lysis. A 1/50 dilution of these antibodies inhibited gp120 specific cytolytic activity by more than 90% while exhibiting a minimal effect on NK/K cell lysis of K562 targets. The blocking activity of these fragments demonstrates the direct involvement of cytophilic antibody in CMC. In attempts to isolate this cytophilic anti-HIV-1 antibody, short 56 degrees C incubations were used to dissociate antibodies from the surface of PBMC of seropositive individuals. The supernatants generated in this manner exhibited specific gp120 activity in antibody-dependent cellular cytotoxicity assays. The ability of Staphylococcal protein A to remove this activity confirms the presence of cytophilic antibody on freshly isolated PBMC. Selective enrichment of specific cell subpopulations revealed the origin of the cytophilic antibody to be CD16+ NK/K cells and not B cells, T cells, or monocytes/macrophages. These studies show that the gp120-specific CMC seen in HIV-1 seropositive individuals is directed by cytophilic antibody bound to circulating CD16+ NK/K cells and represents a form of direct antibody-dependent cellular cytotoxicity which may provide a primary cytotoxic host defense.     

Inhibition of human natural killer activity by lysosomotropic agents

We have examined the effect of three lysosomotropic amines on human NK cell activity. Dansylcadaverine (DCA), diphenylamine (DPA), and lidocaine (LID) inhibited NK activity of nylon wool-purified and large granular lymphocyte (LGL)-enriched cell preparations. Cadaverine (CAD), an analog of DCA that does not affect lysosomal function, had no effect on NK activity. Binding of the K562 target cells to effector cells, as assessed in a single cell assay, was not inhibited by DCA, DPA, or LID. Cytotoxicity was inhibited by DCA and DPA only when these drugs were added within 5 min after the initiation of NK assays. In contrast, LID inhibited NK activity even when added 60 min after the addition of effector cells to target cells. All three amines that inhibited NK activity also reduced the intracellular concentration of the lysosomal enzyme beta-glucuronidase without affecting the activity of the cytoplasmic enzyme lactate dehydrogenase. Kinetic analysis revealed that LID inhibited both the maximum velocity (Vmax) of the cytotoxicity reaction as well as the affinity constant (Km); whereas DCA and DPA only inhibited Vmax.     

Suppression by cannabinoids of a cloned cell line with natural killer cell activity

Preincubation of a cloned cell line with natural killer (NK) cell activity, as well as splenic mononuclear cells with either delta 9-tetrahydrocannabinol (THC) or 11-hydroxy-delta 9-tetrahydrocannabinol (11-OH-THC) suppressed NK cytolytic activity against YAC-1 target cells in a dose-dependent manner. THC was more inhibitory for cloned cells than 11-OH-THC and suppressed the lytic activity of these cells without reducing cell viability in the concentration range of 5 micrograms/ml (16 microM) to 10 micrograms/ml (32 microM). THC also inhibited proliferation of cloned NK cells, but this inhibitory effect was reversible in that extensive washing of cells following cannabinoid pretreatment eliminated the suppressive effect. Single-cell analysis revealed that THC did not inhibit the binding of cloned NK cells to target cells and further showed that NK cells freshly isolated from mouse spleen were restricted in killing capacity following binding to target cells. Therefore, THC and 11-OH-THC appear to directly inhibit NK cell cytolytic activity in a postbinding stage.     

The chemokine CX3CL1 regulates NK cell activity in vivo

In vitro, chemokines can both activate and induce migration of NK cells. However, little is known about how chemokines influence NK cell activity in vivo. We studied the role of CX(3)CL1 and its receptor, CX(3)CR1, in modulating NK cell activity in an established in vivo model of tumour cell clearance. Radiolabelled YAC-1 target cells intravenously injected into C57BL/6 mice rapidly localize to the lungs and are cleared by NK cells. In mice pre-treated with blocking anti-CX(3)CL1 or anti-CX(3)CR1 Ab, target cell clearance decreased by four- to fivefold (p<0.001). In vitro, we found no effect of anti-CX(3)CL1 or anti-CX(3)CR1 Ab on NK lysis of target cells. We further examined adhesion of NK cells to Py-4-1 endothelial cells. NK cell binding to activated endothelial monolayers was significantly inhibited by anti-CX(3)CR1 Ab or soluble CX(3)CL1 (p<0.001). These studies identify a critical role for CX(3)CL1 in modulating NK cell activity in vivo.