Structure of the pyrimidine-rich internal loop in the poliovirus 3'-UTR: the importance of maintaining pseudo-2-fold symmetry in RNA helices containing two adjacent non-canonical base-pairs

Formation of non-canonical base-pairs in RNA often plays a very important functional role. In addition they frequently serve as factors in stabilizing the secondary structure elements that provide the frame of large compact RNA structures. Here we describe the structure of an internal loop containing a 5'CU3'/5'UU3' non-canonical tandem base-pair motif, which is conserved within the 3'-UTR of poliovirus-like enteroviruses. Structural details reveal striking regularities of the local helix geometry, resulting from alternating geometrical adjustments, which are important for understanding and predicting stabilities and configurations of tandem non-canonical base-pairs. The C-U and U-U base-pairs severely contract the minor groove of the sugar-phosphate backbone, which might be important for protein recognition or binding to other RNA elements.     

Structure of a conserved retroviral RNA packaging element by NMR spectroscopy and cryo-electron tomography

The 5′-untranslated regions of all gammaretroviruses contain a conserved “double-hairpin motif” (Ψ^CD) that is required for genome packaging. Both hairpins (SL-C and SL-D) contain GACG tetraloops that, in isolated RNAs, are capable of forming “kissing” interactions stabilized by two intermolecular G-C base pairs. We have determined the three-dimensional structure of the double hairpin from the Moloney murine leukemia virus ([Ψ^CD]₂, 132 nt, 42.8 kDa) using a ²H-edited NMR-spectroscopy-based approach. This approach enabled the detection of ¹H-¹H dipolar interactions that were not observed in previous studies of isolated SL-C and SL-D hairpin RNAs using traditional ¹H-¹H correlated and ¹H-¹³C-edited NMR methods. The hairpins participate in intermolecular cross-kissing interactions (SL-C to SL-D′ and SLC′ to SL-D) and stack in an end-to-end manner (SL-C to SL-D and SL-C′ to SL-D′) that gives rise to an elongated overall shape (ca 95 Å × 45 Å ×  25 Å). The global structure was confirmed by cryo-electron tomography (cryo-ET), making [Ψ^CD]₂ simultaneously the smallest RNA to be structurally characterized to date by cryo-ET and among the largest to be determined by NMR. Our findings suggest that, in addition to promoting dimerization, [Ψ^CD]₂ functions as a scaffold that helps initiate virus assembly by exposing a cluster of conserved UCUG elements for binding to the cognate nucleocapsid domains of assembling viral Gag proteins.     

Resolution of the 1H-1H NOE spectrum of RNA into three dimensions using 15N-1H two-bond couplings

The feasibility of using two-bond ¹⁵N-¹H couplings to resolve the ¹H-¹H nuclear Overhauser effect spectrum of RNA into a third dimension was investigated, using the 36-nucleotide gene 32 messenger RNA pseudoknot of bacteriophage T2 as an example. The two-bond ¹⁵N-¹H couplings present in adenosine and guanosine were found to be suitable for generating a three-dimensional ¹H-¹H-¹⁵N NOESY-HSQC spectrum with reasonably good sensitivity, as well as favorable chemical shift dispersion in the nitrogen dimension. The described NMR experiment provides a tool that can be used to complement other heteronuclear methods in the analysis of RNA structure.     

Solution structures of the double-stranded RNA-binding domains from RNA helicase A

RNA helicase A (RHA) is a highly conserved protein with multifaceted functions in the gene expression of cellular and viral mRNAs. RHA recognizes highly structured nucleotides and catalytically rearranges the various interactions between RNA, DNA, and protein molecules to provide a platform for the ribonucleoprotein complex. We present the first solution structures of the double-stranded RNA-binding domains (dsRBDs), dsRBD1 and dsRBD2, from mouse RHA. We discuss the binding mode of the dsRBDs of RHA, in comparison with the known dsRBD structures in their complexes. Our structural data provide important information for the elucidation of the molecular reassembly mediated by RHA.     

Solution structure of the BHRF1 protein from Epstein-Barr virus, a homolog of human Bcl-2

The three-dimensional structure of BHRF1, the Bcl-2 homolog from Epstein-Barr virus (EBV), has been determined by NMR spectroscopy. Although the overall structure is similar to other Bcl-2 family members, there are important structural differences. Unlike some of the other Bcl-2 family members, BHRF1 does not contain the prominent hydrophobic groove that mediates binding to pro-apoptotic family members. In addition, in contrast to the anti-apoptotic Bcl-2 proteins, BHRF1 does not bind tightly to peptides derived from the pro-apoptotic proteins Bak, Bax, Bik, and Bad. The lack of an exposed, pre-formed binding groove in BHRF1 and the lack of significant binding to peptides derived from pro-apoptotic family members that bind to other anti-apoptotic family members, suggest that the mechanism of the BHRF1 anti-apoptotic activity does not parallel that of cellular Bcl-x(L) or Bcl-2.     

HNHC: a triple resonance experiment for correlating the H2, N1(N3) and C2 resonances in adenine nucleobases of <Superscript>13</Superscript>C-, <Superscript>15</Superscript>N-labeled RNA oligonucleotides

A novel NMR pulse sequence has been developed that correlates the H2 resonances with the C2 and the N1 (N3) resonances in adenine nucleobases of ¹³C, ¹⁵N labeled oligonucleotides. The pulse scheme of the new 3D-HNHC experiment is composed of a ²J-¹⁵N-HSQC and a ¹J-¹³C-HSQC and utilizes large ²J(H2, N1(N3)) and ¹J(H2, C2) couplings. The experiment was applied to a medium-size ¹³C, ¹⁵N-labeled 36mer RNA. It is useful to resolve assignment ambiguities occurring especially in larger RNA molecules due to resonance overlap in the ¹H-dimension. Therefore, the missing link in correlating the imino H3 resonances of the uracils across the AU base pair to the H8 resonances of the adenines via the novel pulse sequence and the TROSY relayed HCCH-COSY (Simon et al. in J Biomol NMR 20:173–176 2001) is provided. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Structure of the RNA signal essential for translational frameshifting in HIV-1

Many pathogenic viruses use a programmed -1 translational frameshifting mechanism to regulate synthesis of their structural and enzymatic proteins. Frameshifting is vital for viral replication. A slippery sequence bound at the ribosomal A and P sites as well as a downstream stimulatory RNA structure are essential for frameshifting. Conflicting data have been reported concerning the structure of the downstream RNA signal in human immunodeficiency virus type 1 (HIV-1). Here, the solution structure of the HIV-1 frameshifting RNA signal was solved by heteronuclear NMR spectroscopy. This structure reveals a long hairpin fold with an internal three-nucleotide bulge. The internal loop introduces a bend between the lower and upper helical regions, a structural feature often seen in frameshifting pseudoknots. The NMR structure correlates with chemical probing data. The upper stem rich in conserved G-C Watson-Crick base-pairs is highly stable, whereas the bulge region and the lower stem are more flexible.     

RNA2D3D: A program for Generating,Viewing, and Comparing 3-Dimensional Models of RNA

Abstract

Using primary and secondary structure information of an RNA molecule, the program RNA2D3D automatically and rapidly produces a first-order approximation of a 3-dimensional conformation consistent with this information. Applicable to structures of arbitrary branching complexity and pseudoknot content, it features efficient interactive graphical editing for the removal of any overlaps introduced by the initial generating procedure and for making conformational changes favorable to targeted features and subsequent refinement. With emphasis on fast exploration of alternative 3D conformations, one may interactively add or delete base-pairs, adjacent stems can be coaxially stacked or unstacked, single strands can be shaped to accommodate special constraints, and arbitrary subsets can be defined and manipulated as rigid bodies. Compaction, whereby base stacking within stems is optimally extended into connecting single strands, is also available as a means of strategically making the structures more compact and revealing folding motifs. Subsequent refinement of the first-order approximation, of modifications, and for the imposing of tertiary constraints is assisted with standard energy refinement techniques. Previously determined coordinates for any part of the molecule are readily incorporated, and any part of the modeled structure can be output as a PDB or XYZ file. Illustrative applications in the areas of ribozymes, viral kissing loops, viral internal ribosome entry sites, and nanobiology are presented.     

RNA DNA discrimination by the antitermination protein NusB

The regulation of ribosomal RNA biosynthesis in Escherichia coli by antitermination requires binding of NusB protein to a dodecamer sequence designated boxA on the nascent RNA. The affinity of NusB protein for boxA RNA exceeds that for the homologous DNA segment by more than three orders of magnitude as shown by surface plasmon resonance measurements. DNA RNA discrimination by NusB protein was shown to involve methyl groups (i.e. discrimination of uracil versus thymine) and 2' hydroxyl groups (i.e. discrimination of ribose versus deoxyribose side-chains) in the RNA motif. Ligand perturbation experiments monitored by 1H15N correlation NMR experiments identified amide NH groups whose chemical shifts are affected selectively by ribose/deoxyribose exchange in the 5' and the central part of the dodecameric boxA motif respectively. The impact of structural modification of the boxA motif on the affinity for NusB protein as observed by 1H15N heterocorrelation was analysed by a generic algorithm.     

Structure and stability of wild-type and mutant RNA internal loops from the SL-1 domain of the HIV-1 packaging signal

The packaging signal (Psi) of the human immunodeficiency virus type 1 (HIV-1) enables encapsidation of the full-length genomic RNA against a background of a vast excess of cellular mRNAs. The core HIV-1 Psi is approximately 109 nucleotides and contains sequences critical for viral genomic dimerisation and splicing, in addition to the packaging signal. It consists of a series of stem-loops (termed SL-1 to SL-4), which can be arranged in a cloverleaf secondary structure. Using a combination of NMR spectroscopy, UV melting experiments, molecular modeling and phylogenetic analyses, we have explored the structure of two conserved internal loops proximal to the palindromic sequence of SL-1. Internal loop A, composed of six purines, forms a flexible structure that is strikingly similar to the Rev responsive element motif when bound to Rev protein. This result suggests that it may function as a protein-binding site. The absolutely conserved four-purine internal loop B is instead conformationally and thermodynamically unstable, and exhibits multiple conformations in solution. By introducing a double AGG to GGA mutation within this loop, its conformation is stabilised to form a new intra-molecular G:A:G base-triplet. The structure of the GGA mutant explains the relative instability of the wild-type loop. In a manner analogous to SL-3, we propose that conformational flexibility at this site may facilitate melting of the structure during Gag protein capture or genomic RNA dimerisation.     

Modeling the dynamics of the solvated SL1 domain of HIV-1 genomic RNA

A mode-coupling solution of the Smoluchowski diffusion equation (MCD theory), designed to describe the dynamics of wobbling macromolecules in water, is applied to a macromolecular bead model including water beads in the nearest layers. The necessary statistical averages are evaluated by time averaging along a molecular dynamics (MD) trajectory where both solute and water are introduced as atomistic models. The cross peaks in (1)H nuclear Overhauser effect spectroscopy (NOESY) NMR spectra that are routinely measured to determine biological structures are here calculated for the mutated 23 nucleotides stem-loop fragment of the SL1 domain in the HIV-1(Lai) genomic RNA. The calculations are in acceptable agreement with experiments without requiring any screening of the hydrodynamic interactions. The screening of hydrodynamics was necessary in previous MCD calculations obtained by using the same full atomistic MD trajectory, but a nonsolvated frictional model.     

Structure and RNA binding of the mouse Pumilio-2 Puf domain

Puf proteins control translation through the interaction of a C-terminal Puf domain with specific sequences present in the 3′ untranslated region of messenger RNAs. In Drosophila, binding of the protein Pumilio to mRNA leads to translational repression which is required for anterior/posterior patterning during embryogenesis. The vertebrate Pumilio homologue 2 (Pum2) has been implicated in controlling germ cell development through interactions with the RNA binding proteins deleted in azoospermia (DAZ), DAZ-like (DAZL) and BOULE. We present the 1.6 Å resolution X-ray crystal structure of the Puf domain from murine Pum2 and demonstrate that this domain is capable of binding with nanomolar affinity to RNA sequences from the hunchback Nanos response element (NRE) and a previously identified Pum2 binding element (PBE).     

The Three-Dimensional Solution Structure of the Src Homology Domain-2 of the Growth Factor Receptor-Bound Protein-2

A set of high-resolution three-dimensional solution structures of the Src homology region-2 (SH2) domain of the growth factor receptor-bound protein-2 was determined using heteronuclear NMR spectroscopy. The NMR data used in this study were collected on a stable monomeric protein solution that was free of protein aggregates and proteolysis. The solution structure was determined based upon a total of 1439 constraints, which included 1326 nuclear Overhauser effect distance constraints, 70 hydrogen bond constraints, and 43 dihedral angle constraints. Distance geometry-simulated annealing calculations followed by energy minimization yielded a family of 18 structures that converged to a root-mean-square deviation of 1.09 Å for all backbone atoms and 0.40 Å for the backbone atoms of the central -sheet. The core structure of the SH2 domain contains an antiparallel -sheet flanked by two parallel -helices displaying an overall architecture that is similar to other known SH2 domain structures. This family of NMR structures is compared to the X-ray structure and to another family of NMR solution structures determined under different solution conditions.     

A dimeric RNA quadruplex architecture comprised of two G:G(:A):G:G(:A) hexads,G:G:G:G tetrads and UUUU loops

Using CD and NMR, we determined the structure of an RNA oligomer, r(GGAGGUUUUGGAGG) (R14), comprising two GGAGG segments joined by a UUUU segment. A modified quadruplex structure was observed for r(GGAGGUUUUGGAGG) in solution even in the absence of K(+). An unusually stable dimeric RNA quadruplex architecture formed from two strands of r(GGAGGUUUUGGAGG) at low K(+) concentration is reported here. In each strand of r(GGAGGUUUUGGAGG), two sets of successive turns in the GGAGG segments and turns at both ends of the UUUU loops drive four G-G steps to align in a parallel manner, a core with two stacked G-tetrads being formed. Two adenine bases bind to two edges of one G:G:G:G tetrad through the sheared G:A mismatch augmenting the tetrad into a G:G(:A):G:G(:A) hexad. Thus, one molecule of r(GGAGGUUUUGGAGG) folds into a modified quadruplex comprising a G:G:G:G tetrad, a UUUU double-chain reversal loop and a G:G(:A):G:G(:A) hexad. Two such molecules further associate by stacking through the dimeric hexad-hexad interface with a rotational symmetry. The ribose rings of most nucleotides take S (close to C2'-endo) puckering, which is unusual for an RNA. K(+) can increase the stability of this quadruplex structure; the number of bound K(+) was estimated from the results of the titration experiment. Besides G:G and G:A mismatches, a network of hydrogen bonds including O4'-NH(2) and C-H..O hydrogen bonds, and the extensive base stacking contribute to the high thermodynamic stability of R14. Our results could provide the stereochemical and thermodynamic basis for elucidating the biological role of the GGAGG-containing RNA segments abundantly existing in various RNAs. Relevance to quadruplex-mediated mRNA-FMRP binding and HIV-1 genome RNA dimerization is discussed.