Non-genomic immunosuppressive actions of progesterone inhibits PHA-induced alkalinization and activation in T cells

Progesterone is an endogenous immunomodulator, and can suppress T‐cell activation during pregnancy. When analyzed under a genome time scale, the classic steroid receptor pathway does not have any effect on ion fluxes. Therefore, the aim of this study was to investigate whether the non‐genomic effect...

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Published in:Journal of cellular biochemistry 2006-09, Vol.99 (1), p.292-304
Main Authors: Chien, Eileen Jea, Chang, Ching-Pang, Lee, Wen-Feng, Su, Tsung-Hsien, Wu, Chia-Hsun
Format: Article
Language:English
Subjects:
Adult
Ca2
Calcium - metabolism
Calcium - pharmacology
Cell Proliferation - drug effects
Cells, Cultured
Cytokines - metabolism
Dose-Response Relationship, Drug
Genome, Human
Humans
Hydrogen-Ion Concentration
IL-2
IL-4
immunosuppressive
Immunosuppressive Agents - pharmacology
Interleukin-2 - metabolism
Interleukin-4 - metabolism
Lymphocyte Activation - drug effects
Male
non-genomic
pHi
Phytohemagglutinins - pharmacology
progesterone
Progesterone - pharmacology
proliferation
Steroids - pharmacology
T cells
T-Lymphocytes - drug effects
T-Lymphocytes - physiology
Tetradecanoylphorbol Acetate - pharmacology
Thymidine - pharmacokinetics
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Summary:Progesterone is an endogenous immunomodulator, and can suppress T‐cell activation during pregnancy. When analyzed under a genome time scale, the classic steroid receptor pathway does not have any effect on ion fluxes. Therefore, the aim of this study was to investigate whether the non‐genomic effects on ion fluxes by progesterone could immunosuppress phytohemagglutinin (PHA)‐induced human peripheral T‐cell activation. The new findings indicated that, first, only progesterone stimulated both [Ca2+]i elevation and pHi decrease; in contrast, estradiol or testosterone stimulated [Ca2+]i elevation and hydrocortisone or dexamethasone stimulated pHi decrease. Secondly, the [Ca2+]i increase by progesterone was dependent on Ca2+ influx, and the acidification was blocked by Na+/H+ exchange (NHE) inhibitor, 3‐methylsulphonyl‐4‐piperidinobenzoyl, guanidine hydrochloride (HOE‐694) but not by 5‐(N,N‐dimethyl)‐amiloride (DMA). Thirdly, progesterone blocked phorbol 12‐myristate 13‐acetate (PMA) or PHA‐induced alkalinization, but PHA did not prevent progesterone‐induced acidification. Fourthly, progesterone did not induce T‐cell proliferation; however, co‐stimulation progesterone with PHA was able to suppress PHA‐induced IL‐2 or IL‐4 secretion and proliferation. When progesterone was applied 72 h after PHA stimulation, progesterone could suppress PHA‐induced T‐cell proliferation. Finally, immobilization of progesterone by conjugation to a large carrier molecule (BSA) also stimulated a rapid [Ca2+]i elevation, pHi decrease, and suppressed PHA‐induced proliferation. These results suggested that the non‐genomic effects of progesterone, especially acidification, are exerted via plasma membrane sites and suppress the genomic responses to PHA. Progesterone might act directly through membrane specific nonclassical steroid receptors to cause immunomodulation and suppression of T‐cell activation during pregnancy. J. Cell. Biochem. © 2006 Wiley‐Liss, Inc.
ISSN:0730-2312
1097-4644
DOI:10.1002/jcb.20858