Use of three-hybrid system to detect RNA-binding activity of alfalfa mosaic virus coat protein

We used yeast three-hybrid system, for studying interaction of alfalfa mosaic virus coat protein AMVCP (AMVCP) with RNA4, which codes this protein. We have shown that AMVCP with high affinity is bound to plus-chain of RNA4 in vivo. The mutational analysis has shown, that the N-terminal part of AMVCP (aa 1 to 85) contains RNA-binding domain. C-terminal part of this protein (aa 86 to 221) does not participate in direct interaction with RNA4. However activity of the reporter-gene LacZ, which codes beta-galactosidase, in case of interaction only N-terminal part of AMVCP is five times lower, in comparison with full-length hybrid protein, that confirms that the tertiary structure of full-length AMVCP is more favourable for interaction with RNA4.     

A modified yeast three-hybrid system enabling both positive and negative selections

Objective

To increase the reporter repertoire of the yeast three-hybrid system and introduce the option of negative selection.

Results

Two new versions of the yeast three-hybrid system were made by modifying the MS2 coat RNA-binding protein and fusing it to the Gal4 DNA-binding protein. This allows the use of Gal4 inducible reporters to measure RNA–protein interactions. We introduced two mutations, V29I and N55K into the tandem MS2 dimer and an 11 amino acid deletion to increase RNA–protein affinity and inhibit capsid formation. Introduction of these constructs into the yeast strains MaV204K and PJ69-2A (which contain more reporters than the conventional yeast three-hybrid strains L40-coat and YBZ-1) allows RNA–protein binding interactions with a wide range of affinities to be detected using histidine auxotrophy, and negative selection with 5-fluoroorotic acid.

Conclusion

This yeast three-hybrid system has advantages over previous versions as demonstrated by the increased dynamic range of detectable binding interactions using yeast survival assays and colony forming assays with multiple reporters using known RNA–protein interactions.

     

Cooperative binding of the hnRNP K three KH domains to mRNA targets

The heterogeneous nuclear ribonucleoprotein (hnRNP) K homology (KH) domain is an evolutionarily conserved module that binds short ribonucleotide sequences. KH domains most often are present in multiple copies per protein. In vitro studies of hnRNP K and other KH domain bearing proteins have yielded conflicting results regarding the relative contribution of each KH domain to the binding of target RNAs. To assess this RNA-binding we used full-length hnRNP K, its fragments and the yeast ortholog as baits in the yeast three-hybrid system. The results demonstrate that in this heterologous in vivo system, the three KH domains bind RNA synergistically and that a single KH domain, in comparison, binds RNA weakly.     

The amino-terminal domain of yeast U1-70K is necessary and sufficient for function.

The Saccharomyces cerevisiae SNP1 gene encodes a protein that shares 30% amino acid identity with the mammalian U1 small nuclear ribonucleoprotein particle protein 70K (U1-70K). We have demonstrated that yeast strains in which the SNP1 gene was disrupted are viable but exhibit greatly increased doubling times and severe temperature sensitivity. Furthermore, snp1-null strains are defective in pre-mRNA splicing. We have tested deletion alleles of SNP1 for their ability to complement these phenotypes. We found that the highly conserved RNA recognition motif consensus domain of Snp1 is not required for complementation of the snp1-null growth or splicing defects nor for the in vivo association with the U1 small nuclear ribonucleoprotein particle. However, the amino-terminal domain of Snp1, less strongly conserved, is necessary and sufficient for complementation.     

StreptoTag: a novel method for the isolation of RNA-binding proteins

We describe a fast and simple one-step affinity-purification method for the isolation of specific RNA-binding proteins. An in vitro-transcribed hybrid RNA consisting of an aptamer sequence with high binding specificity to the antibiotic streptomycin and a putative protein-binding RNA sequence is incubated with crude extract. After complex formation, the sample is applied to an affinity column containing streptomycin immobilized to Sepharose. The binding of the in vitro-assembled RNA-protein complex to streptomycin-Sepharose is mediated by the aptamer RNA and the specifically bound proteins are recovered from the affinity matrix by elution with the antibiotic. Employing two well-characterized RNA-protein interactions, we tested the performance of this new method. The spliceosomal U1A protein and the bacteriophage MS2 coat protein could be isolated via their appropriate RNA motif containing hybrid RNA from crude yeast extracts in high yield and purity after only one round of affinity purification. As the purification principle is independent of the extract source, this new affinity chromatography strategy that makes use of an in vitro-selected antibiotic-binding RNA as a tag, "StreptoTag," should be applicable to extracts from other organisms as well. Therefore, we propose StreptoTag to be a versatile tool for the isolation of unknown RNA-binding proteins.     

The p80 homology region of TEP1 is sufficient for its association with the telomerase and vault RNAs, and the vault particle

TEP1 is a protein component of two ribonucleoprotein complexes: vaults and telomerase. The vault-associated small RNA, termed vault RNA (VR), is dependent upon TEP1 for its stable association with vaults, while the association of telomerase RNA with the telomerase complex is independent of TEP1. Both of these small RNAs have been shown to interact with amino acids 1–871 of TEP1 in an indirect yeast three-hybrid assay. To understand the determinants of TEP1–RNA binding, we generated a series of TEP1 deletions and show by yeast three-hybrid assay that the entire Tetrahymena p80 homology region of TEP1 is required for its interaction with both telomerase and VRs. This region is also sufficient to target the protein to the vault particle. Electrophoretic mobility shift assays using the recombinant TEP1 RNA-binding domain (TEP1–RBD) demonstrate that it binds RNA directly, and that telomerase and VRs compete for binding. VR binds weakly to TEP1–RBD in vitro, but mutation of VR sequences predicted to disrupt helices near its central loop enhances binding. Antisense oligonucleotide-directed RNase H digestion of endogenous VR indicates that this region is largely single stranded, suggesting that TEP1 may require access to the VR central loop for efficient binding.     

A genomic integration method to visualize localization of endogenous mRNAs in living yeast

mRNA localization may be an important determinant for protein localization. We describe a simple PCR-based genomic-tagging strategy (m-TAG) that uses homologous recombination to insert binding sites for the RNA-binding MS2 coat protein (MS2-CP) between the coding region and 3' untranslated region (UTR) of any yeast gene. Upon coexpression of MS2-CP fused with GFP, we demonstrate the localization of endogenous mRNAs (ASH1, SRO7, PEX3 and OXA1) in living yeast (Saccharomyces cerevisiae).     

Down modulation of HIV-1 gene expression using a procaryotic RNA-binding protein.

The coat protein of the single stranded RNA bacteriophages acts as a translational repressor by binding with high affinity to a target RNA that encompasses the ribosomal binding site of the replicase gene. We have expressed this procaryotic RNA-binding protein in mammalian cells. Using the coat protein binding site attached to the HIV-1 5' leader RNA, we tested for the biological effect of co-expressed bacteriophage protein. We found that HIV-1 LTR-directed expression within this context was inhibited in trans by the coat protein. This example suggests the feasibility of using procaryotic RNA-binding proteins as genetic modulators in eucaryotic cells.     

IQCE mRNA与FXR1P在酵母三杂交体系中的相互作用

脆性X相关基因1编码蛋白FXR1P是一种RNA结合蛋白,其所结合的靶RNA目前所知甚少。本研究应用酵母三杂交技术对本课题组从pRH3-cDNA人脑海马RNA表达文库中筛选到的一种可能与FXR1P存在相互作用的RNA IQCE进行研究,以验证该RNA与FXR1P的相互作用。方法为:提取利用酵母三杂交技术初步筛选得到的酵母阳性克隆的质粒,转化大肠杆菌Top10,利用其质粒不相容性分离插入了目的片段的pRH3′-cDNA质粒,将该质粒转化入含目的基因FXR1的酵母菌株L40-ura3/pHyb lex/Zeo-MS2/pYESTrp3/FXR1,进行一对一的酵母三杂交验证,最后将该片段进行测序。测序结果为IQCE的一段编码序列,而目前尚无研究报导FXR1与IQCE的相互关系。结论:提示FXR1P与IQCE mRNA存在相互作用,IQCE可能是FXR1P发育调控网络组成成员之一。     

Combining SELEX and the yeast three-hybrid system for in vivo selection and classification of RNA aptamers

Aptamers are small nucleic acid ligands that bind to their targets with specificity and high affinity. They are generated by a combinatorial technology, known as SELEX. This in vitro approach uses iterative cycles of enrichment and amplification to select binders from nucleic acid libraries of high complexity. Here we combine SELEX with the yeast three-hybrid system in order to select for RNA aptamers with in vivo binding activity. As a target molecule, we chose the RNA recognition motif-containing RNA-binding protein Rrm4 from the corn pathogen Ustilago maydis. Rrm4 is an ELAV-like protein containing three N-terminal RNA recognition motifs (RRMs). It has been implicated in microtubule-dependent RNA transport during pathogenic development. After 11 SELEX cycles, four aptamer classes were identified. These sequences were further screened for their in vivo binding activity applying the yeast three-hybrid system. Of the initial aptamer classes only members of two classes were capable of binding in vivo. Testing representatives of both classes against Rrm4 variants mutated in one of the three RRM domains revealed that these aptamers interacted with the third RRM. Thus, the yeast three-hybrid system is a useful extension to the SELEX protocol for the identification and characterization of aptamers with in vivo binding activity.     

Interaction of the cauliflower mosaic virus coat protein with the pregenomic RNA leader

Using the yeast three-hybrid system, the interaction of the Cauliflower mosaic virus (CaMV) pregenomic 35S RNA (pgRNA) leader with the viral coat protein, its precursor, and a series of derivatives was studied. The purine-rich domain in the center of the pgRNA leader was found to specifically interact with the coat protein. The zinc finger motif of the coat protein and the preceding basic domain were essential for this interaction. Removal of the N-terminal portion of the basic domain led to loss of specificity but did not affect the strength of the interaction. Mutations of the zinc finger motif abolished not only the interaction with the RNA but also viral infectivity. In the presence of the very acidic C-terminal domain, which is part of the preprotein but is not present in the mature CP, the interaction with the RNA was undetectable.     

Analysis of PDZ domain-ligand interactions using carboxyl-terminal phage display

PDZ domains mediate protein-protein interactions at specialized subcellular sites, such as epithelial cell tight junctions and neuronal post-synaptic densities. Because most PDZ domains bind extreme carboxyl-terminal sequences, the phage display method has not been amenable to the study of PDZ domain binding specificities. For the first time, we demonstrate the functional display of a peptide library fused to the carboxyl terminus of the M13 major coat protein. We used this library to analyze carboxyl-terminal peptide recognition by two PDZ domains. For each PDZ domain, the library provided specific ligands with sub-micromolar binding affinities. Synthetic peptides and homology modeling were used to dissect and rationalize the binding interactions. Our results establish carboxyl-terminal phage display as a powerful new method for mapping PDZ domain binding specificity.     

Reassessing the role of a 3'-UTR-binding translational inhibitor in regulation of circadian bioluminescence rhythm in the dinoflagellate Gonyaulax

The nightly bioluminescence of the dinoflagellate Gonyaulax is a circadian rhythm caused by the presence in cells of specialized bioluminescent organelles, termed scintillons, containing the reaction catalyst luciferase, the substrate luciferin and a luciferin-binding protein (LBP). LBP levels increase at the start of the night phase because of increased protein synthesis rates in vivo, and this regulation has been ascribed to circadian binding of an inhibitory protein factor binding to the 3' untranslated region (UTR) of lbp mRNA at times when LBP is not normally synthesized. To purify and characterize the binding factor, the electrophoretic mobility shift assays and UV crosslinking experiments used to first characterize the factor were repeated. However, neither these protocols nor binding to biotinylated RNA probes confirmed the presence of a specific circadian RNA-binding protein. Furthermore, neither RNA probe screening of a cDNA library expressed in bacteria nor three-hybrid assays in yeast were successful in isolating a cDNA encoding a protein able to bind specifically to the lbp 3'UTR. Taken together, these results suggest that alternative mechanisms for regulating lbp translation should now be examined.     

Translational repression and specific RNA binding by the coat protein of the Pseudomonas phage PP7

PP7 is a single-strand RNA bacteriophage of Pseudomonas aeroginosa and a distant relative to coliphages like MS2 and Qbeta. Here we show that PP7 coat protein is a specific RNA-binding protein, capable of repressing the translation of sequences fused to the translation initiation region of PP7 replicase. Its RNA binding activity is specific since it represses the translational operator of PP7, but does not repress the operators of the MS2 or Qbeta phages. Conditions for the purification of coat protein and for the reconstitution of its RNA binding activity from disaggregated virus-like particles were established. Its dissociation constant for PP7 operator RNA in vitro was determined to be about 1 nm. Using a genetic system in which coat protein represses translation of a replicase-beta-galactosidase fusion protein, amino acid residues important for binding of PP7 RNA were identified.