Monoclonal antibody binding to a receptor on nonspecific cytotoxic cells (NCC) increases the expression of proto-oncogene kinases and protein kinase C.

Teleost nonspecific cytotoxic cells (NCC) initiate various cell triggering responses following receptor-target cell interactions. A putative receptor protein on NCC may alternatively initiate signalling processes following crosslinkage by homologous anti-receptor mab 5C6. In the present study, we demonstrated that binding to this receptor by mab 5C6 produced increased levels of expression of cytoplasmic src family proto-oncogene kinases lck, fyn and src. The phosphorylated isoforms of each kinase were approximately the same molecular weight (p60). Unlike their mammalian T-cell and natural killer (NK) cell counterparts, NCC p56lck did not autophosphorylate on tyrosine residues. This was determined by a lack of Western blot reactivity of teleost p56lck with anti-phosphotyrosine specific antibodies PT-66 or 4G10. Additional evidence for this lack of tyrosine phosphorylation was shown by experiments treating mab 5C6 activated NCC with sodium orthovanadate. This protein tyrosine phosphatase inhibitor did not affect levels of p56lck autophosphorylation. Mab 5C6 activated NCC were also examined to determine if levels of protein kinase C (PKC) expression were affected during triggering responses. Maximum increased PKC levels occurred 5-10 min following binding. The NCC receptor-activated PKC consisted of a 60,000 M(r) isoform and a 30,000 M(r) homologue equivalent to the mammalian PKC catalytic subunit. Not all kinases examined, however, were affected by mab 5C6 binding. Levels of expression of c-myc and cdc2p34 did not change following NCC activation. This is the first study of NK-like cells in cold-blooded vertebrates regarding the expression of these vital intermediary transducing kinases.(ABSTRACT TRUNCATED AT 250 WORDS)

An antigen receptor (NCCRP-1) on nonspecific cytotoxic cells is a phosphoprotein associated with the JAK-STAT activation pathway.

The antigen receptor (nonspecific cytotoxic cell receptor protein-1/NCCRP-1) on nonspecific cytotoxic cells (NCC) is a 32-kDa predicted Type III membrane protein. The N-terminal cytoplasmic portion of this receptor contains full length and truncated BOX-1 motifs. These motifs are also found on cytokine, erythropoietin and growth hormone receptors and provide docking sites for JAK kinases. In the present study, we investigated a relationship between NCCRP-1 and JAK2 kinase binding. A possible association with further downstream STAT activation was suggested. NCCRP-1 was phosphorylated on C-terminal domain serine residues. To examine the possibility that NCCRP-1 was associated with JAK kinase(s), NCC were purified and lysates were probed by Westen blotting (WB) for the presence of JAK2 kinase. Unlike their mammalian counterparts, NCC JAK2 kinase existed as a 90-95-kDa primary and a 35-40-kDa secondary breakdown product. Both mol wt. forms were significantly smaller than those reported for human JAK kinases. To determine if NCCRP-1 was physically associated with JAK2 kinase, chemical cross-linking experiments were conducted. NCC membrane preparations were treated with the chemical cross-linker DSS, solubilised and immunoprecipitated with anti-NCCRP-1 (e.g., 32 kDa) mab 5C6. WB analysis using anti-JAK2 mab and mab 5C6 demonstrated that the immunoprecipitate contained both the 32-kDa NCCRP-1 and 85-90-kDa JAK2 kinase. To examine further the possibility that STAT proteins may be associated with NCC/NCCRP-1 activation, NCC lysates were probed (WB) with various anti-STAT mabs. The strongest signal was produced by a 100-kDa STAT-6 protein. Lysates were negative for STAT-1, STAT-3 and STAT-5. These data indicate that the N-terminus of NCCRP-1 may initiate cytokine gene transcription by the JAK-STAT signalling pathway.

NCCRP-1: a novel receptor protein sequenced from teleost nonspecific cytotoxic cells.

The recognition structure responsible for binding to conventional antigen on target cells has not previously been described for nonspecific cytotoxic cells (NCC) or for mammalian natural killer (NK) cells. Although several biochemical pathways may be available for initiation of the lytic cycle in NCC, evidence presented indicates that initial contact with a tumor cell or protozoan parasite is facilitated by recognition of a target antigen by a membrane protein of Mr 34,000 on NCC (NCC receptor protein, NCCRP-1). Binding to NCCRP-1 by monoclonal antibody 5C6, by target cell antigen or by cognate synthetic peptide initiates a signalling response leading to increased cytotoxicity. In the present study, three 20-mer microsequences were obtained from tryptic digests of purified NCCRP-1. Degenerate primers were synthesized (based on each peptide sequence) and were used for RT-PCR with mRNA purified from homogeneous NCC populations. An NCCRP-1 specific cDNA sequence was used to synthesize nondegenerate primers. These primers were used in a 5'/3' RACE PCR to obtain the entire NCCRP-1 specific cDNA. A deduced aa sequence consisted of 235 aa with a derived molecular weight of 30,628 Da. NCCRP-1 is proline rich (9%), has two glycosylation sites and 18% of all amino acids are potential phosphorylation sites (serine, threonine, tyrosine). The identity of the protein was confirmed by finding the previously microsequenced peptides in the derived sequence. Homology searches revealed that NCCRP-1 is a novel protein. Northern blot analysis of mRNA content from teleost NCC, B-cells and T-cells revealed only one band in NCC preparations. Functional studies demonstrated a decrease in membrane NCCRP-1 expression and inhibition of NCC cytotoxicity following treatment with NCCRP-1 anti-sense oligonucleotides. Treatment of NCC with sense oligonucleotides had no inhibitory effects on cytotoxicity. An algorithm predicting the membrane conformation of NCCRP-1 suggests one extracellular proline-rich domain, a transmembrane portion of 15 18 aa and a cytoplasmic tail composed of a high frequency of phosphorylation sites. Current studies suggest that NCC and NCCRP-1 may participate in innate resistance functions in teleost fish.

A novel target cell antigen involved in the NK-like lytic activity of antigen-specific cytotoxic T lymphocytes.

Monoclonal antibodies (mAbs) have been derived which identify a target cell antigen involved in human natural killer (NK) cell lysis. The effects of the mAbs on the NK-like cytotoxic activity exhibited by different populations of human cytolytic T cells were examined. The anti-target cell mAbs 1E7 and 18C2 inhibited the lysis of K562 target cells by endogenous NK cells, antigen-specific cytotoxic T lymphocytes (CTL) with NK-like activity, and non-major histocompatibility complex (MHC)-restricted T cells. Cytolysis of K562 target cells was not affected by treatment of the target cells with the anti-class I HLA mAb W6/32. Further, the anti-target cell mAbs had no effect on antigen-specific lysis by the CTL. The mAb W6/32, however, inhibited the antigen-specific killing. Experiments at the single-cell level revealed that the anti-target cell mAbs inhibited the formation of conjugates between the effector cells and K562 tumor cells but had no effect on CTL binding to the antigen-specific target cells. Thus, antigen-specific CTL exhibiting NK-like lytic function appeared to recognize a novel target cell antigen that is distinct from typical MHC antigens and is identical to the target-cell antigen recognized by true NK cells.

Role of protein phosphatases in the regulation of nonspecific cytotoxic cell activity.

In vitro and in vivo experiments were conducted to determine the effects of the protein phosphatase (PPase) inhibitors sodium fluoride (fluoride), sodium orthovanadate (vanadate), and lithium chloride on nonspecific cytotoxic cell (NCC) lysis of target cells. Both vanadate and fluoride stimulated NCC activity. Lithium chloride had no effects. Optimum enhancement for "normal" NCC was at low effector:target cell ratios and at least 30 min treatment was required to achieve maximum activation effects. Fluoride, but not vanadate activation effects were largely reversible. Vanadate, 2.5-10 mM, produced a 5-10-fold increase in cytotoxicity at 25:1 E:T, whereas less than twofold increases were produced by these concentrations at 100:1. NCC activity from "stressed" fish that had essentially no cytotoxic activity were also activated by vanadate. In vitro preincubation of NCC with 10-20 mM fluoride or 2.5-10 mM vanadate produced up to a 20-fold increase in stressed cytotoxicity. Combined treatments with 2.5 mM vanadate and 20 mM fluoride produced even greater responses. In vivo responses to vanadate were also determined. Treatment of catfish by immersion in 50 microM vanadate produced significant increases in cytotoxicity by 24-48 h posttreatment. Activation of cytotoxicity was not accompanied by increases in percentage of NCC (small lymphocyte content) or in total cell numbers in anterior kidney tissue. These studies indicated that levels of NCC activity are partially regulated by control of dephosphorylation of membrane proteins. Inability of NCC from stressed fish to lyse IM-9 target cells was reversed (probably) by disruption of an equilibrium between kinase and phosphatase activities. Normal NCC were "superactivated" only under conditions were they were in limiting numbers. These data show that phosphatases must be considered as active participants in regulation of signal transduction processes.

Mechanisms of cellular cytotoxic innate resistance in tilapia (Oreochromis nilotica).

Mechanisms of innate cytotoxic immunity in tilapia (O. nilotica) were measured by characterization of the activity, distribution and functions of nonspecific cytotoxic cells (NCC). Active cytotoxic cells were obtained from anterior kidney. spleen and peripheral blood whereas nonlytic but anti-NCC monoclonal antibody 5C6 positive cells were obtained from tilapia liver. Thymocytes were not cytotoxic and were mab 5C6+. Unfractionated anterior kidney cells were 6% mab 5C6+ and had very low cytotoxicity of HL-60 target cells. Percoll (45.5%) purified NCC were 44% mab 5C6+ and had 35% HL-60 cytotoxicity (160:1 E:T ratio). Transformed mouse and human target cells were tested for sensitivity to NCC lysis. HL-60, U937, K562, IM-9 and NC-37 human targets were lysed by NCC. YAC-1 targets were insensitive to lysis. The killing of HL-60 targets by tilapia NCC was inhibited by mab 5C6. Experiments to determine optimal conditions for the cytotoxicity assay revealed that tilapia required 15-20h for optimum lysis of targets. Incubation at 37 C produced the highest cytotoxicity. The proliferative competence of Percoll purified anterior kidney cells was determined. A significant increase in in vitro uptake of tritiated thymidine by anterior kidney cells occurred following stimulation by mab 5C6, Con-A, PMA and calcium ionophore A23187. Purified spleen cells also produced significant increased uptake of tritiated thymidine following in vitro activation with PMA and mab 5C6, but not Con-A. These studies indicated that NCC may provide innate cytotoxic immunity similar to that provided by the NCC of catfish.

Activation of nonspecific cytotoxic cells (NCC) with synthetic oligodeoxynucleotides and bacterial genomic DNA: binding, specificity and identification of unique immunostimulatory motifs.

We have analyzed the effects of synthetic oligodeoxynucleotides (sODNs) and bacterial DNA (bDNA) on the in vitro activation of NCC. Teleost NCC recognition of DNA appeared to differ from that which occurs in higher vertebrates. NCC contain at least two different receptor specificities for DNA. Both oligodeoxyguanosine 20-mers (dG20) and 5'-TGCTGCTTGTGCTTGTGCTT-3' (4GC-2T) bound specifically to NCC. The existence of different receptor specificities was indicated by reciprocal cold target inhibition experiments. dG20 competed with 4GC-2T binding but sODNs composed of GpC or CpG nests did not compete with recognition by NCC of the dG20. ODN binding by NCC primarily depended on the presence of GpC or CpG nests with a preference for -G- serving as the anchor nucleotide. Secondarily, and similar to models of ODN activation in mammals, palindrome sequences of pu-pu-CpG-py-py activated NCC cytotoxicity. Additional analysis of the requirements for ODN activation indicated that guanosine could not substitute for adenosine as a purine spacer and that CpG motifs containing flanking thymidine (i.e.-GTCpGTT-) augmented the activity of the sODN containing this flanking base. Other evidence for the participation of both G and C in the recognition of specific nucleotides by NCC was that poly-dC20, dA20 or dT20 had no activating properties. Methylation of all cytosine nucleotides within an ODN abrogated activation. A canonical ODN motif of 5'-C/AT/AGCTT-3' can now be suggested for teleosts. Additional studies were done to examine the effects of in vitro treatment of NCC with bDNA. bDNA from three different disease isolates of Streptococcus iniae activated NCC cytotoxicity. Treatment of the bDNA with DNase abrogated the enhancement of cytotoxicity. Also, treatment of NCC with eukaryotic DNA had no effects on cytotoxicity. These studies suggested that NCC recognize bacterial nonmethylated DNA. The consequences of these interactions may be increased innate and acquired anti-bacterial immunity.

Function associated molecules on nonspecific cytotoxic cells: role in calcium signaling, redirected lysis, and modulation of cytotoxicity.

Monoclonal antibodies (mAbs) specific for a putative antigen receptor (function associated molecule, FAM) on fish NCC were tested for their ability to initiate signal transduction responses. Anti-FAM hybridoma target cells were significantly lysed by NCC when tested by redirected lysis (RL). Redirected lysis was enhanced by 1-h pretreatment of the NCC with anti-FAM mAb; however, 18-h pretreatment produced significant inhibition. The effects of the calcium ionophore A23187 on RL were also examined: 10(-4) M but not 10(-5) M A23187 significantly increased RL. Purified NCC were treated with mAb and cellular DNA synthesis was determined. Significant increases in NCC incorporation of tritiated thymidine were measured 72 h after treatment with mAb. Experiments were also conducted to determine levels of free cytosolic calcium in NCC following mAb binding. Anti-FAM mAb binding produced a rapid rise in cytosolic calcium (200-500 nM) determined by Fura-2/AM fluorescence. Calcium ionophore A23187, PHA, and Con-A treatment of NCC also produced significantly increased [Ca2+]i. Target cell binding by NCC caused a three-fold increase in [Ca2+]i. These data suggest that triggering of the FAM may initiate a signal(s) that activates cytotoxicity, increases cytosolic free calcium concentrations, and initiates DNA synthesis.

Regulation of innate immunity in tilapia: activation of nonspecific cytotoxic cells by cytokine-like factors.

Exposure of tilapia (Oreochromis niloticus) to water temperatures of 10-15 degrees C for 3-5 min produces physiological stress responses characterized by immediate phenotypic and immunological changes. In the present study, this general stress response was utilized as a model system to study innate immunity mediated by soluble factors and cytotoxic cells. Acute innate cytotoxic responses of nonspecific cytotoxic cells (NCC) in the peripheral blood (PBL), anterior kidney (AK) and spleen (SPL) were measured. Following temperature stress, the levels of NCC activity depended on the presence of soluble factors and on the cell compartments from which the NCC were obtained. NCC from PBL of stressed tilapia had 30x or greater cytotoxic activity compared to nonstressed PBLs from controls. NCC activity from the AK and SPL of stressed tilapia was lower than controls. Flow cytometric analysis of NCC in each tissue showed that increased cytotoxicity was not produced by increased numbers of NCC. To determine the mechanism of amplification of cytotoxicity, NCC from nonstressed tilapia were passively treated with serum from temperature stressed tilapia. Serum containing the "stress activated serum factor" (SASF) passively increased naive NCC cytotoxicity (from PBL) 3-4 fold. The cytotoxic cell response was inhibited by addition of anti-NCC monoclonal antibody 5C6. These data indicated that NCC are (at least one of) the target cells for SASF. SASF required only 15 min pre-incubation with naive NCC to activate cytotoxicity. Activation was nonreversible and concentration dependent. Pretreatment of NCC with SASF reduced the assay time required to amplify target cell cytotoxicity from 12-24 h to 6 h. SASF amplification of NCC cytotoxicity was not restricted by different histological types of target cells. Determination of select physical/chemical properties of SASF revealed: complete heat inactivation of cytotoxicity amplification following 55 degrees C and 65 degrees C pretreatment; SASF was thermostable at room temperature to 45 degrees C for 15 min; and freeze-thaw treatment reduced but did not completely remove amplification activity. The molecular weight range of SASF activity was identified in a 50-100 kDa fraction obtained by differential dialysis. SASF appears to be a protein sensitive to trypsin digestion.

Evidence for antigen recognition by nonspecific cytotoxic cells: initiation of 3H-thymidine uptake following stimulation by a protozoan parasite and homologous cognate synthetic peptide.

Catfish nonspecific cytotoxic cells bind to and lyse certain protozoan parasites and tumor cells. Target cell binding is facilitated by recognition of (minimally) one antigenic determinant. Binding to this determinant initiates multiple signalling pathways in NCC including protooncogene kinase phosphorylation, regulation of phosphatase activity and increased membrane receptor expression. In the present study, highly purified NCC were activated in vitro with the protozoan parasite Tetrahymena pyriformis, with a multiple antigenic peptide (MAP) composed of the cognate antigenic determinant of this parasite (i.e. natural killer target antigen/NKTag) and NCC were activated with a monoclonal antibody specific for the NCC receptor which binds NKTag. NCC were purified by Percoll density gradients and negative selection by panning (2x) over anti-sIg specific mab 9E1. In 5 day proliferation experiments, treatment of NCC with immobilized Tetrahymena initiated a significant increase in uptake of tritiated thymidine. This appeared to be a primary response in that NCC from in vivo parasite primed catfish did not have secondary-like proliferation responses. Stimulation of NCC with immobilized synthetic peptides composed of the cognate antigenic determinant of this parasite (i.e. MAP) also caused significant increased uptake of tritiated thymidine. An indication that NCC recognize a specific antigenic determinant was that sMAP (i.e. peptides composed of the same amino acids as MAP but in a scrambled sequence) failed to increase incorporation. Similar to the MAP results, mab 5C6 binding to NCC also caused increased thymidine uptake. To determine if an IL-2 cosignal was required to achieve optimum activation responses by NCC, different concentrations of human recombinant IL-2 (rHuIL-2) were tested individually or as costimulants. Co-treatment of NCC with rHuIL-2 and any of the three stimuli (parasite, MAP, mab 5C6) did not produce increased proliferation of NCC. These studies demonstrated that NCC specifically recognize an antigenic determinant on protozoan parasites and binding to this antigen produces an activation signal that may have important consequences for elicitation of innate immunity.

Effects of phorbol esters and calcium ionophore on nonspecific cytotoxic cells.

In the present study mechanisms of signal transduction were investigated by treatment of NCC with phorbol esters and calcium ionophore. NCC were stimulated to produce 3-fold increased cytotoxicity by 10(-4) to 10(-5) M A23187. PMA, PDD, and 4-beta phorbol either suppressed NCC lysis (PMA) or had no enhancing effects (PDD and 4-beta). At a concentration of 10(-4) M increased cytotoxicity occurred after 0.5 to 3 hours treatment. Four-hour preincubation enhanced cytotoxicity at suboptimal A23187 concentrations. A23187 produced increased NCC activity at each E:T ratio tested, however, greatest differences in A23187 concentrations were observed at 20:1 and 40:1. The effects of simultaneous treatment of NCC and/or sequential with PMA and A23187 indicated that different transduction pathways might operate to augment cytotoxicity. PMA, 10(-8) M, combined with 10(-4) M concentrations of A23187 produced a 164.7% increase in cytotoxicity compared to media controls, and a 37.7% increase compared to A23187 controls. These data indicate that teleost cytotoxic cells, unlike mammalian NK, are augmentable by increased levels of extracellular calcium without the presence of any other comodulating signals.

The non-specific cytotoxic cell receptor (NCCRP-1): molecular organization and signaling properties.

The evolutionary precursor to mammalian natural killer cells in teleost fish is called non-specific cytotoxic cells (NCC). NCC collaborate with other non-specific effector mechanisms to provide innate resistance during acute stress responses. The NCC receptor protein (NCCRP-1) contains 238 amino acid residues and is believed to be a type III membrane protein with three distinct functional domains. The antigen-binding domain has been mapped to amino acids nos. 104-119. The intracellular C-terminus contains a high concentration of potential phosphorylation sites (Y, S, T). Indeed, we have shown that activation of NCC by crosslinking of NCCRP-1 leads to receptor tyrosine and serine phosphorylation. The N-terminus of the molecule is also inside the cells and has as well signature amino acids, proline-rich motifs (PRM), that are indicative of functional relevance. The cytokine/hormone receptor-like PRMs are known docking sites for JAK kinases. We have evidence that following activation, NCCRP-1 comes in contact with JAK kinase and as a result of this interaction, STAT 6 is translocated into the nucleus. These results suggest that NCCRP-1 may play a dual role in the activation of NCC: first, as an antigen recognition molecule necessary for target cell lysis, and second, as an initiator of cytokine release from NCC. Both of these processes are required for a competent innate immune response.

Nonspecific cytotoxic cells and innate immunity: regulation by programmed cell death.

Although programmed cell death (PCD) and the cellular pathology of apoptosis have been extensively studied in mammals and invertebrates, little is known regarding these important regulatory processes in cold blooded vertebrates, especially teleost fish. In the present review, select immunoregulatory properties of PCD/apoptosis in nonspecific cytotoxic cells (NCC) from catfish and tilapia were identified. The techniques used to define the characteristics of PCD in NCC were DNA ploidy, Annexin-V binding and cellular morphology. Using these procedures, we determined that the biochemical/genetic changes that NCC undergo during PCD are similar to those described in mammalian cells. We hypothesize that one immediate response of NCC to acute stress in teleost fish is the release of apoptosis regulatory factors (ARF) or stress activated serum factors (SASF) into the peripheral blood. These cytokine-like factors activate NCC by protecting them from initiation of: "activation induced cell death" (AICD); from "receptor induced apoptosis"; and from initiation of dexamethasone induced DNA hypoploidy. We predict that the mechanism of these actions is enhanced NCC recycling capacity and initiation of migration of NCC into sites of inflammation. In this review, studies were also summarized regarding the expression and release of "death and survival proteins" by NCC. Although the survey was not exhaustive, we showed that tilapia NCC that were activated in vitro with SASF contained increased levels of two adaptor proteins (i.e. CAS, FADD) and soluble FasL. At present the relevance of expression of the adaptor proteins by NCC is not known, however, additional evidence for the role of FasL in NCC innate immune responses was presented. Interestingly, NCC contained constitutive cytosolic FasL, and activation with tumor cells caused a significant decrease in the cytoplasmic levels of this "death protein". This indicated that FasL in NCC may function as a secretory cytokine-like molecule. Unlike mammalian NK cells and T-cells, activated NCC do not express membrane FasL. A level of phosphatase regulation of NCC apoptosis was indicated by demonstrating a reduced camptothecin induce DNA hypoploidy by pretreatment of NCC with the tyrosine phosphatase inhibitor sodium orthovanadate. This review emphasized the important regulatory functions of PCD/apoptosis for NCC in innate immune responses.

Expression of a novel function-associated molecule on cells mediating spontaneous cytolysis in swine.

In the present study, we have analyzed the effects of the anti-FAM mAb 5C6, on endogenous NK cell and lymphokine-activated killer (LAK) cell activity of swine. We report that the anti-FAM mAb 5C6 binds to fresh and cultured lymphocytes with spontaneous cytotoxic activity from swine peripheral blood. In conjunction, the anti-FAM mAb 5C6 inhibits swine cytolysis against K562 target cells. Inhibition was found to be mediated by blocking of conjugate formation. The level of spontaneous killing and mAb inhibition was correlated with the number of swine cells staining positive with the mAb 5C6 as assessed by flow cytometry.

Identification of a target cell antigen recognized by nonspecific cytotoxic cells using an anti-idiotype monoclonal antibody.

Nonspecific cytotoxic cells (NCC) are the teleost equivalent of mammalian natural killer (NK) cells. In the present study an anti-idiotypic monoclonal antibody (mAb 7D12) was generated against idiotopes on an mAb (mAb 6D3.2) that recognizes a putative receptor on NCC. The idiotypic specificity of mAb 7D12 was determined in competition assays by incubating biotinylated mAb 7D12 with mAb 6D3.2 hybridoma cells following preincubation with combinations of biotinylated 7D12 with either nonbiotinylated homologous or heterologous mAb. The ligand recognized by mAb 7D12 (determined by flow cytometry) was found on cells from the anterior kidney, spleen, thymus, PBL, liver, and brain. NCC lysis of IM-9 targets was inhibited 76% following preincubation of the target cells with different concentrations of mAb 7D12. The involvement of the ligand recognized by mAb 7D12 in the NCC lytic cycle was determined by showing that this mAb produced 50% inhibition of NCC conjugate formation with NC-37 target cells. Biochemical analysis using SDS-PAGE and Western blotting revealed that mAb 7D12 recognized 54 and 65 M(r) proteins in IM-9 target cell lysates. These studies demonstrated that an idiotope on a NCC specific anti-receptor mAb was an "internal image" of a target cell ligand. The anti-id mAb generated against this image (idiotope) inhibited NCC cytotoxicity and thus was equivalent to an NCC receptor that binds to a target cell ligand involved in NCC recognition.

Pathways of signal transduction in teleost nonspecific cytotoxic cells.

In the present study evidence is presented that both a putative "receptor" binding monoclonal antibody (mAb) and the calcium ionophore A23187, either singly or together, increase receptor expression and lysis of IM-9 target cells by catfish NCC. NCC activity against IM-9 target cells was increased 55% after 1 h mAb treatment. Receptor expression determined by flow cytometry increased 95% following 18-h treatment. A23187 treatment of NCC produced greater than 200% increases in receptor expression. Combined treatments of NCC with 10(-4) M A23187 and 10(-7) M PMA however augmented receptor expression only 22% above that produced by A23187 alone. MAb and A23187 comodulated cytotoxicity by a 65% increase over ionophore treatment alone. MAb and 10(-10) M PMA comodulation produced only 10.6% increases in cytotoxicity compared to mAb. These data demonstrate that the moiety on NCC recognized by 5C6 may provide an activation signal for increased cytotoxicity and receptor expression. Calcium ionophore, either singly or together with mAb, provided an even stronger activation signal for increased lysis and receptor expression.

A species-conserved NK cell antigen receptor is a novel vimentin-like molecule.

The role of a novel, evolutionarily conserved function-associated molecule (FAM) in NK cell function has been examined in several species. This molecule has previously been shown to mediate NK and NK-like recognition functions in fish NCC and human NK cells. We now show that this molecule is distributed in those tissues that contain NK cells in mice and rats. Further, we show that this molecule functions as an antigen receptor on NK cells of these species. That is, monoclonal antibodies directed against this FAM inhibit NK cell cytotoxic function and trigger signal transduction pathways in each of the species. Finally, we present evidence that this putative antigen receptor is a vimentin-like molecule which functions to mediate all NK or NK-like recognition functions in a variety of species.

Treadmill exercise training blunts suppression of splenic natural killer cell cytolysis after footshock.

This study extended to treadmill exercise training our prior report (Dishman RK, Warren JM, Youngstedt SD, Yoo H, Bunnell BN, Mougey EH, Meyerhoff JL, Jaso-Friedmann L, and Evans DL. J Appl Physiol 78: 1547-1554, 1995) that activity wheel running abolished the suppression of footshock-induced natural killer (NK) cell cytolysis. Twenty-four male Fischer 344 rats were assigned to one of three groups (n = 8, all groups): 1) a home-cage control group, 2) a sedentary treatment group, or 3) a treadmill-running group (0 degrees incline, 25 m/min, 35 min/day, 6 days/wk). After 6 wk, the treadmill and sedentary groups received 2 days of footshock. Splenic NK cytotoxicity was determined by standard 4-h (51)Cr release assay. Percentages of lymphocytes were determined by flow cytometry. Plasma levels of ACTH, corticosterone, and prolactin concentration were measured by radioimmunoassay. After footshock, percentage of lysis relative to home-cage controls was 40% and 80% for sedentary and treadmill-trained animals, respectively (P < 0.05). Our results indicate that the protective effect of chronic exercise on innate cellular immunity in the Fischer 344 male rat is not restricted to activity wheel running, nor is it explained by elevations in basal NK activity, increased percentages of splenic NK and cytotoxic T cells, or increased plasma levels of ACTH, corticosterone, and prolactin.

Activity-wheel running attenuates suppression of natural killer cell activity after footshock.

We studied whether voluntary running in an activity wheel moderates splenic natural killer (NK) cell cytotoxicity after footshock. Young (50-day) male Fischer 344 rats were randomly assigned to 1) sedentary (n = 16) or 2) activity-wheel (n = 16) groups that each received controllable or uncontrollable footshock on 2 consecutive days or 3) a sedentary home-cage control group (n = 8). Spleens and trunk blood were collected 30 min after the second footshock session. Cytotoxicity was determined by a standard 4-h 51Cr release assay. Percentages of OX6+ (B), OX8+ [T suppressor/cytotoxic (Ts/c)], W3/25+ (T helper), Thy-1.1 (Pan T cell marker), and 5C6+ (NK) cells were determined by flow cytometry. Plasma adrenocorticotropic hormone, corticosterone, and prolactin concentrations were measured by radioimmunoassay as modulators of NK activity. Percentage of specific lysis after footshock was approximately 52% of control values for sedentary animals compared with approximately 96% of control values for activity-wheel animals. The groups did not differ in percentages of NK or Ts/c cells. We conclude that voluntary activity-wheel running protects against the suppression of splenic NK activity induced by footshock. This protective effect of wheel running is not explained by an elevation in baseline NK activity; increased percentages of splenic NK or Ts/c cells; or plasma levels of adrenocorticotropic hormone, corticosterone, and prolactin.

Activity-wheel running blunts suppression of splenic natural killer cell cytotoxicity after sympathectomy and footshock.

We used chemical sympathectomy by 6-hydroxydopamine (6-OHDA) to examine whether adaptation by the sympathetic nervous system (SNS) is a plausible explanation for our prior finding that activity-wheel running blunts the suppression of splenic natural killer cell cytotoxicity after footshock. Male Fischer rats were assigned to treatments using a group (activity wheel vs. sedentary)x treatment (6-OHDA vs. saline)x condition (footshock vs. no shock) design. After 5-6 weeks, rats were injected i.p. with saline or with 40, 80, and 80 mg/kg 6-OHDA on pre experimental days -5, -3, and -1. Half the rats received 6 min of random footshock during a 40-min period. Cytotoxicity was determined by standard 4-h 51Cr release assay. Sympathectomy reduced splenic [NE] by 72%. After 6-OHDA injection and footshock, percent lysis was 33% lower in sedentary rats compared with activity-wheel runners and home-cage controls, p=0.048. The results suggest that activity-wheel running leads to adaptations that offset an altered SNS modulation of splenic NK cell cytotoxicity in response to footshock.