Processing of yeast mitochondrial RNA: involvement of intramolecular hybrids in splicing of cob intron 4 RNA by mutation and reversion

RNA processing in yeast mitochondria: characterization of mit(-) mutants disturbed in the synthesis of subunit I of cytochrome c oxidase

Mit(-) mutants disturbed in the synthesis of cytochrome c oxidase subunit I lack the mRNA for this protein and accumulate longer RNAs still containing intron sequences. We have analyzed the patterns of transcripts occurring in several such mutants in an attempt to define a pathway of processing events and to demarcate intron-sequences involved in RNA splicing. We find that processing does not follow a strictly ordered pathway and, in contrast to the situation for the cytochrome b gene, that a block in the processing of an intron does not necessarily lead to a block in the processing of introns downstream. Although in some cases, this may result from overlapping specificities of intronic-URF encoded RNA maturases, an internal start of translation on precursor RNAs seems more likely.M5-16, a mutant deleted for a large part of the central portion of the subunit I gene exhibits delayed processing and a highly simplified pattern of intermediates. The lengths of these indicate that maturation of the mRNA for subunit I involves processing, as well as splicing.

Ribozymes: recent advances in the development of RNA tools

The discovery 20 years ago that some RNA molecules, called ribozymes, are able to catalyze chemical reactions was a breakthrough in biology. Over the last two decades numerous natural RNA motifs endowed with catalytic activity have been described. They all fit within a few well-defined types that respond to a specific RNA structure. The prototype catalytic domain of each one has been engineered to generate trans-acting ribozymes that catalyze the site-specific cleavage of other RNA molecules. On the 20th anniversary of ribozyme discovery we briefly summarize the main features of the different natural catalytic RNAs. We also describe progress towards developing strategies to ensure an efficient ribozyme-based technology, dedicating special attention to the ones aimed to achieve a new generation of therapeutic agents.

Functional and sequence analysis of splicing defective nrdB mutants of bacteriophage T4 reveal new bases and a new sub-domain required for group I intron self-splicing

The nrdB gene of bacteriophage T4 codes for the small subunit of ribonucleotide reductase and contains a 598 nuclelotide group 1 self splicing intron. In order to study the functional domains for self-splicing of this intron, 23 nrdB splicing defective intron mutants were analyzed for both sequence and functional changes. These mutants cluster towards the ends in regions of conserved structural elements of the intron. These 23 mutants have single base changes at 14 different sites. Interestingly two of these sites that seemed to map within the intron are actually located on the flanking exon sequences on both sides of the intron. A high frequency (4/12) of the mutation sites are in bases not thought to be base-paired in the standard model of group I intron structure. The mutation sites in pairing regions P3, P7, P8, P9 and between P6[3'] and P7[5'] are identical to changes found in the well studied td (encoding dTMP synthase) intron. However, five new mutation sites (S61, SL1, S29, SL11, SL196 and SL126) are unique to the nrdB intron and disrupt self-splicing. A mutation (S61) in the P7.1 pairing region is especially significant because no mutations have been found in this pairing, thus defining a new sub-domain essential for RNA splicing. Like the td intron, the mutation site in P9 of the nrdB intron is a hot spot for mutations, but unlike td, the nrdB intron does not show a mutational hot spot in the P6[5'] region. Our molecular dissection of the nrdB intron also supports the P9.0 and P10 pairings that have been postulated to help form a complex tertiary structure required to give the RNA sequence its catalytic activity: particularly 3' splice site selection, cleavage and exon ligation.

A non-directed, hydroxylamine-generated suppressor mutation in the P3 pairing region of the bacteriophage T4 td intron partially restores self-splicing capability

Hydroxylamine (HA) mutagenesis of an HA-induced splicing-defective bacteriophage T4 td intron mutant with a mutation in the intron P3 RNA pairing region was used to generate pseudorevertants. Because HA can only cause GC to AT transitions, the original mutant (H104A) could not undergo true reversion, yet the compensatory mutation on the opposite side of the P3 helix, which was complementary to the original H104A mutation, could occur. A pseudorevertant was isolated that contained both the original H104A mutation and the compensatory mutation HS9. By phenotypic and molecular genetic criteria, this double mutant (H104A-HS9) was shown to be able to undergo significant RNA splicing, thus confirming the existence and functional importance of the long-range P3 pairing region in this phage intron. The second-site suppressor mutation (HS9) was isolated by phage cross and also exhibited some self-splicing ability. A correlation exists between the strength of P3 helix Watson-Crick base pairing and the apparent level of splicing when wild-type, H104A, HS9, and H104A-HS9 are compared. This suggests that the primary role of the P3 RNA pairing region in the T4 td intron is structural in contributing to the critical RNA secondary structure.

A self-splicing group I intron in the nuclear pre-rRNA of the green alga, Ankistrodesmus stipitatus

The nuclear small subunit ribosomal RNA gene of the unicellular green alga Ankistrodesmus stipitatus contains a group I intron, the first of its kind to be found in the nucleus of a member of the plant kingdom. The intron RNA closely resembles the group I intron found in the large subunit rRNA precursor of Tetrahymena thermophila, differing by only eight nucleotides of 48 in the catalytic core and having the same peripheral secondary structure elements. The Ankistrodesmus RNA self-splices in vitro, yielding the typical group I intron splicing intermediates and products. Unlike the Tetrahymena intron, however, splicing is accelerated by high concentrations of monovalent cations and is rate-limited by the exon ligation step. This system provides an opportunity to understand how limited changes in intron sequence and structure alter the properties of an RNA catalytic center.

Novel hybrid maturases in unstable pseudorevertants of maturaseless mutants of yeast mitochondrial DNA

Unstable pseudorevertants of mitochondrial mutants of Saccharomyces cerevisiae lacking the maturase function encoded by the fourth intron of the cytochrome b gene (bI4) were isolated. They were found to be heteroplasmic cells owing their regained ability to respire (and grow on glycerol medium) to the presence of a rearranged (rho-) mtDNA that contains an in-frame fusion of the reading frames of the group I introns bI4 and intron 4 alpha of the coxl gene encoding subunit I of cytochrome c oxidase (aI4 alpha). The products of those gene fusions suppress the bI4 maturase deficiency still present in those heteroplasmic cells. Similar heteroplasmic pseudorevertants of a group II maturaseless mutant of the first intron of the coxI gene were characterized; they result from partial deletion of the coxI gene that fuses the reading frames of introns 1 and 2. These heteroplasms provide independent support for the existence of RNA maturases encoded by group I and group II introns. Also, since the petite/mit- heteroplasms arise spontaneously at very high frequencies they provide a system that can be used to obtain mutants unable to form or maintain heteroplasmic cells.

Compensatory mutations demonstrate that P8 and P6 are RNA secondary structure elements important for processing of a group I intron

Compensatory mutations have been constructed which demonstrate that P8 and P6, two of nine proposed base-pairing interactions characteristic of group I introns, exist within the folded structure of the Tetrahymena thermophila rRNA intervening sequence, and that these secondary structure elements are important for splicing in E. coli and self-splicing in vitro. Two-base mutations in the 5' and 3' segments of P8 are predicted to disrupt P8 and a strong splicing-defective phenotype is observed in each case. A compensatory four-base mutation in P8 is predicted to restore pairing, and results in the restoration of splicing activity to nearly wild type levels. Thus, we conclude that P8 exists and is essential for splicing. In contrast to the strong phenotypes generally exhibited by mutations which disrupt RNA secondary structure, a two-base mutation in L8, the loop between P8[5'] and P8[3'], results in only a slight decrease in splicing activity. We also tested P6, a pairing which is proposed to consist of only two base-pairs in this intron. A two-base mutation in P6[3'] reduces splicing activity to a greater extent than does a two-base mutation in P6[5']. Comparison of the activities of these mutants and a compensatory P6 four-base mutant support the existence of P6, and suggest that the P6 pairing may be particularly important in the exon ligation step of splicing.

Genetic methods for identification and characterization of RNA-RNA and RNA-protein interactions

Two general strategies using pseudorevertants have been useful in identifying RNA-RNA and RNA-protein interactions, direct synthesis of compensatory changes to test models or in vivo selection of suppressors. The most successful application of these approaches has been in the elucidation of RNA-RNA interactions, in a large part because the rules for RNA base pairing are, at least partially, understood. Beyond the initial identification of interactions, suppressors also provide important starting points for further analysis. In the case of an unknown gene product (i.e., the RNA16 gene product), the suppressor provides a route to cloning and analysis of the gene. In addition, the construction of a specific suppressor in a RNA molecule can provide a starting point for the dissection of the biogenesis and function of that RNA. This aspect is most important when the RNA in question normally provides an essential cellular role or is encoded by a multigene family. For example, the construction of a message-specific 16 S RNA in Escherichia coli should, in principle, allow for a genetic dissection of rRNA biogenesis and function.

Molecular genetics of group I introns: RNA structures and protein factors required for splicing--a review

In vivo and in vitro genetic techniques have been widely used to investigate the structure-function relationships and requirements for splicing of group-I introns. Analyses of group-I introns from extremely diverse genetic systems, including fungal mitochondria, protozoan nuclei, and bacteriophages, have yielded results which are complementary and highly consistent. In vivo genetic studies of fungal mitochondrial systems have served to identify cis-acting sequences within mitochondrial introns, and trans-acting protein products of mitochondrial and nuclear genes which are important for splicing, and to show that some mitochondrial introns are mobile genetic elements. In vitro genetic studies of the self-splicing intron within the Tetrahymena thermophila nuclear large ribosomal RNA precursor (Tetrahymena LSU intron) have been used to examine essential and nonessential RNA sequences and structures in RNA-catalyzed splicing. In vivo and in vitro genetic analysis of the intron within the bacteriophage T4 td gene has permitted the detailed examination of mutant phenotypes by analyzing splicing in vivo and self-splicing in vitro. The genetic studies combined with phylogenetic analysis of intron structure based on comparative nucleotide sequence data [Cech 73 (1988) 259-271] and with biochemical data obtained from in vitro splicing experiments have resulted in significant advances in understanding the biology and chemistry of group-I introns.

Autocatalytic activities of intron 5 of the cob gene of yeast mitochondria

The terminal intron of the mitochondrial cob gene of Saccharomyces cerevisiae can undergo autocatalytic splicing in vitro. Efficient splicing of this intron required a high concentration of monovalent ion (1 M). We found that at a high salt concentration this intron was very active and performed many of the reactions described for other group I introns. The rate of the splicing reaction was dependent on the choice of the monovalent ion; the reaction intermediate, the intron-3' exon molecule, accumulated in NH4Cl but not in KCl. In addition, the intron was more reactive in KCl, accumulating in two different circular forms: one cyclized at the 5' intron boundary and the other at 236 nucleotides from the 5' end. These circular forms were able to undergo the opening and recyclization reactions previously described for the Tetrahymena rRNA intron. Cleavage of the 5' exon-intron boundary by the addition of GTP did not require the 3' terminus of the intron and the downstream exon. An anomalous guanosine addition at the 3' exon and at the middle of the intron was also detected. Hence, this intron, which requires a functional protein to splice in vivo, demonstrated a full spectrum of characteristic reactions in the absence of proteins.

Selection of cryptic 5' splice sites by group II intron RNAs in vitro

Recognition of 5' splice points by group I and group II self-splicing introns involves the interaction of exon sequences--directly preceding the 5' splice site--with intronic sequence elements. We show here that the exon binding sequences (EBS) of group II intron aI5c can accept various substitutes of the authentic intron binding sites (IBS) provided in cis or in trans. The efficiency of cleavages at these cryptic 5' splice sites was enhanced by deletion of the authentic IBS2 element. All cryptic 5' cleavage sites studied here were preceded by an IBS1 like sequence; indicating that the IBS1/EBS1 pairing alone is sufficient for proper 5' splice site selection by the intronic EBS element. The results are discussed in terms of minimal requirements for 5' cleavages and position effects of IBS sites relative to the intron.

Autocatalytic activities of intron 5 of the cob gene of yeast mitochondria

The terminal intron of the mitochondrial cob gene of Saccharomyces cerevisiae can undergo autocatalytic splicing in vitro. Efficient splicing of this intron required a high concentration of monovalent ion (1 M). We found that at a high salt concentration this intron was very active and performed many of the reactions described for other group I introns. The rate of the splicing reaction was dependent on the choice of the monovalent ion; the reaction intermediate, the intron-3' exon molecule, accumulated in NH4Cl but not in KCl. In addition, the intron was more reactive in KCl, accumulating in two different circular forms: one cyclized at the 5' intron boundary and the other at 236 nucleotides from the 5' end. These circular forms were able to undergo the opening and recyclization reactions previously described for the Tetrahymena rRNA intron. Cleavage of the 5' exon-intron boundary by the addition of GTP did not require the 3' terminus of the intron and the downstream exon. An anomalous guanosine addition at the 3' exon and at the middle of the intron was also detected. Hence, this intron, which requires a functional protein to splice in vivo, demonstrated a full spectrum of characteristic reactions in the absence of proteins.

RNA splicing in yeast mitochondria: DNA sequence analysis of mit- mutants deficient in the excision of introns aI1 and aI2 of the gene for subunit I of cytochrome c oxidase

We have characterized two yeast mutants deficient in the splicing of transcripts of the mitochondrial gene for cytochrome c oxidase subunit I (coxI). Both map to the first intron (aI1). RNA blot analysis shows that in addition to a reduced (mutant M15-190) or blocked (mutant M12-193) excision of the mutated intron aI1, the mutants are unable to excise the adjacent aI2 intron, the reading frame of which displays an amino acid sequence similarity to aI1. Splicing of the downstream introns is not affected, however. Sequence analysis of the first mutant DNA (M12-193) reveals a premature termination of the intron-encoded open reading frame, followed by two alterations at a short distance downstream. The other (M15-190) contains 11 separate changes. Although these occur in the intron reading frame, their main effect on RNA splicing may be exerted through the disturbance of intron secondary structure proposed for the 5' end of several group II introns. The implications of these findings in relation to maturase function and structure of intron aI1 are discussed.

Structural conventions for group I introns

Conventions for nomenclature of structural elements and a standard secondary structure representation for group I introns have been established by workers in the field. These conventions are designed to facilitate effective communication of information concerning the structure and function of these self-splicing introns.

Self-cleaving transcripts of satellite DNA from the newt

Satellite 2 of the newt, Notophthalmus viridescens, is a 330 bp tandemly repeated sequence scattered throughout the genome. Cytoplasmic transcripts homologous to satellite 2 are found in a variety of tissues. Most of the transcripts correspond precisely in length to the DNA repeat unit or to whole multiples of that repeat. We show here that dimer-sized satellite 2 transcripts, synthesized with SP6 RNA polymerase from a plasmid clone, undergo site-specific, self-catalyzed cleavage in vitro. The reaction proceeds at neutral pH and requires Mg++ but no other cofactor or energy source. The cleavage products have 5'-hydroxyl and 3'-phosphate groups, at least some of which are in the form of 2',3'-cyclic phosphates. In this respect the reaction resembles the self-cleavage of certain small, infectious RNAs found in plants. Furthermore, the in vitro cleavage of satellite 2 transcripts occurs within a sequence that is homologous to the conserved cleavage site of the infectious RNAs. The existence of monomer and multimer transcripts in the cell suggests that the monomer may arise by site-specific cleavage of long primary transcripts. However, the 5' end of the cellular monomer is 46 or 47 bases upstream of the in vitro cleavage site, suggesting that factors in the cell may modify the cleavage reaction.

Three class I introns in the ND4L/ND5 transcriptional unit of Neurospora crassa mitochondria

The overlapping ND4L and ND5 genes of Neurospora crassa mitochondria are interrupted by one and two intervening sequences, respectively, of about 1,490, 1,408 and 1,135 bp in length. All three intervening sequences are class I introns and as such have the potential to fold into the conserved secondary structure that has been proposed for the majority of fungal mitochondrial introns. They contain long open reading frames (ORFs; from 306 to 425 codons long) that are continuous and in frame with the upstream exon sequences. These ORFs contain the conserved decapeptide-encoding sequences that are characteristic of the ORFs present in most class I introns. Extensive homology exists among the ORFs encoded by the ND4L intron, ND5 intron 1, and the second intron of the N. crassa oli2 gene. Also, internal repeats of about 130 amino acid residues are present twice in each of these three ORFs, suggesting that a duplication event may have occurred in the formation of these ORFs. The ND4L intron shares extensive homology (at the levels of both primary and proposed secondary structures) with the self-splicing intervening sequence present in the Tetrahymena nuclear rRNA gene. This homology includes but is not limited to the core secondary structure, as peripheral structural elements are also conserved in the two introns.

Two domains for splicing in the intron of the phage T4 thymidylate synthase (td) gene established by nondirected mutagenesis

Of 97 nondirected T4 thymidylate synthase-defective (td) mutations, 27 were mapped to the intron of the split td gene. Clustering of these intron mutations defined two domains that are functional in splicing, each within approximately 220 residues of the respective splice sites. Two selected mutations, tdN57 and tdN47, fell within phylogenetically conserved pairings, with tdN57 disrupting the exon I-internal guide pairing (P1) in the 5' domain and tdN47 destabilizing the P9 helix in the 3' domain. A splicing assay with synthetic oligonucleotides complementary to RNA junction sequences revealed processing defects for T4tdN57 and T4tdN47, both of which are impaired in cleavage at the 5' and 3' splice sites. Thus prokaryotic genetics facilitates association of specific residue changes with their consequences to splicing.

The chloroplast tRNALys(UUU) gene from mustard (Sinapis alba) contains a class II intron potentially coding for a maturase-related polypeptide

The trnK gene endocing the tRNALys(UUU) has been located on mustard (Sinapis alba) chloroplast DNA, 263 bp upstream of the psbA gene on the same strand. The nucleotide sequence of the trnK gene and its flanking regions as well as the putative transcription start and termination sites are shown. The 5' end of the transcript lies 121 bp upstream of the 5' tRNA coding region and is preceded by procaryotic-type "-10" and "-35" sequence elements, while the 3' end maps 2.77 kb downstream to a DNA region with possible stemloop secondary structure. The anticodon loop of the tRNALys is interrupted by a 2,574 bp intron containing a long open reading frame, which codes for 524 amino acids. Based on conserved stem and loop structures, this intron has characteristic features of a class II intron. A region near the carboxyl terminus of the derived polypeptide appears structurally related to maturases.

Compensatory mutations suggest that base-pairing with a small nuclear RNA is required to form the 3' end of H3 messenger RNA

Processing of the 3' end of sea urchin H3 histone pre-mRNA requires conserved sequence elements and the presence of U7 snRNA. A mutation in the conserved CAAGAAGA sequence of the H3 pre-mRNA that renders 3' processing of this precursor defective is shown to be suppressed by a compensatory change in the U7 snRNA, restoring the base-pairing potential of the two RNAs. RNA-RNA contacts between these two molecules appear to be an essential feature of the 3' processing reaction.

Viroids and virusoids are related to group I introns

Group I introns are found in nuclear rRNA genes, mitochondrial mRNA and rRNA genes, and chloroplast tRNA genes. The hallmarks of this intron class are a 16-nucleotide consensus sequence and three sets of complementary sequences. The viroids (circular pathogenic plant RNAs) and the virusoids (plant satellite RNAs) also contain the consensus sequence and the three sets of complementary bases. Pairing of the complementary bases would generate a viroid structure resembling a group I intron, which might be stabilized in vivo through interactions with proteins. The Tetrahymena self-splicing rRNA intron further has sequences homologous with regions of potato spindle tuber viroid associated with the severity of viroid symptoms.

Self-splicing of group II introns in vitro: mapping of the branch point and mutational inhibition of lariat formation

Group II intron bl1 from yeast mitochondria can undergo self-splicing in vitro. Exons become correctly ligated, and the excised intron has a lariat structure similar to that of introns from nuclear mRNA. The branch point of the bl1 lariat is located eight or nine nucleotides upstream of the 3' end of the intron and is part of a hairpin structure that is well conserved among group II introns. Several mutations next to the branch point and in other parts of the core structure of group II introns are shown to affect lariat formation. One of them, carried by strain M4873, abolishes splicing in vivo and in vitro, apparently by changing the architecture of the hairpin structure containing the branch point. Similarities between group II introns and nuclear pre-mRNA introns are discussed in terms of evolutionary relatedness.

Role of conserved sequence elements 9L and 2 in self-splicing of the Tetrahymena ribosomal RNA precursor

Oligonucleotide-directed mutagenesis has been used to alter highly conserved sequences within the intervening sequence (IVS) of the Tetrahymena large ribosomal RNA precursor. Mutations within either sequence element 9L or element 2 eliminate splicing activity under standard in vitro splicing conditions. A double mutant with compensatory base changes in elements 9L and 2 has accurate splicing activity restored. Thus, the targeted nucleotides of elements 9L and 2 base-pair with one another in the IVS RNA, and pairing is important for self-splicing. Mutant splicing activities are restored by increased magnesium ion concentrations, supporting the conclusion that the role of the targeted bases in splicing is primarily structural. Based on the temperature dependence, we propose that a conformational switch involving pairing and unpairing of elements 9L and 2 is required for splicing.

Relationship of viroids and certain other plant pathogenic nucleic acids to group I and II introns

The nucleotide sequences of viroids contain features believed to be essential for the splicing of group I introns. Common sequence elements include a 16-nucleotide consensus sequence and three pairs of short sequences arranged in the same sequential order in both types of RNAs. The calculated probability of finding sequences resembling the 16-nucleotide consensus sequence in random nucleotide chains showed that at low fidelity (up to 5 mismatched nucleotides), the number of such sequences in viroids, plant viral satellite RNAs, plant viral RNAs and one plant viral DNA, group I introns and flanking exons does not significantly differ from the number expected at random. As the degree of fidelity is increased, the number in both introns and viroids, but not in exons or the other plant pathogens examined, greatly exceeds that expected in random chains. These findings suggest that viroids may have evolved from group I introns and/or that processing of viroid oligomers to monomers may have structural requirements similar to those of group I introns. The nucleotide sequences of viroids do not show close homology with two conserved regions of group II introns, the 14-base pair consensus region and the 5' terminal segment. However, close homology does exist between the conserved sequence of the 3' terminal segment of group II introns and viroids thus suggesting a possible evolutionary or functional relationship.

Formation of lariats and circles in self-splicing of the precursor to the large ribosomal RNA of yeast mitochondria

Self-splicing of the precursor to large ribosomal RNA of yeast mitochondria leads not only to circles but also to lariats, structures that have not been observed before as products of self-splicing. Lariats were studied by electron microscopy after hybridization with an RNA complementary to the 3' half of the precursor. This leads to differentiation in at least two classes of lariats that vary in the position of the branch point. In all lariats the tail carries the 3' end, which suggests that a 5' end is used for branch formation with an internal nucleotide. The circles are formed from excised introns. They lack only three nucleotides encoded by mitochondrial DNA along with the 5'-terminal G added in the course of self-splicing. The diverse number of self-splicing products arising in vitro testifies to the considerable reactivity of this intron. The formation of lariats in an RNA catalyzed reaction may have implications for views on the mechanism of splicing of nuclear pre-mRNAs.

The mosaic cox1 gene in the mitochondrial genome of Schizosaccharomyces pombe: minimal structural requirements and evolution of group I introns

The gene encoding subunit 1 of cytochrome oxidase (cox1) in the fission yeast Schizosaccharomyces pombe is polymorphic. In strain 50 it contains two group I introns with open reading frames (ORFs) in phase with the upstream exons (Lang, 1984). In strain EF1 two additional very short group I introns which do not possess ORFs were detected by DNA sequencing. These two introns (AI2a and AI3) share distinct characteristics concerning their nucleotide sequence and secondary structure and are located at identical positions as the introns AI4 and AI5 beta, respectively, in the cox1 gene of Saccharomyces cerevisiae. The sequence homology of the cob and cox1 genes around the splice points of introns AI2a, AI4, and BI4 (cob intron 4) might reflect horizontal gene transfer between the distantly related species S. pombe and S. cerevisiae.

Control of cell growth and division in Saccharomyces cerevisiae

Considerable advances have been made in recent years in our understanding of the biochemistry of protein and nucleic acid synthesis and, particularly, the molecular biology of gene expression in eukaryotes. The yeast Saccharomyces cerevisiae, and to a lesser extent Schizosaccharomyces pombe, has had a preeminent role as a focus for these studies, principally because of the facility with which these organisms can be experimentally manipulated biochemically and genetically. This review will be designed to critically examine and integrate recent advances in several vital areas of regulatory control of enzyme synthesis in yeast: structure and organization of DNA, transcriptional regulation, post-transcriptional modification, control of translation, post-translational modification and secretion, and cell-cycle modulation. It will attempt to emphasize and illustrate, where detailed information is available, principal underlying molecular mechanisms, and it will attempt to make relevant comparisons of this material to inferred and demonstrated facets of regulatory control of enzyme and protein synthesis in higher eukaryotes.

Sequence analysis of the pyr-4 (orotidine 5'-P decarboxylase) gene of Neurospora crassa

The pyr-4 gene of Neurospora crassa encodes orotidine-5' -phosphate decarboxylase, which catalyses the sixth step in the pyrimidine biosynthetic pathway. The complete nucleotide sequence of a 1.8-kb genomic fragment containing the pyr-4 gene has been determined. Using transposon mutagenesis, the coding region has been identified, and the amino acid (aa) sequence deduced. Comparison of the pyr-4 aa sequence with URA3, the equivalent gene of Saccharomyces cerevisiae, showed extensive blocks of homology, with non-homologous sequences between these blocks being generally much longer in Neurospora than in yeast. Computer-predicted protein secondary structure of pyr-4 and URA3 was conserved within equivalent blocks. Upstream sequences of pyr-4 were compared with other sequenced Neurospora genes and possible promoter sequences identified.

Mitochondrial class II introns encode proteins related to the reverse transcriptases of retroviruses

Organelle introns share several distinctive features that set them apart from their counterparts in nuclear-encoded pre-messenger RNAs (reviewed in ref. 1): their termini do not obey the GU...AG rule; the introns are 'structured' (members of the same family or 'class' can theoretically adopt very similar RNA secondary conformations and several of the postulated pairings have been confirmed by studies of splicing mutants and their revertants (see, for example, ref. 4); many introns from both classes contain long open reading frames. We report here that the proteins potentially encoded by four class II introns are related to several RNA-dependent polymerases of viral and transposable element origins.

Coupling of Tetrahymena ribosomal RNA splicing to beta-galactosidase expression in Escherichia coli

Splicing of the Tetrahymena ribosomal RNA precursor is mediated by the folded structure of the RNA molecule and therefore occurs in the absence of any protein in vitro. The Tetrahymena intervening sequence (IVS) has been inserted into the gene for the alpha-donor fragment of beta-galactosidase in a recombinant plasmid. Production of functional beta-galactosidase is dependent on RNA splicing in vivo in Escherichia coli. Thus RNA self-splicing can occur at a rate sufficient to support gene expression in a prokaryote, despite the likely presence of ribosomes on the nascent RNA. The beta-galactosidase messenger RNA splicing system provides a useful method for screening for splicing-defective mutations, several of which have been characterized.

Nucleotide sequence of the satellite of peanut stunt virus reveals structural homologies with viroids and certain nuclear and mitochondrial introns

Peanut stunt virus-associated RNA 5 (PARNA 5), the satellite of a plant cucumovirus, is a linear RNA of 393 nucleotides with a 5' cap and a 3' hydroxyl group. Determination of its nucleotide sequence has revealed two consecutive open reading frames that together extend most of its length. Sequences at the 5' and 3' ends are homologous with those of the satellite of the related cucumber mosaic virus, and the double-stranded forms of both satellites contain an unpaired guanosine at the 3' end of the minus strand. However, little other homology exists between the two satellites. In contrast, PARNA 5 has several regions of 90% sequence homology with various plant viroids, including sequences of the conserved central region of most viroids. Such homologies suggest a common origin with viroids coupled with specific adaptation as a linear RNA. The presence within PARNA 5 of conserved intron sequences essential to proper RNA processing suggests a possible origin from plant introns and/or involvement of such sequences in the processing of PARNA 5 multimers to monomers at some stage of replication.

Sequence requirements for self-splicing of the Tetrahymena thermophila pre-ribosomal RNA

The sequence requirements for splicing of the Tetrahymena pre-rRNA have been examined by altering the rRNA gene to produce versions that contain insertions and deletions within the intervening sequence (IVS). The altered genes were transcribed and the RNA tested for self-splicing in vitro. A number of insertions (8-54 nucleotides) at three locations had no effect on self-splicing activity. Two of these insertions, located at a site 5 nucleotides preceding the 3'-end of the IVS, did not alter the choice of the 3' splice site. Thus the 3' splice site is not chosen by its distance from a fixed point within the IVS. Analysis of deletions constructed at two sites revealed two structures, a hairpin loop and a stem-loop, that are entirely dispensable for IVS excision in vitro. Three other regions were found to be necessary. The regions that are important for self-splicing are not restricted to the conserved sequence elements that define this class of intervening sequences. The requirement for structures within the IVS for pre-rRNA splicing is in sharp contrast to the very limited role of IVS structure in nuclear pre-mRNA splicing.

Secondary structure of the circular form of the Tetrahymena rRNA intervening sequence: a technique for RNA structure analysis using chemical probes and reverse transcriptase

The structure of the intervening sequence (IVS) of the Tetrahymena rRNA precursor mediates cleavage-ligation reactions that result in pre-rRNA splicing and IVS cyclization. We have developed a method for RNA structure analysis and applied it to the circular form of the IVS RNA. The native RNA was treated with dimethyl sulfate or diethyl pyrocarbonate to modify bases not involved in secondary or tertiary interactions. The RNA was then used as a template for reverse transcription. Elongation of synthetic oligodeoxynucleotide primers was found to stop (or pause) one nucleotide prior to 1-methyladenosine, 3-methylcytidine, and 7-ethoxycarbonyladenosine residues. The detection of 1-methyladenosine is particularly useful for locating single-stranded regions. After chemical cleavage of the RNA, 7-methylguanosine also could be detected. In general, the sites of modification were consistent with a previous model of the secondary structure of the linear form of the IVS RNA, a model based on enzymatic cleavage data, free energy calculations, and phylogenetic comparison. Thus, IVS RNA autocyclization does not involve major rearrangements of the secondary structure, although there is evidence for a conformational change in one region of the molecule. The methods described here should be of general use for obtaining information about structure far from the ends of RNA molecules.

Role of intron-contained sequences in formation of moloney murine leukemia virus env mRNA

Formation of the Moloney murine leukemia virus envelope mRNA involves the removal of a 5,185-base pair-long intron. Deletion analysis of two Moloney murine leukemia virus-derived expression vectors revealed the existence of two short regions within the viral intron which are required for the efficient formation of the spliced RNA species. One region was present upstream from the 3' splice junction, extended at least 85 nucleotides beyond the splice site, and was not more than 165 nucleotides long. As yeast polymerase II introns, the Moloney murine leukemia virus intron contains the sequence 5'-TACTAAC-3' 15 nucleotides upstream from the 3' splice site. A second region located in the middle of the intron, within a 560-nucleotide-long sequence, was also essential for formation of the spliced RNA species. The efficient splicing of the env mRNA in the absence of expression of viral genes raises the possibility that similar mechanisms are used to remove introns of (some) cellular genes.

RNA splicing in neurospora mitochondria: self-splicing of a mitochondrial intron in vitro

We have used Neurospora nuclear mutant cyt-18-1, which accumulates a number of unspliced mitochondrial precursor RNAs, to identify rapidly mitochondrial introns that are self-splicing in vitro. Incubation of deproteinized whole mitochondrial RNA from the mutant with 32P-GTP resulted in strong labeling of a 1.3 kb RNA, subsequently identified as cytochrome b (cob) intron 1, and weaker labeling of additional RNAs. Self-splicing of cob intron 1, including precise cleavage and ligation, was confirmed using an in vitro transcript synthesized from the SP6 promoter. The in vitro splicing reaction was shown to be analogous to that for the Tetrahymena nuclear rRNA intron. Since splicing of cob intron 1 is inhibited in a recessive nuclear mutant, we infer that this essentially RNA-catalyzed splicing reaction must be facilitated by a protein in vivo.

Leakiness of termination codons in mitochondrial mutants of the yeast Saccharomyces cerevisiae

Seven mutants in exon 1 of the mitochondrial cob gene in yeast are described with respect to their translation products, RNA pattern, and deoxyribonucleotide sequence alteration(s). Sequence analysis of the mutations, which previously were shown to cause premature termination of apocytochrome b, revealed that two of them directly transform sense codons to chain-termination codons, whereas the other four are frame-shift mutations (+1/-1, insertions/deletions). Only the latter mutants are found to be leaky in that (a) RNA splicing occurs, and (b) in three of them, to a minor degree an apocytochrome b homologue is synthesized, which, however, does not lead to respiratory competence. Both require translation through exon 1 into downstream introns to produce 'RNA maturases' necessary for splicing the primary transcript (Lazowska et al. 1980; Weiss-Brummer et al. 1982). These and other previously published data show that mitochondrial frame-shift mutants tend to be leaky to a variable degree. Several possible mechanisms of 'frame-shift suppression' are discussed.

Role of intron-contained sequences in formation of moloney murine leukemia virus env mRNA

Formation of the Moloney murine leukemia virus envelope mRNA involves the removal of a 5,185-base pair-long intron. Deletion analysis of two Moloney murine leukemia virus-derived expression vectors revealed the existence of two short regions within the viral intron which are required for the efficient formation of the spliced RNA species. One region was present upstream from the 3' splice junction, extended at least 85 nucleotides beyond the splice site, and was not more than 165 nucleotides long. As yeast polymerase II introns, the Moloney murine leukemia virus intron contains the sequence 5'-TACTAAC-3' 15 nucleotides upstream from the 3' splice site. A second region located in the middle of the intron, within a 560-nucleotide-long sequence, was also essential for formation of the spliced RNA species. The efficient splicing of the env mRNA in the absence of expression of viral genes raises the possibility that similar mechanisms are used to remove introns of (some) cellular genes.

Two intervening sequences in the ATPase subunit 6 gene of Neurospora crassa. A short intron (93 base-pairs) and a long intron that is stable after excision

A 3590 base-pair region of the mitochondrial genome of Neurospora crassa, including the gene for ATPase subunit 6 (oli2), has been sequenced. The oli2 gene is interrupted by two intervening sequences. The first intron, situated after the third codon of the gene, is 93 base-pairs long; two-thirds of this intron consist of a palindromic sequence. The second intron is 1370 base-pairs long and contains an extended open reading frame that is continuous and in frame with the upstream exon sequence. This intron has structural homology with most other fungal mitochondrial introns. Transcript analysis has yielded a complex pattern of RNA species and demonstrated that the second intron is quite stable after excision. An unknown reading frame (homologous to reading frames of other mitochondrial genomes) is located 1000 base-pairs upstream from the oli2 coding sequence.

Cytochrome b of cob revertants in yeast. 1. Isolation and characterization of revertants derived from cob exon mutants of Saccharomyces cerevisiae

About 300 revertants were derived from 44 cob- mutants, mapping in the structure coding regions (exon 1, 3, 4, 5, or 6) of the mitochondrial apocytochrome b gene in Saccharomyces cerevisiae, strain 777-3A. Most of the revertants could not be distinguished from the wild-type by means of physiological properties. Twenty-two revertants different in phenotype are described here in more detail. The suppressor mutations (supa) that compensate the primary cob- mutations (i.e., restore growth on glycerol) are mitochondrially inherited. They were localized in the same cob exon regions as the respective primary mutations, except for one revertant with a primary mutation in exon 6 and a suppressor, 4.2 map units distant, which may be located either in intron 5 or downstream in exon 6. Of 21 suppressors 17 are closely coupled to the primary mutation with recombination frequencies of less than or equal to 0.1%-0.3%. An estimate predicts that in more than 80% of these revertants only one amino acid is altered at that point of the polypeptide corresponding to the cob- site in the gene. The most interesting revertant phenotypes are: reduced growth rate on glycerol. The respective cob-/supa mutations are scattered over the whole cob region and cannot be correlated exclusively with special gene regions. decreased cytochrome b content. The most extreme reductions (28% and 30% of wild-type level) were observed to be due to mutations located in the 5' proximal part of exon 1. The highest percentage of revertants with decreased cytochrome b content was predominantly found mapping in exon 3.(ABSTRACT TRUNCATED AT 250 WORDS)

Interaction between mitochondrial genes in yeast: evidence for novel box effect(s)

The effects of mutations have been studied within the apocytochrome b gene on the processing of transcripts from the gene for subunit 1 of cytochrome c oxidase (coxI). Most mutations which affect the expression of the reading frame encoded by the fourth intron of the apocytochrome b gene (bI4) result in a failure to remove intron aI4 from precursor transcripts of coxI. Mutations in other apocytochrome b introns result in additional and complex defects in the processing of subunit I transcripts. Mutants M1233 and M1282 are mutated within the second intron (bI2) of the apocytochrome b gene and have OXI3 transcripts of 4900, 6100, and 6500 nucleotides. These transcripts are absent from the wild-type strain and do not hybridize with all exon sequences of this gene. In mutant M1392 (mutated within the third intron of the apocytochrome b gene), two OXI3 transcripts of 2200 and 2800 nucleotides are present which hybridize only with sequences downstream of the fifth exon of this gene (A5 alpha). We propose that all these transcripts result from distinctive cut-no-splice events, occurring at different intron-exon borders of OXI3 pre-RNAs depending on the mutational site within the apocytochrome b gene. The box9 mutant M4458 and the box7 mutant M1431 lack detectable 18S mRNA for subunit I of cytochrome c oxidase. The box9 mutants M4751 and M4701 contain reduced amounts of this mRNA. The fact that these loci complement each other (B. Weiss-Brummer, G. Rödel, R.J. Schweyen, and F. Kaudewitz (1982) Cell 29, 527-536), therefore, suggests that mutations within the different functional domains of bI4 lead to different defects in the processing of OXI3 transcripts. This, together with the defects observed in bI2 and bI3 mutants, implies that the box effect (i.e., the interaction between these two split genes) is not mediated by the box7 element alone. The possibility is discussed that mutated apocytochrome b intronic reading frame products lead to these aberrant events in the processing of transcripts of the gene for subunit I of cytochrome c oxidase.

Assessment of a model for intron RNA secondary structure relevant to RNA self-splicing--a review

A widespread class of introns is characterized by a particular RNA secondary structure, based upon four conserved nucleotide sequences. Among such "class I" introns are found the majority of introns in fungal mitochondrial genes and the self-splicing intron of the large ribosomal RNA of several species of Tetrahymena. A model of the RNA secondary structure, which must underlie the self-splicing activity, is here evaluated in the light of data on 16 further introns. The main body or "core structure" of the intron always consists of the base-paired regions P3 to P9 with the associated single-stranded loops, with P2 present also in most cases. Two minority sub-classes of core structure occur, one of which is typical of introns in fungal ribosomal RNA. Introns in which the core structure is close to the 5' splice site all have an internal guide sequence (IGS) which can pair with exon sequences adjacent to the 5' and 3' splice sites to align them precisely, as proposed by Davies et al. [Nature 300 (1982) 719-724]. In these cases, the internal guide model allows us to predict correctly the exact location of splice sites. All other introns probably use other mechanisms of alignment. This analysis provides strong support for the RNA splicing model which we have developed.

Nucleotide substitutions in a yeast mitochondria cis-acting mutant located in the last intron of the apocytochrome b gene

The region of mitochondrial DNA corresponding to the intron mutant M6-200 in Saccharomyces cerevisiae D273-10B has been isolated, and the nucleotide sequence of a 519 bp RsaI fragment has been determined. Three nucleotide substitutions were found at nucleotides +2650 (G----T), +2668 (G----A) and +2798 (A----G), all within the genetically defined location in the gene. Particular significance can be attributed to the first two changes (+2650 and +2668), that can be genetically isolated from the third substitution and, in addition, alter conserved sequence features detected in a study [(1982) Biochimie 64, 867-881] of fungal mitochondrial introns.

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).