Human T cells were studied with regard to the regulation of interleukin- 4 (IL-4) and IL-3 gene expression. IL-4 and IL-3 mRNA were undetectable in unstimulated T cells. On activation with the lectin concanavalin A (Con A), both IL-4 and IL-3 mRNA were expressed. Accumulation of IL-4 mRNA peaked after 6 to 12 hours, whereas IL-3 mRNA levels peaked after 3 to 6 hours of stimulation with Con A. Nuclear run-on assays showed a low constitutive transcription for both genes. The transcription rates were increased by Con A resulting in a peak for IL-4 after 1 hour (30% increase) and for IL-3 after 3 hours (40% increase) of Con A treatment. mRNA stability studies demonstrated that on activation with Con A both messages decayed with a half-life of approximately 90 minutes. No IL-4 or IL-3 mRNA expression was induced by the protein kinase C activator phorbol myristate acetate (PMA). However, PMA augmented the Con A- induced IL-4 and IL-3 mRNA accumulation. This was shown to be mediated at posttranscriptional level by a large increase in the stability of both messages (t 1/2 > 3 hours). The transcription rate of both genes was also enhanced by Con A+PMA and reached peak levels for IL-4 after 1 hour (90% increase) and for IL-3 after 3 hours (70% increase) of stimulation. Furthermore, it appeared that the induction of IL-4 mRNA was dependent on protein synthesis because cycloheximide (CHX) blocked the Con A- and Con A+PMA-induced expression of IL-4 mRNA. In contrast, CHX inhibited, but failed to completely block, the Con A- and Con A+PMA- induced IL-3 mRNA expression, whereas the expression of both genes was completely blocked by cyclosporine A. With regard to the secretion of IL-4 protein it was shown that it closely follows the accumulation of IL-4 mRNA. Taken together, the data show that expression of the IL-4 and IL-3 genes in human T cells is controlled by different activation pathways that affect the gene regulation at transcriptional and posttranscriptional levels.
Recently it has been demonstrated that in vivo application of interleukin-3 (IL-3) is associated with the release of IL-6. This observation suggests that the transcription factors triggered by IL-3 are in great homology with the transcription factors induced by lipopolysaccharide (LPS). The results of the present study with in vitro activated human monocytes demonstrate that IL-3 alone is incapable of inducing IL-6 mRNA, but primes monocytes to enhance the IL-6 mRNA expression when co-stimulated with LPS. The difference in effect between IL-3 and LPS might be related to our observation that IL-3 induces the p5O subunit of the transcription factor nuclear factor-kappa B (NF-Kappa B), whereas LPS appears to induce both the p5O as well as the p65 subunit of NF-kappa B, as demonstrated with RNA studies and electrophoretic mobility shift assays (EMSA). However, no difference was found with regard to the induction of activator protein-1 (AP-1) and NF-IL6 after treatment with IL-3 or LPS alone. Priming with IL-3 followed by LPS stimulation is associated with a reduced expression of NF-kappa B without changing the composition of the complex. In addition, a reduced expression of c-fos and c-jun mRNA was noticed, combined with a reduced DNA binding activity of AP-1. However, the expression of NF-IL6 was enhanced when priming with IL-3 followed by LPS. Since AP-1 has been suggested as negative regulator of the IL-6 gene expression, it is conceivable that, after priming with IL-3, the reduced DNA binding activity of AP-1, in conjunction with the increased DNA binding of NF-IL6, might result in a synergistic effect on IL-6 mRNA expression, when compared to stimulation with LPS alone.
The stromal derived growth factor IL-7 was studied for its ability to modulate cytokine expression in human T cells. IL-7 alone did not induce IL-3 or granulocyte-macrophage-CSF (GM-CSF) mRNA. However, IL-7 enhanced the Con A-induced IL-3 and GM-CSF mRNA accumulation in a dose-dependent way. mRNA stability studies revealed that the effect of IL-7 was caused by post-transcriptional stabilization of the IL-3 and GM-CSF transcripts. Upon Con A treatment, the IL-3 and GM-CSF mRNA decayed with a t1/2 of approximately 90 and 50 min, respectively. Costimulation with Con A plus IL-7 stabilized both transcripts to t1/2 of greater than 2 h for IL-3 mRNA and 90 min for GM-CSF mRNA. Using nuclear run-on assays, we showed that the transcription rate of both genes was not affected by IL-7. Furthermore, it appeared that the effect of IL-7 was independent on protein synthesis, because cycloheximide did not abolish the promotive effect of IL-7. Finally, it was shown that in accordance with the mRNA results IL-7 enhanced the secretion of GM-CSF protein in Con A-activated T cells. After 12 h of stimulation T cells cultured in the presence of Con A secreted 575 +/- 309 pg GM-CSF/ml (x +/- SD, n = 5), which increased to 1425 +/- 758 pg/ml in the presence of Con A plus IL-7 (p < 0.01). In summary, these data demonstrate that IL-7 augments the expression and secretion of CSF in activated human T cells.
Human T cells were studied with regard to the regulation of interleukin- 4 (IL-4) and IL-3 gene expression. IL-4 and IL-3 mRNA were undetectable in unstimulated T cells. On activation with the lectin concanavalin A (Con A), both IL-4 and IL-3 mRNA were expressed. Accumulation of IL-4 mRNA peaked after 6 to 12 hours, whereas IL-3 mRNA levels peaked after 3 to 6 hours of stimulation with Con A. Nuclear run-on assays showed a low constitutive transcription for both genes. The transcription rates were increased by Con A resulting in a peak for IL-4 after 1 hour (30% increase) and for IL-3 after 3 hours (40% increase) of Con A treatment. mRNA stability studies demonstrated that on activation with Con A both messages decayed with a half-life of approximately 90 minutes. No IL-4 or IL-3 mRNA expression was induced by the protein kinase C activator phorbol myristate acetate (PMA). However, PMA augmented the Con A- induced IL-4 and IL-3 mRNA accumulation. This was shown to be mediated at posttranscriptional level by a large increase in the stability of both messages (t 1/2 > 3 hours). The transcription rate of both genes was also enhanced by Con A+PMA and reached peak levels for IL-4 after 1 hour (90% increase) and for IL-3 after 3 hours (70% increase) of stimulation. Furthermore, it appeared that the induction of IL-4 mRNA was dependent on protein synthesis because cycloheximide (CHX) blocked the Con A- and Con A+PMA-induced expression of IL-4 mRNA. In contrast, CHX inhibited, but failed to completely block, the Con A- and Con A+PMA- induced IL-3 mRNA expression, whereas the expression of both genes was completely blocked by cyclosporine A. With regard to the secretion of IL-4 protein it was shown that it closely follows the accumulation of IL-4 mRNA. Taken together, the data show that expression of the IL-4 and IL-3 genes in human T cells is controlled by different activation pathways that affect the gene regulation at transcriptional and posttranscriptional levels.
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