Mutagenesis and comparative sequence analysis of a base triple joining the two domains of group I ribozymes.

Tertiary interactions are important in the higher-order folding of catalytic RNAs. Recently, a base triple, joining the two major domains of the catalytic core, was determined in group I introns from the cyanobacterium Anabaena PCC7120 and the eukaryote Tetrahymena thermophila. This base triple involves the fifth base pair of P4 and the fifth base of the single-stranded region J8/7. We made base pair and single-nucleotide substitutions in the fifth base pair of P4, a G-C in the wild-type Anabaena intron, and tested them for self-splicing activity. The results suggest a hydrogen bonding model in which only the C of the base pair interacts directly with the fifth base of J8/7. Comparative sequence analysis was used to determine the different combinations of base triples that occur in approximately 450 natural group I introns identified to date. About 94% of the base triples analyzed are compatible with the proposed hydrogen bonding model. Disrupting this base triple in the Tetrahymena intron resulted in the disappearance of splicing intermediates (intron 3' exon and 5' exon), even though the first step of splicing was not affected. Restoration of the base triple by a compensatory mutation reverted the intermediates to wild-type levels. These results suggest that disruption of the base triple increases the rate of the second step of splicing or of a conformational change preceding the second step. Repositioning of the base triple to form a new set of interactions may be required for the second step of splicing.     

Locus-dependent profiles of the rescue of nonexcitable behavioral mutants during conjugation in Tetrahymena thermophila.

The Tetrahymena nonreversal (TNR) mutants of Tetrahymena thermophila are behavioral mutants with nonexcitable membranes. When cells of the tnrB mutant were mated with wild type, a phenotypic change occurred about 1 h after pair formation. The pairs began to lose their heterotypic character in stimulation solution containing high potassium and, within 1 1/2 h, they were not distinguishable from the wild-type homotypic pairs. On the contrary, although pairs of the tnrA and wild type also lost their heterotypic character about 1 1/2 h after pair formation, they never showed a full response as wild-type homotypic pairs. When tnrA was mated with tnrB, more than 50% of pairs expressed a heterotypic pair character 2 h after pair formation, consistent with the tnrB defect having been rescued but not the tnrA defect. Thus, conjugation rescue of the mutant phenotype is locus dependent and probably reflects the nature of the gene products controlling voltage-dependent Ca2+ channels.     

Mass selection of conditional mating mutants of Tetrahymena thermophila

The mating reaction in Tetrahymena thermophila includes a starvation period and two distinct cell interactions, co-stimulation and cell pairing, before the cells are cytoplasmically joined as conjugants. A selection procedure for harvesting mutants unable to mate at a restrictive temperature has been developed. A conjugant pair consisting of one cycloheximide-resistant cell and one wild-type cell (cycloheximide-sensitive) was itself sensitive to the drug. By adding cycloheximide and nutrient medium to a cross made at the restrictive and grow. Repetition of the selection procedure enriched for cells unable to conjugate at the restrictive temperature. The selected cells were able to grow at 38 degrees C and could conjugate at 28 degrees C. This procedure may be narrowed to select specifically for cell interaction mutants.     

A 3′ splice site consensus sequence mutation in the cystic fibrosis gene

Summary In the cystic fibrosis (CF) gene, recently cloned, a three base pair deletion (ΔF508) has been identified in a majority of CF patients. This deletion has been found in 80% of CF chromosomes in families from north west Brittany. In order to identify new mutations we have selected 43 chromosomes negative for the three base pair deletion from these families and directly sequenced exon 11 after DNA amplification by the polymerase chain reaction. We have detected a base change (G→A) at the 3′ end of the consensus sequence of intron ten (namely 1717-1). This mutation destroys a splice site in the cystic fibrosis gene which probably produces a mutant allele. This single nucleotide mutation has been reported on two other CF chromosomes.     

Base-flipping mutations of uracil DNA glycosylase: substrate rescue using a pyrene nucleotide wedge

We recently introduced a new substrate rescue tool for investigating enzymatic base flipping by uracil DNA glycosylase (UDG) in which a bulky pyrene nucleotide wedge (Y) was placed opposite a uracil in duplex DNA (i.e., a U/Y pair), thereby preorganizing the target base in an extrahelical conformation [Jiang, Y. L., et al. (2001) J. Biol. Chem. 276, 42347-54]. The pyrene wedge completely rescued the large catalytic defects resulting from removal of the natural Leu191 wedge, presumably mimicking the pushing and plugging function of this group. Here we employ the pyrene rescue method in combination with transient kinetic approaches to assess the functional roles of six conserved enzymatic groups of UDG that have been implicated in the "pinch, push, plug, and pull" base-flipping mechanism (see the preceding paper in this issue). We find that a U/Y base pair increases the apparent second-order rate constant for damaged site recognition by L191G pushing mutation by 45-fold as compared to a U/A pair, thereby fully rescuing the kinetic effects of the mutation. Remarkably, the U/Y pair also allows L191G to proceed through the conformational docking step that is severely comprised with the normal U/A substrate, and allows the active site of UDG to clamp around the extrahelical base. Thus, pyrene also fulfills the plugging role of the Leu191 side chain. Preorganization of uracil in an extrahelical conformation by pyrene allows diffusion-controlled damage recognition by all of these base-flipping mutants, and allows the UDG conformational change to proceed as rapidly as the rate of uracil flipping with the natural U/A base pair. Thus, the pyrene wedge substrate allows UDG to recognize uracil by a lock-and-key mechanism, rather than the natural induced-fit mechanism. Unnatural pyrene base pairs may provide a general strategy to promote site-specific targeting of other enzymes that recognize extrahelical bases.     

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

Revertants have been obtained from six mutants of the box9 cluster, which are supposed to be defective in RNA splicing as a result of alterations in a splice signal sequence. This sequence is in the 5' part of intron 4 of the cob gene, 330 to 340 bp downstream from the 5' splice site. Sequencing reveals that reversion to splicing competence is achieved by restoration of the wild-type box9 sequence; by creation of novel box9 sequences; and by introduction of a second site or suppressor mutation (sup-) compensating for the effect of the primary box9- mutation. The sup- mutation alters a sequence in intron 4,293 bp upstream from the box9- primary mutation. The box9 sequence and this upstream sequence can base pair to form an intramolecular hybrid in intron RNA in which box9- and sup- are compensatory base pair exchanges (G----A and C----U, respectively). Thus intramolecular hybrid structures of intron RNA are essential for RNA splicing.     

A conserved base pair within helix P4 of the Tetrahymena ribozyme helps to form the tertiary structure required for self-splicing.

Site-specific mutagenesis of the self-splicing Tetrahymena intron has been used to investigate the function of C109-G212, a conserved base pair in the P4 stem of group I introns. Mutation of C109 to G affects splicing only slightly, whereas mutation of G212 to A or C reduces the rate of splicing substantially (500-fold reduction in kcat/Km under standard in vitro splicing conditions for the G212C mutant). Splicing activity of the compensatory double mutant (C109G:G212C) is intermediate between those of the two single mutants. Thus, the stability of the P4 stem as well as the identity of the base at position 212 are important for self-splicing. Single and double mutants containing the G212C substitution have a decreased temperature optimum for self-splicing and are partially Mg2+ suppressible, both indicative of structural destabilization. Chemical structure mapping indicates that the mutations do not redirect the global folding of the RNA, but affect the structure locally and at one other site (A183) that is distant in the secondary structure. We propose that, in addition to its pairing in P4, G212 is involved in a base triplet or an alternate base pair that contributes to the catalytically active tertiary structure of the ribozyme.     

DNA strand specificity for UV-induced mutations in mammalian cells.

The influence of DNA repair on the molecular nature of mutations induced by UV light (254 nm) was investigated in UV-induced hprt mutants from UV-sensitive Chinese hamster cells (V-H1) and the parental line (V79). The nature of point mutations in hprt exon sequences was determined for 19 hprt mutants of V79 and for 17 hprt mutants of V-H1 cells by sequence analysis of in vitro-amplified hprt cDNA. The mutation spectrum in V79 cells consisted of single- and tandem double-base pair changes, while in V-H1 cells three frameshift mutations were also detected. All base pair changes in V-H1 mutants were due to GC----AT transitions. In contrast, in V79 all possible classes of base pair changes except the GC----CG transversion were present. In this group, 70% of the mutations were transversions. Since all mutations except one did occur at dipyrimidine sites, the assumption was made that they were caused by UV-induced photoproducts at these sites. In V79 cells, 11 out of 17 base pair changes were caused by photoproducts in the nontranscribed strand of the hprt gene. However, in V-H1 cells, which are completely deficient in the removal of pyrimidine dimers from the hprt gene and which show a UV-induced mutation frequency enhanced seven times, 10 out of 11 base pair changes were caused by photoproducts in the transcribed strand of the hprt gene. We hypothesize that this extreme strand specificity in V-H1 cells is due to differences in fidelity of DNA replication of the leading and the lagging strand. Furthermore, we propose that in normal V79 cells two processes determine the strand specificity of UV-induced mutations in the hprt gene, namely preferential repair of the transcribed strand of the hprt gene and a higher fidelity of DNA replication of the nontranscribed strand compared with the transcribed strand.     

Differential repair of premutational UV-lesions at tRNA genes in E. coli.

Summary Ultraviolet radiation produces bacterial revertants that frequently are the result of suppressor mutation. When irradiated cells are incubated under conditions unfavorable for protein synthesis there may be a large decrease in the frequency of observed mutants (mutation frequency decline, or MFD). MFD occurs only in excision-proficient strains and is inhibited by inhibitors of pyrimidine dimer excision. It has therefore been interpreted as enhanced excision of some premutational lesions. Potential de novo UAG suppressor mutation is very susceptible to MFD. Potential conversion mutation, the conversion of a UAG to a UAA suppressor, is at least ten times less susceptible to MFD. A base pair transition at a GC target in a particular tRNA gene is suggested for both de novo suppressor mutation and for conversion mutation. We interpret these results as indicating differential repair of premutational UV photoproducts at two closely spaced sites in the same tRNA gene. The significant difference between these two types of mutation may be the orientation of this target base pair in double helical DNA. The C would be in the transcribed strand of DNA when a nucleic acid alteration produces de novo suppressor mutation. The C would be in the nontranscribed strand, two base pairs removed, when a mutagenic alteration produces suppressor conversion. A model involving facilitated incision by hybridization of the transcribed strand of DNA to its cognate tRNA, under conditions promoting MFD, is described to explain this differential repair.     

Hepatitis B virus genotype A rarely circulates as an HBe-minus mutant: possible contribution of a single nucleotide in the precore region.

The emergence of HBe-minus hepatitis B virus (HBV) mutants, usually through a UAG nonsense mutation at codon 28 of the precore region, helps the virus to survive the anti-HBe immune response of the host. Host and viral factors that predispose to the emergence of such mutants are not well characterized. The fact that the precore region forms a hairpin structure essential for the packaging of viral pregenomic RNA may explain the extremely high prevalence of the UAG mutation at codon 28. It converts a wobble U-G pair in the packaging signal between nucleotide 3 of codon 15 (CCU) and nucleotide 2 of codon 28 (UGG) into a U-A pair. Since genotype A of HBV has a CCC sequence at codon 15, the UAG mutation would, instead, disrupt a C-G pair present in the wild-type virus. This alteration was shown by transfection experiments to greatly compromise the packaging of pregenomic RNA. The implication of this finding was elucidated by molecular epidemiological studies. Genotype A was found to be the most prevalent genotype in the wild-type virus populations in France but was found in only 1 of the 46 isolates of HBe-minus mutants found there. These mutants were contributed chiefly by genotype D, the second most prevalent genotype in France, which is characterized by a CCU sequence at codon 15. The role of the single nucleotide at codon 15 was confirmed by the finding of the single genotype A isolate in which both wild-type and mutant viruses were present. Interestingly, nearly all of the mutants had a codon 15 sequence of CCU instead of the CCC present in the wild-type viruses. Our results suggest that genotype A of HBV rarely circulates as HBe-minus mutants, probably because of a requirement for a simultaneous sequence change at codon 15. These data, together with the virtual absence of genotype A in the Chinese samples examined, may provide some insights into the uneven prevalence of HBe-minus mutants in the world.     

Nucleotide sequence of a recA operator mutation

Summary A single base pair change (AT to GC) is shown to be responsible for derepression of recA. The mutation (recAo281) alters the binding sequence for the LEXA repressor.Abbreviations bp base pair - kb kilobase pair     

Suppression of amber codons in vivo as evidence that mutants derived from Escherichia coli initiator tRNA can act at the step of elongation in protein synthesis

The absence of a Watson-Crick base pair at the end of the amino acid acceptor stem is one of the features which distinguishes prokaryotic initiator tRNAs as a class from all other tRNAs. We show that this structural feature prevents Escherichia coli initiator tRNA from acting as an elongator in protein synthesis in vivo. We generated a mutant of E. coli initiator tRNA in which the anticodon sequence is changed from CAU to CUA (the T35A36 mutant). This mutant tRNA has the potential to read the amber termination codon UAG. We then coupled this mutation to others which change the C1.A72 mismatch at the end of the acceptor stem to either a U1:A72 base pair (T1 mutant) or a C1:G72 base pair (G72 mutant). Transformation of E. coli CA274 (HfrC Su- lacZ125am trpEam) with multicopy plasmids carrying the mutant initiator tRNA genes show that mutant tRNAs carrying changes in both the anticodon sequence and the acceptor stem suppress amber codons in vivo, whereas mutant tRNA with changes in the anticodon sequence alone does not. Mutant tRNAs with the above anticodon sequence change are aminoacylated with glutamine in vitro. Measurement of kinetic parameters for aminoacylation by E. coli glutaminyl-tRNA synthetase show that both the nature of the base pair at the end of the acceptor stem and the presence or absence of a base pair at this position can affect aminoacylation kinetics. We discuss the implications of this result on recognition of tRNAs by E. coli glutaminyl-tRNA synthetase.     

Base pairing between the 3'' exon and an internal guide sequence increases 3'' splice site specificity in the Tetrahymena self-splicing rRNA intron.

It has been proposed that recognition of the 3' splice site in many group I introns involves base pairing between the start of the 3' exon and a region of the intron known as the internal guide sequence (R. W. Davies, R. B. Waring, J. Ray, T. A. Brown, and C. Scazzocchio, Nature [London] 300:719-724, 1982). We have examined this hypothesis, using the self-splicing rRNA intron from Tetrahymena thermophila. Mutations in the 3' exon that weaken this proposed pairing increased use of a downstream cryptic 3' splice site. Compensatory mutations in the guide sequence that restore this pairing resulted in even stronger selection of the normal 3' splice site. These changes in 3' splice site usage were more pronounced in the background of a mutation (414A) which resulted in an adenine instead of a guanine being the last base of the intron. These results show that the proposed pairing (P10) plays an important role in ensuring that cryptic 3' splice sites are selected against. Surprisingly, the 414A mutation alone did not result in activation of the cryptic 3' splice site.     

Polyglycylation domain of beta-tubulin maintains axonemal architecture and affects cytokinesis in Tetrahymena

Polyglycylation occurs through the post-translational addition of a polyglycine peptide to the gamma-carboxyl group of glutamic acids near the C terminus of alpha- and beta-tubulin, and has been found only in cells with axonemes, from protists to humans. In Tetrahymena thermophila, multiple sites of polyglycylation on alpha-tubulin are dispensable. By contrast, mutating similar sites on beta-tubulin has site-specific effects, affecting cell motility and cytokinesis, or resulting in cell death. Here, we address the lethality of a polyglycylation deficiency in T. thermophila using heterokaryons. Cells with a lethal mutation in the polyglycylation domain of beta-tubulin assembled axonemes that lack the central pair, B-subfibres and the transitional zone of outer microtubules (MTs). Furthermore, an arrest in cytokinesis occurred, and was associated with incomplete severing of cortical MTs positioned near the cleavage furrow. Thus, tubulin polyglycylation is required for the maintenance of some stable microtubular organelles that are all known to be polyglycylated in vivo, but its effects on MTs appear to be organelle-specific.     

DNA base changes and RNA levels in N-acetoxy-2-acetylaminofluorene-induced dihydrofolate reductase mutants of Chinese hamster ovary cells

Formerly, we isolated a series of dihydrofolate reductase-deficient Chinese hamster ovary cell mutants that were induced by N-acetoxy-2-acetylaminofluorene. Deletions and complex gene rearrangements were detected in 28% of these mutants; 72% contained putative point mutations. In the present study, we have localized the putative point mutations in the 25,000 base dhfr gene by RNase heteroduplex mapping. Assignment of a position for each mutation was successful in 16 of 19 mutants studied. We cloned DNA fragments containing the mapped mutations from nine mutants into a bacteriophage lambda vector. In the case of 11 other mutants, DNA was amplified by the polymerase chain reaction procedure. Sequence analysis of cloned and amplified DNA confirmed the presence of point mutations. Most mutants (90%) carried base substitutions; the rest contained frameshift mutations. Of the point mutations, 75% were G.C to T.A transversions in either the dhfr coding sequence or at splice sites; transition G.C to A.T mutations were found in two mutants (10%). In one of these transition mutants, the base substitution occurred at the fifth base of the third intron. Of the frameshift mutations, one was a deletion of G.C pair and the other was an insertion of an A.T pair. Of the mapped mutants, 38% exhibited greatly reduced (approximately 10-fold) steady-state levels of dhfr mRNA. All eight sequenced mutants displaying this phenotype contained premature chain termination codons. Normal levels of dhfr mRNA were observed in five missense mutants and in five mutants carrying nonsense codons in the translated portion of exon VI. Taken together with the results of other mutagens at this locus, we conclude that the low dhfr mRNA phenotype is correlated with the presence of nonsense codons in exons II to V but not in the last exon of the dhfr gene.     

DNA polymerase catalysis in the absence of Watson-Crick hydrogen bonds: analysis by single-turnover kinetics

We report the first pre-steady-state kinetic studies of DNA replication in the absence of hydrogen bonds. We have used nonpolar nucleotide analogues that mimic the shape of a Watson-Crick base pair to investigate the kinetic consequences of a lack of hydrogen bonds in the polymerase reaction catalyzed by the Klenow fragment of DNA polymerase I from Escherichia coli. With a thymine isostere lacking hydrogen-bonding ability in the nascent pair, the efficiency (k(pol)/Kd) of the polymerase reaction is decreased by 30-fold, affecting the ground state (Kd) and transition state (k(pol)) approximately equally. When both thymine and adenine analogues in the nascent pair lack hydrogen-bonding ability, the efficiency of the polymerase reaction is decreased by about 1000-fold, with most of the decrease attributable to the transition state. Reactions using nonpolar analogues at the primer-terminal base pair demonstrated the requirement for a hydrogen bond between the polymerase and the minor groove of the primer-terminal base. The R668A mutation of Klenow fragment abolished this requirement, identifying R668 as the probable hydrogen-bond donor. Detailed examination of the kinetic data suggested that Klenow fragment has an extremely low tolerance of even minor deviations of the analogue base pairs from ideal Watson-Crick geometry. Consistent with this idea, some analogue pairings were better tolerated by Klenow fragment mutants having more spacious active sites. In contrast, the Y-family polymerase Dbh was much less sensitive to changes in base pair dimensions and more dependent upon hydrogen bonding between base-paired partners.     

Different nucleotide changes in the large rRNA gene of the mitochondrial DNA confer chloramphenicol resistance on two human cell lines.

The nucleotide sequence of the mitochondrial DNA (mtDNA) in the region coding for the 3' end of the large rRNA has been determined for two human cell lines bearing independent cytoplasmic chloramphenicol-resistant (CAP-r) mutations. Comparison of the sequences of these two phenotypically different CAP-r mutants with their CAP-sensitive (CAP-s) parental cell lines has revealed a single base change for each in a region which is highly conserved among species. One CAP-r mutation is associated with an A to G transition on the coding strand while the second contains a G to T transversion 52 nucleotides away. Comparable sequence changes in this region had previously been found for mouse and yeast cell mitochondrial CAP-r mutants. Thus, changes in the large rRNA gene eliminate the inhibition of the ribosome by CAP and different nucleotide changes may result in variations in the drug-r phenotype.