Fumihiko Katakura

Clonal growth of carp (Cyprinus carpio) T cells in vitro: Long-term proliferation of Th2-like cells

Carp kidney leukocytes co-cultured with a supporting cell layer resulted in proliferation of polyclonal CD4(+) αβT cells as described previously. These bulk-cultured T cells expressed transcripts for both T helper 1 cells (Th1) master regulator (T-bet) and T helper 2 cells (Th2) master regulator (GATA-3). To identify the Th subsets in bulk-cultured T cells, single cells were picked up from the bulk culture, proliferated, and characterized. The majority of the clones displayed characteristics consistent with CD4(+) αβT cell identity. These clones expressed both TCRα and TCRβ, but could not produce a TCRγδ heterodimer since they typically only expressed either TCRγ or TCRδ. These clones also expressed the TCR co-receptor genes CD4-1 or CD4-2, whereas they did not express CD8α or CD8β. In addition, GATA-3 was expressed whereas T-bet was not. Among these clones, one clone (KoThL5) continued to proliferate on the supporting cells and was successively transferred for more than 10 months and 90-100 passages. To characterize the KoThL5 cells by their cytokine production profile, they were stimulated with PHA and investigated by real-time RT-PCR. mRNA expression of Th2-related cytokine (IL-4/13B) was only enhanced in KoThL5 cells whereas both Th1-related cytokine (IFNγ) and Th2-related cytokines (IL-4/13A and IL-4/13B) were significantly enhanced in bulk-cultured T cells. Taken together, KoThL5 cells share some features with mammalian Th2 cells. This is the first study to describe in vitro cultures of teleost cell with Th2-like features. The KoThL5 cell line has considerable potential for addressing questions concerning the properties of teleost Th2 cells.

Co-culture of carp (Cyprinus carpio) kidney haematopoietic cells with feeder cells resulting in long-term proliferation of T-cell lineages

To characterise fish haematopoietic stem/progenitor cells, it is necessary to develop a culture system that supports proliferation and differentiation of these cells. In the present study, we established cell lines from various tissues of carp (Cyprinus carpio) and ginbuna (Carassius auratus langsdorfii). By using these cell lines, we developed a culture system in which carp haematopoietic cells proliferated and were successively passaged. Cell lines from carp thymus (KoT), carp fin (KoF1) and ginbuna thymus (GTS6 and GTS9) were newly established. In addition to these cell lines, ginbuna fin (CFS) cell lines were also used as feeder layers. Kidney haematopoietic cells co-cultured with these feeder layers proliferated rapidly and were passaged over 20 times for more than 60 days. To characterise the proliferating cells, expression of marker genes for blood cell development were analysed. In the primary culture, marker genes for myeloid/erythroid progenitors (gata1), haematopoietic stem cells (gata2), neutrophils (mpx/mpo), B-cells (IgH) and T-cells (lck, TCRbeta and gata3) were detected by reverse transcriptase polymerase chain reaction (RT-PCR). Expression of most of the genes disappeared after the third passage, only T-cell marker genes were highly expressed after passages. These results indicate that multiple blood cells developed in the primary culture and then T-cell lineages dominantly proliferated after several passages.

Recombinant carp IL-4/13B stimulates in vitro proliferation of carp IgM+ B cells

Teleost IL-4/13B is a cytokine related to mammalian IL-4 and IL-13, of which hitherto the function had not been studied at the protein level. We identified an IL-4/13B gene in common carp (Cyprinus carpio) and expressed the recombinant protein (rcIL-4/13B). RcIL-4/13B was shown to stimulate proliferation of IgM(+) B cells, because after four days of stimulation the IgM(+) fraction of carp kidney and spleen leukocytes had formed many cell colonies, whereas such colonies were not found in the absence of rcIL-4/13B stimulation. After nine days of incubation with rcIL-4/13B these cells had proliferated to more than 3-to-7-fold higher numbers when compared to untreated cells. The proliferating cells contained a majority of IgM(+) cells but also other cells, as indicated by FACS and RT-PCR analyses. The important conclusion is that in fish not only IL-4/13A has B cell stimulating properties, as a previous publication has shown, but also IL-4/13B.

Regulation of Teleost Macrophage and Neutrophil Cell Development by Growth Factors and Transcription Factors

Macrophages and neutrophils are the sentinel cells of the innate immune response of verte‐ brates, such as bony fish (teleosts). As phagocytic myeloid cells, they are involved in homeo‐ static mechanisms, wound healing, and the detection, elimination and clearance of foreign entities including tumors, virus-infected cells and invading pathogens. Furthermore, macro‐ phages and neutrophils are responsible for producing hundreds of bioactive molecules that are important in pathogen recognition and destruction, cellular communication and activa‐ tion, initiation of an adaptive immune response and later, resolution of an inflammatory re‐ sponse and tissue repair. Neutrophils and macrophages, while essential to survival, have a finite lifespan. Therefore, a manufacturing centre, the hematopoietic niche, is needed for the production of myeloid cells. The hematopoietic niche must maintain basal myeloid cell pro‐ duction levels during homeostasis, yet retain the flexibility to ramp-up cell production in re‐ sponse to physiological demands, such as pathogenic insult. The development of macrophages (monopoiesis) and neutrophils (granulopoiesis) is collectively known as mye‐ lopoiesis, and is regulated by the complex interaction of colony-stimulating factors (CSFs), their receptors, and intracellular transcription factor machinery that control lineage fate de‐ cisions and terminal differentiation events.

Goldfish (Carassius auratus L.) as a model system to study the growth factors, receptors and transcription factors that govern myelopoiesis in fish.

The process of myeloid cell development (myelopoiesis) in fish has mainly been studied in three cyprinid species: zebrafish (Danio rerio), ginbuna carp (Carassius auratus langsdorfii) and goldfish (C. auratus, L.). Our studies on goldfish myelopoiesis have utilized in vitro generated primary kidney macrophage (PKM) cultures and isolated primary kidney neutrophils (PKNs) cultured overnight to study the process of macrophage (monopoiesis) and neutrophil (granulopoiesis) development and the key growth factors, receptors, and transcription factors that govern this process in vitro. The PKM culture system is unique in that all three subpopulations of macrophage development, namely progenitor cells, monocytes, and mature macrophages, are simultaneously present in culture unlike mammalian systems, allowing for the elucidation of the complex mixture of cytokines that regulate progressive and selective macrophage development from progenitor cells to fully functional mature macrophages in vitro. Furthermore, we have been able to extend our investigations to include the development of erythrocytes (erythropoiesis) and thrombocytes (thrombopoiesis) through studies focusing on the progenitor cell population isolated from the goldfish kidney. Herein, we review the in vitro goldfish model systems focusing on the characteristics of cell sub-populations, growth factors and their receptors, and transcription factors that regulate goldfish myelopoiesis.

Isolation and characterization of hematopoietic stem cells in teleost fish.

Despite 400 million years of evolutionary divergence, hematopoiesis is highly conserved between mammals and teleost fish. All types of mature blood cells including the erythroid, myeloid, and lymphoid lineages show a high degree of similarity to their mammalian counterparts at the morphological and molecular level. Hematopoietic stem cells (HSCs) are cells that are capable of self-renewal and differentiating into all hematopoietic lineages over the lifetime of an organism. The study of HSCs has been facilitated through bone marrow transplantation experiments developed in the mouse model. In the last decade, the zebrafish and clonal ginbuna carp (Carassius auratus langsdorfii) have emerged as new models for the study of HSCs. This review highlights the recent progress and future prospects of studying HSCs in teleost fish. Transplantation assays using these teleost models have demonstrated the presence of HSCs in the kidney, which is the major hematopoietic organ in teleost fish. Moreover, it is possible to purify HSCs from the kidney utilizing fluorescent dyes or transgenic animals. These teleost models will provide novel insights into the universal mechanisms of HSC maintenance, homeostasis, and differentiation among vertebrates.

Exploring erythropoiesis of common carp (Cyprinus carpio) using an in vitro colony assay in the presence of recombinant carp kit ligand A and erythropoietin

The use of in vitro colony assays in mammals has contributed to identification of erythroid progenitor cells such as burst-forming unit-erythroid (BFU-E) and colony-forming unit-erythroid (CFU-E) progenitors, and serves to examine functions of erythropoietic growth factors like Erythropoietin (Epo) and Kit ligand. Here, we established an in vitro colony-forming assay capable of investigating erythropoiesis in carp (Cyprinus carpio), cloned and functionally characterized recombinant homologous molecules Epo and Kit ligand A (Kitla), and identified three distinct erythroid progenitor cells in carp. Recombinant carp Epo induced the formation of CFU-E-like and BFU-E-like erythroid colonies, expressing erythroid marker genes, β-globin, epor and gata1. Recombinant carp Kitla alone induced limited colony formation, whereas a combination of Kitla and Epo dramatically enhanced erythroid colony formation and colony cell growth, as well as stimulated the formation of thrombocytic/erythroid colonies expressing not only erythroid markers but also thrombocytic markers, cd41 and c-mpl. Utilizing this colony assay to examine the distribution of distinct erythroid progenitor cells in carp, we demonstrated that carp head and trunk kidney play a primary role in erythropoiesis, while the spleen plays a secondary. Furthermore, we showed that presumably bi-potent thrombocytic/erythroid progenitor cells localize principally in the trunk kidney. Our results indicate that teleost fish possess mechanisms of Epo- and Kitla-dependent erythropoiesis similar to those in other vertebrates, and also help to demonstrate the diversity of erythropoietic sites among vertebrates.

Identification of novel polymorphisms and two distinct haplotype structures in dog leukocyte antigen class I genes: DLA-88, DLA-12 and DLA-64.

The current information on the polymorphism variation and haplotype structure of the domestic dog leukocyte antigen (DLA) genes is limited in comparison to other experimental animals. In this paper, to better elucidate the degree and types of polymorphisms and genetic differences for DLA-88, DLA-12 and DLA-64, we genotyped four families of 38 beagles and another 404 unrelated dogs representing 49 breeds by RT-PCR based Sanger sequencing. We also sequenced and analyzed the genomic organization of the DLA-88 and DLA-12 gene segments to better define these two-gene DLA haplotypes more precisely. We identified 45 alleles for DLA-88, 15 for DLA-12 and six for DLA-64, of which 20, 14 and six, respectively, were newly described alleles. Therefore, this study shows that the DLA-12 and DLA-64 loci are far more polymorphic than previously reported. Phylogenetic analysis strongly supported that the DLA-88, DLA-12 and DLA-64 alleles were independently generated after the original divergence of the DLA-79 alleles. Two distinct DLA-88 and DLA-12 haplotype structures, tentatively named DLA-88–DLA-12 and DLA-88–DLA-88L, were identified, and the novel haplotype DLA-88–DLA-88L contributed to 32.7% of the unrelated dogs. Quantitative real-time PCR analysis showed that the gene expression levels of DLA-88L and DLA-88 were similar, and that the gene expression level of DLA-12 was significantly lower. In addition, haplotype frequency estimations using frequently occurring alleles revealed 45 different DLA-class I haplotypes (88-88L/12-64) overall, and 22 different DLA-class I haplotypes in homozygous dogs for 18 breeds and mongrels.

Thrombopoietin (TPO) induces thrombocytic colony formation of kidney cells synergistically with kit ligand A and a non-secretory TPO variant exists in common carp

&NA; The development of mammalian megakaryocytes and platelets is regulated by numerous cytokine signals, primarily through the thrombopoietin (TPO)/c‐MPL axis. Although non‐mammalian vertebrates are known to possess nucleated thrombocytes functionally equivalent to mammalian platelets, the dynamics of the thrombocyte development remains unclear. Here we identified TPO and a splice variant (TPO‐v) caused by the intron retention in common carp (Cyprinus carpio). Both the tpo and its variant transcripts were highly expressed in heart and liver. Recombinant carp TPO (rcTPO) was produced and purified in HEK293T cells stably expressing tpo, but TPO‐v was shown not to be secreted from the transfectants. rcTPO induced the formation of colony‐forming unit‐thrombocyte (CFU‐T) colonies which were recognized by a monoclonal antibody against carp thrombocytes expressing c‐mpl and cd41, in a dose‐dependent manner. The combination of rcTPO and recombinant carp Kit ligand A (rcKITLA) exerted a significant synergistic effect on three types of colony formation: thrombocytic colonies, thrombocytic burst colonies and thrombocytic/erythroid colonies. Utilizing this colony assay to examine the distribution of thrombocytic progenitor cells in carp, we demonstrated that carp head and trunk kidney play a primary role in thrombopoiesis, while the spleen does not. Our results indicate that carp possess mechanisms of TPO‐ and KITLA‐dependent thrombopoiesis similar to those in other vertebrates and the sites of thrombopoiesis are restricted to the kidney, the primary hematopoietic organ in the teleost fish.