Identification of two novel arginine binding DNAs.

RNA tertiary structure is known to play critical roles in RNA-protein recognition and RNA function. To examine how DNA tertiary structure might relate to RNA structure, we performed in vitro selection experiments to identify single-stranded DNAs that specifically bind arginine, and compared the results with analogous experiments performed with RNA. In the case of RNA, a motif related to the arginine binding site in human immunodeficiency virus TAR RNA was commonly found, whereas in the case of DNA, two novel motifs and no TAR-like structures were found. One DNA motif, found in approximately 40% of the cloned sequences, forms of hairpin structure with a highly conserved 10 nucleotide loop, whereas the second motif is especially rich in G residues. Chemical interference and mutagenesis experiments identified nucleotides in both motifs that form specific arginine binding sites, and dimethylsulfate footprinting experiments identified single guanine residues in both that are protected from methylation in the presence of arginine, suggesting possible sites of arginine contact or conformational changes in the DNAs. Circular dichroism experiments indicated that both DNAs undergo conformational changes upon arginine binding and that the arginine guanidinium group alone is responsible for binding. A model for the G-rich motif is proposed in which mixed guanine and adenine quartets may form a novel DNA structure. Arginine binding DNAs and RNAs should provide useful model systems for studying nucleic acid tertiary structure.     

Specific arginine mediated RNA recognition

In many biological systems substantial roles are played by interactions between amino acids and RNA. Among amino acids L-arginine seems to be particularly relevant, because the guanidinium group of arginine side chain can potentially form five hydrogen bonds with appropriately positioned acceptor groups of RNA. Extensive studies reveal that specific arginine recognition is achieved by many different RNAs over a broad range of binding affinities. Arginine is frequently found among amino acids in the nucleic acid-binding motifs in various proteins. For example, specific binding of the HIV-1 Tat protein to its RNA site (TAR) is mediated by a single arginine residue. Free arginine can be also bound by the guanosine site in the group I Tetrahymena ribosomal RNA intron catalytic centre, as well as by numerous RNA motifs, called arginine aptamers, which have been selected in vitro.     

RNA binding strategies of ribosomal proteins.

Structures of a number of ribosomal proteins have now been determined by crystallography and NMR, though the complete structure of a ribosomal protein-rRNA complex has yet to be solved. However, some ribosomal protein structures show strong similarity to well-known families of DNA or RNA binding proteins for which structures in complex with cognate nucleic acids are available. Comparison of the known nucleic acid binding mechanisms of these non-ribosomal proteins with the most highly conserved surfaces of similar ribosomal proteins suggests ways in which the ribosomal proteins may be binding RNA. Three binding motifs, found in four ribosomal proteins so far, are considered here: homeodomain-like alpha-helical proteins (L11), OB fold proteins (S1 and S17) and RNP consensus proteins (S6). These comparisons suggest that ribosomal proteins combine a small number of fundamental strategies to develop highly specific RNA recognition sites.     

Solution studies of the dimerization initiation site of HIV-1 genomic RNA.

Dimerization of HIV-1 genomic RNA is an essential step of the viral cycle, initiated at a conserved stem-loop structure which forms a 'kissing complex' involving loop-loop interactions (dimerization initiation site, DIS). A 19mer RNA oligonucleotide (DIS-19) has been synthesized which forms a stable symmetrical dimer in solution at millimolar concentrations. Dimerization does not depend on addition of Mg2+. RNA ligation experiments unambiguously indicate that the formed dimer is a stable kissing complex under the NMR experimental conditions.1H NMR resonance assignments were obtained for DIS-19 at 290 K and pH 6.5. Analysis of the pattern of NOE connectivities reveals that the helix formed by loop-loop base pairing is stacked onto the two terminal stems. Non-canonical base pairs between two essential and conserved adenines are found at the junctions between the two intramolecular and the single intramolecular helices.     

Characterization of the nucleoside triphosphatase activity of poliovirus protein 2C reveals a mechanism by which guanidine inhibits poliovirus replication

The highly conserved non-structural protein 2C of picornaviruses is involved in viral genome replication and encapsidation and in the rearrangement of intracellular structures. 2C binds RNA, has nucleoside triphosphatase activity, and shares three motifs with superfamily III helicases. Motifs "A" and "B" are involved in nucleotide triphosphate (NTP) binding and hydrolysis, whereas a function for motif "C" has not yet been demonstrated. Poliovirus RNA replication is inhibited by millimolar concentrations of guanidine hydrochloride (GdnHCl). Resistance and dependence to GdnHCl map to 2C. To characterize the nucleoside triphosphatase activity of 2C, we purified poliovirus recombinant 2C fused to glutathione S-transferase (GST-2C) from Escherichia coli. GST-2C hydrolyzed ATP with a Km of 0.7 mM. Other NTPs, including GTP, competed with ATP for binding to 2C but were poor substrates for hydrolysis. Mutation of conserved residues in motif A and B abolished ATPase activity, as did mutation of the conserved asparagine residue in motif C, an observation indicating the involvement of this motif in ATP hydrolysis. GdnHCl at millimolar concentrations inhibited ATP hydrolysis. Mutations in 2C that confer poliovirus resistant to or dependent on GdnHCl increased the tolerance to GdnHCl up to 100-fold.     

The arginine-1493 residue in QRRGRTGR1493G motif IV of the hepatitis C virus NS3 helicase domain is essential for NS3 protein methylation by the protein arginine methyltransferase 1

The NS3 protein of hepatitis C virus (HCV) contains protease and RNA helicase activities, both of which are likely to be essential for HCV propagation. An arginine residue present in the arginine-glycine (RG)-rich region of many RNA-binding proteins is posttranslationally methylated by protein arginine methyltransferases (PRMTs). Amino acid sequence analysis revealed that the NS3 protein contains seven RG motifs, including two potential RG motifs in the 1486-QRRGRTGRG-1494 motif IV of the RNA helicase domain, in which arginines are potentially methylated by PRMTs. Indeed, we found that the full-length NS3 protein is arginine methylated in vivo. The full-length NS3 protein and the NS3 RNA helicase domain were methylated by a crude human cell extract. The purified PRMT1 methylated the full-length NS3 and the RNA helicase domain, but not the NS3 protease domain. The NS3 helicase bound specifically and comigrated with PRMT1 in vitro. Mutational analyses indicate that the Arg(1493) in the QRR(1488)GRTGR(1493)G region of the NS3 RNA helicase is essential for NS3 protein methylation and that Arg(1488) is likely methylated. NS3 protein methylation by the PRMT1 was decreased in the presence of homoribopolymers, suggesting that the arginine-rich motif IV is involved in RNA binding. The results suggest that an arginine residue(s) in QRXGRXGR motif IV conserved in the virus-encoded RNA helicases can be posttranslationally methylated by the PRMT1.     

Arginine side-chain dynamics in the HIV-1 rev-RRE complex

The binding of human immunodeficiency virus type 1 (HIV-1) Rev protein to its viral RNA target, stem-loop IIB (SLIIB) within the Rev Response element (RRE), mediates the export of singly-spliced and unspliced viral mRNA from the nucleus to the cytoplasm of infected cells; this Rev-mediated transport of viral RNA is absolutely required for the replication of infectious virus. To identify important features that influence the binding affinity and specificity of this Rev-RRE interaction, we have characterized the arginine side-chain dynamics of the Rev arginine-rich motif (ARM) while bound to a 34 nt RNA oligomer that corresponds to SLIIB. As the specificity of the Rev-RRE interaction varies with salt concentration, arginine side-chain dynamics were characterized at two different salt conditions. Following NMR measurements of (15)N spin relaxation parameters for the arginine (15)N(epsilon) nuclei, the dynamics of the corresponding N(epsilon)-H(epsilon) bond vectors were interpreted in terms of Lipari-Szabo model-free parameters using anisotropic expressions for the spectral density functions. Results from these analyses indicate that a number of arginine side-chains display a surprising degree of conformational freedom when bound to RNA, and that arginine residues having known importance for specific RRE recognition show striking differences in side-chain mobility. The (15)N relaxation measurements at different salt conditions suggest that the previously reported increase in Rev-RRE specificity at elevated salt concentrations is likely due to reduced affinity of non-specific Rev-RNA interactions. The observed dynamical behavior of the arginine side-chains at this protein-RNA interface likely plays an important role in the specificity and affinity of Rev-SLIIB complex formation.     

Multisite phosphorylation disrupts arginine-glutamate salt bridge networks required for binding of cytoplasmic linker-associated protein 2 (CLASP2) to end-binding protein 1 (EB1)

A group of diverse proteins reversibly binds to growing microtubule plus ends through interactions with end-binding proteins (EBs). These +TIPs control microtubule dynamics and microtubule interactions with other intracellular structures. Here, we use cytoplasmic linker-associated protein 2 (CLASP2) binding to EB1 to determine how multisite phosphorylation regulates interactions with EB1. The central, intrinsically disordered region of vertebrate CLASP proteins contains two SXIP EB1 binding motifs that are required for EB1-mediated plus-end-tracking in vitro. In cells, both EB1 binding motifs can be functional, but most of the binding free energy results from nearby electrostatic interactions. By employing molecular dynamics simulations of the EB1 interaction with a minimal CLASP2 plus-end-tracking module, we find that conserved arginine residues in CLASP2 form extensive hydrogen-bond networks with glutamate residues predominantly in the unstructured, acidic C-terminal tail of EB1. Multisite phosphorylation of glycogen synthase kinase 3 (GSK3) sites near the EB1 binding motifs disrupts this electrostatic "molecular Velcro." Molecular dynamics simulations and (31)P NMR spectroscopy indicate that phosphorylated serines participate in intramolecular interactions with and sequester arginine residues required for EB1 binding. Multisite phosphorylation of these GSK3 motifs requires priming phosphorylation by interphase or mitotic cyclin-dependent kinases (CDKs), and we find that CDK- and GSK3-dependent phosphorylation completely disrupts CLASP2 microtubule plus-end-tracking in mitosis.     

Sequence determinants for the tandem recognition of UGU and CUG rich RNA elements by the two N--terminal RRMs of CELF1

CUGBP, Elav-like family member 1 (CELF1) is an RNA binding protein with important roles in the regulation of splicing, mRNA decay and translation. CELF1 contains three RNA recognition motifs (RRMs). We used gel retardation, gel filtration, isothermal titration calorimetry and NMR titration studies to investigate the recognition of RNA by the first two RRMs of CELF1. NMR shows that RRM1 is promiscuous in binding to both UGU and CUG repeat sequences with comparable chemical shift perturbations. In contrast, RRM2 shows greater selectivity for UGUU rather than CUG motifs. A construct (T187) containing both binding domains (RRM1 and RRM2) was systematically studied for interaction with tandem UGU RNA binding sites with different length linker sequences UGU(U)_xUGU where x = 1–7. A single U spacer results in interactions only with RRM1, demonstrating both steric constraints in accommodating both RRMs simultaneously at adjacent sites, and also subtle differences in binding affinities between RRMs. However, high affinity co-operative binding (K_d ~ 0.4 µM) is evident for RNA sequences with x = 2–4, but longer spacers (x ≥ 5) lead to a 10-fold reduction in affinity. Our analysis rationalizes the high affinity interaction of T187 with the 11mer GRE consensus regulatory sequence UGUUUGUUUGU and has significant consequences for the prediction of CELF1 binding sites.     

Chemical and structural probing of the N-terminal residues encoded by FMR1 exon 15 and their effect on downstream arginine methylation

Exon 15 of the fragile X mental retardation protein gene (FMR1) is alternatively spliced into three variants. The amino acids encoded by the 5' end of the exon contain several regulatory determinants including phosphorylation sites and a potential conformational switch. Residues encoded by the 3' end of the exon specify FMRP's RGG box, an RNA binding domain that interacts with G-quartet motifs. Previous studies demonstrated that the exon 15-encoded N-terminal residues influence the extent of arginine methylation, independent of S 500 phosphorylation. In the present study we focus on the role the putative conformational switch plays in arginine methylation. Chemical and structural probing of Ex15 alternatively spliced variant proteins and several mutants leads to the following conclusions: Ex15c resides largely in a conformation that is refractory toward methylation; however, it can be methylated by supplementing extracts with recombinant PRMT1 or PRMT3. Protein modeling studies reveal that the RG-rich region is part of a three to four strand antiparallel beta-sheet, which in other RNA binding proteins functions as a platform for nucleic acid interactions. In the Ex15c variant the first strand of this sheet is truncated, and this significantly perturbs the side-chain conformations of the arginine residues in the RG-rich region. Mutating R 507 in the conformational switch to K also truncates the first strand of the beta-sheet, and corresponding decreases in in vitro methylation were found for this and R 507/R 544 and R 507/R 546 double mutants. These effects are not due to the loss of R 507 methylation as a conformational switch-containing peptide reacted under substrate excess and in methyl donor excess was not significantly methylated. Consistent with this, similar changes in beta-sheet structure and decreases in in vitro methylation were observed with a W 513-K mutant. These data support a novel model for FMRP arginine methylation and a role for conformational switch residues in arginine modification.     

Recognition of a cognate RNA aptamer by neomycin B: quantitative evaluation of hydrogen bonding and electrostatic interactions

Aminoglycosides are an important class of antibiotic that selectively target RNA structural motifs. Recently we have demonstrated copper derivatives of amino-glycosides to be efficient cleavage agents for cognate RNA motifs. To fully develop their potential as pharmaceutical agents it is necessary to understand both the structural mechanisms used by aminoglycosides to target RNA, and the relative contributions of hydrogen bonding and electrostatic interactions to recognition selectivity. Herein we report results from a calorimetric analysis of a stem-loop 23mer RNA aptamer complexed to the aminoglycoside neomycin B. Key thermodynamic parameters for complex formation have been determined by isothermal titration calorimetry, and from the metal-ion dependence of these binding parameters the relative contributions of electrostatics and hydrogen bonding toward binding affinity have been assessed. The principal mechanism for recognition and binding of neomycin B to the RNA major groove is mediated by hydrogen bonding.     

The newly discovered Q motif of DEAD-box RNA helicases regulates RNA-binding and helicase activity

DEAD-box proteins are the most common RNA helicases, and they are associated with virtually all processes involving RNA. They have nine conserved motifs that are required for ATP and RNA binding, and for linking phosphoanhydride cleavage of ATP with helicase activity. The Q motif is the most recently identified conserved element, and it occurs approximately 17 amino acids upstream of motif I. There is a highly conserved, but isolated, aromatic group approximately 17 amino acids upstream of the Q motif. These two elements are involved in adenine recognition and in ATPase activity of DEAD-box proteins. We made extensive analyses of the Q motif and upstream aromatic residue in the yeast translation-initiation factor Ded1. We made site-specific mutations and tested them for viability in yeast. Moreover, we purified various mutant proteins and obtained the Michaelis-Menten parameters for the ATPase activities. We also measured RNA affinities and strand-displacement activities. We find that the Q motif not only regulates ATP binding and hydrolysis but also regulates the affinity of the protein for RNA substrates and ultimately the helicase activity.     

Arginine methylation of Sam68 and SLM proteins negatively regulates their poly(U) RNA binding activity

Sam68 (Src substrate associated during mitosis) and its homologues, SLM-1 and SLM-2 (Sam68-like mammalian proteins), are RNA binding proteins and contain the arg-gly (RG) repeats, in which arginine residues are methylated by the protein arginine methyltransferase 1 (PRMT1). However, it remains unclear whether the arginine methylation affects an RNA binding. Here, we report that methylation of Sam68 and SLM proteins markedly reduced their poly(U) binding ability in vitro. The RG repeats of Sam68 bound poly(U), but arginine methylation of the RG repeats abrogated its poly(U) binding ability in vitro. Overexpression of PRMT1 increased arginine methylation of Sam68 and SLM proteins in cells, which resulted in a decrease of their poly(U) binding ability. The results suggest that the RG repeats conserved in Sam68 and SLM proteins may function as an auxiliary RNA binding domain and arginine methylation may eliminate or reduce an RNA binding ability of the proteins.     

Structure-based analysis of protein-RNA interactions using the program ENTANGLE

Until recently, drawing general conclusions about RNA recognition by proteins has been hindered by the paucity of high-resolution structures. We have analyzed 45 PDB entries of protein-RNA complexes to explore the underlying chemical principles governing both specific and non-sequence specific binding. To facilitate the analysis, we have constructed a database of interactions using ENTANGLE, a JAVA-based program that uses available structural models in their PDB format and searches for appropriate hydrogen bonding, stacking, electrostatic, hydrophobic and van der Waals interactions. The resulting database of interactions reveals correlations that suggest the basis for the discrimination of RNA from DNA and for base-specific recognition. The data illustrate both major and minor interaction strategies employed by families of proteins such as tRNA synthetases, ribosomal proteins, or RNA recognition motifs with their RNA targets. Perhaps most surprisingly, specific RNA recognition appears to be mediated largely by interactions of amide and carbonyl groups in the protein backbone with the edge of the RNA base. In cases where a base accepts a proton, the dominant amino acid donor is arginine, whereas in cases where the base donates a proton, the predominant acceptor is the backbone carbonyl group, not a side-chain group. This is in marked contrast to DNA-protein interactions, which are governed predominantly by amino acid side-chain interactions with functional groups that are presented in the accessible major groove. RNA recognition often proceeds through loops, bulges, kinks and other irregular structures that permit use of all the RNA functional groups and this is seen throughout the protein-RNA interaction database.     

A plant viral coat protein RNA binding consensus sequence contains a crucial arginine.

A defining feature of alfalfa mosaic virus (AMV) and ilarviruses [type virus: tobacco streak virus (TSV)] is that, in addition to genomic RNAs, viral coat protein is required to establish infection in plants. AMV and TSV coat proteins, which share little primary amino acid sequence identity, are functionally interchangeable in RNA binding and initiation of infection. The lysine-rich amino-terminal RNA binding domain of the AMV coat protein lacks previously identified RNA binding motifs. Here, the AMV coat protein RNA binding domain is shown to contain a single arginine whose specific side chain and position are crucial for RNA binding. In addition, the putative RNA binding domain of two ilarvirus coat proteins, TSV and citrus variegation virus, is identified and also shown to contain a crucial arginine. AMV and ilarvirus coat protein sequence alignment centering on the key arginine revealed a new RNA binding consensus sequence. This consensus may explain in part why heterologous viral RNA-coat protein mixtures are infectious.