Interactions of CCCH zinc finger proteins with mRNA: tristetraprolin-mediated AU-rich element-dependent mRNA degradation can occur in the absence of a poly(A) tail

The CCCH family of tandem zinc finger proteins has recently been shown to promote the turnover of certain mRNAs containing class II AU-rich elements (AREs). In the case of one member of this family, tristetraprolin (TTP), absence of the protein in knockout mice leads to stabilization of two mRNAs containing AREs of this type, those encoding tumor necrosis factor alpha (TNFalpha) and granulocyte-macrophage colony-stimulating factor. To begin to decipher the mechanism by which these zinc finger proteins stimulate the breakdown of this class of mRNAs, we co-transfected TTP and its related CCCH proteins into 293 cells with vectors encoding full-length TNFalpha, granulocyte-macrophage colony-stimulating factor, and interleukin-3 mRNAs. Co-expression of the CCCH proteins caused the rapid turnover of these ARE-containing mRNAs and also promoted the accumulation of stable breakdown intermediates that were truncated at the 3'-end of the mRNA, even further 5' than the 5'-end of the poly(A) tail. To determine whether an intact poly(A) tail was necessary for TTP to promote this type of mRNA degradation, we inserted the TNFalpha ARE into a nonpolyadenylated histone mRNA and also attached a histone 3'-end-processing sequence to the 3'-end of nonpolyadenylated interleukin-3 and TNFalpha mRNAs. In all three cases, TTP stimulated the turnover of the ARE-containing mRNAs, despite the demonstrated absence of a poly(A) tail. These studies indicate that members of this class of CCCH proteins can promote class II ARE-containing mRNA turnover even in the absence of a poly(A) tail, suggesting that the processive removal of the poly(A) tail may not be required for this type of CCCH protein-stimulated mRNA turnover.     

Evidence that Tristetraprolin Binds to AU-Rich Elements and Promotes the Deadenylation and Destabilization of Tumor Necrosis Factor Alpha mRNA

Mice deficient in tristetraprolin (TTP), the prototype of a family of CCCH zinc finger proteins, develop an inflammatory syndrome mediated by excess tumor necrosis factor alpha (TNF-alpha). Macrophages derived from these mice oversecrete TNF-alpha, by a mechanism that involves stabilization of TNF-alpha mRNA, and TTP can bind directly to the AU-rich element (ARE) in TNF-alpha mRNA (E. Carballo, W. S. Lai, and P. J. Blackshear, Science 281:1001-1005, 1998). We show here that TTP binding to the TNF-alpha ARE is dependent upon the integrity of both zinc fingers, since mutation of a single cysteine residue in either zinc finger to arginine severely attenuated the binding of TTP to the TNF-alpha ARE. In intact cells, TTP at low expression levels promoted a decrease in size of the TNF-alpha mRNA as well as a decrease in its amount; at higher expression levels, the shift to a smaller TNF-alpha mRNA size persisted, while the accumulation of this smaller species increased. RNase H experiments indicated that the shift to a smaller size was due to TTP-promoted deadenylation of TNF-alpha mRNA. This CCCH protein is likely to be important in the deadenylation and degradation of TNF-alpha mRNA and perhaps other ARE-containing mRNAs, both in normal physiology and in certain pathological conditions.     

Interactions of CCCH zinc finger proteins with mRNA: non-binding tristetraprolin mutants exert an inhibitory effect on degradation of AU-rich element-containing mRNAs.

Tristetraprolin (TTP), the prototype of a small family of CCCH tandem zinc finger (TZF) domain proteins, is a physiological stimulator of instability of the mRNAs encoding tumor necrosis factor-alpha and granulocyte/macrophage colony-stimulating factor in certain cell types. TTP stimulates mRNA turnover after binding to class II AU-rich elements (AREs) within the 3'-untranslated regions of both mRNAs. In turn, this binding is dependent upon the key CCCH residues in the TZF domain. To evaluate other primary sequence requirements for ARE binding in this novel mRNA-binding domain, we mutated many of the conserved residues within the TZF domain of human TTP and evaluated the effects of these mutations on RNA binding in a cell-free system and TTP-induced mRNA instability in cell transfection experiments. These mutations revealed a number of conserved amino acids that were required for binding and begin to define the primary protein sequence requirements for this novel mRNA-binding motif. Unexpectedly, all of the point mutations that prevented TTP binding to RNA also caused an increase in steady-state levels of ARE-containing mRNAs in cell transfection experiments. Actinomycin D experiments suggested that this effect was due to inhibition of mRNA turnover. Although expression of the mutant form of TTP could also inhibit the destruction of tumor necrosis factor-alpha mRNA by wild-type TTP, the primary mechanism did not involve heterodimerization with wild-type TTP because the 293 cells used in these studies express no detectable endogenous TTP. These data suggest that TTP may act, at least in part, by physically interacting with an enzyme activity or protein complex and functionally stimulating its ability to deadenylate class II ARE-containing mRNAs.     

Interactions of CCCH zinc finger proteins with mRNA. Binding of tristetraprolin-related zinc finger proteins to Au-rich elements and destabilization of mRNA

Macrophages derived from tristetraprolin (TTP)-deficient mice exhibited increased tumor necrosis factor alpha (TNFalpha) release as a consequence of increased stability of TNFalpha mRNA. TTP was then shown to destabilize TNFalpha mRNA after binding directly to the AU-rich region (ARE) of the 3'-untranslated region of the TNFalpha mRNA. In mammals and in Xenopus, TTP is the prototype of a small family of three known zinc finger proteins containing two CCCH zinc fingers spaced 18 amino acids apart; a fourth more distantly related family member has been identified in Xenopus and fish. We show here that representatives of all four family members were able to bind to the TNFalpha ARE in a cell-free system and, in most cases, promote the breakdown of TNFalpha mRNA in intact cells. Because the primary sequences of these CCCH proteins are most closely related in their tandem zinc finger domains, we tested whether various fragments of TTP that contained both zinc fingers resembled the intact protein in these assays. We found that amino- and carboxyl-terminal truncated forms of TTP, as well as a 77 amino acid fragment that contained both zinc fingers, could bind to the TNFalpha ARE in cell-free cross-linking and gel shift assays. In addition, these truncated forms of TTP could also stimulate the apparent deadenylation and/or breakdown of TNFalpha mRNA in intact cells. Alignments of the tandem zinc finger domains from all four groups of homologous proteins have identified invariant residues as well as group-specific signature amino acids that presumably contribute to ARE binding and protein-specific activities, respectively.     

The p38/MK2-Driven Exchange between Tristetraprolin and HuR Regulates AU–Rich Element–Dependent Translation

TNF expression of macrophages is under stringent translational control that depends on the p38 MAPK/MK2 pathway and the AU–rich element (ARE) in the TNF mRNA. Here, we elucidate the molecular mechanism of phosphorylation-regulated translation of TNF. We demonstrate that translation of the TNF-precursor at the ER requires expression of the ARE–binding and -stabilizing factor human antigen R (HuR) together with either activity of the p38 MAPK/MK2 pathway or the absence of the ARE-binding and -destabilizing factor tristetraprolin (TTP). We show that phosphorylation of TTP by MK2 decreases its affinity to the ARE, inhibits its ability to replace HuR, and permits HuR-mediated initiation of translation of TNF mRNA. Since translation of TTP''s own mRNA is also regulated by this mechanism, an intrinsic feedback control of the inflammatory response is ensured. The phosphorylation-regulated TTP/HuR exchange at target mRNAs provides a reversible switch between unstable/non-translatable and stable/efficiently translated mRNAs.     

Differential regulation of ARE-mediated TNFalpha and IL-1beta mRNA stability by lipopolysaccharide in RAW264.7 cells

Messenger RNA degradation is a mechanism by which eukaryotic cells regulate gene expression and influence cell growth and differentiation. Many protooncogene, cytokine, and growth factor RNAs contain AU-rich element (AREs) in the 3'untranslated regions which enable them to be targeted for rapid degradation. To investigate the mechanism of ARE-mediated RNA stability, we demonstrate the expression and regulation of TNFalpha and IL-1beta mRNAs in LPS-stimulated macrophages. TNFalpha mRNA was rapidly induced by LPS and showed short half-life at 2-h induction, whereas IL-1beta mRNA was induced slowly and had longer half-life. Electrophoretic mobility shift assays showed that the LPS-induced destabilization factor tristetraprolin (TTP) could bind to TNFalpha ARE with higher affinity than to IL-1beta ARE. HuR was identified to interact with TNFalpha ARE to exert RNA stabilization activity. The expression and phosphorylation of TTP could be activated by p38 MAPK pathway during LPS stimulation. Moreover, ectopic expression with TTP and kinases in p38 pathway followed by biochemical assays showed that the activation of p38 pathway resulted in the phosphorylation of TTP and a decrease in its RNA-binding activity. The ARE-containing reporter assay presented that the p38 signal could reverse the inhibitory activity of TTP on IL-1beta ARE but not on TNFalpha ARE. The present results indicate that the heterogeneity of AREs from TNFalpha and IL-1beta could reflect distinct ARE-binding proteins to modulate their RNA expression.     

Functional cloning of BRF1, a regulator of ARE-dependent mRNA turnover

To identify regulators of AU-rich element (ARE)-dependent mRNA turnover we have followed a genetic approach using a mutagenized cell line (slowC) that fails to degrade cytokine mRNA. Accordingly, a GFP reporter construct whose mRNA is under control of the ARE from interleukin-3 gives an increased fluorescence signal in slowC. Here we describe rescue of slowC by a retroviral cDNA library. Flow cytometry allowed us to isolate revertants with reconstituted rapid mRNA decay. The cDNA was identified as butyrate response factor-1 (BRF1), encoding a zinc finger protein homologous to tristetraprolin. Mutant slowC carries frame-shift mutations in both BRF1 alleles, whereas slowB with intermediate decay kinetics is heterozygous. By use of small interfering (si)RNA, independent evidence for an active role of BRF1 in mRNA degradation was obtained. In transiently transfected NIH 3T3 cells, BRF1 accelerated mRNA decay and antagonized the stabilizing effect of PI3-kinase, while mutation of the zinc fingers abolished both function and ARE-binding activity. This approach, which identified BRF1 as an essential regulator of ARE-dependent mRNA decay, should also be applicable to other cis-elements of mRNA turnover.