James L. Stafford

Antimicrobial mechanisms of fish phagocytes and their role in host defense

Phagocytosis is a primitive defense mechanism in all multicellular animals. Phagocytes such as macrophages and neutrophils play an important role in limiting the dissemination of infectious agents, and are responsible for the eventual destruction of phagocytosed pathogens. These cells have evolved elaborate killing mechanisms for destroying pathogens. In addition to their repertoire of degradative enzymes and antimicrobial peptides, macrophages and neutrophils can be activated to produce a number of highly toxic molecules. Production of reactive oxygen and nitrogen intermediates by these cells are potent cytotoxic mechanisms against bacteria and protozoan pathogens. Studies in fish suggest that the biological basis of these inducible killing mechanisms is similar to those described in mammals. More recent work suggest novel roles for regulating these killing responses in fish. In this review, we describe the biological basis of these killing mechanisms and how they are regulated in fish.

Transferrin and the innate immune response of fish: identification of a novel mechanism of macrophage activation

We have previously demonstrated that a non-cytokine serum protein called transferrin was a primary activating molecule of the goldfish (Carassius auratus) macrophage antimicrobial response. The ability of the enzymatically cleaved forms of this protein to modulate fish macrophage function is novel and may represent a primitive and evolutionary conserved mechanism for the induction of NO response of macrophages. In the present study we confirm our earlier findings using immunoaffinity purified goldfish transferrin from mitogen-stimulated leukocyte supernatants. In addition we demonstrate that: (1). products released by necrotic/damaged cells contain transferrin-cleaving activity; (2). the cleavage site is located within the bridge peptide connecting the two lobes of the transferrin molecule; (3). transferrin is expressed by activated goldfish macrophages but not mitogen-stimulated kidney leukocytes; and (4). addition of transferrin significantly enhanced the killing response of goldfish macrophages exposed to different pathogens or pathogen products (e.g. lipopolysaccharide, Mycobacterium chelonei, Trypanosoma danilewskyi, Aeromonas salmonicida, and Leishmania major). We propose a model of fish macrophage activation that is mediated by a non-cytokine host protein (i.e. transferrin) in combination with highly conserved innate immunity recognition receptors that are almost certain to exist in teleost.

Macrophage-mediated innate host defense against protozoan parasites.

Macrophages are immune cells that play a pivotal role in the detection and elimination of pathogenic microorganisms. Macrophages possess a variety of surface receptors devoted to the recognition of non-self by discriminating between host and pathogen-derived structures. Recognition of foreign microorganisms by the macrophage ultimately results in phagocytosis and the eventual destruction of microorganisms by lysosomal enzymes, toxic reactive oxygen and nitrogen intermediates, and/or nutrient deprivational mechanisms. However, protozoan parasites such as Toxoplasma gondii, Trypanosoma cruzi, and Leishmania spp., parasitize macrophages, utilizing them as a host cell for their growth, replication, and/or maintenance of their life cycles. The protozoan parasites of the genus Leishmania are unique in that their intracellular replication in the host is predominantly restricted to a single cell type, the macrophage. This review focuses on the cellular processes involved in macrophage-mediated host defense against protozoan parasites, from the initial host-parasite interactions that mediate recognition to the mechanisms employed by macrophages to destroy and eliminate the pathogen. As an example model system of experimental study, we describe in more more detail the cellular interactions between macrophages and the obligate intracellular parasite of mammalian macrophages, Leishmania spp.

A toll-like receptor (TLR) gene that is up-regulated in activated goldfish macrophages.

An expressed sequence tag screen of a macrophage activation factor and lipopolysaccharide (LPS) stimulated goldfish macrophage subtractive library generated several transcripts of a putative teleost homologue of the toll-like receptor (TLR) family. The full-length TLR cDNA was sequenced and is predicted to encode a type I transmembrane protein with an extracellular domain containing leucine rich repeats and a cytoplasmic tail encoding a toll/interleukin-1 receptor domain. These findings indicate that the gene identified is the first teleost homologue of the TLR family reported. Constitutive expression of TLR was observed in unstimulated macrophages and was also observed in goldfish spleen and kidney but not in heart and liver tissues. A significant up-regulation of the TLR mRNA in cultured macrophages following treatments with each of bacterial LPS, heat-killed Aeromonas salmonicida, and live Mycobacterium chelonei was observed after 3 and 6 h post-stimulation, though with different kinetics from each other. A relative decline in TLR expression was observed after 24 h, but expression levels were still higher than that of unstimulated cells. Thus pathogen-derived factors appear to differentially modulate the expression of TLR in goldfish macrophages, which undoubtedly contributes to the orchestration and/or induction of functional immune responses in fish.

Identification of Two IgD+ B Cell Populations in Channel Catfish, Ictalurus punctatus

Channel catfish Ictalurus punctatus express two Ig isotypes: IgM and IgD. Although catfish IgM has been extensively studied at the functional and structural levels, much less is known about IgD. In this study, IgM+/IgD+ and IgM−/IgD+ catfish B cell populations were identified through the use of anti-IgM and anti-IgD mAbs. Catfish IgM+/IgD+ B cells are small and agranular. In contrast, IgM−/IgD+ B cells are larger and exhibit a plasmablast morphology. The use of cell sorting, flow cytometry, and RT-PCR demonstrated that IgD+ B cell expression varies among individuals. For example, some catfish have <5% IgM−/IgD+ B cells in their PBLs, whereas in others the IgM−/IgD+ B cell population can represent as much as 72%. Furthermore, IgD expressed by IgM−/IgD+ B cells preferentially associates with IgL σ. Comparatively, IgM+/IgD+ B cells can express any of the four catfish IgL isotypes. Also, transfection studies show that IgD functions as a typical BCR, because Igδ-chains associate with CD79a and CD79b molecules, and all membrane IgD transcripts from sorted IgM−/IgD+ B cells contain viable VDJ rearrangements, with no bias in family member usage. Interestingly, all secreted IgD transcripts from IgM+/IgD+ and IgM−/IgD+ B cells were V-less and began with a leader spliced to Cδ1. Importantly, transfection of catfish clonal B cells demonstrated that this leader mediated IgD secretion. Together, these findings imply that catfish IgM−/IgD+ B cells likely expand in response to certain pathogens and that the catfish IgD Fc-region, as has been suggested for human IgD, may function as a pattern recognition molecule.

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

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 37kDa (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 24h 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 37kDa. 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.

Ozone treatment ameliorates oil sands process water toxicity to the mammalian immune system

We evaluated whether ozonation ameliorated the effects of the organic fraction of oil sands process water (OSPW) on immune functions of mice. Ozonation of OSPW eliminated the capacity of its organic fraction to affect various mouse bone marrow-derived macrophage (BMDM) functions in vitro. These included the production of nitric oxide and the expression of inducible nitric oxide synthase, the production of reactive oxygen intermediates and the expression of NADPH oxidase subunits, phagocytosis, and the expression of pro-inflammatory cytokine genes. Ozone treatment also eliminated the ability of OSPW organic fraction to down-regulate the expression of various pro-inflammatory cytokine and chemokine genes in the liver of mice, one week after oral exposure. We conclude that ozone treatment may be a valuable process for the remediation of large volumes of OSPW.

Generation of primary monocyte-like cultures from rainbow trout head kidney leukocytes

Trout primary kidney monocyte-like cultures (T-PKM) were generated by incubating head kidney leukocytes in the presence of cell-conditioned medium (CCM). This technique was adapted from procedures that were previously used to cultivate in vitro-derived kidney macrophages (IVDKM) from the goldfish. Flow cytometric analysis of the initial T-PKM cultures, identified three cell sub-populations, but only one of these sub-populations survived extensive cultivation periods (i.e. >8 days) in the presence of CCM. Functionally, reactive oxygen intermediate (ROI) production was detected following stimulation of T-PKM with PMA. However, these cells failed to produce reactive nitrogen intermediates (RNI) in response to immunological stimuli. In contrast, goldfish IVDKM were capable of producing both ROI and RNI. Using the dihydrorhodamine (DHR) assay and flow cytometry, we identified two ROI-producing sub-populations in goldfish IVDKM but only a single ROI-producing sub-population was present after extended cultivation of T-PKM. This T-PKM sub-population was subsequently sorted using the flow cytometer and shown to possess monocyte-like morphology by microscopic and cytometric analysis. Thus, acquisition of antimicrobial functions following cultivation of kidney leukocytes of rainbow trout and goldfish is markedly different, and may be due to the failure of trout monocyte-like cells to undergo a final differentiation step in vitro.

Evaluating the Toxicity of Hydroxyapatite Nanoparticles in Catfish Cells and Zebrafish Embryos

The toxicity of needle-(nHA-ND) and rod-shaped (nHA-RD) hydroxyapatite (HA) nanoparticles is evaluated in vitro on catfish B-cells (3B11) and catfish T-cells (28s.3) and in vivo on zebrafish embryos to determine if biological effects are similar to the effects seen in mammalian in vitro systems. Neither nHA-ND nor nHA-RD affect cell viability at concentrations of 10 to 300 μg mL(-1) . However, 30 μg mL(-1) needle-shaped nHA lower metabolic activity of the cells. Axial deformations are seen in zebrafish exposed to 300 μg mL(-1) needle shaped nHA after 120 h. For the first time, nHA is reported to cause zebrafish hatching delay. The lowest concentration (3 μg mL(-1) ) of both types of nHA cause the highest hatching inhibition and needle-shaped nHA exposed zebrafish exhibit the lowest hatch at 72 h post fertilization.

Induction of nitric oxide and respiratory burst response in activated goldfish macrophages requires potassium channel activity.

Potassium channel activity is important for modulating mammalian macrophage antimicrobial functions. The involvement of potassium channels in mediation of immune cell function in lower vertebrates, such as teleost, has not been explored. Since relatively little is known about the types of potassium channels present in fish macrophages, pharmacological blockers with broad ranges of activity were tested: 4-aminopyridine (4-AP), quinine, and tetraethylammonium chloride (TEA). The potassium channel blockers inhibited reactive nitrogen intermediates (RNI) and reactive oxygen intermediates (ROI) production by goldfish macrophages activated with bacterial lipopolysaccharide (LPS) and/or macrophage activating factor (MAF)-containing supernatants. Quinine was the most potent inhibitor with an IC(50) of 50 microM, while the other blockers, 4-AP and TEA, had IC(50) of 1.2 and 0.6mM, respectively. A reversible depolarization of the goldfish macrophage plasma membrane potential (Vm) was observed following treatments with potassium channel blockers, and was related to transcriptional changes in the inducible nitric oxide synthase gene (iNOS). Down-regulation of antimicrobial activities and depolarization of the goldfish macrophage plasma membrane were not a consequence of reduced cell number or viability, suggesting that potassium channels are required for generation of appropriate goldfish macrophage antimicrobial functions.