Characterization of an anti-RNA recombinant autoantibody fragment (scFv) isolated from a phage display library and detailed analysis of its binding site on U1 snRNA.

This is the first study in which the complex of a monoclonal autoantibody fragment and its target, stem loop II of U1 snRNA, was investigated with enzymatic and chemical probing. A phage display antibody library derived from bone marrow cells of an SLE patient was used for selection of scFvs specific for stem loop II. The scFv specificity was tested by RNA immunoprecipitation and nitrocellulose filter binding competition experiments. Immunofluorescence data and immunoprecipitation of U1 snRNPs containing U1A protein, pointed to an scFv binding site different from the U1A binding site. The scFv binding site on stem loop II was determined by footprinting experiments using RNase A, RNase V1, and hydroxyl radicals. The results show that the binding site covers three sequence elements on the RNA, one on the 5' strand of the stem and two on the 3' strand. Hypersensitivity of three loop nucleotides suggests a conformational change of the RNA upon antibody binding. A three-dimensional representation of stem loop II reveals a juxtapositioning of the three protected regions on one side of the helix, spanning approximately one helical turn. The location of the scFv binding site on stem loop II is in full agreement with the finding that both the U1A protein and the scFv are able to bind stem loop II simultaneously. As a consequence, this recombinant monoclonal anti-U1 snRNA scFv might be very useful in studies on U1 snRNPs and its involvement in cellular processes like splicing.     

A pre-export U1 snRNP in Xenopus laevis oocyte nuclei.

We demonstrate that precursors of U1 snRNA are associated with nuclear proteins prior to export to the cytoplasm. The approximately 15S complexes containing pre-U1 RNA, which we call pre-export U1 snRNPs, were identified in extracts of Xenopus laevis oocyte nuclei that were synthesizing U1 RNAs from injected U1 genes. The U1 snRNP-specific A protein was associated with nuclear pre-U1 RNA since both this protein and the RNA were co-precipitated by antibodies directed against either the m7G-cap of the precursor RNA or the U1-A protein. The interaction of the U1-A protein with pre-U1 RNA required sequences in the loop II region although this region of U1 RNA was not necessary for the association of U1 A protein with mature U1 snRNPs. The U1 A protein helps protect pre-U1 RNA against degradation in the nucleus.     

RNA binding specificity of a Drosophila snRNP protein that shares sequence homology with mammalian U1-A and U2-B" proteins.

We have characterized a recombinant Drosophila melanogaster RNA binding protein, D25, by virtue of its antigenic relationship to mammalian U1 and U2 small nuclear ribonucleoprotein (U snRNP) proteins. Sequence analysis revealed that D25 bears strong similarity to both the human U1 snRNP-A (U1-A) and U2 snRNP-B" (U2-B") proteins. However, at residues known to be critical for the RNA binding specificities of U1-A and U2-B" D25 sequence is more similar to U2-B". Using direct RNA binding assays D25 selected U1 RNA from either HeLa or Drosophila Kc cell total RNA. Furthermore, D25 bound U1 RNA when transfected into mammalian cells. Thus, D25 appears to be a Drosophila homolog of the mammalian U1-A protein, despite its sequence similarity to U2-B".     

Contribution of the C-terminal tail of U1A RBD1 to RNA recognition and protein stability.

The N-terminal RNA binding domain (RBD1) of the human U1A protein interacts specifically with a short RNA hairpin containing the U1 snRNA stem/loop II sequence. Previous RNA binding studies have suggested that the C-terminal tail of RBD1 contributes to RNA recognition in addition to interactions on the beta-sheet surface of the protein. To evaluate the contributions of these C-terminal residues in RBD1 to RNA binding affinity and specificity, as well as to study the thermodynamic stability of RBDs, a number of RBD1 mutants with truncated tails, with single amino acid substitutions, and with both a truncation and an amino acid substitution, have been constructed. The thermodynamic stabilities of these mutants have been measured and compared by GdnHCI unfolding experiments. The RNA binding affinity and specificity of these mutant proteins have been assessed by measuring the binding of each protein to the wild-type RNA hairpin and to selected RNA mutants with nucleotide substitutions in the RNA loop. The results demonstrate first that, although the C-terminal tail of RBD1 makes significant contributions to RNA binding affinity, it is not required for RNA binding, and second, its contributions to binding specificity are mediated only through selected nucleotides in the RNA loop, for in the absence of the tail, the protein continues to use other nucleotides to discriminate among RNAs. In these truncated proteins, the secondary structure intrinsic to the C-terminal tail is absent, yet their affinity and discrimination for RNAs are not lost. Thus, a structured tail is not required for RNA recognition.     

Direct, sequence-specific binding of the human U1-70K ribonucleoprotein antigen protein to loop I of U1 small nuclear RNA.

We have studied the interaction of two of the U1 small nuclear ribonucleoprotein (snRNP)-specific proteins, U1-70K and U1-A, with U1 small nuclear RNA (snRNA). The U1-70K protein is a U1-specific RNA-binding protein. Deletion and mutation analyses of a beta-galactosidase/U1-70K partial fusion protein indicated that the central portion of the protein, including the RNP sequence domain, is both necessary and sufficient for specific U1 snRNA binding in vitro. The highly conserved eight-amino-acid RNP consensus sequence was found to be essential for binding. Deletion and mutation analyses of U1 snRNA showed that both the U1-70K fusion protein and the native HeLa U1-70K protein bound directly to loop I of U1 snRNA. Binding was sequence specific, requiring 8 of the 10 bases in the loop. The U1-A snRNP protein also interacted specifically with U1 snRNA, principally with stem-loop II.     

The role of RNA structure in the interaction of U1A protein with U1 hairpin II RNA

The N-terminal RNA Recognition Motif (RRM1) of the spliceosomal protein U1A interacting with its target U1 hairpin II (U1hpII) has been used as a paradigm for RRM-containing proteins interacting with their RNA targets. U1A binds to U1hpII via direct interactions with a 7-nucleotide (nt) consensus binding sequence at the 5' end of a 10-nt loop, and via hydrogen bonds with the closing C-G base pair at the top of the RNA stem. Using surface plasmon resonance (Biacore), we have examined the role of structural features of U1hpII in binding to U1A RRM1. Mutational analysis of the closing base pair suggests it plays a minor role in binding and mainly prevents "breathing" of the loop. Lengthening the stem and nontarget part of the loop suggests that the increased negative charge of the RNA might slightly aid association. However, this is offset by an increase in dissociation, which may be caused by attraction of the RRM to nontarget parts of the RNA. Studies of a single stranded target and RNAs with untethered loops indicate that structure is not very relevant for association but is important for complex stability. In particular, breaking the link between the stem and the 5' side of the loop greatly increases complex dissociation, presumably by hindering simultaneous contacts between the RRM and stem and loop nucleotides. While binding of U1A to a single stranded target is much weaker than to U1hpII, it occurs with nanomolar affinity, supporting recent evidence that binding of unstructured RNA by U1A has physiological significance.     

Structure and dimerization of HIV-1 kissing loop aptamers

Dimerization of two homologous strands of genomic RNA is an essential feature of the retroviral replication cycle. In HIV-1, genomic RNA dimerization is facilitated by a conserved stem-loop structure located near the 5' end of the viral RNA called the dimerization initiation site (DIS). The DIS loop is comprised of nine nucleotides, six of which define an autocomplementary sequence flanked by three conserved purine residues. Base- pairing between the loop sequences of two copies of genomic RNA is necessary for efficient dimerization. We previously used in vitro evolution to investigate a possible structural basis for the marked sequence conservation of the DIS loop. In this study, chemical structure probing, measurements of the apparent dissociation constants, and computer structure analysis of dimerization-competent aptamers were used to analyze the dimers' structure and binding. The selected aptamers were variants of the naturally occurring A and B subtypes. The data suggest that a sheared base-pair closing the loop of the DIS is important for dimerization in both subtypes. On the other hand, the open or closed state of the last base-pair in the stem differed in the two subtypes. This base-pair appeared closed in the subtype A DIS dimer and open in subtype B. Finally, evidence for a cross-talk between nucleotides 2, 5, and 6 was found in some, but not all, loop contexts, indicating some structural plasticity depending on loop sequence. Discriminating between the general rules governing dimer formation and the particular characteristics of individual DIS aptamers helps to explain the affinity and specificity of loop-loop interactions and could provide the basis for development of drugs targeted against the dimerization step during retroviral replication.     

NMR structures of loop B RNAs from the stem-loop IV domain of the enterovirus internal ribosome entry site: a single C to U substitution drastically changes the shape and flexibility of RNA

The 5'-untranslated region of positive-strand RNA viruses harbors many cis-acting RNA structural elements that are important for various viral processes such as replication, translation, and packaging of new virions. Among these is loop B RNA of the stem-loop IV domain within the internal ribosomal entry site (IRES) of enteroviruses, including Poliovirus type 1 (PV1). Studies on PV1 have shown that specific recognition of loop B by the first KH (hnRNP K homology) domain of cellular poly(rC)-binding protein 2 (PCBP2) is essential for efficient translation of the viral mRNA. Here we report the NMR solution structures of two representative sequence variants of enteroviral loop B RNA. The two RNA variants differ at only one position (C vs U) within a six-nucleotide asymmetric internal loop sequence that is the binding site for the PCBP2 KH1 domain. Surprisingly, the two RNAs are drastically different in the overall shape and local dynamics of the bulge region. The RNA with the 5'-AUCCCU bulge sequence adopts an overall L shape. Its bulge nucleotides, especially the last four, are highly flexible and not very well defined by NMR. The RNA with the 5'-AUUCCU bulge sequence adopts an overall U shape, and its bulge sequence exhibits only limited flexibility. A detailed analysis of the two RNA structures and their dynamic properties, as well as available sequence data and known KH domain-RNA complex structures, not only provides insights into how loop B RNA might be recognized by the PCBP2 KH1 domain but also suggests a possible correlation between structural flexibility and pre-existing structural features for protein recognition.     

RNA binding specificity of hnRNP A1: significance of hnRNP A1 high-affinity binding sites in pre-mRNA splicing.

Pre-mRNA is processed as a large complex of pre-mRNA, snRNPs and pre-mRNA binding proteins (hnRNP proteins). The significance of hnRNP proteins in mRNA biogenesis is likely to be reflected in their RNA binding properties. We have determined the RNA binding specificity of hnRNP A1 and of each of its two RNA binding domains (RBDs), by selection/amplification from pools of random sequence RNA. Unique RNA molecules were selected by hnRNP A1 and each individual RBD, suggesting that the RNA binding specificity of hnRNP A1 is the result of both RBDs acting as a single RNA binding composite. Interestingly, the consensus high-affinity hnRNP A1 binding site, UAGGGA/U, resembles the consensus sequences of vertebrate 5' and 3' splice sites. The highest affinity 'winner' sequence for hnRNP A1 contained a duplication of this sequence separated by two nucleotides, and was bound by hnRNP A1 with an apparent dissociation constant of 1 x 10(-9) M. hnRNP A1 also bound other RNA sequences, including pre-mRNA splice sites and an intron-derived sequence, but with reduced affinities, demonstrating that hnRNP A1 binds different RNA sequences with a > 100-fold range of affinities. These experiments demonstrate that hnRNP A1 is a sequence-specific RNA binding protein. UV light-induced protein-RNA crosslinking in nuclear extracts demonstrated that an oligoribonucleotide containing the A1 winner sequence can be used as a specific affinity reagent for hnRNP A1 and an unidentified 50 kDa protein. We also show that this oligoribonucleotide, as well as two others containing 5' and 3' pre-mRNA splice sites, are potent inhibitors of in vitro pre-mRNA splicing.     

Correlated motions in the U1 snRNA stem/loop 2:U1A RBD1 complex

The complex formed by U1A RBD1 and the U1 snRNA stem/loop II is noted for its high affinity and exquisite specificity. Here, that complex is investigated by 5 ns molecular dynamics simulations and analyzed by reorientational eigenmode dynamics to determine the dynamic properties of the RNA:protein interface that could contribute to the binding mechanism. The analysis shows that there is extensive correlation between motions of the RNA and protein, involving 7 of the 10 RNA loop nucleotides, the protein beta-sheet surface, two of its loops, and its C-terminal tripeptide sequence. Order parameters of these regions of the complex are uniformly high, indicating restricted motion. However, several regions of both RNA and protein retain local flexibility, notably three nucleotides of the RNA loop and one loop of RBD1 that does not contact RNA. The highly correlated motions involving both molecules reflect the intricate network of interactions that characterize this complex and could account in part for the thermodynamic coupling observed for complex formation.     

Prediction of a new class of RNA recognition motif

The observation that activation domains (AD) of procarboxypeptidases are rather long compared to the pro-regions of other zymogens raises the possibility that they could play additional roles apart from precluding enzymatic activity within the proenzyme and helping in its folding process. In the present work, we compared the overall pro-domain tertiary structure with several proteins belonging to the same fold in the structural classification of proteins (SCOP) database by using structure and sequence comparisons. The best score obtained was between the activation domain of human procarboxypeptidase A4 (ADA4h) and the human U1A protein from the U1 snRNP. Structural alignment revealed the existence of RNP1- and RNP2-related sequences in ADA4h. After modeling ADA4h on U1A, the new structure was used to extract a new sequence pattern characteristic for important residues at key positions. The new sequence pattern allowed scanning protein sequences to predict the RNA-binding function for 32 sequences undetected by PFAM. Unspecific RNA electrophoretic mobility shift assays experimentally supported the prediction that ADA4h binds an RNA motif similar to the U1A binding-motif of stem-loop II of U1 small nuclear RNA. The experiments carried out with ADA4h in the present work suggest the sharing of a common ancestor with other RNA recognition motifs. However, the fact that key residues preventing activity within the proenzyme are also key residues for RNA binding might have induced the activation domains of procarboxypeptidases to evolve from the canonical RNP1 and RNP2 sequences.     

Architecture of the U5 small nuclear RNA.

We have used comparative sequence analysis and deletion analysis to examine the secondary structure of the U5 small nuclear RNA (snRNA), an essential component of the pre-mRNA splicing apparatus. The secondary structure of Saccharomyces cerevisiae U5 snRNA was studied in detail, while sequences from six other fungal species were included in the phylogenetic analysis. Our results indicate that fungal U5 snRNAs, like their counterparts from other taxa, can be folded into a secondary structure characterized by a highly conserved stem-loop (stem-loop 1) that is flanked by a moderately conserved internal loop (internal loop 1). In addition, several of the fungal U5 snRNAs include a novel stem-loop structure (ca. 30 nucleotides) that is adjacent to stem-loop 1. By deletion analysis of the S. cerevisiae snRNA, we have demonstrated that the minimal U5 snRNA that can complement the lethal phenotype of a U5 gene disruption consists of (i) stem-loop 1, (ii) internal loop 1, (iii) a stem-closing internal loop 1, and (iv) the conserved Sm protein binding site. Remarkably, all essential, U5-specific primary sequence elements are encoded by a 39-nucleotide domain consisting of stem-loop 1 and internal loop 1. This domain must, therefore, contain all U5-specific sequences that are essential for splicing activity, including binding sites for U5-specific proteins.     

Identification of the RNA binding segment of human U1 A protein and definition of its binding site on U1 snRNA.

The interaction between the U1 snRNP-specific U1 A protein and U1 snRNA has been analysed. The binding site for the protein on the RNA is shown to be in hairpin II, which extends from positions 48 to 91 in the RNA. Within this hairpin the evolutionarily conserved loop sequence is crucial for interaction with U1 A protein. U1 A protein can also bind the loop sequence when it is part of an artificial RNA which cannot form a stable hairpin structure. The region of the protein required to bind to U1 snRNA consists of a conserved 80 amino acid motif, previously identified in many ribonucleoprotein (RNP) proteins, together with (maximally) 11 N-terminal and 10 C-terminal flanking amino acids. Point mutations introduced into two of the most highly conserved regions of this motif abolish RNA binding. U1 snRNA mutants from which the U1 A binding site has been deleted are shown to be capable of assembly into RNP particles which are immunoprecipitable by patient antisera which recognize U1 A protein. The role of RNA-protein and protein-protein interactions in U snRNP assembly are discussed.     

Loop I of U1 small nuclear RNA is the only essential RNA sequence for binding of specific U1 small nuclear ribonucleoprotein particle proteins.

The binding of the U1 small nuclear ribonucleoprotein (snRNP)-specific proteins C, A, and 70K to U1 small nuclear RNA (snRNA) was analyzed. Assembly of U1 snRNAs from bean and soybean and a set of mutant Xenopus U1 snRNAs into U1 snRNPs in Xenopus egg extracts was studied. The ability to bind proteins was analyzed by immunoprecipitation with monospecific antibodies and by a protein-sequestering assay. The only sequence essential for binding of the U1-specific proteins was the conserved loop sequence in the 5' hairpin of U1. Further analysis suggested that protein C binds directly to the loop and that the assembly of proteins A and 70K into the RNP requires mainly protein-protein interactions. Protein C apparently recognizes a specific RNA sequence rather than a secondary structural element in the RNA.     

Structure-probing of U1 snRNPs gradually depleted of the U1-specific proteins A, C and 70k. Evidence that A interacts differentially with developmentally regulated mouse U1 snRNA variants.

The interaction of the U1-specific proteins 70k, A and C with U1 snRNP was studied by depleting gradually U1 snRNPs of the U1-specific proteins by Mono-Q chromatography at elevated temperatures (20-37 degrees C). U1 snRNP species were obtained which were selectively depleted of either protein C, A, C and A, or of all three U1-specific proteins C, A and 70k while retaining the common proteins B' to G. These various types of U1 snRNP particles were used to study the differential accessibility of defined regions of U1 RNA towards nucleases V1 and S1 dependent on the U1 snRNP protein composition. The data indicate that in the U1 snRNP protein 70k interacts with stem/loop A and protein A with stem/loop B of U1 RNA. The presence or absence of protein C did not affect the nuclease digestion patterns of U1 RNA. Our results suggest further that the binding of protein A to the U1 snRNP particle should be independent of proteins 70k and C. Mouse cells contain two U1 RNA species, U1a and U1b, which differ in the structure of stem/loop B, with U1a exhibiting the same stem/loop B sequence as U1 RNA from HeLa cells. When we used Mono Q chromatography to investigate possible structural differences in the two types of U1 snRNPs, we observed that protein A was always preferentially lost from U1b snRNP as compared to U1a snRNPs. This indicates that one consequence of the structural difference between U1a and U1b is a lowering of the strength of binding of protein A to U1b snRNP. The possible functional significance of this finding is discussed with respect to the fact that U1b RNA is preferentially expressed in embryonal cells.     

3' end processing of mouse histone pre-mRNA: evidence for additional base-pairing between U7 snRNA and pre-mRNA.

We have analysed the extent of base-pairing interactions between spacer sequences of histone pre-mRNA and U7 snRNA present in the trans-acting U7 snRNP and their importance for histone RNA 3' end processing in vitro. For the efficiently processed mouse H4-12 gene, a computer analysis revealed that additional base pairs could be formed with U7 RNA outside of the previously recognised spacer element (stem II). One complementarity (stem III) is located more 3' and involves nucleotides from the very 5' end of U7 RNA. The other, more 5' located complementarity (stem I) involves nucleotides of the Sm binding site of U7 RNA, a part known to interact with snRNP structural proteins. These potential stem structures are separated from each other by short internal loops of unpaired nucleotides. Mutational analyses of the pre-mRNA indicate that stems II and III are equally important for interaction with the U7 snRNP and for processing, whereas mutations in stem I have moderate effects on processing efficiency, but do not impair complex formation with the U7 snRNP. Thus nucleotides near the processing site may be important for processing, but do not contribute to the assembly of an active complex by forming a stem I structure. The importance of stem III was confirmed by the ability of a complementary mutation in U7 RNA to suppress a stem III mutation in a complementation assay using Xenopus laevis oocytes. The main role of the factor(s) binding to the upstream hairpin loop is to stabilise the U7-pre-mRNA complex. This was shown by either stabilising (by mutation) or destabilising (by increased temperature) the U7-pre-mRNA base-pairing under conditions where hairpin factor binding was either allowed or prevented (by mutation or competition). The hairpin dependence of processing was found to be inversely related to the strength of the U7-pre-mRNA interaction.     

Convergence of natural and artificial evolution on an RNA loop-loop interaction: the HIV-1 dimerization initiation site

Loop-loop interactions among nucleic acids constitute an important form of molecular recognition in a variety of biological systems. In HIV-1, genomic dimerization involves an intermolecular RNA loop-loop interaction at the dimerization initiation site (DIS), a hairpin located in the 5' noncoding region that contains an autocomplementary sequence in the loop. Only two major DIS loop sequence variants are observed among natural viral isolates. To investigate sequence and structural constraints on genomic RNA dimerization as well as loop-loop interactions in general, we randomized several or all of the nucleotides in the DIS loop and selected in vitro for dimerization-competent sequences. Surprisingly, increasing interloop complementarity above a threshold of 6 bp did not enhance dimerization, although the combinations of nucleotides forming the theoretically most stable hexanucleotide duplexes were selected. Noncanonical interactions contributed significantly to the stability and/or specificity of the dimeric complexes as demonstrated by the overwhelming bias for noncanonical base pairs closing the loop and covariations between flanking and central loop nucleotides. Degeneration of the entire loop yielded a complex population of dimerization-competent sequences whose consensus sequence resembles that of wild-type HIV-1. We conclude from these findings that the DIS has evolved to satisfy simultaneous constraints for optimal dimerization affinity and the capacity for homodimerization. Furthermore, the most constrained features of the DIS identified by our experiments could be the basis for the rational design of DIS-targeted antiviral compounds.     

Interaction of N-terminal domain of U1A protein with an RNA stem/loop.

The U1A protein is a sequence-specific RNA binding protein found in the U1 snRNP particle where it binds to stem/loop II of U1 snRNA. U1A contains two 'RNP' or 'RRM' (RNA Recognition Motif) domains, which are common to many RNA-binding proteins. The N-terminal RRM has been shown to bind specifically to the U1 RNA stem/loop, while the RNA target of the C-terminal domain is unknown. Here, we describe experiments using a 102 amino acid N-terminal RRM of U1A (102A) and a 25-nucleotide RNA stem/loop to measure the binding constants and thermodynamic parameters of this RNA:protein complex. Using nitrocellulose filter binding, we measure a dissociation constant KD = 2 x 10(-11) M in 250 mM NaCl, 2 mM MgC2, and 10 mM sodium cacodylate, pH 6 at room temperature, and a half-life for the complex of 5 minutes. The free energy of association (delta G degrees) of this complex is about -14 kcal/mol in these conditions. Determination of the salt dependence of the binding suggests that at least 8 ion-pairs are formed upon complex formation. A mutation in the RNA loop sequence reduces the affinity 10 x, or about 10% of the total free energy.