Tadashi Mikami

Transcriptional control of the IL-5 gene by human helper T cells: IL-5 synthesis is regulated independently from IL-2 or IL-4 synthesis

BACKGROUND IL-5 is fundamentally involved in eosinophilic inflammation. Control of IL-5 production may be effective for the management of allergic diseases. OBJECTIVE We aimed to find the transcriptional mechanisms that regulate the IL-5 gene to selectively control IL-5 synthesis. METHODS Allergen-specific T-cell clones and T-cell hybridomas were established from the peripheral blood lymphocytes of patients with asthma, and the transcriptional regulation of the IL-5 gene was investigated with transient transfection and electrophoretic mobility shift analysis. RESULTS A human IL-5 promoter/enhancer-luciferase gene construct, pIL-5(-511)Luc, was transcribed on activation of IL-5-producing T-cell clones, but not IL-5-nonproducing clones. pIL-5(-511)Luc was transcribed by T-cell hybridomas derived from fusion between IL-5-producing T-cell clones and an IL-5 gene-nonexpressing T-cell line, but not by hybridomas derived from IL-5-nonproducing T-cell clones. IL-5 synthesis was not only induced by T-cell receptor stimulation but also by IL-2 receptor stimulation. Binding of NF-AT, NF-kappaB, and AP-1 was induced by T-cell receptor (TcR) stimulation, although there was no significant upregulation of binding by IL-2 stimulation. CONCLUSION IL-5 synthesis by human helper T cells is regulated at the transcriptional level. A unique transcriptional mechanism distinct from those regulating the IL-2 or IL-4 genes seems to control the IL-5 gene. Selective regulation of IL-5 gene transcription may be useful for treating eosinophlic inflammation.

Interleukin-6 is antiproliferative to a mouse hybridoma cell line and promotive for its antibody productivity

Monoclonal antibody production by hybridoma cells at moderately slowed growth states would be favorable for commercial scale production since cells can devote their resources to performing the differentiated function, immunoglobulin production. We found that a purified recombinant human interleukin-6, which had been reported to support or stimulate proliferation of B cell hybridoma/plasmacytoma cells, suppressed growth of a hybridoma cell line in serum-free medium. In the presence of the interleukin, the growth-suppressed cells were viable for remarkably long periods in batch culture, and after removal of the interleukin from the culture medium, they started to proliferate at their normal growth rate. As the concentration of the interleukin increased in the culture, the growth rate decreased and the specific antibody productivity (antibody production rate per cell) increased to 5-fold of control at 10 U ml−1 (2 ng ml−1) of the interleukin.

Cellular and molecular mechanisms of IL-5 synthesis in atopic diseases: A study with allergen-specific human helper T cells ☆ ☆☆ ★

BACKGROUND Cytokines produced by helper T cells are intimately involved in chronic allergic diseases associated with eosinophilic inflammation. OBJECTIVE We investigated the production of IL-5, a potent growth factor and chemotactic factor for eosinophils, by CD4+ T lymphocytes in patients with asthma. METHODS Allergen-specific T cell clones and T cell hybridomas were established from the peripheral blood lymphocytes of patients with asthma, and the responses to various stimuli were determined. RESULTS After nonspecific stimulation, IL-5 production by CD4+ T cells from both atopic and nonatopic subjects with asthma was significantly enhanced compared with that by cells from healthy controls. Peripheral blood mononuclear cells from atopic asthma patients both proliferated and produced IL-5 after incubation with mite allergen, suggesting that mite-specific helper T cells were involved in the eosinophilic inflammation of atopic asthma. A human IL-5 promoter/enhancer luciferase gene construct transfected into IL-5-producing T cell clones was clearly transcribed after stimulation, indicating that the 515 base pair IL-5 gene segment upstream of the coding region was sufficient to respond to activating signals in human helper T cells. The same gene segment was not transcribed in IL-5-nonproducing T cell clones, suggesting that human T cell IL-5 synthesis is regulated at the transcriptional level. Experiments with T cell hybridomas confirmed these findings and suggested that a unique transcription factor may be essential for human IL-5 gene transcription. CONCLUSION Enhanced IL-5 production by helper T cells seems to cause the eosinophilic inflammation of both atopic and nonatopic asthma. Elucidation of IL-5-specific regulatory mechanisms may facilitate the development of novel treatments for allergic diseases associated with eosinophilic inflammation.

Enhancingin vitro antibody production rate per cell by applying mouse peritoneal factors

SummaryMonoclonal antibody production rateper hybridoma cell was measured as much larger in mouse peritoneal cavity thanin vitro culture. To identify factors enhancing antibody productivity per cell, a hybridoma was culturedin vitro with ascites and peritoneal exudate cells(PEC). Both the ascites and the PEC improved the productivity per cellin vitro. Each chromatograph-fraction of ascites was assayed for the enhancing activity.

Enhanced Production and Gene Expression of IL-5 in Bronchial Asthma

Infiltration of various inflammatory cells into the bronchial mucosa and submucosa is a prominent pathological feature of bronchial asthma.1–3 Persistent mucosal inflammation, particularly epithelial damage caused by eosinophil-derived products, is believed to contribute to the pathogenesis of bronchial hypersensitivity.4–7 Inhalation of a relevant allergen results in an early asthmatic reaction (EAR) that subsides within 1 to 2 hours. In 40–60% of patients, this early reaction is followed after 6 to 10 hours by a late asthmatic reaction (LAR), which usually subsides during the next 1 to 2 days.8 Accumulating evidence suggests that LAR is a consequence of eosinophilic inflammation in the lung induced by a T cell cytokine, interleukin 5 (IL-5).9–15

Enhancing effect of mouse peritoneal exudate cells and their products on antibody productivity of hybridoma cells: Application of in vivo factors to in vitro culture

Mouse peritoneal exudate cells induced by casein enhanced in vitro antibody production rate per cell of a hybridoma in co-culture. Culture supernatant of the exudate cells also enhanced three-fold the antibody productivity when added to cultures of a hybridoma at 10% (v/v). Hence the enhancement of antibody productivity by the exudate cells seemed to be caused by soluble enhancing factors secreted by the exudate cells. The exudate cells maximally secreted the enhancing factors when harvested from mice on day 4 of the induction period following the injection of casein. A semi-continuous culture of the hybridoma demonstrated the applicability of the culture supernatant to enhance antibody production by producing a two-fold increase over the control for seven days when supplemented with the supernatant at 5%. Significant amounts of interleukin-6 were detected in culture supernatant of the exudate cells. Interleukin-6 obtained from other sources enhanced the antibody productivity two-fold when added to the hybridoma culture at the concentration of 5 unit/ml. Interleukin-6, therefore, is expected to be one of the principal antibody enhancing factors secreted by the exudate cells. Other interleukins examined, that is, interleukin-1 to-5 did not enhance the antibody productivity.