L.W. Clem

Molecular identification and expression analysis of tumor necrosis factor in channel catfish (Ictalurus punctatus).

A tumor necrosis factor (TNF) alpha-like gene, encoding a propeptide of 230 amino acids and a mature (soluble) peptide of 162 amino acids, was identified in channel catfish (Ictalurus punctatus). While the catfish protein shared features in common with both mammalian TNFalpha and TNFbeta homologs, overall sequence identity/similarity was slightly higher vs. TNFalpha genes when mature TNF sequences were compared. Phylogenetic analysis placed catfish and other fish TNF sequences within their own cluster apart from mammalian TNFalpha and beta genes, and supported the suggestion that TNFalpha and beta genes separated after the divergence of mammals and teleosts. In contrast to trout and carp, but similar to flounder, catfish TNF was present as a single copy gene. Expression studies demonstrated that catfish TNFalpha mRNA was present in all tested tissues (i.e. liver, spleen, head kidney, mesonephros, gill, thymus, and PBLs) from an unstimulated fish. Moreover, catfish TNF was constitutively expressed in actively proliferating, but otherwise unstimulated, macrophage (42TA) and T cell (G14D; TS32.17) lines, but not in B cell (1G8 or 3B11) or fibroblast lines. TNF expression was upregulated in PBLs, and in G14D and 42TA cells, but not in 3B11 cells, by PMA/calcium ionophore treatment. These results demonstrate that a catfish homolog of TNFalpha has been identified, and indicate that catfish TNFalpha is expressed in catfish in a manner similar to that seen in mammals.

T-cell receptors in channel catfish: structure and expression of TCR α and β genes

Abstract Herein are reported full length cDNA sequences for TCR α- and β-chains of the channel catfish. Included are sequences belonging to four Vα and six Vβ families which share hallmarks in common with the Vα and Vβ genes of other species. Similar to the situation in other vertebrates, the catfish Cα and Cβ sequences exhibit distinct immunoglobulin, connecting peptide, transmembrane and cytoplasmic domains. However, the catfish TCR Cα and Cβ regions are shorter than those of mammals and the catfish Cβ chain lacks a cysteine in its connecting peptide region. Two different catfish Cβ cDNA sequences were identified, suggesting the existence of either two Cβ 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 Cβ sequence exhibits 42% identity with the Cβ of Atlantic salmon, 41% identity with the Cβ of rainbow trout and 26% identity with Cβ of the horned shark. The catfish Cα amino acid sequence exhibits 44 and 29% identity with Cα of the rainbow trout and southern pufferfish, respectively. TCRα and β messages are selectively expressed and rearranged in a catfish clonal cell line that appears to be of the T lineage. This TCR α⧹β 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.

Immunoglobulin Isotypes: Structure, Function, and Genetics

Immunoglobulin (Ig) classes (in mammals, IgM, IgA, IgD, IgG, IgE) are defined by the isotypes of heavy (H) chains (µ, α, δ, γ, and e). Each isotype is in turn distinguished by unique structures in its constant region domains. These different structures confer distinctive functions on the Ig classes. When two or more Ig classes are very similar, as occurs with the four different types of IgG found in man and mouse, they are usually termed subclasses. Each isotype is encoded by a distinct gene and multiple heavy chain isoforms can be produced by alternative pathways of RNA processing, such as the secreted (slg) and membrane (mlg) forms of all H chains, or the full-length and truncated H chain isoforms of certain avian antibodies. Allelic variation in the constant (C) regions gives rise to allotypes. The different types of light (L) chains (in mammals, к and λ) are also typically referred to as isotypes. This system of classification of Igs was developed from studies of man and his immunological understudy, the mouse, and has proven useful not only in these two species, but also in other mammalian species. Although the classification of mammalian Ig classes and isotypes is quite clear, the situation with Igs from nonmammalian vertebrates is not. For example, is the shark molecule referred to as IgM really IgM? Should we call the predominant low molecular weight Ig in chickens IgG or IgY? This chapter discusses the ways in which these and similar questions have been approached.

Cortisol-induced hematologic and immunologic changes in channel catfish (Ictalurus punctatus)

1. Intravenous injections of physiologic doses of cortisol resulted in both hematologic and immunologic changes in channel catfish peripheral blood leucocytes. These changes mimicked those seen when catfish were acutely stressed by handling and transport. 2. Eighteen hours after the administration of cortisol, decreases in the number of circulating lymphocytes and concomitant increases in the number of circulating neutrophils were observed, i.e. to the same levels seen previously in stressed fish. 3. Functional analysis of peripheral blood leucocytes from cortisol-injected fish indicated that the remaining lymphocytes were no longer capable of responding to mitogenic stimuli. 4. This suppression of mitogenic stimuli was not seen when peripheral blood leucocytes were cultured in vitro with physiologic doses of cortisol. 5. This latter observation suggests that the cortisol alone was probably not directly responsible for the loss of responsiveness but possibly acted in vivo as an initiator of other events that eventually resulted in the observed immunosuppression.

Temperature-mediated processes in teleost immunity: Differential effects of invitro and invivo temperatures on mitogenic responses of channel catfish lymphocytes☆

The in vitro mitogenic responses of channel catfish peripheral blood leucocytes to ConA and LPS were differentially affected by both in vitro and in vivo temperatures. The magnitude of the response to LPS was relatively independent of both in vitro culture temperature and in vivo acclimation temperature. The magnitude of the response to ConA was suppressed at lower in vitro temperatures although this suppression could be reduced by lower in vivo acclimation temperatures. In vitro temperature-shift experiments indicated that channel catfish PBL could respond to ConA at a lower in vitro temperature if first stimulated with ConA at a higher in vitro temperature. The converse, however was not true in that channel catfish PBL did not respond at a higher in vitro temperature after an initial stimulation with ConA at a lower in vitro temperature. This latter failure to respond could not be attributed to the induction of a suppressor cell (or factor) by exposure to ConA at a lower temperature. These studies, when coupled with other available data on channel catfish PBL subpopulations, are interpreted as supporting the hypothesis that low temperature immunosuppression in fish may result from preferential inhibitory effects on T cells rather than B cells.

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.

Phylogeny of lymphocyte heterogeneity: the thymus of the channel catfish

The number of thymocytes (approximately 3 x 10(7)) that were recoverable from fingerling channel catfish remained constant from about 3 to 10 months of age, i.e. from September to April following hatching the previous June. Between 11 and 12 months, i.e. May and June, the thymus dramatically increased in size with 3 x 10(9) thymocytes being recoverable from the tissue of individual fish. The thymus remained enlarged for several months (throughout the summer) but at about 15 months (in September) began to involute such that by 17 months (November) no thymus tissue could be seen macroscopically. This natural involution could be accelerated by subjecting the fish to handling and transport stress. Thymocytes of channel catfish aged 4 to 16 months exhibited reactivity with monoclonal antibodies against peripheral T cells but not B cells. Thymocytes responded to the mitogen Concanavalin A only in the presence of added accessory cells (peripheral blood monocytes) or a monocyte-derived supernatant (presumably containing IL-1) at permissive temperatures (27 degrees C). Thymocytes could also be induced to divide at nonpermissive temperatures (17 degrees C) when incubated in the presence of the following combinations of stimulants, a) the phorbol ester 12-O-tetradecanoyl-phorbol-13-acetate (TPA) and the calcium ionophore A23187, b) TPA and ConA, or c) A23187 and ConA. In those cases where TPA or A23187 were used, accessory cells or their products were not needed. Collectively, these results support the notion that channel catfish thymocytes functionally mimic those lymphocytes in the peripheral blood previously designated as T cells.

A novel family of diversified immunoregulatory receptors in teleosts is homologous to both mammalian Fc receptors and molecules encoded within the leukocyte receptor complex

Three novel and closely related leukocyte immune-type receptors (IpLITR) have been identified in channel catfish (Ictalurus punctatus). These receptors belong to a large polymorphic and polygenic subset of the Ig superfamily with members located on at least three independently segregating loci. Like mammalian and avian innate immune regulatory receptors, IpLITRs have both putative inhibitory and stimulatory forms, with multiple types coexpressed in various lymphoid tissues and clonal leukocyte cell lines. IpLITRs have an unusual and novel relationship to mammalian and avian innate immune receptors: the membrane distal Ig domains of an individual IpLITR are related to fragment crystallizable receptors (FcRs) and FcR-like proteins, whereas the membrane proximal Ig domains are related to several leukocyte receptor complex encoded receptors. This unique composition of Ig domains within individual receptors supports the hypothesis that functionally and genomically distinct immune receptor families found in tetrapods may have evolved from such ancestral genes by duplication and recombination events. Furthermore, the discovery of a large heterogeneous family of immunoregulatory receptors in teleosts, reminiscent of amphibian, avian, and mammalian Ig-like receptors, suggests that complex innate immune receptor networks have been conserved during vertebrate evolution.

MHC class I genes of the channel catfish: sequence analysis and expression

Abstract Four cDNAs encoding the major histocompatibility complex (MHC) class I α chain were isolated from a channel catfish clonal B-cell cDNA library. Sequence analysis suggests these cDNAs represent three different MHC class I loci. All cDNAs encoded conserved residues characteristic of the MHC class I α chain: namely, those involved in peptide binding, salt bridges, disulfide bond formation, and glycosylation. Southern blot analyses of individual outbred and second-generation gynogenetic fish indicated the existence of both polygenic and polymorphic loci. Northern blot studies demonstrated that catfish B, T, and macrophage cell lines transcribed markedly higher levels of class I α and β2-microglobulin (β2m) mRNA than fibroblast cell lines. In addition, immunoprecipitation data showed that a 41 000 Mr glycoprotein (presumably class I α) was associated with β2m on the surface of catfish B cells. This latter finding is the first direct evidence for the cell surface association of β2m with the MHC class I α chain on teleost cells and supports the notion that functional MHC class I proteins exist in teleosts.

Identification and Characterization of a FcR Homolog in an Ectothermic Vertebrate, the Channel Catfish (Ictalurus punctatus)

An FcR homolog (IpFcRI), representing the first such receptor from an ectothermic vertebrate, has been identified in the channel catfish (Ictalurus punctatus). Mining of the catfish expressed sequence tag databases using mammalian FcR sequences for CD16, CD32, and CD64 resulted in the identification of a teleost Ig-binding receptor. IpFcRI is encoded by a single-copy gene containing three Ig C2-like domains, but lacking a transmembrane segment and cytoplasmic tail. The encoded Ig domains of IpFcRI are phylogenetically and structurally related to mammalian FcR and the presence of a putative Fc-binding region appears to be conserved. IpFcRI-related genomic sequences are also present in both pufferfish and rainbow trout, indicating the likely presence of a soluble FcR in other fish species. Northern blot and qualitative PCR analyses demonstrated that IpFcRI is primarily expressed in IgM-negative leukocytes derived from the lymphoid kidney tissues and PBL. Significantly lower levels of IpFcRI expression were detected in catfish clonal leukocyte cell lines. Using the native leader, IpFcRI was secreted when transfected into insect cells and importantly the native IpFcRI glycoprotein was detected in catfish plasma using a polyclonal Ab. Recombinant IpFcRI binds catfish IgM as assessed by both coimmunoprecipation and cell transfection studies and it is presumed that it functions as a secreted FcR akin to the soluble FcR found in mammals. The identification of an FcR homolog in an ectothermic vertebrate is an important first step toward understanding the evolutionary history and functional importance of vertebrate Ig-binding receptors.