Entropy and Mg2+ control ligand affinity and specificity in the malachite green binding RNA aptamer

The binding of small molecule targets by RNA aptamers provides an excellent model to study the versatility of RNA function. The malachite green aptamer binds and recognizes its ligand via stacking and electrostatic interactions. The binding of the aptamer to its original selection target and three related molecules was determined by isothermal titration calorimetry, equilibrium dialysis, and fluorescence titration. The results reveal that the entropy of complex formation plays a large role in determining binding affinity and ligand specificity. These data combined with previous structural studies show that metal ions are required to stabilize the complexes with non-native ligands whereas the complex with the original selection target is stable at low salt and in the absence of divalent metal ions.     

Thermodynamics of ligand binding to a heterogeneous RNA population in the malachite green aptamer

The malachite green aptamer binds two closely related ligands, malachite green (MG) and tetramethylrosamine (TMR), with nearly equal affinity. The MG ligand consists of three phenyl rings emanating from a central carbon, while TMR has two of the three rings connected by an ether linkage. The binding pockets for MG and TMR in the aptamer, known from high-resolution structures, differ only in the conformation of a few nucleotides. Herein, we applied isothermal titration calorimetry (ITC) to compare the thermodynamics of binding of MG and TMR to the aptamer. Binding heat capacities were obtained from ITC titrations over the temperature range of 15-60 °C. Two temperature regimes were found for MG binding: one from 15 to 45 °C where MG bound with a large negative heat capacity and an apparent stoichiometry (n) of ~0.4 and another from 50 to 60 °C where MG bound with a positive heat capacity and an n of ~1.1. The binding of TMR, on the other hand, revealed only one temperature regime for binding, with a more modest negative heat capacity and an n of ~1.2. The large difference in heat capacity between the two ligands suggests that significantly more conformational rearrangement occurs upon the binding of MG than that of TMR, which is consistent with differences in solvent accessible surface area calculated for available ligand-bound structures. Lastly, we note that the binding stoichiometry of MG was improved not only by an increase in the temperature but also by a decrease in the concentration of Mg(2+) or an increase in the time between ITC injections. These studies suggest that binding of a dynamical ligand to a functional RNA requires the RNA itself to have significant dynamics.     

2.8 A crystal structure of the malachite green aptamer

Previous in vitro selection experiments identified an RNA aptamer that recognizes the chromophore malachite green (MG) with a high level of affinity, and which undergoes site-specific cleavage following laser irradiation. To understand the mechanism by which this RNA folds to recognize specifically its ligand and the structural basis for chromophore-assisted laser inactivation, we have determined the 2.8 A crystal structure of the aptamer bound to tetramethylrosamine (TMR), a high-affinity MG analog. The ligand-binding site is defined by an asymmetric internal loop, flanked by a pair of helices. A U-turn and several non-canonical base interactions stabilize the folding of loop nucleotides around the TMR. The aptamer utilizes several tiers of stacked nucleotides arranged in pairs, triples, and a novel base quadruple to effectively encapsulate the ligand. Even in the absence of specific stabilizing hydrogen bonds, discrimination between related fluorophores and chromophores is possible due to tight packing in the RNA binding pocket, which severely limits the size and shape of recognized ligands. The site of laser-induced cleavage lies relatively far from the bound TMR ( approximately 15 A). The unusual backbone conformation of the cleavage site nucleotide and its high level of solvent accessibility may combine to allow preferential reaction with freely diffusing hydroxyl radicals generated at the bound ligand. Several observations, however, favor alternative mechanisms for cleavage, such as conformational changes in the aptamer or long-range electron transfer between the bound ligand and the cleavage site nucleotide.     

Riboswitch Detection Using Profile Hidden Markov Models

Background  

Riboswitches are a type of noncoding RNA that regulate gene expression by switching from one structural conformation to another on ligand binding. The various classes of riboswitches discovered so far are differentiated by the ligand, which on binding induces a conformational switch. Every class of riboswitch is characterized by an aptamer domain, which provides the site for ligand binding, and an expression platform that undergoes conformational change on ligand binding. The sequence and structure of the aptamer domain is highly conserved in riboswitches belonging to the same class. We propose a method for fast and accurate identification of riboswitches using profile Hidden Markov Models (pHMM). Our method exploits the high degree of sequence conservation that characterizes the aptamer domain.     

孔雀石绿适配体生物传感器的研究进展

荧光适配体作为一种无需标记的荧光探针,具有许多潜在的优势,并被应用于多种靶物质(如ATP、RNA)的检测,是目前适配体研究领域的热点。孔雀石绿适配体(malachite green aptamer,MGA)属于荧光适配体,其能通过配体诱导折叠形成结合口袋,进而促进孔雀石绿(malachite green,MG)的发光。目前,已经筛选得到的MGA的种类较少,主要介绍了已知的MG RNA适配体及其变构体和MG DNA适配体的特性,以及影响MG-MGA复合物荧光强度的因素。同时,还对主要的MG衍生物和共聚物进行了总结。最后,综述了MGA在生物传感、荧光成像等方面的应用,并对MGA的发展方向进行了展望,以期为MGA在生物检测、生物成像等方面的应用提供指导。     

Translational control of beta2-adrenergic receptor mRNA by T-cell-restricted intracellular antigen-related protein

Cellular expression of the beta(2)-adrenergic receptor (beta(2)-AR) is suppressed at the translational level by 3'-untranslated region (UTR) sequences. To test the possible role of 3'-UTR-binding proteins in translational suppression of beta(2)-AR mRNA, we expressed the full-length 3'-UTR or the adenylate/uridylate-rich (A+U-rich element (ARE)) RNA from the 3'-UTR sequences of beta(2)-AR in cell lines that endogenously express this receptor. Reversal of beta(2)-adrenergic receptor translational repression by retroviral expression of 3'-UTR sequences suggested that ARE RNA-binding proteins are involved in translational suppression of beta(2)-adrenergic receptor expression. Using a 20-nucleotide ARE RNA from the receptor 3'-UTR as an affinity ligand, we purified the proteins that bind to these sequences. T-cell-restricted intracellular antigen-related protein (TIAR) was one of the strongly bound proteins identified by this method. UV-catalyzed cross-linking experiments using in vitro transcribed 3'-UTR RNA and glutathione S-transferase-TIAR demonstrated multiple binding sites for this protein on beta(2)-AR 3'-UTR sequences. The distal 340-nucleotide region of the 3'-UTR was identified as a target RNA motif for TIAR binding by both RNA gel shift analysis and immunoprecipitation experiments. Overexpression of TIAR resulted in suppression of receptor protein synthesis and a significant shift in endogenously expressed beta(2)-AR mRNA toward low molecular weight fractions in sucrose gradient polysome fractionation. Taken together, our results provide the first evidence for translational control of beta(2)-AR mRNA by TIAR.     

RNase MRP cleaves the CLB2 mRNA to promote cell cycle progression: novel method of mRNA degradation

RNase mitochondrial RNA processing (RNase MRP) mutants have been shown to have an exit-from-mitosis defect that is caused by an increase in CLB2 mRNA levels, leading to increased Clb2p (B-cyclin) levels and a resulting late anaphase delay. Here we describe the molecular defect behind this delay. CLB2 mRNA normally disappears rapidly as cells complete mitosis, but the level remains high in RNase MRP mutants. This is in direct contrast to other exit-from-mitosis mutants and is the result of an increase in CLB2 mRNA stability. We found that highly purified RNase MRP cleaved the 5' untranslated region (UTR) of the CLB2 mRNA in several places in an in vitro assay. In vivo, we identified RNase MRP-dependent cleavage products on the CLB2 mRNA that closely matched in vitro products. Disposal of these products was dependent on the 5'-->3' exoribonuclease Xrn1 and not the exosome. Our results demonstrate that the endoribonuclease RNase MRP specifically cleaves the CLB2 mRNA in its 5'-UTR to allow rapid 5' to 3' degradation by the Xrn1 nuclease. Degradation of the CLB2 mRNA by the RNase MRP endonuclease provides a novel way to regulate the cell cycle that complements the protein degradation machinery. In addition, these results denote a new mechanism of mRNA degradation not seen before in the yeast Saccharomyces cerevisiae.     

Ligand-induced conformational capture of a synthetic tetracycline riboswitch revealed by pulse EPR

RNA aptamers are in vitro-selected binding domains that recognize their respective ligand with high affinity and specificity. They are characterized by complex three-dimensional conformations providing preformed binding pockets that undergo conformational changes upon ligand binding. Small molecule-binding aptamers have been exploited as synthetic riboswitches for conditional gene expression in various organisms. In the present study, double electron-electron resonance (DEER) spectroscopy combined with site-directed spin labeling was used to elucidate the conformational transition of a tetracycline aptamer upon ligand binding. Different sites were selected for post-synthetic introduction of either the (1-oxyl-2,2,5,5-tetramethylpyrroline-3-methyl) methanethiosulfonate by reaction with a 4-thiouridine modified RNA or of 4-isocyanato-2,6-tetramethylpiperidyl-N-oxid spin label by reaction with 2'-aminouridine modified RNA. The results of the DEER experiments indicate the presence of a thermodynamic equilibrium between two aptamer conformations in the free state and capture of one conformation upon tetracycline binding.     

miR-122 activates hepatitis C virus translation by a specialized mechanism requiring particular RNA components

In animals, microRNAs (miRNAs) generally repress gene expression by binding to sites in the 3'-untranslated region (UTR) of target mRNAs. miRNAs have also been reported to repress or activate gene expression by binding to 5'-UTR sites, but the extent of such regulation and the factors that govern these different responses are unknown. Liver-specific miR-122 binds to sites in the 5'-UTR of hepatitis C virus (HCV) RNA and positively regulates the viral life cycle, in part by stimulating HCV translation. Here, we characterize the features that allow miR-122 to activate translation via the HCV 5'-UTR. We find that this regulation is a highly specialized process that requires uncapped RNA, the HCV internal ribosome entry site (IRES) and the 3' region of miR-122. Translation activation does not involve a previously proposed structural transition in the HCV IRES and is mediated by Argonaute proteins. This study provides an important insight into the requirements for the miR-122-HCV interaction, and the broader consequences of miRNAs binding to 5'-UTR sites.