Differential role of tyrosine phosphorylation in adhesion-induced transcription, mRNA stability, and cytoskeletal organization in human monocytes.

Monocyte adhesion resulted in rapid tyrosine phosphorylation and subsequent cytokine mRNA induction. The objective of this study was to determine the role of specific tyrosine phosphorylation events, particularly those involving members of the MAP kinase family, in regulating adhesion-induced cytokine expression. Using nuclear run-on analyses, we demonstrated that on adhesion, monocytes rapidly transcriptionally activated numerous cytokine mRNAs, coincident with the activation of the transcription factors NF-KB and AP-1. Both an inhibitor of tyrosine phosphorylation, genistein, and the cytoplasmic tyrosine phosphatase PTP1B, were unable to prevent adhesion-mediated transcriptional activation. However, both blocked adhesion-induced ERK and JNK but not p38 kinase activation and at the same time decreased the stability of interleukin-1beta (IL-1beta) and IL-8 transcripts. In addition, whereas adhesive events occurred in the presence of genistein and PTP1B, monocyte spreading was markedly inhibited. Our results suggest that the majority of protein phosphorylation events are associated with adhesion-induced cytokine expression through transcript stabilization and cytoskeletal organization. A minority of protein phosphorylation events, not sensitive to genistein or PTP1B exposure, may be instrumental in regulating transcription. Thus the spectrum of protein tyrosine kinases required for transcription appear distinct from those involved in maintaining the stability of some cytokine mRNAs and the integrity of the cytoskeleton to which mRNA destined for translation must be associated.

Adhesion-dependent regulation of an A+U-rich element-binding activity associated with AUF1.

Monocyte adherence results in the rapid transcriptional activation and mRNA stabilization of numerous mediators of inflammation and tissue repair. While the enhancer and promoter elements associated with transcriptional activation have been studied, mechanisms linking adhesion, mRNA stabilization, and translation are unknown. GROalpha and interleukin-1beta (IL-1beta) mRNAs are highly labile in nonadhered monocytes but stabilize rapidly after adherence. GROalpha and IL-1beta transcripts both contain A+U-rich elements (AREs) in the 3' untranslated region (UTR) which have been directly associated with rapid mRNA turnover. To determine if the GROalpha ARE region was recognized by factors associated with mRNA degradation, we carried out mobility gel shift analyses using a series of RNA probes encompassing the entire GROalpha transcript. Stable complexes were formed only with the proximal 3' UTR which contained the ARE region. The two slower-moving complexes were rapidly depleted following monocyte adherence but not direct integrin engagement. Deadherence reactivated the two largest ARE-binding complexes and destabilized IL-1beta transcripts. Antibody supershift studies demonstrated that both of these ARE RNA-binding complexes contained AUF1. The formation of these complexes and the accelerated mRNA turnover are phosphorylation-dependent events, as both are induced in adherent monocytes by the tyrosine kinase inhibitor genistein and the p38 MAP kinase inhibitor of IL-1beta translation, SK&F 86002. These results demonstrate that cell adhesion and deadhesion rapidly and reversibly modify both cytokine mRNA stability and the RNA-binding complexes associated with AUF1.

Taxol-dependent transcriptional activation of IL-8 expression in a subset of human ovarian cancer.

Taxol is important in the treatment of both primary and drug-resistant ovarian cancer. Although Taxol is known to stabilize microtubules and block cell mitosis, the effectiveness of this drug exceeds that of other antimitotic agents, suggesting it may have an additional mode of action. Stimulated by murine macrophage studies indicating cytokine induction by Taxol, we have investigated proinflammatory cytokine expression in a series of cell lines and recent explants of human ovarian cancer. Taxol induced secretion of interleukin (IL) 8 but not IL-6, IL-1alpha, or IL-1beta in 4 of 10 samples. Induction was dependent on transcriptional activation, and, in contrast to murine macrophage studies, was apparently independent of an active lipopolysaccharide signaling pathway. Confluent cultures secreted as much IL-8 as proliferating cells. Taxol did not induce IL-8 in breast carcinoma, endometrial stromal, or T-lymphocyte or monocyte cultures. We propose that the local expression of this chemokine in vivo may elicit a host response similar in effectiveness to that of cytokine gene therapy. These data are the first to suggest that a chemotherapeutic agent may have a direct effect on transcription of cytokine and/or growth factor genes in ovarian cancer, and that this effect may not be restricted to proliferating tumor cells.

The intracellular IL-1 receptor antagonist alters IL-1-inducible gene expression without blocking exogenous signaling by IL-1 beta.

The epithelium-associated tissue distribution of the intracellular IL-1R antagonist (icIL-1Ra) suggests that it functions as a novel regulatory molecule for IL-1 in somatic tissues. We examined the role of the icIL-1Ra in IL-1 beta-induced responses in human ovarian cancer cells because ovarian surface epithelium expresses transcripts for the icIL-1Ra, and the majority of ovarian cancers arise from these cells. Several human ovarian and cervical cancer cell lines spontaneously express the icIL-1Ra. icIL-1Ra-expressing cells did not have altered growth characteristics or altered short term responses to IL-1 compared with icIL-1Ra-nonexpressing cells. While a 90-min exposure to IL-1 beta resulted in increased steady state cytokine mRNA levels in all cells, icIL-1Ra-positive cells were incapable of maintaining IL-1-beta-induced expression of GRO mRNA. This did not result from decreased transcriptional activity of the GRO gene, but reflected differences in mRNA stability and/or degradation. To determine whether the icIL-1Ra altered mRNA stability, we used a retroviral expression vector to express the icIL-1Ra in an icIL-1Ra-negative cell line. The resulting cells displayed a profile of IL-1 beta-induced genes analogous to that found in cells spontaneously expressing icIL-1Ra. These data show for the first time an intrinsic biologic activity for the icIL-1Ra. The capacity to selectively alter IL-1-induced gene expression suggests that this version of the IL-1Ra is a unique intracellular inhibitor that attenuates IL-1 responses at a point downstream of the initial IL-1/IL-1 receptor interaction.

Role of transcriptional activation of I kappa B alpha in mediation of immunosuppression by glucocorticoids.

Glucocorticoids are potent immunosuppressive drugs, but their mechanism is poorly understood. Nuclear factor kappa B (NF-kappa B), a regulator of immune system and inflammation genes, may be a target for glucocorticoid-mediated immunosuppression. The activation of NF-kappa B involves the targeted degradation of its cytoplasmic inhibitor, I kappa B alpha, and the translocation of NF-kappa B to the nucleus. Here it is shown that the synthetic glucocorticoid dexamethasone induces the transcription of the I kappa B alpha gene, which results in an increased rate of I kappa B alpha protein synthesis. Stimulation by tumor necrosis factor causes the release of NF-kappa B from I kappa B alpha. However, in the presence of dexamethasone this newly released NF-kappa B quickly reassociates with newly synthesized I kappa B alpha, thus markedly reducing the amount of NF-kappa B that translocates to the nucleus. This decrease in nuclear NF-kappa B is predicted to markedly decrease cytokine secretion and thus effectively block the activation of the immune system.

Transcription-independent turnover of I kappa B alpha during monocyte adherence: implications for a translational component regulating I kappa B alpha/MAD-3 mRNA levels.

We identified I kappa B alpha/MAD-3 as an immediate-early gene in human monocytes that is expressed in response to a variety of signals, including adhesion, lipopolysaccharide, and phorbol myristate acetate. Within 5 min of monocyte adhesion, the level of the I kappa B alpha protein is markedly diminished but is rapidly replaced in a cycloheximide-sensitive manner within 20 min. Accompanying the rapid turnover of the I kappa B alpha protein is simultaneous translocation of NF-kappa B-related transcription factors to nuclei of adhered monocytes. The demonstration that NF-kappa B can regulate I kappa B alpha/MAD-3 gene transcription in other cell types suggested that the rapid increase in steady-state I kappa B alpha/MAD-3 mRNA levels we observed within 30 min of monocyte adherence would result from NF-kappa B-dependent transcriptional stimulation of the I kappa B alpha/MAD-3 gene. Nuclear run-on analyses indicated that, instead, while several immediate-early cytokine genes, such as the interleukin 1 beta (IL-1 beta) gene, were transcriptionally activated during monocyte adhesion, the rate of I kappa B alpha/MAD-3 gene transcription remained constant. The adherence-dependent increase in I kappa B alpha/MAD-3 mRNA levels was also not a consequence of mRNA stabilization events. Interestingly, while increases in both IL-1 beta and I kappa B alpha/MAD-3 mRNA levels were detected in nuclei of adherent monocytes, cytoplasmic levels of IL-1 beta mRNA increased during adherence whereas those of I kappa B alpha/MAD-3 mRNA did not. Taken together, our data suggest that two interactive mechanisms regulate monocytic I kappa B alpha/MAD-3 mRNA levels. We propose that adherent monocytes regulate nuclear processing (or decay) of I kappa B alpha/MAD-3 mRNA, thereby increasing mRNA levels without stimulating I kappa B alpha/MAD-3 gene transcription. Moreover, since inhibition of protein synthesis leads to accumulation of I kappa B alpha/MAD-3 mRNA without stimulating I kappa B alpha/MAD-3 gene transcription, we suggest that low cytoplasmic levels of I kappa B alpha/MAD-3 mRNA are maintained by a translation-dependent degradation mechanism.

Promoter opening (melting) and transcription initiation by RNA polymerase I requires neither nucleotide beta,gamma hydrolysis nor protein phosphorylation.

With some bacterial RNA polymerases and in eukaryotic RNA polymerase II, DNA melting during initiation requires the coupling of energy derived from beta,gamma hydrolysis of ATP. A detailed analysis of this possible requirement for eukaryotic RNA polymerase I reveals no such requirement. However, in some cases, beta,gamma non-hydrolyzable derivatives (beta,gamma imido or methylene) of nucleotide substrates have been found to significantly inhibit transcription initiation because of their inefficient use as the first nucleotide of the transcript. In addition, the results presented here show that protein kinase activity is not required as an integral part of transcription initiation by RNA polymerase I. Prior phosphorylation of proteins participating in the process is not ruled out.

An exonuclease requiring an intact helical stem for specificity produces the 3' end of Acanthamoeba castellanii 5 S RNA.

A nuclear extract from Acanthamoeba castellanii which contains all of the components necessary for specific transcription of a 5 S RNA gene was separated into fractions required for specific transcription initiation and an additional fraction needed in the reconstituted system to produce the 3' end characteristic of mature 5 S RNA. The latter fraction contained a novel processing activity characterized by an exonuclease specific for highly structured RNAs, including 5 S RNA. An intact helical stem formed between the 5' and 3' ends of the 5 S RNA precursor determines the 3' nucleotide. In addition, the presence of ATP is required for specific processing. However, the possibility has not been ruled out that ATP inhibits a nonspecific ribonuclease in the extract since processing proceeds into the helical stem in its absence.

A discrete region centered 22 base pairs upstream of the initiation site modulates transcription of Drosophila tRNAAsn genes.

We have studied the mechanism by which 5'-flanking sequences modulate the in vitro transcription of eucaryotic tRNA genes. Using deletion and linker substitution mutagenesis, we have found that the 5'-flanking sequences responsible for the different in vitro transcription levels of three Drosophila tRNA5Asn genes are contained within a discrete region centered 22 nucleotides upstream from the transcription initiation site. In conjunction with the A-box intragenic control region, this upstream transcription-modulatory region functions in the selection mechanism for the site of transcription initiation. Since the transcription-modulatory region directs the position of the start site and the actual sequence of the transcription-modulatory region determines the level of tRNAAsn gene transcription, the possibility is raised that the transcription-modulatory region directs a transcription initiation event similar to open complex formation at procaryotic promoters.