RNA binding site of R17 coat protein

The specific interaction between R17 coat protein and its target of translational repression at the initiation site of the R17 replicase gene was studied by synthesizing variants of the RNA binding site and measuring their affinity to the coat protein by using a nitrocellulose filter binding assay. Substitution of two of the seven single-stranded residues by other nucleotides greatly reduced the Ka, indicating that they are essential for the RNA-protein interaction. In contrast, three other single-stranded residues can be substituted without altering the Ka. When several of the base-paired residues in the binding site are altered in such a way that pairing is maintained, little change in Ka is observed. However, when the base pairs are disrupted, coat protein does not bind. These data suggest that while the hairpin loop structure is essential for protein binding, the base-paired residues do not contact the protein directly. On the basis of these and previous data, a model for the structural requirements of the R17 coat protein binding site is proposed. The model was successfully tested by demonstrating that oligomers with sequences quite different from the replicase initiator were able to bind coat protein.     

Purification of RNA and RNA-protein complexes by an R17 coat protein affinity method.

We describe an affinity chromatography method to isolate specific RNAs and RNA-protein complexes formed in vivo or in vitro. It exploits the highly selective binding of the coat protein of bacteriophage R17 to a short hairpin in its genomic RNA. RNA containing that hairpin binds to coat protein that has been covalently bound to a solid support. Bound RNA-protein complexes can be eluted with excess R17 recognition sites. Using purified RNA, we demonstrate that binding to immobilized coat protein is highly specific and enables one to separate an RNA of interest from a large excess of other RNAs in a single step. Surprisingly, binding of an RNA containing non-R17 sequences to the support requires two recognition sites in tandem; a single site is insufficient. We determine optimal conditions for purification of specific RNAs by comparing specific binding (retention of RNAs with recognition sites) to non-specific binding (retention of RNAs without recognition sites) over a range of experimental conditions. These results suggest that binding of immobilized coat protein to RNAs containing two sites is cooperative. We illustrate the potential utility of the approach in purifying RNA-protein complexes by demonstrating that a U1 snRNP formed in vivo on an RNA containing tandem recognition sites is selectively retained by the coat protein support.     

RNA binding properties of the coat protein from bacteriophage GA.

The coat protein of bacteriophage GA, a group II RNA phage, binds to a small RNA hairpin corresponding to its replicase operator. Binding is specific, with a Ka of 71 microM -1. This interaction differs kinetically from the analogous coat protein-RNA hairpin interactions of other RNA phage and also deviates somewhat in its pH and salt dependence. Despite 46 of 129 amino acid differences between the GA and group I phage R17 coat proteins, the binding sites are fairly similar. The essential features of the GA coat protein binding site are a based-paired stem with an unpaired purine and a four nucleotide loop having an A at position -4 and a purine at -7. Unlike the group I phage proteins, the GA coat protein does not distinguish between two alternate positions for the unpaired purine and does not show high specificity for a pyrimidine at position -5 of the loop.     

Elucidation of the RNA target of linezolid by using a linezolid-neomycin B heteroconjugate and genomic SELEX

A covalently modified heteroconjugate between linezolid and neomycin B leads to an enhanced and more specific binding affinity to hairpin RNA targets in comparison to neomycin B itself. This heteroconjugate was used as a lure to select linezolid-specific hairpin RNA from an Escherichia coli genome RNA. The selected RNA obtained after eight cycles not only has typical stem–loop structures but also includes known sequences of the linezolid binding site. The results of RNA footprinting show that the binding site of the heteroconjugate encompasses both stem and loop regions, suggesting that the possible binding site for linezolid is in the terminal loop. In addition, findings from application of a surface plasmon resonance assay clearly demonstrate that linezolid binds to selected hairpin RNA in a highly specific manner with a low millimolar affinity. The results suggest that heteroconjugates might represent a generally useful approach in studies aimed at uncovering loop-specific RNA binding ligands that would be otherwise difficult to identify owing to their weak affinities.     

Nucleoside and nucleotide inactivation of R17 coat protein: evidence for a transient covalent RNA-protein bond

R17 coat protein forms a specific complex with a 21-nucleotide RNA hairpin containing the initiation site for the phage replicase gene. The RNA binding activity of the protein is inhibited by prior incubation with 5-bromouridine (BrU). The inactivation occurs with pseudo-first-order kinetics, and the inactive protein is stable to dilution. RNA binding activity of the BrU-inactivated protein is restored upon incubation with dithiothreitol. Inactivation of coat protein by N-ethylmaleimide or p-(chloromercuri)-benzenesulfonate indicates that a cysteine residue is located near the RNA binding site. Since 5-bromodeoxyuridine does not inactivate coat protein, a specific binding event appears to be required before inactivation can occur. Surprisingly, unmodified cytidine nucleotides also inactivate coat protein, with a specificity similar to the modified analogues. These results are discussed with regard to the formation of a transient covalent RNA-protein bond.     

RNA binding specificity of Drosophila muscleblind

Members of the muscleblind family of RNA binding proteins found in Drosophila and mammals are key players in both the human disease myotonic dystrophy and the regulation of alternative splicing. Recently, the mammalian muscleblind-like protein, MBNL1, has been shown to have interesting RNA binding properties with both endogenous and disease-related RNA targets. Here we report the characterization of RNA binding properties of the Drosophila muscleblind protein Mbl. Mutagenesis of double-stranded CUG repeats demonstrated that Mbl requires pyrimidine-pyrimidine mismatches for binding and that the identity and location of the C-G and G-C base pairs within the repeats are essential for Mbl binding. Systematic evolution of ligands by exponential enrichment (SELEX) was used to identify RNA sequences that bind Mbl with much higher affinity than CUG repeats. The RNA sequences identified by SELEX are structured and contain a five-nucleotide consensus sequence of 5'-AGUCU-3'. RNase footprinting of one of the SELEX RNA sequences with Mbl showed that Mbl binds both double-stranded and single-stranded regions of the RNA. Three guanosines show the strongest footprint in the presence of Mbl; mutation of any of these three guanosines eliminates Mbl binding. It was also found that Mbl specifically bound a human MBNL1 RNA target, demonstrating the conservation of the muscleblind proteins in recognizing RNA targets. Our results reveal that Mbl recognizes complex RNA secondary structures.     

Sequence-specific interaction of R17 coat protein with its ribonucleic acid binding site

The interaction between phage R17 coat protein and its RNA binding site for translational repression was studied as an example of a sequence-specific RNA--protein interaction. Nuclease protection and selection experiments define the binding site to about 20 contiguous nucleotides which form a hairpin. A nitrocellulose filter retention assay is used to show that the binding between the coat protein and a synthetic 21-nucleotide RNA fragment conforms to a simple bimolecular reaction. Unit stoichiometry and a Kd of about 1 nM are obtained at 2 degrees C in buffer containing 0.19 M salt. The interaction is highly sequence specific since a variety of RNAs failed to compete with the 21-nucleotide fragment for coat protein binding.     

Specific RNA binding by Q beta coat protein

The interaction between the bacteriophage Q beta coat protein and its specific binding site on Q beta genomic RNA was characterized by using a nitrocellulose filter binding assay. Q beta coat protein bound to a synthetic 29-nucleotide RNA hairpin with an association constant of 400 microM-1 at 4 degrees C, 0.2 M ionic strength, pH 6.0. Complex formation had a broad pH optimum centered around pH 6.0 and was favored by both enthalpy and entropy. The salt dependence of Ka revealed that four to five ion pairs may be formed in the complex although approximately 80% of the free energy of complex formation is contributed by nonelectrostatic interactions. Truncation experiments revealed that coat protein binding required only the presence of a hairpin with an eight base pair stem and a three-base loop. Analysis of the binding properties of hairpin variants showed that the sequence of the stem was not important for coat protein recognition and only one of the three loop residues was essential. A bulged adenosine present in the coat protein binding site was not required for coat protein binding. Q beta coat protein binding specific is therefore primarily achieved by the structure and not by the sequence of the operator.     

一种结合SELEX与二代测序技术筛选RNA结合蛋白特异识别序列新方法的建立

RNA结合蛋白通过特异识别RNA底物发挥重要的生物学作用。指数富集的配体系统进化(Systematic evolution of ligands by exponential enrichment,SELEX)技术是一种体外筛选核酸底物的基本方法,SELEX技术通过重复多轮筛选从随机核酸序列库中筛选出特异性与靶物质高度亲和的核酸底物,本研究将利用该技术与二代高通量测序(NGS)相结合,体外合成含有20个随机碱基的RNA文库,将所要研究的蛋白构建到带有可被链亲和酶素磁珠捕获的SBP标记的载体上去,显著提高筛选效率,仅需1轮筛选即可获得所需RNA底物motif。通过该方法获得了人的hn RNP A1的UP1结构域特异识别AGG和AG二种RNA序列,并通过EMSA实验证实其可以与获得的RNA motif结合。这一方法的建立对于研究RNA结合蛋白识别底物的序列特异性,并进一步了解其在生物体内的调控机制有重要意义。     

In vitro selection of packaging sites in a double-stranded RNA virus.

The Saccharomyces cerevisiae double-stranded RNA virus ScVL1 recognizes a small sequence in the viral plus strand for both packaging and replication. Viral particles will bind to this viral binding sequence (VBS) with high affinity in vitro. An in vitro selection procedure has been used to optimize binding, and the sequences isolated have been analyzed for packaging and replication in vivo. The selected sequence consists of a stem with a bulged A residue topped by a loop of several bases. Four residues of the 18 bases are absolutely conserved for tight binding. These all fall in regions that appear to be single stranded. Eight more residues have preferred identities, and six of these are in the stem. The VBS is similar to the R17 bacteriophage coat protein binding site. Packaging and replication require tight binding to viral particles.     

A sol-gel-based microfluidics system enhances the efficiency of RNA aptamer selection

RNA and DNA aptamers that bind to target molecules with high specificity and affinity have been a focus of diagnostics and therapeutic research. These aptamers are obtained by SELEX often requiring many rounds of selection and amplification. Recently, we have shown the efficient binding and elution of RNA aptamers against target proteins using a microfluidic chip that incorporates 5 sol-gel binding droplets within which specific target proteins are imbedded. Here, we demonstrate that our microfluidic chip in a SELEX experiment greatly improved selection efficiency of RNA aptamers to TATA-binding protein, reducing the number of selection cycles needed to produce high affinity aptamers by about 80%. Many aptamers were identical or homologous to those isolated previously by conventional filter-binding SELEX. The microfluidic chip SELEX is readily scalable using a sol-gel microarray-based target multiplexing. Additionally, we show that sol-gel embedded protein arrays can be used as a high-throughput assay for quantifying binding affinities of aptamers.     

A comparison of two phage coat protein-RNA interactions.

The interaction between the coat protein of the group I bacteriophage fr with its translational operator site is compared with the previously studied R17 interaction. The sequence of the two RNA binding sites differ by 2 of 20 nucleotides and two coat proteins by 17 of 129 amino acids. An analysis of the binding of fr coat protein to 24 operator variants revealed that the two proteins recognize operator sequences in virtually the same way. However, fr coat protein binds to nearly every RNA 6 to 14-fold tighter than R17 coat protein. Since the fr operator is a weaker binding variant and the fr coat protein shows a different temperature dependence of binding, it is unlikely that the two systems have different Kas in vivo. RNA fragments containing the operator sequences can initiate the capsid assembly with both fr and R17 coat protein. Surprisingly, the two coat proteins can form a mixed capsid in vitro.     

Crystal Structure of the Bacteriophage Qβ Coat Protein in Complex with the RNA Operator of the Replicase Gene

The coat proteins of single-stranded RNA bacteriophages specifically recognize and bind to a hairpin structure in their genome at the beginning of the replicase gene. The interaction serves to repress the synthesis of the replicase enzyme late in infection and contributes to the specific encapsidation of phage RNA. While this mechanism is conserved throughout the Leviviridae family, the coat protein and operator sequences from different phages show remarkable variation, serving as prime examples for the co-evolution of protein and RNA structure. To better understand the protein–RNA interactions in this virus family, we have determined the three-dimensional structure of the coat protein from bacteriophage Qβ bound to its cognate translational operator. The RNA binding mode of Qβ coat protein shares several features with that of the widely studied phage MS2, but only one nucleotide base in the hairpin loop makes sequence-specific contacts with the protein. Unlike in other RNA phages, the Qβ coat protein does not utilize an adenine-recognition pocket for binding a bulged adenine base in the hairpin stem but instead uses a stacking interaction with a tyrosine side chain to accommodate the base. The extended loop between β strands E and F of Qβ coat protein makes contacts with the lower part of the RNA stem, explaining the greater length dependence of the RNA helix for optimal binding to the protein. Consequently, the complex structure allows the proposal of a mechanism by which the Qβ coat protein recognizes and discriminates in favor of its cognate RNA.     

In polycistronic Q�� RNA, single-strandedness at one ribosome binding site directly affects translational initiations at a distal upstream cistron

In Qβ RNA, sequestering the coat gene ribosome binding site in a putatively strong hairpin stem structure eliminated synthesis of coat protein and activated protein synthesis from the much weaker maturation gene initiation site, located 1300 nucleotides upstream. As the stability of a hairpin stem comprising the coat gene Shine–Dalgarno site was incrementally increased, there was a corresponding increase in translation of maturation protein. The effect of the downstream coat gene ribosome binding sequence on maturation gene expression appeared to have occurred only in cis and did not require an AUG start codon or initiation of coat protein synthesis. In all cases, no structural reorganization was predicted to occur within Qβ RNA. Our results suggest that protein synthesis from a relatively weak translational initiation site is greatly influenced by the presence or absence of a stronger ribosome binding site located elsewhere on the same RNA molecule. The data are consistent with a mechanism in which multiple ribosome binding sites compete in cis for translational initiations as a means of regulating protein synthesis on a polycistronic messenger RNA.     

RNA recognition site of PP7 coat protein

The coat proteins of different single-strand RNA phages use a common protein tertiary structural framework to recognize different RNA hairpins and thus offer a natural model for understanding the molecular basis of RNA-binding specificity. Here we describe the RNA structural requirements for binding to the coat protein of bacteriophage PP7, an RNA phage of Pseudomonas. Its recognition specificity differs substantially from those of the coat proteins of its previously characterized relatives such as the coliphages MS2 and Qbeta. Using designed variants of the wild-type RNA, and selection of binding-competent sequences from random RNA sequence libraries (i.e. SELEX) we find that tight binding to PP7 coat protein is favored by the existence of an 8 bp hairpin with a bulged purine on its 5' side separated by 4 bp from a 6 nt loop having the sequence Pu-U-A-G/U-G-Pu. However, another structural class possessing only some of these features is capable of binding almost as tightly.     

Enzymatic synthesis of a 21-nucleotide coat protein binding fragment of R17 ribonucleic acid

An oligoribonucleotide with a sequence identical with the bacteriophage R17 replicase initiator region has been synthesized. The sequence also encompasses the binding domain of R17 coat protein, which is known to act as a translational repressor at this site. The 21-nucleotide fragment was synthesized entirely by enzymatic methods, T4 RNA ligase being used to join shorter oligomers. The resulting fragment has a secondary structure with the expected thermal stability. Since the synthetic fragment binds R17 coat protein with the same affinity as a 59-nucleotide fragment isolated from R17 RNA, we conclude that it has full biological activity.     

Cooperative binding of R17 coat protein to RNA.

The binding of the R17 coat protein to synthetic RNAs containing one or two coat protein binding sites was characterized by using nitrocellulose filter and gel-retention assays. RNAs with two available sites bound coat protein in a cooperative manner, resulting in a higher affinity and reduced sensitivity to pH, ionic strength, and temperature when compared with RNAs containing only a single site. The cooperativity can contribute up to -5 kcal/mol to the overall binding affinity with the greatest cooperativity found at low pH, high ionic strength, and high temperatures. Similar solution properties for the encapsidation of the related fr and f2 phage suggest that the cooperativity is due to favorable interactions between the two coat proteins bound to the RNA. This system therefore resembles an intermediate state of phage assembly. No cooperative binding was observed for RNAs containing a single site and a 5' or 3' extension of nonspecific sequence, indicating that R17 coat protein has a very low nonspecific binding affinity. Unexpectedly weak binding was observed for several RNAs due to the presence of alternative conformational states of the RNA.