Inhibition by cortisol of human natural killer (NK) cell activity

The effects of cortisol on the natural killer (NK) activity of human peripheral blood mononuclear (PBM) cells were studied in vitro using a direct 4-h 51Cr-release assay and K 562 cell line as a target. Preincubation for 20 h of PBM cells drawn from healthy donors with 1 X 10(-8) to 1 X 10(-5) M cortisol resulted in a significant decrease of NK cell activity. The magnitude of the suppression was directly related to the steroid concentration and inversely related to the number of effector cells. Cortisol was able to minimize the enhancement of NK cytotoxicity obtainable in the presence of immune interferon (IFN-gamma). A significantly higher suppression was achieved after sequential exposure of PBM cells to cortisol and equimolar levels of prostaglandin E2 (PgE2). The concomitant incubation with theophylline and isobutyl-methylxanthine failed to enhance the cortisol-induced suppression, whereas PgE2-dependent inhibition significantly increased after exposure of PBM cells to methyl-xanthines. The inhibitory effect of cortisol was partially or totally prevented by the concomitant incubation with equimolar amounts of 11-deoxycortisol and RU 486 but not of progesterone. Treatment of NK effectors with a monoclonal anti-human corticosteroid-binding globulin (CBG) antibody produced an enhancement of the spontaneous NK activity and a partial suppression of cortisol-mediated effects. Our results suggest that endogenous glucocorticoids play a role in the regulation of NK cell-mediated cytotoxicity. Since the effect of cortisol was additive to that of PgE2 and was not changed by phosphodiesterase inhibitors, it is conceivable that the hormone acts at a level different from the adenylate cyclase-phosphodiesterase system. Data obtained with the use of antiglucocorticoids and the anti-CBG antibody are compatible with a role both of high-affinity glucocorticoid receptors and of CBG in mediating cortisol action on the human NK cell activity.     

Interleukin 2 dependence of human natural killer (NK) cell activity

When purified populations of human natural killer (NK) cells were tested for cytotoxic activity in the presence of partially purified preparations of human interleukin 2 (IL 2), a definite, dose-dependent linear increase in reactivity was observed. To determine whether such augmentation by IL 2 might reflect an important aspect of the physiologic regulation of NK activity, we examined the effects of monoclonal antibodies against human IL 2 on spontaneous NK activity. The presence of such antibodies during the 4-hr cytotoxicity assay resulted in significant inhibition of NK activity, and when the NK cells were pretreated for 16 to 20 hr with anti-IL 2, little or no activity remained. These data suggest that the spontaneous cytotoxic activity of NK cells is dependent on their continued exposure to IL 2. The reduction in NK activity resulting from treatment with anti-IL 2 could be at least partially restored by exposure to only low amounts of partially purified IL 2. These data have provided the basis for formulating a novel model of NK cell activation.     

In vitro augmentation of rat natural killer (NK) cell activity

In vitro augmentation of rat natural killer (NK) cell activity was produced by 2 types of treatment. Increased activity occurred "spontaneously" when spleen cells were cultured alone at 37 degrees C. This augmentation was dependent on the presence of adherent, phagocytic cells, presumably macrophages, and was independent of LPS of FCS. Normally low levels of NK activity, present in macrophage-depleted cultured cells, could also be boosted in vitro by incubation with Corynebacterium parvum. This augmentation appeared to be independent of both B cells and macrophages and may be due to stimulation of rat NK cells themselves. Both forms of augmentation were associated with the production of interferon, were found in rats of all ages and strains tested, and should provide an excellent in vitro system for detailed studies of activation of rat NK cells.     

Mutations in mice that influence natural killer (NK) cell activity

A series of mutations in mice was tested for splenic NK-cell activity against YAC-1 target cells. Mutations at six loci that reduce NK-cell activity in the homozygous state were identified, including beige (bg), hairless (hr), motheaten (me), obese (ob), steel (Sl) and, to a lesser extent, dominant spotting (W). Motheaten mice displayed the most profound NK-cell deficiency, with NK-cell activity virtually absent. Two mutations, nude (nu) and lymphoproliferation (Ipr), produced elevated NK-cell-mediated lysis. The double homozygous recessivenu/nu bg/bg nude-beige mouse was viable and NK-cell-deficient, with activity slightly higher than that of +/?bg/bg beige littermate controls. Pigmentation mutants related to beige, including pale ears (ep), pearl (pe), and ruby eyes (ru ^2J ) did not dramatically influence NK-cell levels. Unlike the obese gene, other mutations leading to obesity, diabetes (db) and yellow (Asuy), did not impair NK-cell function. The possible site of gene action of these mutants in the NK-cell pathway is discussed.     

Redistribution of natural killer (NK) cell frequency and NK cytotoxic activity in primary IgA nephropathy.

Recent findings have indicated an imbalance of immune responsiveness in primary IgA nephropathy (IgAN). Thus natural killer (NK) cell frequency and NK cytotoxicity were evaluated in fifteen IgAN patients. CD8+, CD11+, CD56+ and CD57+ lymphocyte percentages in IgAN individuals fell within normal values, while a significant decrease of CD16+ cells was observed in the same group of patients. In contrast, NK activity overlapped that seen in controls as assessed by an agarose-single cell cytotoxic assay. To further investigate the discrepancy between CD16+ cell level and NK cytotoxic activity in IgAN, the proportion of CD11+ CD57+, CD56+ CD16+ and CD57+ CD16+ lymphocytes was determined. In spite of the unaffected CD56+ CD16+ cell frequency, IgAN subjects exhibited a significant decrease of CD11+ CD57+ and CD57+ CD16+ lymphocyte percentages in comparison to controls. It is suggested that a redistribution of NK lymphocyte subsets occurs in IgAN. This may have an important role in the impairment of the immunoregulatory network.     

Natural killer (NK) cell activity of first trimester human decidua

The NK cell functional capacity of first trimester human decidua against K562 targets was assessed in a 3-hr CRA. Collagenase dispersal combined with plastic adherence, nylon wool passage, and density gradient centrifugation yielded NKH-1 (Leu 19) positive enriched decidual large granular lymphocyte fraction (mean 75% positive). Decidual effectors displayed reduced lytic activity compared with autologous PB effectors at every effector:target ratio but this difference in cytotoxicity was abolished by short-term culture before the CRA. Decidual effectors treated with 50 units rIL-2 showed increased lytic activity compared to untreated decidual cells. By FACS analysis the majority of NKH-1 positive decidual effectors were CD3 and CD16 negative which corresponds with a minority PB NK population. The implications of a population of functional NK cells in early pregnancy decidua for the materno-fetal relationship is discussed.     

Suppression of natural killer (NK) cell activity of spleen cells by thymocytes

The in vitro influence of thymus cells on natural killer cell activity of spleen cells against prelabeled target cells (YAC-I and RL♂I) has been studied in syngeneic as well as in allogeneic murine models. In mixing experiments to demonstrate suppression, total thymocytes have been found to have no effect on NK activity of syngeneic or allogeneic spleen cells. Among several thymocyte fractions separated by velocity sedimentation, a relatively faster sedimenting fraction showed remarkable suppression of NK activity by spleen cells against two target cells. The suppressive effect of this particular fraction on NK activity was demonstrated to be proportional to the cell dose. The suppressive function was resistant to irradiation at 1000 or 2000 rad administered in vitro and was not restricted by the major histocompatibility complex. Moreover, the thymocyte fraction which induced suppression was not sensitive to NK-mediated cytolysi? by syngeneic spleen cells. The suppression of NK cytolysis in vitro by certain subpopulations of thymocytes as observed in the present studies may be consistent with a role for the thymus in regulating NK activity in vivo.     

Impaired natural killer (NK) cell activity in leptin receptor deficient mice: leptin as a critical regulator in NK cell development and activation

Leptin is an adipocyte-secreted hormone that centrally regulates weight control via targeting the leptin receptor in the central nervous system. Recently, the leptin receptor has also been detected in peripheral systems including immune tissues, suggesting that leptin may play an important role in the regulation of immune function. It has been shown that leptin modulates functions of T lymphocytes, B lymphocytes, and monocytes/macrophage. However, the effect of leptin on NK cells remains unknown. In the present paper, we observed that percentage of NK cells and total amount of NK cells in the liver, spleen, lung, and peripheral blood were declined in leptin receptor deficient mice (db/db B6 mice), indicating that NK cell development was vigorously influenced by leptin receptor deficiency. Both basal and poly I:C-stimulated NK cell activation (CD69 surface marker expression) were retarded in db/db mice. In addition, leptin treatment increased the basal or synergistically enhanced IL-15- and poly I:C-induced specific lysis of splenocytes in normal littermates but not in db/db mice. Taken together, these findings suggest that leptin plays an important role in NK cell development and activation.     

A 14-mer Hsp70 peptide stimulates natural killer (NK) cell activity

Compared with normal cells, tumor cell lines exhibit an unusual plasma membrane localization of heat shock protein 70 (Hsp70). This tumor-selective Hsp70 membrane expression has been found to correlate with an increased sensitivity to lysis mediated by human natural killer (NK) cells that transiently adhere to plastic following cytokine stimulation. A human Hsp70-specific monoclonal antibody (mAb) detects membrane-bound Hsp70 on viable tumor cells and blocks the immune response of NK cells against Hsp70-expressing tumor cells. By peptide scanning (pep-scan) analysis, the epitope of this mAb was mapped as the C-terminal-localized 8-mer NLLGRFEL (NLL, amino acids [aa] 454-461). Most interestingly, similar to full-length Hsp70 protein, the N-terminal-extended 14-mer peptide TKDNNLLGRFELSG (TKD, aa 450-463) was able to stimulate the cytolytic and proliferative activity of NK cells at concentrations equivalent to full-length Hsp70 protein. Blocking studies revealed that an excess of the 14-mer peptide TKDNNLLGRFELSG inhibits the cytolytic activity of NK cells similar to that of Hsp70 protein. In comparison, other TKD-related peptides, including the 8-mer antibody epitope NLLGRFEL (aa 454-461), the 12-mer TKDNNLLGRFEL (aa 450-461), the 13-mer C-terminal-extended peptide NLLGRFELSGIPP (aa 454-466), the 14-mer TKD-equivalent sequences of Hsp70hom TKDNNLLGRFELTG (aa 450-463), Hsc70 TKDNNLLGKFELTG (aa 450-463), and DnaK AADNKSLGQFNLDG (aa 447-460) failed to activate NK activity.     

Inhibition of human natural killer (NK) activity by calcium channel modulators and a calmodulin antagonist

The presence of calcium (Ca2+) in the culture medium is a requirement for the NK cytotoxic reaction. To further explore the role of Ca2+ and calmodulin (a cytoplasmic protein that mediates most of the biological effects of Ca2+) in this process, we evaluated the effects of nifedipine (a Ca2+ channel antagonist), BAY-K-8644 (a Ca2+ channel agonist), and haloperidol (an inhibitor of calmodulin) on the NK activity of human peripheral blood mononuclear cells (PBMC), and the augmentation of this activity by recombinant interleukin 2 (r-IL 2) and interferon-gamma (r-gamma-IFN). We found that all of these drugs inhibit NK activity in a dose-dependent fashion. This appears to result from interference with the programming for lysis stage of the lytic process. In contrast, the presence of these agents during the incubation of PBMC with r-IL 2 or r-gamma-IFN did not induce any change in the enhancement of NK activity. These data suggest that Ca2+ exerts its effect at the intracellular level during the NK cytotoxic process, and that the augmentation of NK activity by lymphokines is independent of the calcium-calmodulin system.     

Dendritic cells (DC) promote natural killer (NK) cell functions: dynamics of the human DC/NK cell cross talk

Dendritic cells (DC) were originally found critical in the setting of cognate immune responses. We first demonstrated that DC can also induce mouse NK cell activation and NK cell dependent-antitumor effects in mice. Here we analyzed the dynamics between DC and NK cells in human in vitro model systems. In the absence of LPS, DC do not trigger resting NK cells. Conversely, in the presence of LPS, resting bulk NK cells interacting with DC acquire CD25 and CD69 surface expression, produce high levels of IFN-gamma and lyse DAUDI cells. On activated IL-2 dependent NK cell lines, regardless of their differentiation stage, DC maintain or enhance NK cell proliferation and effector functions in the absence of exogenous cytokines. While IL-12, IL-15 and IL-18 are not critical, a direct cell-to-cell contact is mandatory for NK activation by DC and required for optimal proliferation. These data imply that DC also modulate human NK cell innate effector functions.     

Studies on murine natural killer (NK) cells. V. Genetic analysis of NK cell markers

This paper attempts to clarify the number and nomenclature of murine natural killer (NK) cell specific alloantigens by defining the genetic relationships between them, that is, are they coded by loci which are independent, allelic, or linked. Strain typing and F2 analyses using five alloantisera (C3H X BALB/c)F1 anti-CE, CE anti-CBA, NZB anti-BALB/c, C3H anti-ST, and BALB/c anti-DBA/2 revealed that (a) the alloantigens NK-1.1 and NK-3.1 are determined by distinct loci which are linked on the same chromosomes, (b) the alloantigen NK-2.1 is determined by an independently segregating locus to those coding for NK-1.1 and NK-3.1, (c) the alloantisera, CE anti-CBA and NZB anti-BALB/c, which have been designated anti-NK-2.1 alloantisera recognize different alloantigens coded by independent genetic loci. Thus, these five alloantisera detect four NK cell specific alloantigens which, based on the chronology of their discovery, have been designated NK-1.1-(C3H X BALB/c)F1 anti-CE, NK-2.1-CE anti-CBA, NK-3.1-C3H anti-ST, and BALB/c anti-DBA/2 and NK-4.1-NZB anti-BALB/c.     

Specific inhibition of natural killer (NK) activity against different alloantigens

Allogeneic lymphocyte cytotoxicity (ALC), i. e., rapid rejection of i. v. injected allogeneic lymphocytes in unprimed hosts, is an example of NK activity. Apparently anomalous rejection patterns, such as acceptance of F₁ hybrid cells by parental hosts and rejection of parental cells by F₁ hybrid hosts in many strain combinations, would fit the hypothesis that the effector cells in ALC recognize the absence of certain self-molecules (passwords) rather than the presence of nonself determinants. However, cold target inhibition studies showed that ALC displays allospecificity: when a mixture of radiolabeled AO and DA cells were injected i. v. into euthymic or athymic PVG rats, adding a surplus of cold DA cells reduced killing only of labeled DA cells and vice versa. Furthermore, semiallogeneic cold target cells were ineffective in inhibiting elimination of fully allogeneic cells, which supports the argument against a modification of the hypothesis that self-determinants inhibit a postbinding stage of lysis. Finally, (DA × AO)F₁ cells injected into (DA × PVG)F₁ hosts were rapidly rejected, despite the fact that donor and host shared expressed DA determinants. In sum, our results show that a hypothesis based on inhibition of killing by self-determinants can only be sustained with extensive modifications, and favor the alternative mechanism that the effector cells positively recognize the presence of allospecific determinants on the target cell surface.     

Immunoregulatory role of in vitro differentiated macrophages on human natural killer (NK)-cell activity

Immunoregulatory effects of human macrophages on natural killer (NK) activity were studied. Monocytes were isolated by adherence to plastic, after leukapheresis of normal blood donors, and cultured for 1 to 14 days. In vitro-differentiated (5-7 days) human macrophages consistently and significantly (P less than 0.01) augmented NK activity of fresh autologous or allogeneic PBMNC. During culture, these macrophages also developed increased antitumor cytostatic activity. The optimal time for both the expression of cytostatic activity and up-regulation of NK activity was 5-7 days in culture. In contrast, 12- to 14-day macrophages significantly suppressed NK activity and had less cytostatic activity. Macrophages in culture demonstrated shifts in Leu-M3+HLA-DR+ phenotype from the mean of 60% +/- 11 (SD) in fresh monocytes to 90% +/- 5 between Days 5 and 7 in culture and then down to 10% +/- 5 in 14-day cultures. The activity of NK (CD56+CD3-) cells, purified by Percoll gradient centrifugation and flow cytometry, was up-regulated directly by in vitro-differentiated macrophages at low macrophage to NK cell ratios, and this up-regulation was not dependent on T lymphocytes or other accessory cells. The modulation of NK activity by differentiated macrophages was not MHC-restricted and depended on the viability and cellular integrity of macrophages. Sonicated macrophages could no longer up-regulate NK activity. This study shows that antitumor effects mediated by human in vitro differentiated LeuM3+HLA-DR+ macrophages may simultaneously involve more than one mechanism, namely direct cytostasis of tumor cells and activation of NK cells.     

T cell nature and heterogeneity of recognition structures of human natural killer (NK) cells

Very low doses of trypsin (5 micrograms/ml) are sufficient to ablate NK cell activity. This finding was used to make several observations, and we have attempted to relate these observations to specific cell surface macromolecules. First, trypsinized effector cells no longer lysed seven different NK-susceptible targets, but the lysis of three additional targets was unaffected. These results suggest a heterogeneity of recognition potential that is inconsistent with the notion that there is only one class of NK "receptors" and one class of "target structures." Trypsin does not affect the conjugation of effector and target cells. Secondly, we have tried to identify those cell surface molecules that are affected by this low dose of enzyme. The examination of the 125I-labeled glycoprotein fraction NK-enriched cells showed that at least four molecules are cleaved, one of which may be in the T200 family. The examination of the [3H]galactose-labeled cell surface glycoproteins suggested in particular that some high m.w. glycoproteins were affected at the dose of trypsin that ablates NK function. Analysis of those molecules that we previously implicated in NK function, defined by monoclonal antibodies that block NK lysis, allowed us to rule out a role for the Tp 50 and Lp95-150 structures, while providing additional evidence of a role for the T200 glycoproteins in the trypsin-sensitive stage of cytolysis. Finally, closer examination of the electrophoretic mobilities and trypsin sensitivity of the T200 structures on highly enriched NK cells showed these structures to be indistinguishable from the T cell form of T200, yet quite distinct from the monocyte form. These results are therefore consistent with the possibility that NK cells are of the T rather than the monocyte lineage, and furthermore support a role for the T200 structure in the post-binding trypsin-sensitive stage of the NK cytolytic process.     

In vitro modulation of mouse natural killer (NK) cell activity by the serum thymic factor (FTS)

Previous studies indicated that the serum thymic factor (FTS) could modulate in vivo the level of splenic natural killer (NK) cell activity in mice. The present report shows that such an effect is also observed after a short term in vitro incubation of the effector cells with FTS. The regulatory effects of FTS result in an increase or a decrease of the splenic NK cell cytotoxicity depending upon the age and the mouse strain. Furthermore, FTS is able to enhance the NK cell activity of thymus and bone marrow cells which are known to be weakly reactive in NK cytotoxicity. Depletion experiments demonstrated that the FTS-induced increase of NK cell activity was not mediated by Thy 1+ cells nor macrophages, thus suggesting a direct action of FTS on the effector cells. Comparative studies using other thymic hormones revealed similar patterns of reactivity. These results favor the hypothesis of a close relationship between the thymus and NK cells.     

Enhanced natural killer (NK) cell activity and NK-sensitive thymic cells in murine muscular dystrophy

Studies have shown that there is an abnormality in the thymus of dystrophic mice with respect to age-dependent thymus weight changes and altered morphology (T. DeKretser and B. Livett, Nature (London), 263, 682, 1976). Recently, others have shown that natural killer (NK) cells can lyse cells of a large, immature, rapidly dividing cell subpopulation within the thymus of normal young (3 weeks of age) mice (M. Hansson, K. Karre, R. Kiessling, J. Roder, B. Anderson, and P. Hayry, J. Immunol., 123, 765, 1979). The NK susceptibility of dystrophic mouse thymocytes as targets was therefore studied. Spleen cells from normal (+/+) and dystrophic ($\text{dy}{}^{\mathrm{2J}}\text{dy}{}^{\mathrm{2J}}$) male C57BL/6J mice 8–10 weeks old were passed over nylon wool and the nonadherent cells were incubated with ⁵¹Cr-labeled YAC-1 lymphoma target cells or thymocytes in a ⁵¹Cr-release assay. Spleen cells from dystrophic mice killed twofold more YAC-1 target cells than did spleen cells from normal mice. Thymocytes from 3- to 4-week-old dystrophic mice were three to four times more susceptible to NK lysis by dystrophic mouse spleen cells as compared with normal mouse spleen cells. Spleen cells from dystrophic mice had the same NK activity against dystrophic and normal mouse thymocytes as targets. Normal mouse spleen cells killed three- to fourfold more dystrophic mouse thymocytes than that of normal mouse thymocytes as targets. Target cellbinding studies revealed that conjugate-forming cells from nylon nonadherent dystrophic mouse spleen cells were found to be two- to fourfold greater than for normal mouse spleen cells using YAC-1 tumor cells as targets. The number of lymphocytes bound per YAC-1 target cell ranged from 2 to 5 for dystrophic mouse spleen cells as compared with 1 to 2 for the normal control group. Using both normal and dystrophic mouse thymocytes as targets, the conjugate-forming cells from dystrophic mouse spleen cells were also found to be twofold greater than in the normal control group. Cold target inhibition studies revealed that the natural killing of dystrophic mouse thymocytes was due to a YAC-1-reactive NK cell. Effector cell depletion studies using monoclonal anti-Thy-1.2 plus complement treatment and plastic petri dish adherence also revealed that the natural killing of dystrophic mouse thymocytes was not due to either T lymphocytes or macrophages. Taken together, these results show an increase in NK-sensitive thymocyte targets in dystrophic mice, in combination with an increase in splenic NK activity.