Products of proteolytic cleavage of transferrin induce nitric oxide response of goldfish macrophages

Abstract

Enzymatic cleavage product of transferrin induced the production of nitric oxide (NO) by LPS-stimulated goldfish macrophages. A NO-inducing factor was purified from the supernatants of mitogen-stimulated goldfish kidney leukocytes using fast performance liquid chromatography (FPLC) and the purified proteins analyzed by microcapillary reverse-phase HPLC nano-electrospray tandem mass spectrometry. The proteins were identified as truncated forms of transferrin, having approximate molecular weights (MW) of 33, 35, and 37 kDa (kilodaltons). The precursor form (i.e. full-length) of transferrin did not enhance NO production by LPS-stimulated goldfish macrophages, but enzymatic cleavage of this precursor form correlated with enhanced production of NO by goldfish macrophages. Enzymatic cleavage of transferrin was dependent on the presence of stimulated kidney leukocytes and was shown to occur in response to both mixed lymphocyte reactions (MLR) and the mitogenic stimulation of goldfish kidney leukocytes. Time course analysis revealed that 24 h after kidney leukocyte MLR or mitogen stimulation, cleaved transferrin products appeared in the supernatants of cultured cells, which was related to the on-set of NO-inducing activity of these preparations. To confirm these findings, bovine transferrin was digested in vitro using protease XXVII. The resulting cleavage products had approximate MW of 33, 35, and 37 kDa. When these peptides were subjected to the purification protocols used to purify a NO-inducing factor from goldfish leukocyte supernatants, they were shown to elute to identical fractions. To examine the potential role of fish transferrin in mediating goldfish NO production, carp transferrin was purified from serum and following protease-digestion and purification by FPLC, the truncated proteins were found to elute to similar fractions as bovine transferrin. Furthermore, mitogen-stimulated leukocyte supernatants prepared in the absence of bovine serum (carp serum only) retained NO-inducing activity, indicating that this response was not an artifact of bovine serum components (i.e. bovine transferrin). Anti-bovine and anti-carp transferrin polyclonal antibodies identified the presence of truncated forms of transferrin in the active fractions of FPLC-separated mitogen-stimulated leukocyte supernatants prepared in the presence of bovine or carp serum, respectively. Thus, our results suggest a novel role for fish transferrin as one of the factors that mediates teleost macrophage antimicrobial functions.