Nobuyuki Harada

Cloning of complementary DNA encoding T-cell replacing factor and identity with B-cell growth factor II

Proliferation and maturation of antigen-stimulated B cells are regulated by several soluble factors derived from macrophages and T cells1,2. These soluble factors are functionally divided into two groups: B-cell growth factor (BCGF), thought to be involved in B-cell proliferation; and B-cell differentiation factor (BCDF), responsible for maturation of activated B cells into immunoglobulin-secreting cells3–6. This classification needs to be re-examined in the light of the recent cloning of complementary DNA encoding IgG1 induction factor (interleukin-4, IL-4) from the 2.19 mouse T-cell line7. Recombinant IL-4 has BCGF and BCDF activities and affects B cells, T cells and mast cells (refs 7, 8; our unpublished data). Another well-characterized B-cell factor is T-cell replacing factor (TRF)9–12, which, when secreted by the murine T-cell hybridoma B151K12, is defined by two activities10–12: induction of IgM secretion by BCL1 leukaemic B-cell line; and induction of secondary anti-dinitrophenol (DNP) immunoglobulin G (IgG) synthesis in vitro by DNP-primed B cells. Although TRF from B151K12 was classified as BCDF, purified TRF has BCGF-II activity13. To elucidate the molecular properties of TRF we isolated cDNA encoding TRF from the 2.19 T-cell line and report here the structure and multiple activities of this lymphokine.

T Cell‐Replacing Factor (TRF)/Interleukin 5 (IL‐5): Molecular and Functional Properties

TRF has originally been defined as a T-cell-derived lymphokine that triggers activated B cells for a terminal differentiation into Ig-secreting cells. HPLC-purified TRF from Sup of a murine TRF-producing B151 cell is an acidic glycoprotein, exerts BCGF II activity and induces expression of IL-2 receptors. It does not show IL-1, IL-2, IL-3, BSF-1/IL-4, or IFN gamma activity. We prepared monoclonal TB13 and NC17 antibodies against HPLC-purified B151-TRF which are specific for and can inhibit TRF as well as BCFG II activity of B151-TRF. Moreover, TB13 as well as NC17 antibody can immunoprecipitate the 46 Kd molecule from B151 Sup which exerts TRF as well as BCGF II activity. Complementary DNA (pSP6K-mTRF23) encoding for murine TRF/IL-5 was cloned and its entire nucleotide sequences were determined. The murine TRF/IL-5 cDNA encodes 133 amino acids including N-terminal strongly hydrophobic regions. Secreted recombinant TRF/IL-5 (apparent m.w. of 46 Kd) has 113 amino acid residues and also comprises homodimers of a molecule with an apparent m.w. of 25 to 30 Kd. TRF/IL-5 mRNA is constitutively expressed in constitutively TRF-producing B151 and is inducible in some T cell lines upon stimulation with PMA or Con A. TRF/IL-5 mRNA is also expressed in Tbc-primed T cells upon the stimulation with PPD, whereas its expression is not effectively induced in non-primed spleen cells by stimulation with Con A or PMA plus calcium ionophore. The translation product of murine TRF/IL-5 cDNA triggers resting as well as activated (DNP-primed or LPS-stimulated) murine B cells for terminal differentiation into Ig-secreting cells (IgM, IgG1, or IgA) accompanied by increased mRNA expression for secreted forms of relevant Ig heavy chain (mu, gamma, or alpha). Among these, increases in the level of mu, and alpha-specific mRNA for the secreted form of IgM and IgA, respectively, are prominent. Moreover, TRF/IL-5 induces maturation of resting B cells into IgM-secreting cells. TRF/IL-5 promotes growth of activated B cells as well as BCL1 cells. TRF/IL-5 is, therefore, a growth as well as a differentiation inducing factor for B cells. Moreover, it induces functional IL-2 receptors on resting as well as activated B cells, besides TRF and BCGF II activities.(ABSTRACT TRUNCATED AT 400 WORDS)

Phagocytic uptake of polystyrene microspheres by alveolar macrophages: effects of the size and surface properties of the microspheres

Abstract Polystyrene microspheres with diameters of 0.2, 0.5, 1.0, 6.0 and 10 μm were added to alveolar macrophages, and their uptake was determined as the amount of superoxide generated from macrophages by the usage of chemiluminescence assay with luminol. The amount of superoxide generated was apparently higher with polystyrene microspheres with a diameter of 1 μm than those with diameters smaller than 1 μm (i.e. 0.2 or 0.5 μm) and with larger than 1 μm (6 or 10 μm). The effects of the functional groups located on the microsphere surfaces upon the uptake by alveolar macrophages were studied with polystyrene microspheres of 1 μm diameter having the primary amine, sulfate, hydroxyl, or carboxyl groups on their surfaces. We found that the macrophages most effectively trapped polystyrene microspheres with primary amine groups, those with carboxyl groups to a slightly lesser extent, and other microspheres much less amounts. The surface properties of these microspheres were determined by measuring their electrophoretic mobility in phosphate buffer solution (pH 7.4) with various ionic strengths. By the analysis of data with Ohshimas electrokinetic theory for soft particles, the surface charge density and the electrophoretic softness of the microsphere surfaces were determined. All the microsphere surfaces were found to be negatively charged, and those with primary amine groups and carboxyl groups were softer than other microspheres. From these findings, it is suggested that microspheres having soft surfaces are easily accessible to alveolar macrophages, and effectively trapped by macrophages.

T cell replacing factor/interleukin 5 induces not only B-cell growth and differentiation, but also increased expression of interleukin 2 receptor on activated B-cells

A T-cell replacing factor (TRF)/interleukin-5 (IL-5) is a B-cell growth and differentiation factor. In the present study, we examined the role of TRF/IL-5 in the increase in the levels of interleukin-2 (IL-2) receptor expression on activated B-cells. High pressure liquid chromatography (HPLC)-purified TRF/IL-5 (B151-TRF) from TRF-producing T-cell hybridoma, B151K12, as well as recombinant TRF/IL-5 (rec-TRF) were used for the analysis. Maximum anti-2,4-dinitrophenyl (DNP) IgG antibody response of DNP-primed B-cells or polyclonal IgM secretion of B-cell tumor line BCL1 was seen when HPLC-purified B151-TRF was added or when suboptimal doses of B151-TRF were added to the culture in the presence of IL-2. Normal resting B-cells gave maximum anti-SRBC IgM PFC responses when HPLC-purified B151-TRF and IL-2 were present. The purified B151-TRF as well as rec-TRF also induced on B-cells increased expression of IL-2 receptors that react with monoclonal anti-murine IL-2 receptor antibody, PC61, and 125I-labelled IL-2. The numbers of functional high affinity IL-2 receptors on activated B cells increased at least 20-fold by culturing them with purified B151-TRF. Moreover, B151-TRF induced increase in the levels of steady-state mRNA for IL-2 receptor by approximately 8-fold. These results suggest that activated B-cells as well as BCL1-cells may express functional IL-2 receptors or closely related molecules when stimulated with HPLC-purified B151-TRF as well as rec-TRF.

The critical region in the cytoplasmic domain of human IL-4 receptor for induction of IgE synthesis

To examine the region critical for differentiation in the human IL-4 receptor (hIL-4R), we transfected the Abelson murine leukemia virus (A-MuLV)-transformed murine pre-B cell line A20 with plasmid DNA encoding the hIL-4R. Transfectants expressed high affinity hIL-4Rs on the cell surface. Treatment with LPS and hIL-4 induced germline C epsilon transcripts in hIL-4R expressing A20 cells. Several hIL-4R mutant plasmids were then transfected into A20 cells and the transfectants were examined for hIL-4R expression and the ability to induce germline C epsilon transcripts upon stimulation with LPS and hIL-4. Although all A20 transfectants tested expressed the high-affinity hIL-4R, A20 transfectants expressing the mutant hIL-4R, which contains only 8 amino acids in the cytoplasmic domain, did not respond to LPS and hIL-4 with germline C epsilon transcripts. In addition, A20 transfectants expressing an internally deleted hIL-4R, in which the deleted region has been identified as the critical region for growth signal transduction in the previous study, failed to induce germline C epsilon transcripts with LPS and hIL-4. These results indicate that the critical region for the differentiation signal in the hIL-4R is identical to that for the growth signal, suggesting that IL-4 may share, at least partly, a common signal pathway for both growth and differentiation.

Establishment of an Assay System for the Detection of Translated Materials of T Cell-Replacing Factor mRNA in Xenopus Oocytes

We established an assay system for detecting T cell‐replacing factor (TRF) activity of translated materials in Xenopus oocytes of poly (A)‐positive mRNA extracted from a T cell hybrid cell line, B151K12 (B151) which constitutively produces TRF. Since it was difficult to detect TRF activity of the translated products of B151‐mRNA, partly because of low TRF activities, we developed the following two systems. First, RNA was prepared from B151 cells stimulated with phorbol myristate acetate and calcium ionophore A23187 because such stimulations augmented TRF production by approximately three to five‐fold. Second, interleukin 2 (IL‐2, 125 U/ml) was added to the culture of BCL1 cells to detect a small amount of TRF‐active materials since IL‐2 synergizes with a suboptimal dose of TRF to induce IgM secretion in TRF‐responding BCL1 cells (chronic B cell leukemic cells). Here we describe TRF activity of translation products of B151‐mRNA in Xenopus oocytes. B151‐TRF mRNA was detected in the fractions sedimented between 15 and 18S by analysis using sucrose density gradient centrifugation.