Isolation of specific RNA-binding proteins using the streptomycin-binding RNA aptamer

Here we report a simple and cheap one-step affinity purification protocol for isolating RNAs or proteins that interact with selected functional RNAs. The streptomycin-binding aptamer, termed 'StreptoTag,' is embedded in or fused to either end of any RNA of interest. The resulting hybrid RNA can then be immobilized on a streptomycin affinity matrix. When a complex protein mixture or total cellular lysate is applied to the matrix, subsequent elution with free streptomycin allows efficient recovery of specific ribonucleoprotein or RNA-RNA complexes. The method was successfully used to purify yeast and phage RNA-binding proteins and group II intron, viral and bacterial noncoding RNA (ncRNA)-binding proteins. The selective enrichment of bacterial mRNAs that bind ncRNAs has also been demonstrated. Once the affinity matrix, the RNA construct and the protein extracts have been prepared, the experimental procedure can be performed in 1-2 h.     

RNA-binding proteins in RNA interference

Short RNAs (21–27 nt) silence genes that contain homologous nucleotide sequences; this is known as RNA silencing. This review considers the generation of short RNAs from their precursors: double-stranded RNAs, capable of inducing RNA interference, and hairpin RNAs, whose processing yields microRNAs, as well as the properties of RNA-binding domains that were initially identified in proteins operating in RNA interference. The interactions between these domains and known RNA-binding modules within proteins involved in RNA interference and microRNA generation are described.     

RNA-binding strategies common to cold-shock domain- and RNA recognition motif-containing proteins

Numerous RNA-binding proteins have modular structures, comprising one or several copies of a selective RNA-binding domain generally coupled to an auxiliary domain that binds RNA non-specifically. We have built and compared homology-based models of the cold-shock domain (CSD) of the Xenopus protein, FRGY2, and of the third RNA recognition motif (RRM) of the ubiquitous nucleolar protein, nucleolin. Our model of the CSD_FRG–RNA complex constitutes the first prediction of the three-dimensional structure of a CSD–RNA complex and is consistent with the hypothesis of a convergent evolution of CSD and RRM towards a related single-stranded RNA-binding surface. Circular dichroism spectroscopy studies have revealed that these RNA-binding domains are capable of orchestrating similar types of RNA conformational change. Our results further show that the respective auxiliary domains, despite their lack of sequence homology, are functionally equivalent and indispensable for modulating the properties of the specific RNA-binding domains. A comparative analysis of FRGY2 and nucleolin C-terminal domains has revealed common structural features representing the signature of a particular type of auxiliary domain, which has co-evolved with the CSD and the RRM.     

Mammalian single-stranded DNA binding proteins and heterogeneous nuclear RNA proteins have common antigenic determinants.

Antibodies were raised in rabbit against a pure subset of calf thymus single-stranded DNA binding proteins (ssDBPs) and purified by affinity chromatography on antigen-Sepharose. In Western blot experiments these antibodies were shown to react to the same extent with the whole family of bovine ssDBPs, as well as with ssDBPs from HeLa cells. When used to stain total cell extracts from both calf thymus and HeLa cells the antibodies reacted only with bands corresponding to the ssDBPs and with a set of bands of higher molecular weight, whose electrophoretic pattern matched that of the 40S hnRNP core proteins. In effect we observed that purified 40S hnRNP core proteins from HeLa cells were strongly reactive with the antibodies. Moreover after partial tryptic digestion HeLa cells ssDBPs and hnRNPs produced immunoreactive fragments of the same molecular weight and isoelectric point. Extensive structural homologies can thus be evidenced between these two classes of proteins, which share the property of selective binding to single-stranded nucleic acids.     

Detection of common motifs in RNA secondary structures.

We describe a novel computerized system for comparison of RNA secondary structures and demonstrate its use for experimental studies. The system is able to screen a very large number of structures, to cluster similar structures and to detect specific structural motifs. In particular, the system is useful for detecting mutations with specific structural effects among all possible point mutations, and for predicting compensatory mutations that will restore the wild type structure. The algorithms are independent of the folding rules that are used to generate the secondary structures.     

Arginine-rich motifs present multiple interfaces for specific binding by RNA

A number of proteins containing arginine-rich motifs (ARMs) are known to bind RNA and are involved in regulating RNA processing in viruses and cells. Using automated selection methods we have generated a number of aptamers against ARM peptides from various natural proteins. Aptamers bind tightly to their cognate ARMs, with K(d) values in the nanomolar range, and frequently show no propensity to bind to other ARMs or even to single amino acid variants of the cognate ARM. However, at least some anti-ARM aptamers can cross-recognize a limited set of other ARMs, just as natural RNA-binding sites have been shown to exhibit so-called "chameleonism." We expand upon the number of examples of cross-recognition and, using mutational and circular dichroism (CD) analyses, demonstrate that there are multiple mechanisms by which RNA ligands can cross-recognize ARMs. These studies support a model in which individual arginine residues govern binding to an RNA ligand, and the inherent flexibility of the peptide backbone may make it possible for "semi-specific" recognition of a discrete set of RNAs by a discrete set of ARM peptides and proteins.     

The role of RNA-binding and ribosomal proteins as specific RNA translation regulators in cellular differentiation and carcinogenesis

Tight control of mRNA expression is required for cell differentiation; imbalanced regulation may lead to developmental disorders and cancer. The activity of the translational machinery (including ribosomes and translation factors) regulates the rate (slow or fast) of translation of encoded proteins, and the quality of these proteins highly depends on which mRNAs are available for translation. Specific RNA-binding and ribosomal proteins seem to play a key role in controlling gene expression to determine the differentiation fate of the cell. This demonstrates the important role of RNA-binding proteins, specific ribosome-binding proteins and microRNAs as key molecules in controlling the specific proteins required for the differentiation or dedifferentiation of cells. This delicate balance between specific proteins (in terms of quality and availability) and post-translational modifications occurring in the cytoplasm is crucial for cell differentiation, dedifferentiation and oncogenic potential. In this review, we report how defects in the regulation of mRNA translation can be dependent on specific proteins and can induce an imbalance between differentiation and dedifferentiation in cell fate determination.     

CAG trinucleotide RNA repeats interact with RNA-binding proteins.

Genes associated with several neurological diseases are characterized by the presence of an abnormally long trinucleotide repeat sequence. By way of example, Huntington's disease (HD), is characterized by selective neuronal degeneration associated with the expansion of a polyglutamine-encoding CAG tract. Normally, this CAG tract is comprised of 11-34 repeats, but in HD it is expanded to > 37 repeats in affected individuals. The mechanism by which CAG repeats cause neuronal degeneration is unknown, but it has been speculated that the expansion primarily causes abnormal protein functioning, which in turn causes HD pathology. Other mechanisms, however, have not been ruled out. Interactions between RNA and RNA-binding proteins have previously been shown to play a role in the expression of several eukaryotic genes. Herein, we report the association of cytoplasmic proteins with normal length and extended CAG repeats, using gel shift and UV crosslinking assays. Cytoplasmic protein extracts from several rat brain regions, including the striatum and cortex, sites of neuronal degeneration in HD, contain a 63-kD RNA-binding protein that specifically interacts with these CAG-repeat sequences. These protein-RNA interactions are dependent on the length of the CAG repeat, with longer repeats binding substantially more protein. Two CAG repeat-binding proteins are present in human cortex and striatum; one comigrates with the rat protein at 63 kD, while the other migrates at 49 kD. These data suggest mechanisms by which RNA-binding proteins may be involved in the pathological course of trinucleotide repeat-associated neurological diseases.     

RNA editing in trypanosomes

Guide RNAs are encoded in maxicircle and minicircle DNA of trypanosome mitochondria. They play a pivotal role in RNA editing, a process during which the nucleotide sequence of mitochondrial RNAs is altered by U-insertion and deletion. Guide RNAs vary in length from 35 to 78 nucleotides, which correlates with the variation in length of the three functionally important regions of which they are composed: (i) a 4–14 nucleotide anchor sequence embedded in the 5 region, which is complementary to a target sequence on the pre-edited RNA downstream of an editing domain, (ii) a middle part containing the editing information, which ranges from guiding the insertion of just one U into one site to that of the insertion of 32 Us into 10 sites, and (iii) a 5–24 nucleotide 3 terminal oligo [U] extension. Moreover, a variable uridylation site creates gRNAs containing a varying segment of editing information for the same domain. Comparison of different guide RNAs demonstrates that, besides the U-tail, they have no obvious common primary and secondary sequence motifs, each particular sequence being unique. The occurrence in vivo and the synthesis in vitro of chimeric molecules, in which a guide RNA is covalently linked through its 3 U-tail to an editing site of a pre-edited RNA, suggests that RNA editing occurs by consecutive transesterification reactions and is evidence that the guide RNAs not only provide the genetic information, but also the Us themselves.Abbreviations gRNA guide RNA     

Structural properties and RNA-binding activities of two RNA recognition motifs of a mouse neural RNA-binding protein,mouse-Musashi-1

mouse-Musashi-1 (m-Msi-1) is an RNA-binding protein, abundantly expressed in the developing mammalian central nervous system (CNS). m-Msi-1 contains two RNA recognition motifs (RRMs). In this study, we found that the N-terminal RRM of m-Msi-1 (MMA) binds strongly to poly(G) and weakly to poly(U) in a way similar to that of the full-length m-Msi-1 protein characterized previously. The C-terminal RRM of m-Msi-1 (MMB), however, does not bind to RNA. In addition, the circular dichroism (CD) spectra of the two RRMs showed that the α-helical content of MMA is significantly higher than that of MMB, indicating that some differences in the secondary structure may be responsible for the distinct RNA binding properties of MMA and MMB.