Correlation between intrinsic mRNA stability and the affinity of AUF1 (huRNP D) and HuR for A+U-rich mRNAs

Presence of A+U-rich elements (AREs) within 3-untranslated regions (3UTRs) of numerous mRNAs has been associated with rapid mRNA turnover; however, the interaction of specific factors with AREs is also associated with mRNA stabilization. Recently, two ARE binding proteins with putative mRNA destabilizing (AUF1) and stabilizing (HuR) properties have been described. However, no direct comparison of AUF1 and HuR binding properties has been made. Therefore, we examined the relative affinities of p37AUF1 and HuR for a diverse set of ARE-containing mRNAs encoding -adrenergic receptors, a proto-oncogene, and a cytokine. We find that high-affinity AUF1 binding appears to require elements beyond primary nucleotide sequence. In contrast, binding of HuR appears considerably less constrained. As a functional correlate, we determined the ability of these specific mRNA sequences to affect the stability of chimeric -globin mRNA constructs. Although the relative affinity of AUF1 and HuR are generally predictive of mRNA stability, we find that certain mRNA sequences do not conform to these generalizations.     

Aberrant regulation of mRNA 3' untranslated region in cancers and inflammation

Almost 10% of mammalian coding mRNAs contain in their 3' untranslated region a sequence rich in adenine and uridine residues known as AU-rich element (ARE). Many of them encode oncogenes (for instance c-Myc and c-Fos), cell cycle regulators (cyclin D1, A1, B1), cytokines (TNFalpha, IL2) and growth factors (GM-CSF) which are overexpressed in cancer or inflammatory diseases due to increased mRNA stability and/or translation. AREs are recognized by a group of proteins, collectively called AUBPs which display various functions. For instance, HuR/ELAV is mainly known to protect ARE-containing mRNAs from degradation, while AUF1, TTP and KSRP act to destabilize their bound target mRNAs and TIA/TIAR to inhibit their translation. Alterations in ARE sequences or AUBP abundance, cellular localization or activity due to post-translational modifications such as phosphorylation can promote or enhance malignancy or perturb immune homeostasis. Here, c-myc and TNFalpha are chosen as examples to illustrate how altered 3' UTR gene regulation impacts on pathologies.     

Chaperone Hsp27 modulates AUF1 proteolysis and AU-rich element-mediated mRNA degradation

AUF1 is an AU-rich element (ARE)-binding protein that recruits translation initiation factors, molecular chaperones, and mRNA degradation enzymes to the ARE for mRNA destruction. We recently found chaperone Hsp27 to be an AUF1-associated ARE-binding protein required for tumor necrosis factor alpha (TNF-α) mRNA degradation in monocytes. Hsp27 is a multifunctional protein that participates in ubiquitination of proteins for their degradation by proteasomes. A variety of extracellular stimuli promote Hsp27 phosphorylation on three serine residues--Ser(15), Ser(78), and Ser(82)-by a number of kinases, including the mitogen-activated protein (MAP) pathway kinases p38 and MK2. Activating either kinase stabilizes ARE mRNAs. Likewise, ectopic expression of phosphomimetic mutant forms of Hsp27 stabilizes reporter ARE mRNAs. Here, we continued to examine the contributions of Hsp27 to mRNA degradation. As AUF1 is ubiquitinated and degraded by proteasomes, we addressed the hypothesis that Hsp27 phosphorylation controls AUF1 levels to modulate ARE mRNA degradation. Indeed, selected phosphomimetic mutants of Hsp27 promote proteolysis of AUF1 in a proteasome-dependent fashion and render ARE mRNAs more stable. Our results suggest that the p38 MAP kinase (MAPK)-MK2-Hsp27 signaling axis may target AUF1 destruction by proteasomes, thereby promoting ARE mRNA stabilization.     

Sequence requirements for RNA binding by HuR and AUF1

The stability of RNAs bearing AU-rich elements in their 3'-UTRs, and thus the level of expression of their protein products, is regulated by interactions with cytoplasmic RNA-binding proteins. Binding by HuR generally leads to mRNA stabilization and increased protein production, whereas binding by AUF1 isoforms generally lead to rapid degradation of the mRNA and reduced protein production. The exact nature of the interplay between these and other RNA-binding proteins remains unclear, although recent studies have shown close interactions between them and even suggested competition between the two for binding to their cognate recognition sequences. Other recent reports have suggested that the sequences recognized by the two proteins are different. We therefore performed a detailed in vitro analysis of the binding site(s) for HuR and AUF1 present in androgen receptor mRNA to define their exact target sequences, and show that the same sequence is contacted by both proteins. Furthermore, we analysed a proposed HuR target within the 3'-UTR of MTA1 mRNA, and show that the contacted bases lie outside of the postulated motif and are a better match to a classical ARE than the postulated motif. The defining features of these HuR binding sites are their U-richness and single strandedness.     

Facilitation of mRNA deadenylation and decay by the exosome-bound, DExH protein RHAU

The AU-rich element (ARE) in the 3' untranslated region of unstable mRNAs mediate their rapid degradation. ARE binding proteins (AUBPs) have been described that either stabilize or otherwise degrade ARE-mRNAs by recruiting the exosome, a complex of 3'-to-5' exoribonucleases. We have identified RHAU, a putative DExH RNA helicase that was isolated in association with the ARE of urokinase plasminogen activator mRNA (ARE(uPA)). RHAU physically interacts with the deadenylase PARN and the human exosome and enhances the deadenylation and decay of ARE(uPA)-mRNAs. An alternatively spliced isoform of RHAU that localized to the cytoplasm had a more pronounced effect on ARE(uPA)-mRNA destabilization than full-length RHAU. Furthermore, the ATPase activity of RHAU is essential for its mRNA-destabilizing function. ARE(uPA)-mRNA recognition by RHAU may be mediated through its RNA-dependent interaction with the AUBPs HuR and NFAR1. A model is presented to describe the action of RHAU in ARE(uPA)-directed mRNA turnover.     

Posttranscriptional regulation of cyclin D1 by ARE-binding proteins AUF1 and HuR in cycling myoblasts

RNA binding proteins (RBPs) can regulate the stability and/or translatability of messengerRNAs (mRNAs) through interactions with their 3′-untranslated regions. However, individual mRNAs may be regulated simultaneously or successively by more than one RBP, as well as by Argonaute (AGO)-bound miRNAs; the coordination of these various influences on an individual mRNA is therefore complex and not well studied. In this report we examine the roles of two RBPs that bind to AU-rich elements (ARE) – AUF1 and HuR – in the stability and translation of cyclin D1 (Ccnd1) mRNA in rat myoblasts transiting the G phase of the cell cycle, and their interactions with miRNAs. Knockdown (KD) of AUF1 resulted in (1) transient upregulation of the mRNA level as well as an advancement of translation onset time (TOT) from 6 to 5 h post-serum addition, (2) loss of miRNA loading on AGO1 and AGO2 and (3) reduction in the level of AGO-1 and AGO-2 bound mRNA. In contrast, KD of HuR had no effect on the mRNA level, or on the AGO–mRNA complexes, but delayed TOT by 1 h independent of miRNA let-7. Thus the dynamics of RBP–mRNA binding and –RBP–AGO–miRNA interactions are coordinated to fine tune the expression of Ccnd1 in the G1 phase.     

RNA-binding protein HuR autoregulates its expression by promoting alternative polyadenylation site usage

RNA-binding protein HuR modulates the stability and translational efficiency of messenger RNAs (mRNAs) encoding essential components of the cellular proliferation, growth and survival pathways. Consistent with these functions, HuR levels are often elevated in cancer cells and reduced in senescent and quiescent cells. However, the molecular mechanisms that control HuR expression are poorly understood. Here we show that HuR protein autoregulates its abundance through a negative feedback loop that involves interaction of the nuclear HuR protein with a GU-rich element (GRE) overlapping with the HuR major polyadenylation signal (PAS2). An increase in the cellular HuR protein levels stimulates the expression of long HuR mRNA species containing an AU-rich element (ARE) that destabilizes the mRNAs and thus reduces the protein production output. The PAS2 read-through occurs due to a reduced recruitment of the CstF-64 subunit of the pre-mRNA cleavage stimulation factor in the presence of the GRE-bound HuR. We propose that this mechanism maintains HuR homeostasis in proliferating cells. Since only the nuclear HuR is expected to contribute to the auto-regulation, our model may explain the longstanding observation that the increase in the total HuR expression in cancer cells often correlates with the accumulation of its substantial fraction in the cytoplasm.     

Highly selective actions of HuR in antagonizing AU-rich element-mediated mRNA destabilization

Human RNA-binding protein HuR, a nucleocytoplasmic shuttling protein, is a ubiquitously expressed member of the family of Hu proteins, which consist of two N-terminal RNA recognition motifs (RRM1 and RRM2), a hinge region, and a C-terminal RRM (RRM3). Although in vitro experiments showed indiscriminate binding of Hu proteins synthesized in bacterial systems to many different AU-rich elements (AREs), in vivo studies have pointed to a cytoplasmic role for HuR protein in antagonizing the rapid decay of some specific ARE-containing mRNAs, depending on physiological situations. By ectopically overexpressing HuR and its mutant derivatives in NIH 3T3 cells to mimic HuR upregulation of specific ARE-containing mRNAs in other systems, we have examined the in vivo ARE-binding specificity of HuR and dissected its functionally critical domains. We show that in NIH 3T3 cells, HuR stabilizes reporter messages containing only the c-fos ARE and not other AREs. Two distinct binding sites were identified within the c-fos ARE, the 5' AUUUA-containing domain and the 3' U-stretch-containing domain. These actions of HuR are markedly different from those of another ARE-binding protein, hnRNP D (also termed AUF1), which in vivo recognizes AUUUA repeats found in cytokine AREs and can exert both stabilizing and destabilizing effects. Further experiments showed that any combination of two of the three RRM domains of HuR is sufficient for strong binding to the c-fos ARE in vitro and to exert an RNA stabilization effect in vivo comparable to that of intact HuR and that the hinge region containing nucleocytoplasmic shuttling signals is dispensable for the stabilization effect of HuR. Our data suggest that the ARE-binding specificity of HuR in vivo is modulated to interact only with and thus regulate specific AREs in a cell type- and physiological state-dependent manner.     

AUF1 Is a bcl-2 A + U-rich element-binding protein involved in bcl-2 mRNA destabilization during apoptosis

We previously identified a conserved A + U-rich element (ARE) in the 3'-untranslated region of bcl-2 mRNA. We have also recently demonstrated that the bcl-2 ARE interacts with a number of ARE-binding proteins (AUBPs) whose pattern changes during apoptosis in association with bcl-2 mRNA half-life reduction. Here we show that the AUBP AUF1 binds in vitro to bcl-2 mRNA. The results obtained in a yeast RNA three-hybrid system have demonstrated that the 1-257-amino acid portion of p37 AUF1 (conserved in all isoforms), containing the two RNA recognition motifs, also binds to the bcl-2 ARE in vivo. UVC irradiation-induced apoptosis results in an increase of AUF1. Inhibition of apoptosis by a general caspase inhibitor reduces this increase by 2-3-fold. These results indicate involvement of AUF1 in the ARE/AUBP-mediated modulation of bcl-2 mRNA decay during apoptosis.