Identification of HuR as a protein implicated in AUUUA-mediated mRNA decay.

Expression of many proto-oncogenes, cytokines and lymphokines is regulated by targeting their messenger RNAs for rapid degradation. Essential signals for this control are AU-rich elements (AREs) in the 3' untranslated region (UTR) of these messages. The ARE is loosely defined as the five-nucleotide sequence AUUUA embedded in a uracil-rich region. A transacting factor, presumably a protein, binds the ARE and initiates recognition by the destabilization machinery. Numerous candidate ARE-binding proteins have been proposed. We show that a 32 kDa protein in HeLa nuclear extracts characterized previously has RNA-binding specificity that correlates with the activity of an ARE in directing mRNA decay. Purification and subsequent analyses demonstrate that this 32 kDa protein is identical to a recently identified member of the Elav-like gene family (ELG) called HuR. The in vitro binding selectivity of HuR is indicative of an ARE sequence's ability to destabilize a mRNA in vivo, suggesting a critical role for HuR in the regulation of mRNA degradation.     

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.     

HuR protein attenuates miRNA-mediated repression by promoting miRISC dissociation from the target RNA

The microRNA (miRNA)-mediated repression of protein synthesis in mammalian cells is a reversible process. Target mRNAs with regulatory AU-rich elements (AREs) in their 3'-untranslated regions (3'-UTR) can be relieved of miRNA repression under cellular stress in a process involving the embryonic lethal and altered vision family ARE-binding protein HuR. The HuR-mediated derepression occurred even when AREs were positioned at a considerable distance from the miRNA sites raising questions about the mechanism of HuR action. Here, we show that the relief of miRNA-mediated repression involving HuR can be recapitulated in different in vitro systems in the absence of stress, indicating that HuR alone is sufficient to relieve the miRNA repression upon binding to RNA ARE. Using in vitro assays with purified miRISC and recombinant HuR and its mutants, we show that HuR, likely by its property to oligomerize along RNA, leads to the dissociation of miRISC from target RNA even when miRISC and HuR binding sites are positioned at a distance. Further, we demonstrate that HuR association with AREs can also inhibit miRNA-mediated deadenylation of mRNA in the Krebs-2 ascites extract, in a manner likewise depending on the potential of HuR to oligomerize.     

Specific protein domains mediate cooperative assembly of HuR oligomers on AU-rich mRNA-destabilizing sequences

The RNA-binding factor HuR is a ubiquitously expressed member of the Hu protein family that binds and stabilizes mRNAs containing AU-rich elements (AREs). Hu proteins share a common domain organization of two tandemly arrayed RNA recognition motifs (RRMs) near the N terminus, followed by a basic hinge domain and a third RRM near the C terminus. In this study, we engineered recombinant wild-type and mutant HuR proteins lacking affinity tags to characterize their ARE-binding properties. Using combinations of electrophoretic mobility shift and fluorescence anisotropy-based binding assays, we show that HuR can bind ARE substrates as small as 13 nucleotides with low nanomolar affinity, but forms cooperative oligomeric protein complexes on ARE substrates of at least 18 nucleotides in length. Analyses of deletion mutant proteins indicated that RRM3 does not contribute to high affinity recognition of ARE substrates, but is required for cooperative assembly of HuR oligomers on RNA. Finally, the hinge domain between RRM2 and RRM3 contributes significant binding energy to HuR.ARE complex formation in an ARE length-dependent manner. The hinge does not enhance RNA-binding activity by increased ion pair formation despite extensive positive charge within this region, and it does not thermodynamically stabilize protein folding. Together, the results define distinct roles for the HuR hinge and RRM3 domains in formation of cooperative HuR.ARE complexes in solution.     

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.     

The association of Alu repeats with the generation of potential AU-rich elements (ARE) at 3' untranslated regions.

Background  

A significant portion (about 8% in the human genome) of mammalian mRNA sequences contains AU (Adenine and Uracil) rich elements or AREs at their 3' untranslated regions (UTR). These mRNA sequences are usually stable. However, an increasing number of observations have been made of unstable species, possibly depending on certain elements such as Alu repeats. ARE motifs are repeats of the tetramer AUUU and a monomer A at the end of the repeats ((AUUU)_nA). The importance of AREs in biology is that they make certain mRNA unstable. Proto-oncogene, such as c-fos, c-myc, and c-jun in humans, are associated with AREs. Although it has been known that the increased number of ARE motifs caused the decrease of the half-life of mRNA containing ARE repeats, the exact mechanism is as of yet unknown. We analyzed the occurrences of AREs and Alu and propose a possible mechanism for how human mRNA could acquire and keep AREs at its 3' UTR originating from Alu repeats.     

Distinct domains of AU-rich elements exert different functions in mRNA destabilization and stabilization by p38 mitogen-activated protein kinase or HuR

AU-rich elements (AREs) control the expression of numerous genes by accelerating the decay of their mRNAs. Rapid decay and deadenylation of beta-globin mRNA containing AU-rich 3' untranslated regions of the chemoattractant cytokine interleukin-8 (IL-8) are strongly attenuated by activating the p38 mitogen-activated protein (MAP) kinase/MAP kinase-activated protein kinase 2 (MK2) pathway. Further evidence for a crucial role of the poly(A) tail is provided by the loss of destabilization and kinase-induced stabilization in ARE RNAs expressed as nonadenylated forms by introducing a histone stem-loop sequence. The minimal regulatory element in the IL-8 mRNA is located in a 60-nucleotide evolutionarily conserved sequence with a structurally and functionally bipartite character: a core domain with four AUUUA motifs and limited destabilizing function on its own and an auxiliary domain that markedly enhances destabilization exerted by the core domain and thus is essential for the rapid removal of RNA targets. A similar bipartite structure and function are observed for the granulocyte-macrophage colony-stimulating factor (GM-CSF) ARE. Stabilization in response to p38/MK2 activation is seen with the core domain alone and also after mutation of the AUUUA motifs in the complete IL-8 ARE. Stabilization by ARE binding protein HuR requires different sequence elements. Binding but no stabilization is observed with the IL-8 ARE. Responsiveness to HuR is gained by exchanging the auxiliary domain of the IL-8 ARE with that of GM-CSF or with a domain of the c-fos ARE, which results in even stronger responsiveness. These results show that distinct ARE domains differ in function with regard to destabilization, stabilization by p38/MK2 activation, and stabilization by HuR.