P5abc of the Tetrahymena ribozyme consists of three functionally independent elements.

P5abc domain of Tetrahymena LSU intron functions as an activator that is not essential for but enhances the activity of the ribozyme either when present in cis or when added in trans. This domain contains three regions (A-rich bulge, L5b, and L5c) that have been demonstrated to interact with the rest of the intron. Although these regions are presumably important for efficient activation, the role of each element is not understood in the mechanism of activation. We employed circularly permuted introns and examined the roles of each element. The results show that each of the three elements can activate the intron independently. We also found that a correlation between the activation by P5abc and the physical affinity of P5abc to the intron exists.     

Mutations of the two-nucleotide bulge of D5 of a group II intron block splicing in vitro and in vivo: phenotypes and suppressor mutations.

Domain 5 (D5) is a highly conserved substructure of group II introns that is essential for catalysis of both steps of the splicing pathway. Here we studied the effects of mutations of the conserved 2-nt bulge in the binding and catalytic functions of D5 of intron aI5gamma of yeast mitochondrial DNA. Sequence variants of the 2-nt bulge reduced the rate of self-splicing somewhat. Deletion of one or both bulge nucleotides inhibited splicing more than 10(4)-fold, whereas mutants with a 3-nt bulge were much less debilitated. A novel allele with a symmetrical internal loop in place of the bulge self-splices nearly as actively as the control. Trans-splicing assays of D5 function showed some mutations primarily affect the catalytic function of D5, whereas others chiefly affect its binding function. Representative alleles were transformed into mtDNA and each inhibited splicing and respiratory growth. Pseudo-revertants included suppressor mutations nearby in D5 and one mutant yielded a dominant nuclear suppressor. These experiments provide new evidence that the D5 bulge is crucial for D5 binding and catalysis. It is possible that the bulge bends the D5 helix and that the extent of bending is especially important for D5 binding. The presence and exact nature of the bulge is also likely to have local structural consequences (besides bending) that influence the participation of specific backbone groups in binding and catalysis.     

Folding path of P5abc RNA involves direct coupling of secondary and tertiary structures

Folding mechanisms in which secondary structures are stabilized through the formation of tertiary interactions are well documented in protein folding but challenge the folding hierarchy normally assumed for RNA. However, it is increasingly clear that RNA could fold by a similar mechanism. P5abc, a small independently folding tertiary domain of the Tetrahymena thermophila group I ribozyme, is known to fold by a secondary structure rearrangement involving helix P5c. However, the extent of this rearrangement and the precise stage of folding that triggers it are unknown. We use experiments and simulations to show that the P5c helix switches to the native secondary structure late in the folding pathway and is directly coupled to the formation of tertiary interactions in the A-rich bulge. P5c mutations show that the switch in P5c is not rate-determining and suggest that non-native interactions in P5c aid folding rather than impede it. Our study illustrates that despite significant differences in the building blocks of proteins and RNA, there may be common ways in which they self-assemble.     

The polypyrimidine tract binding protein (PTB) requirement for internal initiation of translation of cardiovirus RNAs is conditional rather than absolute.

Picornavirus RNAs are translated by an unusual mechanism of internal ribosome entry that requires a substantial segment of the viral 5'-untranslated region, generally known as the internal ribosome entry segment (IRES), and in some circumstances may require cellular trans-acting proteins, particularly polypyrimidine tract binding protein (PTB). It is shown here that for encephalomyocarditis virus (EMCV), the PTB dependence of IRES function in vitro is determined partly by the nature of the reporter cistron, and more especially by the size of an A-rich bulge in the IRES. With a wild-type EMCV IRES (which has a bulge of 6 As), translation is effectively independent of PTB provided the IRES is driving the synthesis of EMCV viral polyprotein. With an enlarged (7A) bulge and heterologous reporters, translation is highly dependent on PTB. Intermediate levels of PTB dependence are seen with a 7A bulge IRES driving viral polyprotein synthesis or a wild-type (6A) bulge IRES linked to a heterologous reporter. None of these parameters influenced the binding of PTB to the high-affinity site in the IRES. These results argue that PTB is not an essential and universal internal initiation factor, but, rather, that when it is required, its binding to the IRES helps to maintain the appropriate higher-order structure and to reverse distortions caused, for example, by an enlarged A-rich bulge.     

Three essential and conserved regions of the group II intron are proximal to the 5'-splice site

Despite the central role of group II introns in eukaryotic gene expression and their importance as biophysical and evolutionary model systems, group II intron tertiary structure is not well understood. In order to characterize the architectural organization of intron ai5gamma, we incorporated the photoreactive nucleotides s(4)U and s(6)dG at specific locations within the intron core and monitored the formation of cross-links in folded complexes. The resulting data reveal the locations for many of the most conserved, catalytically important regions of the intron (i.e., the J2/3 linker region, the IC1(i-ii) bulge in domain 1, the bulge of D5, and the 5'-splice site), showing that all of these elements are closely colocalized. In addition, we show by nucleotide analog interference mapping (NAIM) that a specific functional group in J2/3 plays a role in first-step catalysis, which is consistent with its apparent proximity to other first-step components. These results extend our understanding of active-site architecture during the first step of group II intron self-splicing and they provide a structural basis for spliceosomal comparison.     

Competition between the ATPase Prp5 and branch region-U2 snRNA pairing modulates the fidelity of spliceosome assembly

ATPase-facilitated steps during spliceosome function have been postulated to afford opportunities for kinetic proofreading. Spliceosome assembly requires the ATPase Prp5p, whose activity might thus impact fidelity during initial intron recognition. Using alanine mutations in S. cerevisiae Prp5p, we identified a suboptimal intron whose splicing could be improved by altered Prp5p activity and then, using this intron, screened for potent prp5 mutants. These prp5 alleles specifically alter branch region selectivity, with improved splicing in vivo of suboptimal substrates correlating with reduced ATPase activity in vitro for a series of mutants in ATPase motif III (SAT). Because these effects are abrogated by compensatory U2 snRNA mutations or other changes that increase branch region-U2 pairing, these results explicitly link a fidelity event with a defined physical structure, the branch region-U2 snRNA duplex, and provide strong evidence that progression of the splicing pathway requires branch region-U2 snRNA pairing prior to Prp5p-facilitated conformational change.     

In vitro selection of RNAs with increased tertiary structure stability.

An in vitro selection system was devised to select RNAs based on their tertiary structural stability, independent of RNA activity. Selection studies were conducted on the P4-P6 domain from the Tetrahymena thermophila group I intron, an autonomous self-folding unit that contains several important tertiary folding motifs including the tetraloop receptor and the A-rich bulge. Partially randomized P4-P6 molecules were selected based on their ability to fold into compact structures using native gel electrophoresis in the presence of decreasing concentrations of MgCl2. After 10 rounds of the selection process, a number of sequence alterations were identified that stabilized the P4-P6 RNA. One of these, a single base deletion of C209 within the P4 helix, significantly stabilized the P4-P6 molecule and would not have been identified by an activity-based selection because of its essential role for ribozyme function. Additionally, the sequence analysis provided evidence that stabilization of secondary structure may contribute to overall tertiary stability for RNAs. This system for probing RNA structure irrespective of RNA activity allows analysis of RNA structure/function relationships by identifying nucleotides or motifs important for folding and then comparing them with RNA sequences required for function.     

In vivo selection of better self-splicing introns in Escherichia coli: the role of the P1 extension helix of the Tetrahymena intron

In vivo selection was used to improve the activity of the Tetrahymena pre-rRNA self-splicing intron in the context of heterologous exons. The intron was engineered into a kanamycin nucleotidyltransferase gene, with the pairing between intron bases and the 5' and 3' splice sites maintained. The initial construct failed to confer kanamycin resistance on Escherichia coli, although the pre-mRNA was active in splicing in vitro. Random mutation libraries were constructed to identify active intron variants in E. coli. All the active mutants sequenced contained mutations disrupting a base-paired region above the paired region P1 (referred to as the P1 extension region or P1ex) that involves the very 5' end of the intron. Subsequent site-directed mutagenesis confirmed that these P1ex mutations are responsible and sufficient to activate the intron splicing in E. coli. Thus, it appears that too strong of a secondary structure in the P1ex element can be inhibitory to splicing in vivo. In vitro splicing assays demonstrated that two P1ex mutant constructs splice six to eight times faster than the designed construct at 40 microM GTP concentration. The relative reaction rates of the mutant constructs compared to the original design are further increased at a lower GTP concentration. Possible mechanisms by which the disrupted P1ex structure could influence splicing rates are discussed. This study emphasizes the value of using libraries of random mutations to improve the activity of ribozymes in heterologous contexts in vivo.     

Solution structure of domain 5 of a group II intron ribozyme reveals a new RNA motif

Domain 5 (D5) is the central core of group II intron ribozymes. Many base and backbone substituents of this highly conserved hairpin participate in catalysis and are crucial for binding to other intron domains. We report the solution structures of the 34-nucleotide D5 hairpin from the group II intron ai5 gamma in the absence and presence of divalent metal ions. The bulge region of D5 adopts a novel fold, where G26 adopts a syn conformation and flips down into the major groove of helix 1, close to the major groove face of the catalytic AGC triad. The backbone near G26 is kinked, exposing the base plane of the adjacent A-U pair to the solvent and causing bases of the bulge to stack intercalatively. Metal ion titrations reveal strong Mg(2+) binding to a minor groove shelf in the D5 bulge. Another distinct metal ion-binding site is observed along the minor groove side of the catalytic triad, in a manner consistent with metal ion binding in the ribozyme active site.     

Characterization and significance of nine novel mutations in exon 16 of the neurofibromatosis type 1 (NF1) gene

Nine novel mutations have been characterized as the result of screening exon 16 of the human NF1 gene in 465 unrelated neurofibromatosis type 1 patients. These lesions include three nonsense and two missense mutations, two deletions, one duplication, and one mutation in the 5′ splice site of intron 16. Although exon 16 is the largest NF1 exon, no mutations have so far been reported in this region. This apparent paucity of lesions may be due either to a reduced functional importance of exon 16 or a screening bias or both. However, consideration of the mutability of exon 16 in comparison with other exons suggests that, at least for single base pair substitutions, no such factors need be invoked. Any previous lack of exon 16 mutations in this category would be explicable in terms of a lower propensity to mutate for codons in this gene region. Received: 1 November 1996 / Revised: 5 December 1996     

5' cleavage site in eukaryotic pre-mRNA splicing is determined by the overall 5' splice region, not by the conserved 5' GU

We have generated all possible single point mutations of the invariant 5' GT of the large beta-globin intron and determined their effect on splicing in vitro. None of the mutants prevented cleavage in the 5' splice region, but many reduced or abolished exon joining. The mutations GT----TT and GT----CT resulted in a shift of the 5' cleavage site on nucleotide upstream; in the case of the mutation GT----TT, this shift was reverted by a second site mutation within the 5' splice region. Our results suggest that the 5' cleavage site is determined not by the conserved GU sequence but by the 5' splice region as a whole, most probably via base-pairing to the 5' end of the U1 snRNA.     

Critical base substitutions that affect the splicing and/or homing activities of the group I intron bi2 of yeast mitochondria

The second intron (bi2) of the cyt b gene from related Saccharomyces species has an extraordinarily conserved sequence and can have different functions in wild-type cells. The protein encoded by the S. cerevisiae intron functions as a maturase to promote intron splicing, while the homologous S. capensis intron encodes a bifunctional protein that acts both as a maturase and as a homing endonuclease (I-ScaI) promoting intron mobility. The protein encoded by intron bi2 belongs to a large gene family characterized by the presence of two conserved LAGLIDADG motifs (P1 and P2). In this study, we analysed a set of splicing-deficient mutants of the S. cerevisiae intron bi2 that carry non-directed mutations affecting the maturase activity, and a set of directed missense mutations introduced into the bifunctional protein encoded by the S. capensis intron. Analysis of these mutations has allowed identification of the residues in the conserved P1 and P2 motifs which are crucial for splicing and homing activities. Moreover, several mutations which are located in the C-terminal part of the protein have been found to affect both functions.     

Structure of a self-splicing group II intron catalytic effector domain 5: parallels with spliceosomal U6 RNA

Domain 5 (D5) is absolutely required for all catalytic functions of group II introns. Here we describe the solution NMR structure, electrostatic calculations, and detailed magnesium ion-binding surface of D5 RNA from the Pylaiella littoralis large ribosomal RNA intron (D5-PL). The overall structure consists of a hairpin capped by a GNRA tetraloop. The stem is divided into lower and upper helices of 8 and 5 bp, respectively, separated by an internal bulge. The D5-PL internal bulge nucleotides stack into the helical junction, resulting in a coupling between the bulge A25 and the closing base pair (G8-C27) of the lower helix. Comparison of the D5-PL structure to previously reported related structures indicates that our structure is most similar, in the helical regions, to the crystal structure of D5 from yeast Ai5gamma (D5-Ai5gamma) and the NMR structure of the U6 snRNA stem-loop region. Our structure differs in many respects from both the NMR and X-ray structures of D5-Ai5gamma in the bulge region. Electrostatic calculations and NMR chemical shift perturbation analyses reveal magnesium ion-binding sites in the tetraloop, internal bulge, and the AGC triad in the lower stem. Our results suggest that the structure, electrostatic environment, and the magnesium ion-binding sites within the tetraloop, bulge, and triad regions are conserved features of the splicing machinery of both the group II introns and the spliceosome that are likely key for catalytic function.     

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.     

Position of the rearranged V kappa and its 5' flanking sequences determines the location of somatic mutations in the J kappa locus

Somatic hypermutation is known to occur in the VJ kappa exon and its flanking sequences, yet little is known about the hypermutation mechanism or its exact target within the rearranged locus. Mutations may occur at the same frequency, spanning a region from the leader intron to 3' of J kappa 5, regardless of which J is chosen for VJ rearrangement. Another possibility is that mutations may be limited to the rearranged VJ kappa and its immediate flanking sequences. To distinguish between these possibilities, the JC introns of 21 alleles with V kappa rearranged to J kappa 1 were sequenced, and mutations were located. The frequency of mutations was determined for different sections of the intron and compared with the frequencies of mutations found in the JC intron of a set of VJ kappa 5 alleles. The results showed that mutations were concentrated in and around the rearranged VJ, regardless of whether J kappa 1 or J kappa 5 was used. These data imply that the hypermutational mechanism focuses on rearranged V genes.