Heterogeneity of channel catfish CTL with respect to target recognition and cytotoxic mechanisms employed.

Two types of catfish alloantigen-dependent cytotoxic T cells were cloned from PBL from a fish immunized in vivo and stimulated in vitro with the allogeneic B cell line 3B11. Because these are the first clonal cytotoxic T cell lines derived from an ectothermic vertebrate, studies were undertaken to characterize their recognition and cytotoxic mechanisms. The first type of CTL (group I) shows strict alloantigen specificity, i.e., they specifically kill and proliferate only in response to 3B11 cells. The second type (group II) shows broad allogeneic specificity, i.e., they kill and proliferate in response to several different allogeneic cells in addition to 3B11. "Cold" target-inhibition studies suggest that group II CTL recognize their targets via a single receptor, because the killing of one allotarget can be inhibited by a different allotarget. Both types of catfish CTL form conjugates with and kill targets by apoptosis. Killing by Ag-specific cytotoxic T cells (group I) was completely inhibited by treatment with EGTA or concanamycin A, and this killing is sensitive to PMSF inhibition, suggesting that killing was mediated exclusively by the secretory perforin/granzyme mechanism. In contrast, killing by the broadly specific T cytotoxic cells (group II) was only partially inhibited by either EGTA or concanamycin A, suggesting that these cells use a cytotoxic mechanism in addition to that involving perforin/granzyme. Consistent with the presumed use of a secretory pathway, both groups of CTL possess putative lytic granules. These results suggest that catfish CTL show heterogeneity with respect to target recognition and cytotoxic mechanisms.

An IgH enhancer that drives transcription through basic helix-loop-helix and Oct transcription factor binding motifs. Functional analysis of the E(mu)3' enhancer of the catfish.

The transcriptional enhancer (E(mu)3') of the IgH locus of the channel catfish, Ictalurus punctatus, shows strong B cell-specific activity and differs from the mammalian E(mu) enhancer in both location and structure. It occurs between the mu and delta genes and contains numerous transcription factor binding sites, predominantly octamer and muE5 motifs of consensus and variant sequences. It lacks the classical muA-muE3(CBF)-muB core array of binding motifs seen within mammalian IgH E(mu) enhancers. To determine the functionally important motifs, a series of mutant enhancers was created using sequence-targeted polymerase chain reaction. Whereas the mutation of consensus and variant octamer motifs (individually or in multiples) decreased enhancer function, mutation of a single consensus muE5 motif destroyed the function of this enhancer in mammalian plasmacytomas. Mutation of this consensus muE5 site, combined with mutations of certain octamer sites, destroyed function in catfish B cells. Experiments using artificial enhancers containing multimers of motifs or short regions of the native enhancer suggested that the minimal E(mu)3' enhancer (a) contains a consensus muE5 site and two octamer sites, (b) is B cell-specific, and (c) is active across species. The dependence of an Ig enhancer on sites that bind basic helix-loop-helix and Oct transcription factors has not previously been observed and confirms large differences in structure and function between fish and mammalian IgH enhancers.

Thioredoxin acts as a B cell growth factor in channel catfish.

To identify differentially expressed genes from channel catfish macrophages, a cDNA library from LPS-stimulated catfish macrophages was screened by subtractive hybridization. This screening yielded a 552-bp cDNA coding for catfish thioredoxin (CF-TRX). The deduced amino acid sequence revealed that CF-TRX contains 107 amino acids and is 59% homologous to human adult T cell leukemia-derived factor/TRX, originally described as an IL-2R alpha-inducing factor. Northern blot analyses showed that CF-TRX is expressed in catfish T and macrophage cell lines, but weakly in B cell lines. Similar results were also observed in Western blot analyses using a mAb specific for recombinant CF-TRX (rTRX). The use of rTRX in functional studies demonstrated that rTRX induces in vitro proliferative responses of catfish PBL that were synergistically enhanced by the addition of culture supernatants from catfish T cell lines. In addition, cell separation studies and flow cytometric analyses revealed that the cells proliferating in rTRX-stimulated cultures were mostly B cells. These results suggest that CF-TRX may have an important role in the activation and proliferation of channel catfish B cells.

Induction of target cell apoptosis by channel catfish cytotoxic cells.

This study examines cytotoxic mechanisms used by channel catfish peripheral blood-derived effector cells. Transmission electron microscopy (TEM), coupled with [(3)H]thymidine DNA fragmentation (JAM) and terminal deoxynucleotidyl nick-end labeling (TUNEL) assays, provided the first evidence that catfish peripheral blood cytotoxic effectors killed allogeneic targets via an apoptotic pathway. TEM demonstrated that the effector cell population present within peripheral blood leukocytes (PBLs) was composed of agranular lymphocytes that formed conjugates with, and induced apoptosis in, allogeneic target cells. Both JAM and TUNEL assays showed that PBLs induced target cell DNA fragmentation within 1 h of coculture. In addition, fixed effectors did not induce target cell necrosis or apoptosis, and target cell lysis was completely inhibited by chelation of free Ca(2+) by EGTA. These results suggest that catfish peripheral blood-derived effector cells utilize a secretory mechanism rather than a ligand-based mechanism to trigger apoptosis.

Catfish Oct2 binding affinity and functional preference for octamer motifs, and interaction with OBF-1.

The DNA-binding (POU) domain of the catfish Oct2 transcription factor was shown, by electromobility shift assays and surface plasmon resonance techniques, to have an affinity for the consensus octamer motif (ATGCAAAT) that was slightly higher than its affinity for a variant motif (ATGtAAAT). This observation is consistent with the transcriptional activation potentials of catfish Oct2 alpha and Oct2 beta, which were shown to activate transcription in catfish B and T cell lines to an equivalent extent from both the consensus and variant octamer motifs. When tested in a mouse plasmacytoma cell line, catfish Oct2 alpha and Oct2 beta, as well as mouse Oct2, showed higher transcriptional activation with the variant, as compared to the consensus, octamer motif. Catfish Oct2 was shown to function synergistically with the mammalian co-activator, OBF-1, activating octamer-dependent transcription in catfish T cells. The strong transcriptional activity of OBF-1 in catfish cells was dependent on the presence of octamer motif(s) at the proximal (promoter) rather than the distal (enhancer) position.

Identification and characterization of the tumor suppressor p53 in channel catfish (Ictalurus punctatus).

Herein is presented the sequence of a catfish full-length p53 cDNA obtained from a cloned B cell line cDNA library. Southern blot analyses determined that a restriction fragment linked polymorphism (RFLP) existed with PstI among outbred catfish. Western blot analyses demonstrated that, when compared to PBLs, the catfish leukocyte lines express higher levels of p53 protein. Additionally, the results of Western blot analyses and in vitro translation experiments suggest that the catfish leukocyte lines may produce truncated forms of p53 due to internal initiation.

T-cell receptors in channel catfish: structure and expression of TCR alpha and beta genes.

Herein are reported full length cDNA sequences for TCR alpha- and beta-chains of the channel catfish. Included are sequences belonging to four Valpha and six Vbeta families which share hallmarks in common with the Valpha and Vbeta genes of other species. Similar to the situation in other vertebrates, the catfish Calpha and Cbeta sequences exhibit distinct immunoglobulin, connecting peptide, transmembrane and cytoplasmic domains. However, the catfish TCR Calpha and Cbeta regions are shorter than those of mammals and the catfish Cbeta chain lacks a cysteine in its connecting peptide region. Two different catfish Cbeta cDNA sequences were identified, suggesting the existence of either two Cbeta loci or allotypes. Based on Southern blot analyses, each of the catfish TCR gene loci appear to be arranged in a translocon (as opposed to multicluster) organization with multiple V elements and a single or few copies of C region DNA. At the deduced amino acid level, the catfish Cbeta sequence exhibits 42% identity with the Cbeta of Atlantic salmon, 41% identity with the Cbeta of rainbow trout and 26% identity with Cbeta of the horned shark. The catfish Calpha amino acid sequence exhibits 44 and 29% identity with Calpha of the rainbow trout and southern pufferfish, respectively. TCRalpha and beta messages are selectively expressed and rearranged in a catfish clonal cell line that appears to be of the T lineage. This TCR alpha/beta expressing clonal lymphocyte line, designated 28S.1, has T-cell like function in that it constitutively produces a supernatant factor(s) with growth promoting activity. These findings should facilitate functional studies of fish TCRs and T cells in ways not previously possible with other 'lower' vertebrate models.

Cytotoxic activity generated from channel catfish peripheral blood leukocytes in mixed leukocyte cultures.

In previous work, lysis of allotargets was routinely observed with PBL from nonimmune channel catfish. In the work reported here, greatly increased (approximately 100-fold) cytotoxic responses were generated by stimulation of channel catfish PBL with irradiated cells of allogeneic cloned B cell lines in mixed leukocyte cultures (MLC). This increased cytotoxicity did not appear to be simply a consequence of cell proliferation since stimulation of catfish PBL proliferative responses with polyclonal mitogens did not result in increased lysis. Somewhat surprisingly, the MLC-generated cytotoxicity did not exhibit allospecificity; i.e., allogeneic targets from other fish were as susceptible to lysis as were the cells used as stimulators. This apparent lack of allospecificity in MLC-generated cytotoxicity was confirmed by "cold" target inhibition assays. However, autologous targets were not killed, clearly demonstrating that MLC-generated effectors could distinguish "self" from "nonself" at the level of lysis/recognition. Although their origin is unresolved, the MLC-generated effectors may be a source of highly enriched fish cytotoxic cells and thus facilitate directly addressing questions pertaining to the evolution of such cells.

MHC class II B genes in the channel catfish (Ictalurus punctatus).

Two different cDNA sequences for major histocompatibility complex (MHC) class II beta chains from the channel catfish (Ictalurus punctatus) have been identified. Homology between these sequences and those previously identified as MHC class II B genes in other teleosts suggests they represent alleles of the DAB locus. The inferred amino acid sequences show strong evidence for a functional polypeptide chain with a peptide binding region. Southern blot analysis reveals polymorphism in the MHC class II B gene(s) of the channel catfish and suggests the presence of two to four genes.

Fish immunology: the utility of immortalized lymphoid cells--a mini review.

Long term cell lines can be readily established at high frequency with PBLs from normal channel catfish. Depending upon the mode of stimulation, morphologically and functionally distinct catfish lymphoid cell lines resembling B cells, T cells and monocytes have been developed. These fish cell lines appear unique from their putative mammalian counterparts in that they are immortalized without the need for exogenous factors or overt attempts at transformation.

Anti-viral cytotoxic cells in the channel catfish (Ictalurus punctatus).

Cytotoxic cells isolated from the head kidney and peripheral blood of the channel catfish appear to represent distinct subpopulations of effector cells. Previous studies showed that the former lyse xenogeneic natural killer (NK) cell targets, whereas the latter preferentially lyse allogeneic cells. Here we extend these studies and present data suggesting a third class of cytotoxic effectors responsible for killing virus-infected allogeneic and autologous cells. Peripheral blood leukocytes (PBLs) freshly isolated from unimmunized catfish lyse uninfected allogeneic target cells as well as virus-infected allogeneic and autologous cells. Cell depletion and unlabeled ("cold") target inhibition studies discriminated between putative effector classes and supported the view that at least two populations of cytotoxic cells are present within peripheral blood leukocytes. One population lyses allogeneic targets, whereas a second population kills channel catfish virus (CCV)-infected cells. In addition, inhibitor studies demonstrated that early virus gene products are sufficient to render infected cells susceptible to lysis. These results suggest that channel catfish possess distinct populations of NK-like, PBL-derived cytotoxic cells capable of lysing allogeneic and virus-infected target cells.

An Ig heavy chain enhancer of the channel catfish Ictalurus punctatus: evolutionary conservation of function but not structure.

The teleost fishes are among the earliest evolutionary lineages to have an Ig heavy chain (IgH) locus whose organization approximates that of mammals. To understand transcriptional control of the IgH locus in a teleost fish and to gain insight into the evolution of the control elements, the enhancer activity in the IgH locus of the channel catfish, Ictalurus punctatus, was investigated. Segments of the locus extending from upstream of the proximal JH gene to 2.5 kb downstream of the second transmembrane (TM2) exon of the mu gene were tested in transient transfection expression assays in murine myeloma and T cell lines, and in catfish B lymphoblastoid, monocyte-like, and putative T cell lines. In marked contrast to mammals, no enhancer activity was observed in the catfish JH to C mu intron, but strong enhancer activity (approaching that of the murine IgH intronic enhancer) was identified in a 1.8-kb segment that included the TM2 exon. This catfish enhancer was active in a B lineage-specific manner in both catfish and murine cells. It was not localized in a small core region, but appeared to contain multiple, dispersed cooperative elements rich in octamer- and mu E5-related motifs. Although the catfish IgH enhancer shares functional characteristics with the mammalian IgH intronic and 3' enhancers, its unusual organization does not permit any obvious inferences concerning evolutionary relationships between the catfish enhancer and any one of the murine IgH enhancers.

Expression of a mouse-channel catfish chimeric IgM molecule in a mouse myeloma cell.

Fusion genes encoding a murine VH domain and the constant region domains of the mu chain from the channel catfish, Ictalurus punctatus, were stably expressed in the lambda light chain producing mouse myeloma cell line J558L. Although the pathways of pre-mRNA processing for expression of membrane (micron and secreted (microsecond) forms of the mu chain differ between mammals and teleosts, mRNAs encoding both catfish micron and microsecond were correctly expressed in the mouse myeloma cells. The mouse-channel catfish chimeric mu chain polypeptide was able to associate covalently with the mouse lambda light chain and assemble, intracellularly, into polymers of covalent structure (microL)2-8 which resembled those seen with native catfish IgM. In contrast to native catfish IgM, the mouse-catfish chimeric IgM showed the property of binding strongly to protein A of Staphylococcus aureus. The mouse-channel catfish chimeric IgM was core-glycosylated, but did not contain terminal sialic acid. Secretion rates for the chimeric IgM were low, and the possibility could not be excluded that extracellular chimeric IgM was released from dead or dying cells. The reason(s) for the intracellular retention of the chimeric IgM (probably in the endoplasmic reticulum) are not known, but those mechanisms involving retention via cysteine residues were excluded.

Productive infection of continuous lines of channel catfish leukocytes by channel catfish virus.

Channel catfish virus (CCV) undergoes extensive replication in fingerling catfish and establishes latent infection in survivors. Although the site of viral latency in carriers is unknown, a variety of tissues, including leukocytes, have been implicated. To explore the interaction of CCV and leukocytes further, we examined in vitro infection of continuous lines of cloned catfish B cells and non-cloned lines containing predominantly macrophages and putative T-cells. Our results indicate that all three leukocyte subpopulations were productively infected with CCV, but that the kinetics of infection and the final yields differed markedly. These findings shed light on CCV-leukocyte interaction and suggest that CCV-infected autologous macrophage or T-cell lines might be suitable targets for assays of catfish cytotoxic T cell activity.

Phylogeny of immune recognition: antigen processing/presentation in channel catfish immune responses to hemocyanins.

Studies were conducted to address the role(s) of antigen (Ag) processing/presentation in channel catfish immune responses. Vigorous and specific secondary in vitro proliferative and antibody (Ab) responses were obtained to keyhole limpet and Limulus polyphemus hemocyanins with peripheral blood leukocytes (PBL) from catfish previously primed in vivo with Ag. In addition, such antigen-specific in vitro proliferative and Ab responses were efficiently elicited by antigen-pulsed and subsequently paraformaldehyde-fixed autologous PBL used as putative antigen-presenting cells (APC) but not by APC fixed prior to Ag pulsing. Treatment of these putative APC with lysosomotropic agents, protease inhibitors, or the ionophore monensin prior to or during pulsing with Ag significantly inhibited both in vitro responses. Furthermore, the use of radiolabeled protein indicated that both untreated and inhibitor-treated PBL but not erythrocytes take up Ag; however, only untreated PBL were able to degrade Ag. Immune restriction was indicated by the use of allogeneic PBL as APC in that only strong MLRs were generated with no detectable antibodies produced in vitro. Finally, the employment of isolated leukocyte subpopulations demonstrated that both catfish B (sIg+) lymphocytes and monocytes were efficient Ag presentors.