RNA-binding proteins: modular design for efficient function

Many RNA-binding proteins have modular structures and are composed of multiple repeats of just a few basic domains that are arranged in various ways to satisfy their diverse functional requirements. Recent studies have investigated how different modules cooperate in regulating the RNA-binding specificity and the biological activity of these proteins. They have also investigated how multiple modules cooperate with enzymatic domains to regulate the catalytic activity of enzymes that act on RNA. These studies have shown how, for many RNA-binding proteins, multiple modules define the fundamental structural unit that is responsible for biological function.     

RNA-binding proteins of mammalian mitochondria

A UV-cross-linking assay was used to identify RNA-binding proteins in mammalian mitochondria. A number of these proteins were detected ranging in molecular mass from 15 to 120 kDa. All of the mRNA-binding activities were localized to the matrix except for two proteins which are primarily associated with the inner membrane. None of the polypeptides is specific for binding mitochondrial mRNAs since all bound mRNAs from other sources with comparable efficiency. Some preference for binding mRNA over tRNA or homoribopolymers was observed with several of the proteins. A protein with characteristic pentatricopeptide repeat motifs found in many RNA binding proteins was identified associated with the small subunit of the mitochondrial ribosome.     

GraphProt: modeling binding preferences of RNA-binding proteins

We present GraphProt, a computational framework for learning sequence- and structure-binding preferences of RNA-binding proteins (RBPs) from high-throughput experimental data. We benchmark GraphProt, demonstrating that the modeled binding preferences conform to the literature, and showcase the biological relevance and two applications of GraphProt models. First, estimated binding affinities correlate with experimental measurements. Second, predicted Ago2 targets display higher levels of expression upon Ago2 knockdown, whereas control targets do not. Computational binding models, such as those provided by GraphProt, are essential for predicting RBP binding sites and affinities in all tissues. GraphProt is freely available at http://www.bioinf.uni-freiburg.de/Software/GraphProt.     

Trading translation with RNA-binding proteins

RNA-binding proteins regulate every aspect of RNA metabolism, including pre-mRNA splicing, mRNA trafficking, stability, and translation. This review summarizes the available information on molecular mechanisms of translational repression by RNA-binding proteins. By using a specific set of well-defined examples, we also describe how regulation can be reversed.     

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-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 properties of hnRNP proteins

The RNA-binding properties of the hnRNP monoparticle proteins were examined using a renaturing blotting procedure. All 'core' proteins are able to bind single-stranded nucleic acids, probably not sequence-specific. The core proteins C1 and, in one case A2 and B2, are able to bind nucleic acids which are double-stranded or which show a high degree of base-paired regions, among them U1 snRNA, whereas A1, B1 and C2 are unable to bind base-paired nucleic acids. The characteristics of C1 in binding base-paired nucleic acids are especially interesting, since the involvement of C1 in the splicing process has been described.     

RNA-binding proteins in neurological diseases

Emerging studies support that RNA-binding proteins(RBPs)play critical roles in human biology and pathogenesis.RBPs are essential players in RNA processing and metabolism,including pre-mRNA splicing,polyadenylation,transport,surveillance,mRNA localization,mRNA stability control,translational control and editing of various types of RNAs.Aberrant expression of and mutations in RBP genes affect various steps of RNA processing,altering target gene function.RBPs have been associated with various diseases,including neurological diseases.Here,we mainly focus on selected RNA-binding proteins including Nova-1/Nova-2,HuR/HuB/HuC/HuD,TDP-43,Fus,Rbfox1/Rbfox2,QKI and FMRP,discussing their function and roles in human diseases.     

RNA-binding proteins in early development

RNA-binding proteins play a major part in the control of gene expression during early development. At this stage, the majority of regulation occurs at the levels of translation and RNA localization. These processes are, in general, mediated by RNA-binding proteins interacting with specific sequence motifs in the 3'-untranslated regions of their target RNAs. Although initial work concentrated on the analysis of these sequences and their trans-acting factors, we are now beginning to gain an understanding of the mechanisms by which some of these proteins function. In this review, we will describe a number of different families of RNA-binding proteins, grouping them together on the basis of common regulatory strategies, and emphasizing the recurrent themes that occur, both across different species and as a response to different biological problems.     

Characterization of RNA-binding properties of three types of RNA-binding proteins in Anabaena sp. PPC 7120.

The Rbp proteins in cyanobacteria are RNA-binding proteins with a single RNA recognition motif or RRM. A comprehensive assembly of genomic data suggests that there are two major classes of Rbp proteins (classes I and II) that diverged before the diversification of cyanobacteria. Class I proteins are further classified into two types with or without a C-terminal glycine-rich domain. The results of selection from a random RNA pool suggest that RbpA1 (class I) has affinity to C-rich and G-rich sequences. In vitro RNA binding assay with homopolymers indicated that class II protein has low affinity to poly(G) in contrast with class I proteins. Site-specific mutagenesis analysis of the RRM in RbpA1 showed that the aromatic residues Tyr4 or Phe46 are important in RNA binding as well as maintenance of secondary structure. We also tested various truncated proteins lacking the C-terminal domain as well as point mutants. Most of these proteins exhibited decreased affinity to RNA. Circular dichroism analysis as well as chromatographic analysis showed that Tyr4 and Phe46 are also important in maintaining the structure of RbpA1 protein. The C-terminal glycine-rich domain itself does not contribute much to the RNA-binding, but Arg83 which is located close to the C-terminal end of RRM is important in the RNA-binding.     

Conservation of structure and cold-regulation of RNA-binding proteins in cyanobacteria: probable convergent evolution with eukaryotic glycine-rich RNA-binding proteins

The rbp gene family of the cyanobacterium Anabaena variabilis strain M3 consists of eight members that encode small RNA-binding proteins containing a single RNA recognition motif (RRM). Similar genes are found in the genomes of Synechocystis sp. PCC6803, Helicobacter pylori and Treponema pallidum, but are absent from the other completely sequenced prokaryotic genomes. The expression of the rbp genes of Anabaena is induced by low temperature, with the exception of the rbpD gene. We found four stretches of conserved sequences in the 5'-untranslated region of the cyanobacterial rbp genes that are known to be induced by low temperature. The cold-regulated Rbp proteins contain a short C-terminal glycine-rich domain. In this respect, these proteins are similar to plant and mammalian glycine-rich RNA-binding proteins (GRPs), which also contain a single RRM domain with a C-terminal glycine-rich domain and are highly expressed at low temperature. Detailed phylogenetic analysis showed, however, that the cyanobacterial Rbp proteins and the eukaryotic GRPs do not belong to a single lineage, but that the glycine-rich domains are likely to have been added independently. The cold-regulation of both types of proteins is also likely to have evolved independently. Furthermore, the chloroplast RNA-binding proteins are not likely to have originated from the Rbp proteins of endosymbiont cyanobacterium, but are supposed to have diverged from the GRPs. These results suggest that the cyanobacterial Rbp proteins and the eukaryotic GRPs are similar in both structure and regulation, but that this apparent similarity has resulted from convergent evolution.