Identification and characterization of a FasL-like protein and cDNAs encoding the channel catfish death-inducing signaling complex.

To elucidate cytolytic mechanisms in the channel catfish, lysates from catfish lymphoid and fibroblast cell lines were screened by Western blot analysis using a panel of antibodies reactive with components of the mammalian apoptotic pathway. Strong reactivity with three proteins (approximate Mr 70,000, 37,000, and 15,000) was seen using an antibody targeted to mammalian Fas ligand (FasL). The sizes of the two smaller proteins are consistent with their tentative designation as membrane-bound (37,000 Mr) and soluble (15,000 Mr) FasL. Treatments known to induce FasL in mammalian systems (e.g., PMA/calcium ionophore, UV-irradiation) induced expression of the 37,000- Mr protein in catfish T-cell lines. Moreover, expression of the 37,000- Mr protein in clonal T cells was up-regulated by increasing cell density. At the nucleotide level, homologues of Fas receptor (FasR), FADD, and caspase 8 were identified and characterized. These gene products likely constitute the teleost equivalent of the death-inducing signaling complex (DISC). FADD was constitutively expressed in all (T, B, macrophage, and fibroblast) cell lines examined as well as in peripheral blood lymphocytes (PBL), whereas FasR and caspase 8 were expressed in all cell lines except CCO, a FasL-positive fibroblast line. In contrast to FasL, expression of FasR and caspase 8 was inversely proportional to cell density. Collectively these studies identified four membrane-proximal proteins involved in the initiation of apoptosis in channel catfish and suggest that mechanisms of cell-mediated cytotoxicity in teleosts are similar to those used by mammals.

Immortal and mortal clonal lymphocyte lines from channel catfish: comparison of telomere length, telomerase activity, tumor suppressor and heat shock protein expression.

Channel catfish autonomous (immortal) and nonautonomous (mortal) leukocyte lines were phenotyped with respect to telomere length and the expression of telomerase, Hsp70 and p53, potentially important factors in cellular immortalization. The autonomous cells constitutively expressed telomerase whereas the nonautonomous cells expressed this activity only transiently. This observation, coupled with the low telomerase activity level seen in freshly isolated leukocytes, suggests that telomerase expression in catfish leukocytes is activation induced. In contrast both types of cell lines exhibited quite similar patterns of significantly shortened telomeres, suggesting that telomerase does not stabilize catfish telomeres until a critical short length is reached. Northern analyses indicated that, like telomerase, Hsp70 gene expression was constitutive in autonomous cells and transient in nonautonomous cells. In contrast, p53 mRNA levels appeared similarly low and noncycling in both long-term cultured types of catfish cells, regardless of the culture situation. Furthermore it was noted, by Western analyses, that both types of cells display multiple sized forms of p53 proteins. This latter observation implies that truncation of p53 protein is probably not directly involved in the in vitro immortalization process of channel catfish leukocytes.

Channel catfish cytotoxic cells: a mini-review.

The use of allogeneic and autologous lymphoid cell lines has facilitated studies of cytotoxic T lymphocytes (CTL) and natural killer (NK)-like cells in channel catfish. Naïve catfish leukocytes were shown to spontaneously kill allogeneic cells and virally-infected autologous cells without the need for prior sensitization, and allogeneic cytotoxic responses were greatly enhanced by in vitro alloantigen stimulation. Both catfish CTL and NK-like cells have been successfully cloned from these alloantigen-stimulated cultures, and represent the first cytotoxic cell lines derived from any ectothermic vertebrate. These cloned cytotoxic cells contain granules and likely induce apoptosis in sensitive targets via a putative perforin/granzyme mechanism. In addition, some catfish CTL clones may also kill targets by an additional mechanism, possibly by Fas/FasL-like interactions. Importantly, these cytotoxic cells do not express the marker for catfish nonspecific cytotoxic cells (NCCs), and thus represent cell types distinct from NCCs. The use of monoclonal antibodies against the catfish F and G immunoglobulin light chain isotypes revealed the presence of a putative Fc receptor for IgM (Fc mu R) on some catfish NK-like cells that appears to 'arm' these cells with surface IgM. In addition, a potentially important monoclonal antibody (CC41) developed against catfish NK-like cells was found to recognize an approximately 150kDa molecule on the surface of catfish cytotoxic cells. These studies clearly demonstrate that catfish possess an array of different cytotoxic cells. The availability of various cloned cytotoxic cell lines should enable unambiguous functional studies to be performed in ways not currently possible with any other fish species.