RNA chaperone activity and RNA-binding properties of the E. coli protein StpA

The E. coli protein StpA has RNA annealing and strand displacement activities and it promotes folding of RNAs by loosening their structures. To understand the mode of action of StpA, we analysed the relationship of its RNA chaperone activity to its RNA-binding properties. For acceleration of annealing of two short RNAs, StpA binds both molecules simultaneously, showing that annealing is promoted by crowding. StpA binds weakly to RNA with a preference for unstructured molecules. Binding of StpA to RNA is strongly dependent on the ionic strength, suggesting that the interactions are mainly electrostatic. A mutant variant of the protein, with a glycine to valine change in the nucleic-acid-binding domain, displays weaker RNA binding but higher RNA chaperone activity. This suggests that the RNA chaperone activity of StpA results from weak and transient interactions rather than from tight binding to RNA. We further discuss the role that structural disorder in proteins may play in chaperoning RNA folding, using bioinformatic sequence analysis tools, and provide evidence for the importance of conformational disorder and local structural preformation of chaperone nucleic-acid-binding sites.     

Assaying RNA chaperone activity in vivo using a novel RNA folding trap.

In the absence of proteins, RNAs often misfold in vitro due to alternative base pairings which result from the molecule being trapped in inactive conformations. We identify an in vivo folding trap in the T4 phage td gene, caused by nine base pairs between a sequence element in the upstream exon of the td gene and another at the 3' end of the intron. During translation, the ribosome resolves this interaction; consequently the intron folds correctly and splicing occurs. The introduction of a stop codon upstream of this base pairing prevents resolution of the inactive structure so that splicing cannot proceed. We have used this folding trap to probe for RNA binding proteins which, when overexpressed, either resolve the misfolded structure or impede its formation in vivo. We distinguish between proteins which recognize the intron structure and those which bind non-specifically and apparently ignore the intron. The first class, e.g. Neurospora crassa CYT-18, can rescue the exonic trap and intron mutants which cause a structural defect. However, known RNA chaperones such as Escherichia coli StpA and S12 and the HIV protein NCp7, only resolve the exonic trap without suppressing intron mutations. Thus, this structural trap enables detection of RNA chaperone activity in vivo.     

Escherichia coli protein StpA stimulates self-splicing by promoting RNA assembly in vitro.

An Escherichia coli gene, stpA, has been identified and cloned based on its ability to suppress the Td- phenotype of a resident, splicing-defective phage T4 td (thymidylate synthase) gene. The stpA gene, which was localized to 60.24 min on the E. coli chromosome, encodes a 15.3-kDa protein. Overproduction of StpA in vivo led to an increase in td pre-mRNA levels and modest enhancement of td mRNA:pre-mRNA ratios. Consistent with its in vivo effect, purified StpA promoted RNA splicing in vitro, and facilitated RNA annealing and strand exchange with model substrates. These results suggest that StpA promotes splicing of the intron by binding RNA nonspecifically, resolving misfolded precursor molecules and facilitating association of critical base pair elements. Furthermore, proteinase K treatment of StpA-assembled precursors prior to the initiation of the splicing reaction still resulted in splicing enhancement, indicating that StpA is not required for the catalytic step, unlike the Neurospora splicing effector CYT-18, whose presence was necessary for catalysis to proceed. Together these results suggest that StpA has chaperone activity in vitro, with the property of promoting assembly of the precursors into an active conformation, in contrast to splicing effectors that stabilize the catalytically active intron structure.     

Distribution and characterization of mutations induced by nitrous acid or hydroxylamine in the intron-containing thymidylate synthase gene of bacteriophage T4

The detailed distribution and characterization of 51 hydroxylamine (HA)-induced and 59 nitrous acid (NA)-induced mutations in the intron-containing bacteriophage T4 thymidylate synthase (td) gene is reported here. Mutations were mapped in 10 regions of thetd gene by recombinational marker rescue using plasmid or M13 subclones of thetd gene. Phage crosses using deletion mutants with known breakpoints in the 3′ end of thetd intron subdivided HA and NA mutations which mapped in this region. At least 31 of the mutations map within the 1-kb group I self-splicing intron. Intron mutations mapped only in the 5′ and 3′ ends of the intron sequence, in accordance with the hypothesis that the 5′ and 3′ domains of the T4td intron are essential for correct RNA splicing. RNA sequence analysis of a number of mappedtd mutations has identified two intron nucleotides and one exon nucleotide where both HA- and NA-induced mutations commonly occur. These three loci are characterized by a GC dinucleotide, with the mutations occurring at the cytosine residue. Thus, these data indicate at least three potential sites of both HA- and NA-induced mutagenic hotspot activity within thetd gene.     

Dissecting RNA chaperone activity

Many RNA-binding proteins help RNAs to fold via their RNA chaperone activity. This term has been used widely without accounting for the diversity of the observed reactions, which include complex events like restructuring of misfolded catalytic RNAs, promoting the assembly of RNA-protein complexes, and mediating RNA-RNA interactions. Proteins display very diverse activities depending on the assays used to measure RNA chaperone activity. To classify proteins with this activity, we compared three exemplary proteins from E. coli, host factor Hfq, ribosomal protein S1, and the histone-like protein StpA for their abilities to promote two simple reactions, RNA annealing and strand displacement. The results of a FRET-based assay show that S1 promotes only RNA strand displacement while Hfq solely enhances RNA annealing. StpA, in contrast, is active in both reactions. To test whether the two activities can be assigned to different domains of the bipartite-structured StpA, we assayed the purified N- and C- terminal domains separately. While both domains are unable to promote RNA annealing, we can attribute the RNA strand displacement activity of StpA to the C-terminal domain. Correlating with their RNA annealing activities, only Hfq and full-length StpA display simultaneous binding of two RNAs, suggesting a matchmaker-like model for this activity. For StpA, this "RNA crowding" requires protein-protein interactions, since a dimerization-deficient StpA mutant lost the ability to bind and anneal two RNAs. These results underline the difference between the two reaction types, making it necessary to distinguish and classify proteins according to their specific RNA chaperone activities.     

Antibiotic-induced Oligomerisation of Group I Intron RNA

Antibiotics act as inhibitors of various biological processes. Here we demonstrate that some tuberactinomycins, hitherto known as inhibitors of prokaryotic protein synthesis and of group I intron self-splicing, have a modulatory effect on group I intron RNAs. The linear intron, which is excised during the self-splicing process, is still an active molecule capable of performing an intramolecular transesterification resulting in a circular molecule. However, in the presence of sub-inhibitory concentrations of tuberactinomycins, the intron reacts intermolecularly leading to the formation of linear head-to-tail intron-oligomers. The antibiotic stimulates the intron to reactin transinstead ofin cis. The phage T4-derivedtdintron uses the same sites for oligomerisation as for circularisation. Gel-retardation experiments demonstrate that the intron RNA forms non-covalent complexes in the presence of the antibiotic. It might be envisaged that the role of these peptide antibiotics is to bridge RNA molecules mediating RNA – RNA interactions and thus enabling their reaction. The tuberactinomycins are further able to induce the interaction of heterologous introns. The ligation of the T4 phage-derivedtdintron with theTetrahymenarRNA intron is very efficient, resulting in molecules composed of two introns derived from different species. Thetdintron attacks theTetraymenaintron at various sites, which are located within double-stranded regions. These observations suggest that small molecules like these basic peptide antibiotics could have mediated RNA–RNA interactions in a pre-protein era.     

The RNA chaperone StpA enables fast RNA refolding by destabilization of mutually exclusive base pairs within competing secondary structure elements

In bacteria RNA gene regulatory elements refold dependent on environmental clues between two or more long-lived conformational states each associated with a distinct regulatory state. The refolding kinetics are strongly temperature-dependent and especially at lower temperatures they reach timescales that are biologically not accessible. To overcome this problem, RNA chaperones have evolved. However, the precise molecular mechanism of how these proteins accelerate RNA refolding reactions remains enigmatic. Here we show how the RNA chaperone StpA of Escherichia coli leads to an acceleration of a bistable RNA’s refolding kinetics through the selective destabilization of key base pairing interactions. We find in laser assisted real-time NMR experiments on photocaged bistable RNAs that the RNA chaperone leads to a two-fold increase in refolding rates at low temperatures due to reduced stability of ground state conformations. Further, we can show that upon interaction with StpA, base pairing interactions in the bistable RNA are modulated to favor refolding through the dominant pseudoknotted transition pathway. Our results shed light on the molecular mechanism of the interaction between RNA chaperones and bistable RNAs and are the first step into a functional classification of chaperones dependent on their biophysical mode of operation.     

ATP-dependent roles of the DEAD-box protein Mss116p in group II intron splicing in vitro and in vivo

The yeast DEAD-box protein Mss116p functions as a general RNA chaperone in splicing mitochondrial group I and group II introns. For most of its functions, Mss116p is thought to use ATP-dependent RNA unwinding to facilitate RNA structural transitions, but it has been suggested to assist in the folding of one group II intron (aI5γ) primarily by stabilizing a folding intermediate. Here we compare three aI5γ constructs: one with long exons, one with short exons, and a ribozyme construct lacking exons. The long exons result in slower splicing, suggesting that they misfold and/or stabilize nonnative intronic structures. Nevertheless, Mss116p acceleration of all three constructs depends on ATP and is inhibited by mutations that compromise RNA unwinding, suggesting similar mechanisms. Results of splicing assays and a new two-stage assay that separates ribozyme folding and catalysis indicate that maximal folding of all three constructs by Mss116p requires ATP-dependent RNA unwinding. ATP-independent activation is appreciable for only a subpopulation of the minimal ribozyme construct and not for constructs containing exons. As expected for a general RNA chaperone, Mss116p can also disrupt the native ribozyme, which can refold after Mss116p removal. Finally, using yeast strains with mitochondrial DNA containing only the single intron aI5γ,? we show that Mss116p mutants promote splicing in vivo to degrees that correlate with their residual ATP-dependent RNA-unwinding activities. Together, our results indicate that, although DEAD-box proteins play multiple roles in RNA folding, the physiological function of Mss116p in aI5γ splicing includes a requirement for ATP-dependent local unfolding, allowing the conversion of nonfunctional RNA structure into functional RNA structure.     

Unwinding by Local Strand Separation Is Critical for the Function of DEAD-Box Proteins as RNA Chaperones

The DEAD-box proteins CYT-19 in Neurospora crassa and Mss116p in Saccharomyces cerevisiae are broadly acting RNA chaperones that function in mitochondria to stimulate group I and group II intron splicing and to activate mRNA translation. Previous studies showed that the S. cerevisiae cytosolic/nuclear DEAD-box protein Ded1p could stimulate group II intron splicing in vitro. Here, we show that Ded1p complements mitochondrial translation and group I and group II intron splicing defects in mss116Δ strains, stimulates the in vitro splicing of group I and group II introns, and functions indistinguishably from CYT-19 to resolve different nonnative secondary and/or tertiary structures in the Tetrahymena thermophila large subunit rRNA-ΔP5abc group I intron. The Escherichia coli DEAD-box protein SrmB also stimulates group I and group II intron splicing in vitro, while the E. coli DEAD-box protein DbpA and the vaccinia virus DExH-box protein NPH-II gave little, if any, group I or group II intron splicing stimulation in vitro or in vivo. The four DEAD-box proteins that stimulate group I and group II intron splicing unwind RNA duplexes by local strand separation and have little or no specificity, as judged by RNA-binding assays and stimulation of their ATPase activity by diverse RNAs. In contrast, DbpA binds group I and group II intron RNAs nonspecifically, but its ATPase activity is activated specifically by a helical segment of E. coli 23S rRNA, and NPH-II unwinds RNAs by directional translocation. The ability of DEAD-box proteins to stimulate group I and group II intron splicing correlates primarily with their RNA-unwinding activity, which, for the protein preparations used here, was greatest for Mss116p, followed by Ded1p, CYT-19, and SrmB. Furthermore, this correlation holds for all group I and group II intron RNAs tested, implying a fundamentally similar mechanism for both types of introns. Our results support the hypothesis that DEAD-box proteins have an inherent ability to function as RNA chaperones by virtue of their distinctive RNA-unwinding mechanism, which enables refolding of localized RNA regions or structures without globally disrupting RNA structure.     

A DEAD-box protein functions as an ATP-dependent RNA chaperone in group I intron splicing

The Neurospora crassa CYT-18 protein, the mitochondrial tyrosyl-tRNA synthetase, functions in splicing group I introns by inducing formation of the catalytically active RNA structure. Here, we identified a DEAD-box protein (CYT-19) that functions in concert with CYT-18 to promote group I intron splicing in vivo and vitro. CYT-19 does not bind specifically to group I intron RNAs and instead functions as an ATP-dependent RNA chaperone to destabilize nonnative RNA structures that constitute kinetic traps in the CYT-18-assisted RNA-folding pathway. Our results demonstrate that a DExH/D-box protein has a specific, physiologically relevant chaperone function in the folding of a natural RNA substrate.     

RNA chaperone activity of L1 ribosomal proteins: phylogenetic conservation and splicing inhibition

RNA chaperone activity is defined as the ability of proteins to either prevent RNA from misfolding or to open up misfolded RNA conformations. One-third of all large ribosomal subunit proteins from E. coli display this activity, with L1 exhibiting one of the highest activities. Here, we demonstrate via the use of in vitro trans- and cis-splicing assays that the RNA chaperone activity of L1 is conserved in all three domains of life. However, thermophilic archaeal L1 proteins do not display RNA chaperone activity under the experimental conditions tested here. Furthermore, L1 does not exhibit RNA chaperone activity when in complexes with its cognate rRNA or mRNA substrates. The evolutionary conservation of the RNA chaperone activity among L1 proteins suggests a functional requirement during ribosome assembly, at least in bacteria, mesophilic archaea and eukarya. Surprisingly, rather than facilitating catalysis, the thermophilic archaeal L1 protein from Methanococcus jannaschii (MjaL1) completely inhibits splicing of the group I thymidylate synthase intron from phage T4. Mutational analysis of MjaL1 excludes the possibility that the inhibitory effect is due to stronger RNA binding. To our knowledge, MjaL1 is the first example of a protein that inhibits group I intron splicing.     

RNA splicing in Neurospora mitochondria: nuclear mutants defective in both splicing and 3' end synthesis of the large rRNA

We have identified nuclear mutants of Neurospora that are defective in splicing the mitochondrial large rRNA and that accumulate unspliced pre-rRNA (35S RNA). In cyt-4 mutants, the unspliced pre-rRNA contains short 3' end extensions (110 nucleotides) that are not present in pre-rRNAs from the other mutants. This and other characteristics suggest that the cyt-4 mutants may be primarily defective in 3' end synthesis and the RNA splicing defect occurs secondarily as a result of impaired RNA folding. The cyt-4 mutants also accumulate a "short" intron RNA and small exon RNAs that may reflect aberrant RNA cleavages. The 5' end of the short intron is about 285 nucleotides downstream from the 5' splice site at or near the base of the "central hairpin", a putative intermediate in folding of the pre-rRNA. Furthermore, the aberrant cleavage sites are immediately after a six nucleotide sequence (GAUAAU) homologous to the final splice junction (GAU/AAC).     

RNA chaperoning and intrinsic disorder in the core proteins of Flaviviridae

RNA chaperone proteins are essential partners of RNA in living organisms and viruses. They are thought to assist in the correct folding and structural rearrangements of RNA molecules by resolving misfolded RNA species in an ATP-independent manner. RNA chaperoning is probably an entropy-driven process, mediated by the coupled binding and folding of intrinsically disordered protein regions and the kinetically trapped RNA. Previously, we have shown that the core protein of hepatitis C virus (HCV) is a potent RNA chaperone that can drive profound structural modifications of HCV RNA in vitro. We now examined the RNA chaperone activity and the disordered nature of core proteins from different Flaviviridae genera, namely that of HCV, GBV-B (GB virus B), WNV (West Nile virus) and BVDV (bovine viral diarrhoea virus). Despite low-sequence similarities, all four proteins demonstrated general nucleic acid annealing and RNA chaperone activities. Furthermore, heat resistance of core proteins, as well as far-UV circular dichroism spectroscopy suggested that a well-defined 3D protein structure is not necessary for core-induced RNA structural rearrangements. These data provide evidence that RNA chaperoning—possibly mediated by intrinsically disordered protein segments—is conserved in Flaviviridae core proteins. Thus, besides nucleocapsid formation, core proteins may function in RNA structural rearrangements taking place during virus replication.     

Assaying RNA chaperone activity in vivo in bacteria using a ribozyme folding trap

Here, we report an assay to evaluate the intracellular RNA chaperone activity of a protein of interest in vivo in bacterial cells. The method is based on self-splicing of the group I intron, which is located in the thymidylate synthase (td) gene of phage T4. A previously described td mutant (tdSH1) has significantly impaired splicing due to formation of splicing-incompetent alternative structures. In this procedure, overexpression of RNA chaperones in the presence of the td mutant SH1 is used to evaluate whether the putative RNA chaperone is able to rescue the incorrectly folded group I intron. The ability of the RNA chaperone to assist during folding is measured indirectly by assessing the difference between the splicing efficiencies of the td mutant in the absence and in the presence of the RNA chaperone. This procedure can be completed in 5-6 d, not including the time needed to clone the putative RNA chaperone.     

RNA chaperone activity of large ribosomal subunit proteins from Escherichia coli

The ribosome is a highly dynamic ribonucleoprotein machine. During assembly and during translation the ribosomal RNAs must routinely be prevented from falling into kinetic folding traps. Stable occupation of these trapped states may be prevented by proteins with RNA chaperone activity. Here, ribosomal proteins from the large (50S) ribosome subunit of Escherichia coli were tested for RNA chaperone activity in an in vitro trans splicing assay. Nearly a third of the 34 large ribosomal subunit proteins displayed RNA chaperone activity. We discuss a possible role of this function during ribosome assembly and during translation.     

Better late than early: delayed translation of intron‐encoded endonuclease I‐TevI is required for efficient splicing of its host group I intron

The td group I intron interrupting the thymidylate synthase (TS) gene of phage T4 is a mobile intron that encodes the homing endonuclease I‐TevI. Efficient RNA splicing of the intron is required to restore function of the TS gene, while expression of I‐TevI from within the intron is required to initiate intron mobility. Three distinct layers of regulation temporally limit I‐TevI expression to late in the T4 infective cycle, yet the biological rationale for stringent regulation has not been tested. Here, we deleted key control elements to deregulate I‐TevI expression at early and middle times post T4 infection. Strikingly, we found that deregulation of I‐TevI, or of a catalytically inactive variant, generated a thymidine‐dependent phenotype that is caused by a reduction in td intron splicing. Prematurely terminating I‐TevI translation restores td splicing, full‐length TS synthesis, and rescues the thymidine‐dependent phenotype. We suggest that stringent translational control of I‐TevI evolved to prevent the ribosome from disrupting key structural elements of the td intron that are required for splicing and TS function at early and middle times post T4 infection. Analogous translational regulatory mechanisms in unrelated intron‐open reading frame arrangements may also function to limit deleterious consequences on splicing and host gene function.     

The RNA Chaperone and Protein Chaperone Activity of Arabidopsis Glycine-Rich RNA-Binding Protein 4 and 7 is Determined by the Propensity for the Formation of High Molecular Weight Complexes

RNA chaperones and protein chaperones are cellular proteins that can aid the correct folding of target RNAs and proteins, respectively. Although many proteins possessing RNA chaperone or protein chaperone activity have been demonstrated in diverse organisms, report evaluating the RNA chaperone and protein chaperone activity of a given protein is severely limited. Here, two glycine-rich RNA-binding proteins in Arabidopsis thaliana (AtGRPs), AtGRP7 exhibiting RNA chaperone activity and AtGRP4 exhibiting no RNA chaperone activity, were investigated for their protein chaperone activity. The heat-induced thermal aggregation of a substrate protein was significantly decreased with the addition of AtGRP4 depending on protein concentration, whereas the thermal aggregation of a substrate protein was further increased with the addition of AtGRP7, demonstrating that AtGRP4 but not AtGRP7 possesses protein chaperone activity. Size exclusion chromatography and electron microscopy analyses revealed that the formation of high molecular weight (HMW) complexes is closely related to the protein chaperone activity of AtGRP4. Importantly, the additional 25 amino acids at the N-terminus of AtGRP4 are crucial for HMW complex formation and protein chaperone activity. Taken together, these results show that the formation of HMW complexes is important for determining the RNA chaperone and protein chaperone activity of AtGRP4 and AtGRP7.     

Characterization of RNase R-digested cellular RNA source that consists of lariat and circular RNAs from pre-mRNA splicing

Besides linear RNAs, pre-mRNA splicing generates three forms of RNAs: lariat introns, Y-structure introns from trans-splicing, and circular exons through exon skipping. To study the persistence of excised introns in total cellular RNA, we used three Escherichia coli 3′ to 5′ exoribonucleases. Ribonuclease R (RNase R) thoroughly degrades the abundant linear RNAs and the Y-structure RNA, while preserving the loop portion of a lariat RNA. Ribonuclease II (RNase II) and polynucleotide phosphorylase (PNPase) also preserve the lariat loop, but are less efficient in degrading linear RNAs. RNase R digestion of the total RNA from human skeletal muscle generates an RNA pool consisting of lariat and circular RNAs. RT–PCR across the branch sites confirmed lariat RNAs and circular RNAs in the pool generated by constitutive and alternative splicing of the dystrophin pre-mRNA. Our results indicate that RNase R treatment can be used to construct an intronic cDNA library, in which majority of the intron lariats are represented. The highly specific activity of RNase R implies its ability to screen for rare intragenic trans-splicing in any target gene with a large background of cis-splicing. Further analysis of the intronic RNA pool from a specific tissue or cell will provide insights into the global profile of alternative splicing.