Activation of natural killer-like YT-INDY cells by oligodeoxynucleotides and binding by homologous pattern recognition proteins.

The present study was designed to examine the binding and signalling effects of single base and CpG dinucleotide phosphodiester (Po) oligodeoxynucleotides (ODN) on the human natural killer (NK)-like cell line (YT-INDY). Single base Po ODN composed of 20-mers of guanosine (dG20), adenosine (dA20), cytosine (dC20) or thymidine (dT20) as well as 'conventional' Po CpG ODN were examined for their ability to bind and activate YT-INDY cells. Binding by dG20 and CpG ODN to YT-INDY cells was saturable and specific. dG20 binding was competitively inhibited by homologous dG20 and heterologous CpG ODN but not by dC20 and dA20. Two different YT-INDY membrane proteins (18 and 29 kDa) were identified by ligand (Southwestern) blotting with biotinylated dG20 and CpG. The specificity of the ODN-binding protein(s) was further confirmed by ODN depletion experiments using a teleost recombinant protein orthologue [nonspecific cytotoxic cells (NCC) cationic antimicrobial protein-1 (ncamp-1)] known to bind CpG and dG20. Cell proliferation and activation studies showed that dG20 and CpG treatment of YT-INDY cells induced cellular DNA synthesis (i.e. G1 to S-phase conversion). This signalling function was accompanied in dG20-treated cells by proliferation 10 h posttreatment. Both dG20 and CpG ODN binding induced a calcium flux in YT-INDY cells within seconds of treatment. These experiments demonstrated that Po single base dG20 and CpG ODN bind to a (potential) new class of cell-surface proteins that mediate the activation of YT-INDY cells.

Single-base oligodeoxyguanosine-binding proteins on nonspecific cytotoxic cells: identification of a new class of pattern-recognition receptors.

The present study was designed to identify a possible new class of pathogen-recognition proteins that bind single-base oligodeoxynucleotide (ODN) ligands. Binding by the teleost natural killer cell equivalent [referred to as nonspecific cytotoxic cells (NCC)] was compared with mammalian cells (mouse RAW264.7 cells and human THP-1 cells). The ODN analysed were composed of 20-mers of guanosine (dG20), adenosine (dA20), thymidine (dT20) or cytosine (dC20). Binding studies first determined the 50% saturation levels for NCC (1.25 microg/ml), RAW264.7 (0.2 microg/ml) and THP-1 (0.8 microg/ml). Binding by dG20 to all the three cell types was saturable. Ligand blots of NCC membrane lysates with biotinylated dG20 revealed two different major molecular weight species (16-18 and 29 kDa) of binding proteins. The 29-kDa protein was identified with the help of Western blot analysis using a polyclonal antibody specific to an NCC antimicrobial protein (ncamp-1). The membrane expression of the 29-kDa ncamp-1 was determined by the binding of surface-biotinylated NCC membrane proteins with digoxigenin dG20 followed by immunoprecipitation using anti-digoxigenin agarose beads. The 29 and 14-18 kDa NCC membrane proteins were cross-reactive using Western blot examination with a polyclonal anti-histone 1 antibody. Function studies revealed that dG20 activated a twofold upregulation of membrane binding by homologous dG20-biotin. dG20 also stimulated NCC-increased membrane expression of NCC receptor protein 1. Additional experiments were performed to determine the DNase sensitivity of the different ODN. dG20 appeared to be more resistant to DNase treatment, compared to dC20, dA20 and dT20. The single-base ODN-binding proteins may represent a new class of pattern-recognition receptors that are involved in innate anti-bacterial resistance mediated by NCC.

Phosphorylation-induced activation of tilapia nonspecific cytotoxic cells by serum cytokines.

Cytokines as soluble mediators of immunity are important in understanding immunological mechanisms against infectious organisms and during stress conditions. In the present study, the role of protein tyrosine phosphorylation is assessed in the activation of nonspecific cytotoxic cells (NCC) from tilapia Oreochromis niloticus by cytokine-like serum factors. NCC are the teleost equivalent of mammalian natural killer (NK) cells. In teleost fish, NCC are important mediators of innate immunity against bacterial and parasite insult and tumor growth. We have previously shown that exposure of tilapia (a tropical fish) to cold water temperatures (3 to 5 min at 5 to 10 degrees C) produces physiological stress responses characterized by immediate phenotypic and immunological changes. The serum obtained from stressed tilapia contains a 'stress activating serum factor' (SASF) which passively increases in vitro naive NCC cytotoxicity 2- to 4-fold over control levels. In an effort to identify the mechanisms of activation of cytotoxicity by SASF, the phosphorylation status of tyrosine residues in proteins from treated NCC was determined. NCC were incubated with heat-inactivated or untreated stress serum and Western blots of the cell lysates were probed with anti-phosphotyrosine monoclonal antibodies (mabs). The levels of tyrosine phosphorylation in several proteins of the SASF-activated NCC were higher than in control cells. Increased tyrosine phosphorylation was also induced by incubation of NCC in the presence of the tyrosine phosphatase inhibitor Na orthovanadate (vanadate). In every case, an increase in phosphorylation status shown by Western blotting was correlated with increases in cytotoxic activity of NCC against HL-60 target cells. The enzyme inhibitor Herbimycin A (HA) has been previously used to inhibit the activity of the src-family of tyrosine kinases. In the present study, a 4 h pretreatment of NCC with HA (2 microM), followed by treatment with SASF blocked the activation of cytotoxicity produced by SASF. These results suggested that activation of NCC by cytokine-like factors is mediated through activation of the src family of protein tyrosine kinases. Activation was associated with increased phosphorylation and higher cytotoxic effector functions.

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.

Role of nonspecific cytotoxic cells in the induction of programmed cell death of pathogenic protozoans: participation of the Fas ligand-Fas receptor system.

Numerous different species of parasites and pathogenic microorganisms produce programmed cell death (PCD) and apoptosis in eukaryotic targets. How ever, only a few studies have demonstrated that effector cells, cytokines, growth factors, or soluble apoptosis-inducing factors are capable of initiating apoptosis in protozoan parasites. Certain Tetrahymena spp. in teleosts are opportunistic pathogens. In the present study these pathogenic protozoans were developed as a model system to describe the potential role of the Fas ligand (FasL)-Fas receptor (FasR) system as a means of innate immunity in teleosts. Nonspecific cytotoxic cells (NCC) constitutively express soluble FasL (sFasL). Binding of the antigen receptor (i.e., NCCRP-1) on NCC to target cells caused the release of sFasL into the milieu. The presence of functional sFasL in these supernatants was determined by Western blot analysis and by demonstrating the lysis of FasR(+) HL-60 but not IM-9 (FasR(-)) targets. Soluble FasL containing supernatants generated by tumor cell-activated NCC also produced a reduction in 2 N DNA (i.e., DNA hypoploidy) of T. furgasoni. The induction of DNA hypoploidy by NCC supernatants could be neutralized by adsorption of the supernatants with anti-FasL antibody (but not with an isotype control). Experiments were next done to determine the expression of FasR on Tetrahymena and study the effects of anti-FasR monoclonal crosslinkage and treatment with soluble human recombinant FasL (huFasL) on initiation of PCD in Tetrahymena. Cell cycle analysis revealed that both crosslinkage and soluble huFasL binding to Tetrahymena produced DNA hypoploidy. The reduction in diploid DNA was confirmed by observing oligonucleosome fragmentation (DNA laddering) following anti-FasR treatment. Additional evidence for FasR expression on Tetrahymena was obtained using fluorescence microscopy and flow cytometry. Both methods showed that all Tetrahymena examined (three species consisting of four isolates) expressed membrane FasR. These studies demonstrated the potential of the FasL-FasR system in teleosts for initiation of antiparasite innate immunity. Effector NCC may initiate PCD of Tetrahymena that express a FasR-like protein. Induction of apoptosis may be a major mechanism of homeostatic control of protozoan parasite infestations/infections.

In vivo activation of tilapia nonspecific cytotoxic cells by Streptococcus iniae and amplification with apoptosis regulatory factor(s).

An important component of immediate innate responses of tilapia to stress is the release within minutes of soluble cytokine-like substances into the peripheral circulation. These cytokine-like stress factors bind nonspecific cytotoxic cells (NCC) and produce 3-4-fold increased cytotoxicity. In the present study, the in vivo responses of tilapia NCC following injection with different isolates of intact killed Streptococcus iniae was investigated. Activated cytotoxicity of NCC in the peripheral blood (PB) was produced by increased specific activity of resident cells rather than increased numbers. Tilapia injected intravenously (i.v.) with killed S. iniae produced different cytotoxicity responses compared to fish injected intraperitoneally (i.p.). In the spleen (S) and anterior kidney (AK), there was no correlation between S. iniae isolate and cytotoxicity response at 4, 8 or 24 h following i.p. injection. The NCC response following i.v. injection of killed bacteria was different. Within minutes following i.v. injection, NCC cytotoxicity from the PB increased 100% compared to naive controls. The existence of subsets of differentiated NCC in the PB was suggested because i.v. injection had no amplification effects on NCC from the AK or S. Likewise, NCC from the PB only appeared to exhibit a degree of antigen specificity. S. iniae strain #173 produced activation of cytotoxicity compared to isolates #164 and ATCC. Evidence for soluble factor (cytokine?) involvement in increased cytotoxicity was obtained by passive activation of NCC with serum from #173 (i.v.) injected fish. Incubation of this serum with control (naïve) NCC produced large increases in the cytotoxicity of labelled HL-60 target cells. Similarly obtained serum from fish injected with ATCC and #164 isolates had no amplification activity. Studies were also performed to study the mechanism(s) of passive activation. Flow cytometric analysis revealed that NCC from the S, AK and PB constitutively expressed cytosolic (not membrane) FasL. Stress serum treated NCC obtained from the peripheral blood produced an increase in the expression of FasL, CAS and FADD by Western blot examination. These data indicated that cytokine like factors in the serum of stressed tilapia activate increased NCC cytotoxicity (possibly) by stimulating the expression of proteins involved in activation of programmed cell death.

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.

Nonspecific cytotoxic cell receptor protein-1: a novel (predicted) type III membrane receptor on the teleost equivalent of natural killer cells recognizes conventional antigen.

The phylogenetic model for "conventional" antigen recognition by NK cells may be a protein (NCCRP-1) recently identified from catfish nonspecific cytotoxic cells (NCC). NCCRP-1 may be a Type III membrane protein. The antigen binding domain was identified by competition experiments using synthetic peptides. Within this domain, a 38-mer peptide (aa 104-140) inhibited NCC killing of IM-9, HL-60, NC-37, U937, and MOLT-4 target cells. Biotinylated 38-mer also bound to IM-9 target cells. A mab which inhibited conjugate formation between NCC and target cells also bound to the 38-mer. Nonbiotinylated 38-mer inhibited mab 5C6 binding to immobilized homologous biotinylated peptide in cold competition ELISA experiments. Peptide 104-140 was truncated into two peptides. Amino acid 104-119 bound to (68%) and inhibited lyis of IM-9 target cells, whereas aa 120-140 had no activity. A predicted structure-function algorithm suggested an N-terminal domain containing BOX-1 motifs for cytokine activation; a C-terminal domain containing abundant phosphorylation sites (i.e., Y, S, and T amino acids); and an extracellular antigen binding domain.

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.

Receptor associated phosphorylation following monoclonal antibody or synthetic peptide binding to nonspecific cytotoxic cells.

We have previously shown that crosslinkage of a receptor protein on catfish nonspecific cytotoxic cells (NCC) with anti-receptor monoclonal antibody or with a synthetic peptide activates cytotoxicity and initiates signalling responses. Receptor linked signalling was associated with the production of increased levels of expression of 50-60 and 20-30 kDa phosphoproteins determined by immunoprecipitation with anti-phosphoserine and anti-phosphotyrosine mabs. These proteins are components of a macromolecular protein complex (>200 kDa) determined by reducing and nonreducing SDS-PAGE. The calcium ionophore A23187 treatment produced the same pattern of phosphoprotein expression as peptide or mab. Maximum phosphoserine expression occurred at 15'-30' post-mab binding. We now show that synthetic peptide or mab treatment initiated the same serine and tyrosine phosphorylation profiles. The PKC specific inhibitor MDL 29,152 produced 50% inhibition of NCC lysis of IM-9 target cells, and completely inhibited serine phosphorylation of peptide activated cells but had no effect on tyrosine phosphorylation of the phosphointermediates. Genistein pretreatment of NCC inhibited cytotoxicity and tyrosine phosphorylation. Sequential immunprecipitation of the phosphointermediate demonstrated that the phosphorylated serine and tyrosine residues were on the same 50-60 kDa protein. These data indicate that both proximal and distal signalling events required for NCC activation may be associated with ATPase phosphorylation.

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.

Molecular characterization of a protozoan parasite target antigen recognized by nonspecific cytotoxic cells.

The target cell antigen(s) on tumor cells and on protozoan parasites recognized by NK and nonspecific cytotoxic cells (NCC) has not yet been specifically identified. NCC may be the teleost equivalent of NK cells and IL-2-activated NK cells. A ligand recognized by NCC has been identified. It is expressed on both protozoan parasites and mammalian tumor target cells. In the present study, a protozoan parasite antigen (NK target antigen/NKTag/p46) was purified from Tetrahymena pyriformis and the entire amino acid sequence was deduced from cDNA. Soluble and purified NKTag inhibited NCC lysis of human and mouse transformed target cells. Homology comparisons using Swissprot database revealed that NKTag is a novel protein. Molecular weight computation of the deduced sequence demonstrated that NKTag is a 48.17-kDa protein containing 422 amino acids with relatively high percentages of tyrosine and serine residues. Expression of NKTag on various mammalian tumor target cells, normal tissue, and T. pyriformis was determined using anti-multiple antigenic peptide (MAP) monoclonal antibody (mab) 22A12 [generated against an N-terminal 20-mer (aa 61-80) of p46]. This mab bound to tissue-cultured and tumor cells (YAC-1, IM-9, NC-37, MOLT-4, and U937) with low levels of binding to fish, mouse, and equine cells. Studies were also done to determine if purified and iodinated NKTag bound specifically to NCC. Binding was saturable and specific. These data provide evidence that NCC recognize a target cell ligand which is found on both protozoan and tumor cells. This may provide an explanation as to how NCC (including activated NK cells) recognize a vast array of targets in the absence of haplotype recognition and in spite of a diverse species of origin.

Activation of nonspecific cytotoxic cells with a multiple antigenic peptide: specificity and requirements for receptor crosslinkage.

Nonspecific cytotoxic cells (NCC) of teleost fish recognize a conserved antigenic determinant found on the protozoan Tetrahymena pyriformis and on many different tumor target cells. This determinant is located on a 46-kDa Tetrahymena protein referred to as natural killer target antigen (NKTag). The NKTag cognate sequence recognized by NCC is composed of seven to nine amino acids. In the present study, synthetic peptides of the cognate NKTag determinant were prepared as multiple antigenic peptides (MAP). Immobilized MAP activated NCC lysis of IM-9 target cells in the absence of antigen presenting cells or exogenous added cytokines. NCC binding to immobilized MAP produced two- to fivefold increased lysis of IM-9, U937, and HL-60 target cells compared to scrambled control MAP (composed of the same amino acids only in random sequence). NCC receptor crosslinkage was required for activation. Immobilized monomeric homologous cognate peptide did not activate increased NCC lysis of IM-9 target cells; however, NCC preincubated with soluble homologous monomer inhibited MAP activation of lysis. Ligand activation of NCC was antigen specific. Binding of the immobilized ligand with anti-MAP mab 22A12 prior to addition of NCC blocked activation. Mab 22A12 also inhibited NCC lysis of IM-9 target cells. A possible mechanism of NCC activation was determined. Binding of NCC to immobilized MAP produced significantly increased membrane expression of a putative receptor as defined by mab 5C6 binding. These studies demonstrate that activation of NCC by a target cell antigenic determinant depends on crosslinkage of an NCC "receptor" by polymeric repetitive sequences, a soluble or fixed monomer cannot activate but can inhibit activation, and MAP binding initiates increased expression of a putative NCC receptor protein.

Mapping of the epitope recognized by non-specific cytotoxic cells: determination of the fine specificity using synthetic peptides.

NCC recognize a conserved target cell antigen (NKTag) expressed on protozoan parasites and on transformed tumour cells. In the present study, synthetic peptides corresponding to N-terminal, C-terminal and internal NKTag(deduced) amino acid sequences were tested for binding and inhibition of NCC lysis of sensitive target cells. A 20-mer peptide equivalent to amino acids (aa) nos. 55-74 specifically inhibited NCC lysis of human EBV transformed target cells (IM-9). Inhibitory effects were nonreversible and concentration dependent, and 30 min pre-incubation produced optimum inhibition. The inhibitory 20-mer peptide was truncated into 17, 14, 10, 9 and 6-mer peptides and tested for inhibition of cytotoxicity. All produced almost complete inhibition except the 6-mer which had no activity. The NKTag sequence required for NCC binding (minimally) consisted of seven amino acids [aa nos 68-74 (ARG-ASN-LEU-THR-PHE-ILE-LEU-)]. The specificity of inhibition and the distribution of target cells expressing NKTag was determined. A 14-mer peptide composed of aa nos 61-74 inhibited lysis of HL-60, IM-9, DAUDI, YAC-1, U937 and NC-37 target cells. Flanking peptides (aa nos 35-54 and 75-94) were negative. Biotinylated aa nos 61-74 bound to NCC effector cells. The recognition requirements for aa sequence versus aa content were determined. Randomization of the aa in the cognate 9-mer obliterated the inhibitory effects. The 17-mer (cognate) synthetic peptide inhibited conjugate formation between NCC and IM-9 targets. These data demonstrate that NCC recognize a conserved antigen determinant on susceptible target cells consisting of a minimum of 7-9 amino acids in the N-terminal region of NKTag.

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)

Partial amino acid sequence of a novel protozoan parasite antigen that inhibits non-specific cytotoxic cell activity.

Monoclonal antibody (MoAb) 18C2, prepared against a human EBV transformed lymphoblastic cell line (NC-37) is specific for a target cell ligand recognized by fish NCC and by mammalian NK cells. MoAb 18C2 inhibits the lysis of a variety of transformed murine and human cells (e.g. NC-37, YAC-1, K562, etc.). This MoAb also recognizes a determinant on the fish protozoan parasite Tetrahymena pyriformis. In the present study, we used MoAb 18C2 to identify a target antigen in detergent lysates of T. pyriformis. MoAb 18C2 recognized a 46-50 kDa target antigen (NKTag) by Western blot analysis of both crude and ammonium sulphate (AS) fractionated (25-40% saturation) T. pyriformis lysates. AS fractionated or purified soluble NKTag inhibited NCC mediated lysis of IM-9 target cells in a dose dependent fashion. AS fractionated NKTag also inhibited NCC lysis of a variety of human and murine transformed targets (e.g. HL-60, MOLT-4, DAUDI, NC-37, U-937, YAC-1, EL-4). Inhibition was specific for NCC and inhibition could be removed by adsorption of AS fractionated NKTag with MoAb 18C2 hybridoma cells. NKTag was prepared for amino acid sequencing by preparative SDS PAGE of whole cell detergent (CHAPS) lysate followed by Western transfer to nitrocellulose. The MoAb 18C2 recognized NKTag was excised and submitted for microsequence analysis. Direct N-terminal analysis yielded a 12 residue sequence. Additional sequences, obtained from in situ trypsin digests of the NKTag on nitrocellulose yielded four additional peptides of 10, 13, 16 and 21 residues. None of the sequences examined had significant homology to known sequences (Swiss-Prot protein sequence database). These data indicate that MoAb 18C2 recognized a novel protein on T. pyriformis which may be involved in target cell recognition/lysis by NCC. Further, these data extend our previous observation that a common target determinant exists between higher and lower eukaryotic cells, and its expression may provide an explanation for the susceptibility of both protozoan parasites and transformed tumour cells to NK/NCC lysis.

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 signaling in nonspecific cytotoxic cells: effects of protein kinase and phosphatase inhibitors and evidence for membrane tyrosine phosphorylation.

The present study was done to examine the role of protein kinases (PK) and phosphatases in nonspecific cytotoxic cell (NCC) activation processes. Treatment of NCC with 30 or 60 microM H-7 prior to adding IM-9 target cells significantly inhibited cytotoxicity. A similar concentration and time-dependent inhibition response was observed following treatment with H-8. The calcium and cyclic nucleotide antagonist HA1004, however, produced a significant increase in cytotoxicity at 30 and 60 microM concentrations. Treatment with genistein produced almost 100% inhibition of NCC lysis of IM-9 targets at a 142 micrograms/ml concentration. Studies were also carried out to determine the effects of these cytotoxicity modulators on stimulus-induced responses. In all cases where the costimulus consisted of the calcium ionophore A23187, cytotoxicity was markedly increased. In experiments using subsaturating concentrations of mab 5C6 as the costimulus, genistein completely reversed (inhibited) the modulating effects of this mab. Additional evidence for protein phosphorylation was obtained by immunoprecipitation and Western blot analysis (using antiphosphotyrosine mab 4G10) of membranes from mab 5C6-stimulated NCC. The role of protein phosphorylation on cytotoxic activity was further analyzed by the use of phosphatase inhibitors. Preincubation of NCC with either sodium orthovanadate or sodium fluoride significantly increased cytotoxicity. Lithium chloride had little or no effect on the killing of IM-9 target cells. These data indicate that multiple second messenger pathways participate in NCC lytic responses, the most crucial of which appears to facilitate phosphorylation of tyrosine residues on membrane proteins.