Substitution of an invariant nucleotide at the base of the highly conserved '530-loop' of 15S rRNA causes suppression of yeast mitochondrial ochre mutations

A single mutation in the 15S rRNA gene confers non sense suppressor activity and interacts with mRF1 the release factor in yeast mitochondria

We have determined the nucleotide sequence of the mim3-1 mitochondrial ribosomal suppressor, acting on ochre mitochondrial mutations and one frameshift mutation in Saccharomyces cerevisiae. The 15s rRNA suppressor gene contains a G633 to C transversion. Yeast mitochondrial G633 corresponds to G517 of the E.coli 15S rRNA, which is occupied by an invariant G in all known small rRNA sequences. Interestingly, this mutation has occurred at the same position as the known MSU1 mitochondrial suppressor which changes G633 to A. The suppressor mutation lies in a highly conserved region of the rRNA, known in E.coli as the 530-loop, interacting with the S4, S5 and S12 ribosomal proteins. We also show an interesting interaction between the mitochondrial mim3-1 and the nuclear nam3-1 suppressors, both of which have the same action spectrum on mitochondrial mutations: nam3-1 abolishes the suppressor effect when present with mim3-1 in the same haploid cell. We discuss these results in the light of the nature of Nam3, identified by 1 as the yeast mitochondrial translation release factor. A hypothetical mechanism of suppression by "ribosome shifting" is also discussed in view of the nature of mutations suppressed and not suppressed.

The Pet309 pentatricopeptide repeat motifs mediate efficient binding to the mitochondrial COX1 transcript in yeast

Mitochondrial synthesis of Cox1, the largest subunit of the cytochrome c oxidase complex, is controlled by Mss51 and Pet309, two mRNA-specific translational activators that act via the COX1 mRNA 5′-UTR through an unknown mechanism. Pet309 belongs to the pentatricopeptide repeat (PPR) protein family, which is involved in RNA metabolism in mitochondria and chloroplasts, and its sequence predicts at least 12 PPR motifs in the central portion of the protein. Deletion of these motifs selectively disrupted translation but not accumulation of the COX1 mRNA. We used RNA coimmunoprecipitation assays to show that Pet309 interacts with the COX1 mRNA in vivo and that this association is present before processing of the COX1 mRNA from the ATP8/6 polycistronic mRNA. This association was not affected by deletion of 8 of the PPR motifs but was undetectable after deletion of the entire 12-PPR region. However, interaction of the Pet309 protein lacking 12 PPR motifs with the COX1 mRNA was detected after overexpression of the mutated form of the protein, suggesting that deletion of this region decreased the binding affinity for the COX1 mRNA without abolishing it entirely. Moreover, binding of Pet309 to the COX1 mRNA was affected by deletion of Mss51. This work demonstrates an in vivo physical interaction between a yeast mitochondrial translational activator and its target mRNA and shows the cooperativity of the PPR domains of Pet309 in interaction with the COX1 mRNA.

Crystal structures of 70S ribosomes bound to release factors RF1, RF2 and RF3

Termination is a crucial step in translation, most notably because premature termination can lead to toxic truncated polypeptides. Most interesting is the fact that stop codons are read by a completely different mechanism from that of sense codons. In recent years, rapid progress has been made in the structural biology of complexes of bacterial ribosomes bound to translation termination factors, much of which has been discussed in earlier reviews [1-5]. Here, we present a brief overview of the structures of bacterial translation termination complexes. The first part summarizes what has been learned from crystal structures of complexes containing the class I release factors RF1 and RF2. In the second part, we discuss the results and implications of two recent X-ray structures of complexes of ribosomes bound to the translational GTPase RF3. These structures have provided many insights and a number of surprises. While structures alone do not tell us how these complicated molecular assemblies work, is it nevertheless clear that it will not be possible to understand their mechanisms without detailed structural information.

The pentatricopeptide repeats present in Pet309 are necessary for translation but not for stability of the mitochondrial COX1 mRNA in yeast

Pet309 is a protein essential for respiratory growth. It is involved in translation of the yeast mitochondrial COX1 gene, which encodes subunit I of the cytochrome c oxidase. Pet309 is also involved in stabilization of the COX1 mRNA. Mutations in a similar human protein, Lrp130, are associated with Leigh syndrome, where cytochrome c oxidase activity is affected. The sequence of Pet309 reveals the presence of at least seven pentatricopeptide repeats (PPRs) located in tandem in the central portion of the protein. Proteins containing PPR motifs are present in mitochondria and chloroplasts and are in general involved in RNA metabolism. Despite the increasing number of proteins from this family found to play essential roles in mitochondria and chloroplasts, little is understood about the mechanism of action of the PPR domains present in these proteins. In a series of in vivo analyses we constructed a pet309 mutant lacking the PPR motifs. Although the stability of the COX1 mRNA was not affected, synthesis of Cox1 was abolished. The deletion of one PPR motif at a time showed that all the PPR motifs are required for COX1 mRNA translation and respiratory growth. Mutations of basic residues in PPR3 caused reduced respiratory growth. According to a molecular model, these residues are facing a central cavity that could be involved in mRNA-binding activity, forming a possible path for this molecule on Pet309. Our results show that the RNA metabolism function of Pet309 is found in at least two separate domains of the protein.

Alteration of a novel dispensable mitochondrial ribosomal small-subunit protein, Rsm28p, allows translation of defective COX2 mRNAs

Mutations affecting the RNA sequence of the first 10 codons of the Saccharomyces cerevisiae mitochondrial gene COX2 strongly reduce translation of the mRNA, which encodes the precursor of cytochrome c oxidase subunit II. A dominant chromosomal mutation that suppresses these defects is an internal in-frame deletion of 67 codons from the gene YDR494w. Wild-type YDR494w encodes a 361-residue polypeptide with no similarity to proteins of known function. The epitope-tagged product of this gene, now named RSM28, is both peripherally associated with the inner surface of the inner mitochondrial membrane and soluble in the matrix. Epitope-tagged Rsm28p from Triton X-100-solubilized mitochondria sedimented with the small subunit of mitochondrial ribosomes in a sucrose gradient containing 500 mM NH4Cl. Complete deletion of RSM28 caused only a modest decrease in growth on nonfermentable carbon sources in otherwise wild-type strains and enhanced the respiratory defect of the suppressible cox2 mutations. The rsm28 null mutation also reduced translation of an ARG8m reporter sequence inserted at the COX1, COX2, and COX3 mitochondrial loci. We tested the ability of RSM28-1 to suppress a variety of cox2 and cox3 mutations and found that initiation codon mutations in both genes were suppressed. We conclude that Rsm28p is a dispensable small-subunit mitochondrial ribosomal protein previously undetected in systematic investigations of these ribosomes, with a positive role in translation of several mitochondrial mRNAs.

Antagonistic signals within the COX2 mRNA coding sequence control its translation in Saccharomyces cerevisiae mitochondria

Translation of the mitochondrially coded COX2 mRNA within the organelle in yeast produces the precursor of Cox2p (pre-Cox2p), which is processed and assembled into cytochrome c oxidase. The mRNA sequence of the first 14 COX2 codons, specifying the pre-Cox2p leader peptide, was previously shown to contain a positively acting element required for translation of a mitochondrial reporter gene, ARG8(m), fused to the 91st codon of COX2. Here we show that three relatively short sequences within the COX2 mRNA coding sequence, or structures they form in vivo, inhibit translation of the reporter in the absence of the positive element. One negative element was localized within codons 15 to 25 and shown to function at the level of the mRNA sequence, whereas two others are within predicted stem-loop structures formed by codons 22-44 and by codons 46-74. All three of these inhibitory elements are antagonized in a sequence-specific manner by reintroduction of the upstream positive-acting sequence. These interactions appear to be independent of 5'- and 3'-untranslated leader sequences, as they are also observed when the same reporter constructs are expressed from the COX3 locus. Overexpression of MRS2, which encodes a mitochondrial magnesium carrier, partially suppresses translational inhibition by each isolated negatively acting element, but does not suppress them in combination. We hypothesize that interplay among these signals during translation in vivo may ensure proper timing of pre-Cox2p synthesis and assembly into cytochrome c oxidase.

Genetic approaches to studying protein synthesis: effects of mutations at Psi516 and A535 in Escherichia coli 16S rRNA

A genetic system for the study of ribosomal RNA function and structure was developed. First, the ribosome binding sequence of the chloramphenicol acetyltransferase gene and the message binding sequence of 16S ribosomal RNA were randomly mutated and alternative highly functional sequences were selected and characterized. From this set of mutants, a single clone was chosen and subjected to a second round of mutagenesis to optimize the specificity of the system. In the resulting system, plasmid-encoded ribosomes efficiently and exclusively translate specific mRNA containing the appropriate ribosome binding sequences. This system allows facile isolation and analysis of mutations that would normally be lethal and allows direct selection of rRNA mutants with predetermined levels of ribosome function. The system was used to examine the effects of mutations at the sole pseudouridine (Psi) in Escherichia coli 16S rRNA which is located at position 516 of the conserved 530 loop. The nucleotide opposite Psi516 in the hairpin, A535, was also mutated. The data show that a pyrimidine (Psi or C) is required at position 516, while substitutions at position 535 reduce ribosome function by < 50%. A requirement for base pair formation between Psi516 and A535 was not indicated.

Meanderings of the mRNA through the ribosome

A map of how mRNA travels through the ribosome is critical for any detailed understanding of the process of translation. This feat has recently been achieved using X-ray crystallography. The structure reveals, for the first time, details of the interactions between the mRNA and the 30S subunit beyond those at the tRNA binding sites. Elements of both 16S rRNA and ribosomal proteins contribute to mRNA binding. This work also identifies two tunnels that the mRNA passes through as it wraps around the 30S subunit. The mechanisms and mechanics of reading frame selection, translational fidelity, and translocation can now be informed by the structure.

Mitochondrial translation of Saccharomyces cerevisiae COX2 mRNA is controlled by the nucleotide sequence specifying the pre-Cox2p leader peptide

The mitochondrial gene encoding yeast cytochrome oxidase subunit II (Cox2p) specifies a precursor protein with a 15-amino-acid leader peptide. Deletion of the entire leader peptide coding region is known to block Cox2p accumulation posttranscriptionally. Here, we examined in vivo the role of the pre-Cox2p leader peptide and the mRNA sequence that encodes it in the expression of a mitochondrial reporter gene, ARG8m, fused to the 91st codon of COX2. We found within the coding sequence antagonistic elements that control translation: the positive element includes sequences in the first 14 codons specifying the leader peptide, while the negative element appears to be within codons 15 to 91. Partial deletions, point mutations, and local frameshifts within the leader peptide coding region were placed in both the cox2::ARG8m reporter and in COX2 itself. Surprisingly, the mRNA sequence of the first six codons specifying the leader peptide plays an important role in positively controlling translation, while the amino acid sequence of the leader peptide itself is relatively unconstrained. Two mutations that partially block translation can be suppressed by nearby sequence substitutions that weaken a predicted stem structure and by overproduction of either the COX2 mRNA-specific translational activator Pet111p or the large-subunit mitochondrial ribosomal protein MrpL36p. We propose that regulatory elements embedded in the translated COX2 mRNA sequence could play a role, together with trans-acting factors, in coupling regulated synthesis of nascent pre-Cox2p to its insertion in the mitochondrial inner membrane.

Cloning and characterization of COX18, a Saccharomyces cerevisiae PET gene required for the assembly of cytochrome oxidase

Nuclear mutants of Saccharomyces cerevisiae assigned to complementation group G34 are respiratory-deficient and lack cytochrome oxidase activity and the characteristic spectral peaks of cytochromes a and a(3). The corresponding gene was cloned by complementation, sequenced, and identified as reading frame YGR062C on chromosome VII. This gene was named COX18. The COX18 gene product is a polypeptide of 316 amino acids with a putative amino-terminal mitochondrial targeting sequence and predicted transmembrane domains. Respiratory chain carriers other than cytochromes a and a(3) and the ATPase complex are present at near wild-type levels in cox18 mutants, indicating that the mutations specifically affect cytochrome oxidase. The synthesis of Cox1p and Cox3p in mutant mitochondria is normal whereas Cox2p is barely detected among labeled mitochondrial polypeptides. Transcription of COX2 does not require COX18 function, and a chimeric COX3-COX2 mRNA did not suppress the respiratory defect in the null mutant, indicating that the mutation does not impair transcription or translation of the mRNA. Western analysis of cytochrome oxidase subunits shows that inactivation of the COX18 gene greatly reduces the steady state amounts of subunit 2 and results in variable decreases in other subunits of cytochrome oxidase. A gene fusion expressing a biotinylated form of Cox18p complements cox18 mutants. Biotinylated Cox18p is a mitochondrial integral membrane protein. These results indicate Cox18p to be a new member of a group of mitochondrial proteins that function at a late stage of the cytochrome oxidase assembly pathway.

In vivo analysis of Saccharomyces cerevisiae COX2 mRNA 5'-untranslated leader functions in mitochondrial translation initiation and translational activation

We have used mutational and revertant analysis to study the elements of the 54-nucleotide COX2 5'-untranslated leader involved in translation initiation in yeast mitochondria and in activation by the COX2 translational activator. Pet111p. We generated a collection of mutants with substitutions spanning the entire COX2 5'-UTL by in vitro mutagenesis followed by mitochondrial transformation and gene replacement. The phenotypes of these mutants delimit a 31-nucleotide segment, from -16 to -46, that contains several short sequence elements necessary for COX2 5'-UTL function in translation. The sequences from -16 to -47 were shown to be partially sufficient to promote translation in a foreign context. Analysis of revertants of both the series of linker-scanning alleles and two short deletion/ insertion alleles has refined the positions of several possible functional elements of the COX2 5'-untranslated leader, including a putative RNA stem-loop structure that functionally interacts with Pet111p and an octanucleotide sequence present in all S. cerevisiae mitochondrial mRNA 5'-UTLs that is a potential rRNA binding site.

A new model for the three-dimensional folding of Escherichia coli 16 S ribosomal RNA. III. The topography of the functional centre

We describe the locations of sites within the 3D model for the 16 S rRNA (described in two accompanying papers) that are implicated in ribosomal function. The relevant experimental data originate from many laboratories and include sites of foot-printing, cross-linking or mutagenesis for various functional ligands. A number of the sites were themselves used as constraints in building the 16 S model. (1) The foot-print sites for A site tRNA are all clustered around the anticodon stem-loop of the tRNA; there is no "allosteric" site. (2) The foot-print sites for P site tRNA that are essential for P site binding are similarly clustered around the P site anticodon stem-loop. The foot-print sites in 16 S rRNA helices 23 and 24 are, however, remote from the P site tRNA. (3) Cross-link sites from specific nucleotides within the anticodon loops of A or P site-bound tRNA are mostly in agreement with the model, whereas those from nucleotides in the elbow region of the tRNA (which also exhibit extensive cross-linking to the 50 S subunit) are more widely spread. Again, cross-links to helix 23 are remote from the tRNAs. (4) The corresponding cross-links from E site tRNA are predominantly in helix 23, and these agree with the model. Electron microscopy data are presented, suggestive of substantial conformational changes in this region of the ribosome. (5) Foot-prints for IF-3 in helices 23 and 24 are at a position with close contact to the 50 S subunit. (6) Foot-prints from IF-1 form a cluster around the anticodon stem-loop of A site tRNA, as do also the sites on 16 S rRNA that have been implicated in termination. (7) Foot-print sites and mutations relating to streptomycin form a compact group on one side of the A site anticodon loop, with the corresponding sites for spectinomycin on the other side. (8) Site-specific cross-links from mRNA (which were instrumental in constructing the 16 S model) fit well both in the upstream and downstream regions of the mRNA, and indicate that the incoming mRNA passes through the well-defined "hole" at the head-body junction of the 30 S subunit.

Pet127p, a membrane-associated protein involved in stability and processing of Saccharomyces cerevisiae mitochondrial RNAs

Nuclear mutations that inactivate the Saccharomyces cerevisiae gene PET127 dramatically increased the levels of mutant COX3 and COX2 mitochondrial mRNAs that were destabilized by mutations in their 5' untranslated leaders. The stabilizing effect of pet127 delta mutations occurred both in the presence and in the absence of translation. In addition, pet127 delta mutations had pleiotropic effects on the stability and 5' end processing of some wild-type mRNAs and the 15S rRNA but produced only a leaky nonrespiratory phenotype at 37 degrees C. Overexpression of PET127 completely blocked respiratory growth and caused cells to lose wild-type mitochondrial DNA, suggesting that too much Pet127p prevents mitochondrial gene expression. Epitope-tagged Pet127p was specifically located in mitochondria and associated with membranes. These findings suggest that Pet127p plays a role in RNA surveillance and/or RNA processing and that these functions may be membrane bound in yeast mitochondria.

Decoding fidelity at the ribosomal A and P sites: influence of mutations in three different regions of the decoding domain in 16S rRNA

The involvement of defined regions of Escherichia coli 16S rRNA in the fidelity of decoding has been examined by analyzing the effects of rRNA mutations on misreading errors at the ribosomal A and P sites. Mutations in the 1400-1500 region, the 530 loop and in the 1050/1200 region (helix 34) all caused readthrough of stop codons and frameshifting during elongation and stimulated initiation from non-AUG codons at the initiation of protein synthesis. These results indicate the involvement of all three regions of 16S rRNA in decoding functions at both the A and P sites. The functional similarity of all three mutant classes are consistent with close physical proximity of the 1400- 1500 region, the 530 loop and helix 34 and suggest that all three regions of rRNA comprise a decoding domain in the ribosome.

Expansion of the 16S and 23S ribosomal RNA mutation databases (16SMDB and 23SMDB)

The Ribosomal RNA Mutation Databases (16SMDB and 23SMDB) provide lists of mutated positions in 16S and 23S ribosomal RNA from Escherichia coli and the identity of each alteration. Information provided for each mutation includes: (i) a brief description of the phenotype(s) associated with each mutation; (ii) whether a mutant phenotype has been detected by in vivo or in vitro methods; and (iii) relevant literature citations. The databases are available via ftp and on the World Wide Web. Expansion of the databases to include information about mutations isolated in organisms other than E.coli is currently in progress.

Ribosomes and translation

The ribosome is a large multifunctional complex composed of both RNA and proteins. Biophysical methods are yielding low-resolution structures of the overall architecture of ribosomes, and high-resolution structures of individual proteins and segments of rRNA. Accumulating evidence suggests that the ribosomal RNAs play central roles in the critical ribosomal functions of tRNA selection and binding, translocation, and peptidyl transferase. Biochemical and genetic approaches have identified specific functional interactions involving conserved nucleotides in 16S and 23S rRNA. The results obtained by these quite different approaches have begun to converge and promise to yield an unprecedented view of the mechanism of translation in the coming years.

The translational function of nucleotide C1054 in the small subunit rRNA is conserved throughout evolution: genetic evidence in yeast

Mutations at position C1054 of 16S rRNA have previously been shown to cause translational suppression in Escherichia coli. To examine the effects of similar mutations in a eukaryote, all three possible base substitutions and a base deletion were generated at the position of Saccharomyces cerevisiae 18S rRNA corresponding to E. coli C1054. In yeast, as in E. coli, both C1054A (rdn-1A) and C1054G (rdn-1G) caused dominant nonsense suppression. Yeast C1054U (rdn-1T) was a recessive antisuppressor, while yeast C1054-delta (rdn-1delta) led to recessive lethality. Both C1054U and two previously described yeast 18S rRNA antisuppressor mutations, G517A (rdn-2) and U912C (rdn-4), inhibited codon-nonspecific suppression caused by mutations in eukaryotic release factors, sup45 and sup35. However, among these only C1054U inhibited UAA-specific suppressions caused by a UAA-decoding mutant tRNA-Gln (SLT3). Our data implicate eukaryotic C1054 in translational termination, thus suggesting that its function is conserved throughout evolution despite the divergence of nearby nucleotide sequences.

UGA suppression by a mutant RNA of the large ribosomal subunit

A role for rRNA in peptide chain termination was indicated several years ago by isolation of a 168 rRNA (small subunit) mutant of Escherichia coli that suppressed UGA mutations. In this paper, we describe another interesting rRNA mutant, selected as a translational suppressor of the chain-terminating mutant trpA (UGA211) of E. coli. The finding that it suppresses UGA at two positions in trpA and does not suppress the other two termination codons, UAA and UAG, at the same codon positions (or several missense mutations, including UGG, available at one of the two positions) suggests a defect in UGA-specific termination. The suppressor mutation was mapped by plasmid fragment exchanges and in vivo suppression to domain II of the 23S rRNA gene of the rrnB operon. Sequence analysis revealed a single base change of G to A at residue 1093, an almost universally conserved base in a highly conserved region known to have specific interactions with ribosomal proteins, elongation factor G, tRNA in the A-site, and the peptidyltransferase region of 23S rRNA. Several avenues of action of the suppressor mutation are suggested, including altered interactions with release factors, ribosomal protein L11, or 16S rRNA. Regardless of the mechanism, the results indicate that a particular residue in 23S rRNA affects peptide chain termination, specifically in decoding of the UGA termination codon.

The accuracy center of a eukaryotic ribosome

Mutations in yeast ribosomal proteins and ribosomal RNAs have been shown to affect translational fidelity. These mutations include: proteins homologous to Escherichia coli's S4, S5, and S12; a eukaryote specific ribosomal protein; yeast ribosomal rRNA alterations at positions corresponding to 517, 912, and 1054 in 16S E. coli rRNA and to 2658 in the sarcin-ricin domain of 23S E. coli rRNA. Overall there appears to be a remarkable conservation of the accuracy center throughout evolution.

The NAM9-1 suppressor mutation in a nuclear gene encoding ribosomal mitochondrial protein of Saccharomyces cerevisiae

The nuclear gene NAM9 from Saccharomyces cerevisiae (Sc) codes for a protein which, on the basis of sequence homology, was previously postulated to be a mitochondrial (mt) equivalent of the Escherichia coli (Ec) S4 ribosomal protein (r-protein) [Boguta et al., Mol. Cell. Biol. 12 (1992) 402-412]. The mt-r character of the NAM9 product is now confirmed by cross-reaction with the antisera for the Sc mt r-proteins. The NAM9-1 mutation, characterized previously as the nuclear suppressor of some ochre mt mit- mutants, is found to be a single nucleotide substitution changing Ser82 to Leu within the part of NAM9 corresponding to the S4 region involved in interaction with the 16S rRNA. This indicates that the mechanism of NAM9-1 suppression could be analogous to the suppression due to ram (ribosomal ambiguity) mutations in the Ec structural gene encoding r-protein S4. The NAM9-1 mutation leads also to defect in respiratory growth in the background of the wild-type mit+ genome.

The site-specific DNA endonuclease encoded by a group I intron in the Chlamydomonas pallidostigmatica chloroplast small subunit rRNA gene introduces a single-strand break at low concentrations of Mg2+

Two group I introns (CpSSU.1 and CpSSU.2) that each potentially encode a protein with two copies of the LAGLI-DADG motif were identified in the Chlamydomonas pallidostigmatica chloroplast small subunit rRNA gene. They both belong to subgroup IA3 and represent novel insertion positions in this gene (sites 508 and 793 in the Escherichia coli 16S rRNA). The proteins encoded by the two introns were synthesized in vitro and tested for their ability to cleave the homing site of their respective introns. Only the CpSSU.1-encoded protein (I-CpaII) was found to display specific DNA endonuclease activity. At 0.1 mM MgCl2, I-CpaII nicks only the bottom (transcribed) DNA strand, but at concentrations ranging from 0.5 to 5.0 mM, it cleaves both DNA strands (leaving a 4 nucleotide single-stranded extension with 3'-OH overhangs) while preferentially nicking the bottom strand. The rate of cleavage of the top strand increases with increasing concentration of MgCl2. The preliminary data derived from these endonuclease assays suggest that the mode of DNA cleavage by I-CpaII is directed by the availability of Mg2+ and the affinity of different binding sites for this cation.

Prokaryotic translation: the interactive pathway leading to initiation

Finding answers to the many open questions concerning the mechanism and control of prokaryotic translation remains one of the central challenges of molecular biology. In fact, recent experimental data even force us to reconsider aspects that were previously thought to be established fact. Here, we attempt a synthesis of new and not-so-new information, which leads to a revised and testable working hypothesis for translational initiation.

Sequence analysis of three deficient mutants of cytochrome oxidase subunit I of Saccharomyces cerevisiae and their revertants

Three respiratory-deficient mutants of cytochrome oxidase subunit I in the yeast mitochondrion have been sequenced. They are located in, or near, transmembrane segment VI, the catalytic core of the enzyme. Respiratory-competent revertants have been selected and studied. The mutant V244M was found to revert at the same site in valine (wild-type), isoleucine or threonine. The revertants of the mutant G251R were of three types: glycine (wild-type), serine and threonine at position 251. A search for second-site mutations was carried out but none were found. Among 60 revertants tested, the mutant K265M was found to revert only to the wild-type allele.

Ribosomal components neighboring the conserved 518-533 loop of 16S rRNA in 30S subunits

We report the synthesis of a radioactive, photolabile oligodeoxyribonucleotide probe complementary to 16S rRNA nucleotides 518-526 and its exploitation in identifying 30S ribosomal subunit components neighboring its target site in 16S rRNA. Nucleotides 518-526 lie within an almost universally conserved single-stranded loop that has been linked to the decoding region of Escherichia coli ribosomes. On photolysis in the presence of activated 30S ribosomes, the probe site-specifically incorporates into proteins S3, S4, S7, and S12 (identified by SDS-PAGE, RP-HPLC, and immunological analysis); nucleotides C525, C526, and G527 adjacent to its target binding site; and the 3'-terminus of 16S rRNA. When the probe is photoincorporated into 30S subunits subjected to brief cold inactivation (SI subunits), S7 labeling is increased compared to activated subunit incorporation, while S3, S4, and S12 labeling is decreased, as is labeling to nucleotides C525, C526, and G527; labeling at the 16S rRNA 3'-terminus appears unchanged. Longer cold inactivation of the 30S subunits (LI subunits) leads to decreases in the labeling of all components. These results provide clear evidence that C526 lies within 24 A (the distance between C526 and the photogenerated nitrene) of proteins S3, S4, S7, and S12 and the 3'-terminus of 16S rRNA. The identity of the tryptic digestion patterns of S7 labeled with the probe complementary to 16S rRNA nucleotides 518-526 and with a probe complementary to nucleotides 1397-1405 [Muralikrishna, P., & Cooperman, B. S. (1994) Biochemistry 33, 1392-1398] also provides evidence for proximity between C526 and G1405. Our results support the conclusion of Dontsova et al. [Dontsova, O., et al. (1992) EMBO J. 11, 3105-3116] in placing the 530 loop in close proximity to the decoding center of the 30S subunit but are apparently inconsistent with some protein-protein distances determined by neutron diffraction [Capel, M. S., et al. (1988) J. Mol. Biol. 200, 65-87]. This inconsistency suggests that a multistate model of subunit conformation may be required to account for the totality of results pertaining to the internal structure of the 30S subunit.

The single pseudouridine residue in Escherichia coli 16S RNA is located at position 516

The number and location of pseudouridine residues in Escherichia coli 16S ribosomal RNA has been determined by a combination of direct and indirect methods. Only one residue was found, at position 516. This site is at the 5'-end of one of the three most highly conserved long sequences of this RNA molecule. A number of experimental findings have strongly implicated this loop in the fidelity of codon recognition by A-site bound tRNA. By virtue of its location, we suggest that psi 516 may also play a role in maintaining the fidelity of protein synthesis.

PET112, a Saccharomyces cerevisiae nuclear gene required to maintain rho+ mitochondrial DNA

The nuclear gene PET112 was originally identified by a mutation (pet112-1) that specifically blocked accumulation of cytochrome c oxidase subunit II. The mutation causes a post-transcriptional defect since the level of COX2 mRNA in the mutant is the same as in the wild-type. However, PET112 does not have a function similar to that of PET111, a COX2 mRNA-specific translational activator: while pet111 mutations are suppressed by chimeric COX2 mRNAs bearing 5' leaders of other mitochondrial mRNAs, pet112-1 is not. The PET112 gene was isolated and shown to code a protein of 541 residues (62 kDa) with no significant homology to known amino-acid sequences. By hybridization to defined genomic clones the gene was mapped to chromosome II between cdc25 and ils1. Disruption of the PET112 open reading frame destabilized the mitochondrial genome, causing cells to become rho-. This finding suggests that PET112 has an important general function in mitochondrial gene expression, probably in translation.

Replacement of a conserved glycine residue in subunit II of cytochrome c oxidase interferes with protein function

In this paper we describe the isolation and characterization of a respiration-deficient yeast strain which is defective in the function of subunit II of cytochrome c oxidase. This strain, VC32, carries a mutation in the mitochondrial COX2 gene which converts a conserved glycine residue to arginine. The conserved glycine is in a region implicated as important for ligating the CuA redox center and for interaction with cytochrome c. We have also characterized five revertants of VC32 which have recovered respiratory function; all five were mapped to the mitochondrial genome. In three of the five revertants the wild-type glycine codon is restored, while in two of the five the mutant arginine codon is still present. These two strains are likely to possess alterations either in components of the mitochondrial translation machinery or in mitochondrially-encoded gene products that interact directly with subunit II to assemble an active oxidase complex.

Reduced but accurate translation from a mutant AUA initiation codon in the mitochondrial COX2 mRNA of Saccharomyces cerevisiae

We have changed the translation initiation codon of the COX2 mRNA of Saccharomyces cerevisiae from AUG to AUA, generating a mutation termed cox2-10. This mutation reduced translation of the COX2 mRNA at least five-fold without affecting the steady-state level of the mRNA, and produced a leaky nonrespiratory growth phenotype. To address the question of whether residual translation of the cox2-10 mRNA was initiating at the altered initiation codon or at the next AUG codon downstream (at position 14), we took advantage of the fact that the mature coxII protein is generated from the electrophoretically distinguishable coxII precursor by removal of the amino-terminal 15 residues, and that this processing can be blocked by a mutation in the nuclear gene PET2858. We constructed a pet2858, cox2-10 double mutant strain using a pet2858 allele from our mutant collection. The double mutant accumulated low levels of a polypeptide which comigrated with the coxII precursor protein, not the mature species, providing strong evidence that residual initiation was occurring at the mutant AUA codon. Residual translation of the mutant mRNA required the COX2 mRNA-specific activator PET111. Furthermore, growth of cox2-10 mutant strains was sensitive to alterations in PET111 gene dosage: the respiratory-defective growth phenotype was partially suppressed in haploid strains containing PET111 on a high-copy-number vector, but became more severe in diploid strains containing only one functional copy of PET111.

Selective perturbation of G530 of 16 S rRNA by translational miscoding agents and a streptomycin-dependence mutation in protein S12

Previous studies have shown that a concise set of universally conserved bases in 16 S rRNA are strongly protected from attack by chemical probes when tRNA is bound specifically to the ribosomal A site. Two of these bases, A1492 and A1493, are located in the cleft of the 30 S subunit, the site of codon-anticodon interaction. A third residue, G530, is located within the highly conserved 530 stem-loop, a region that is involved in interactions with proteins S4 and S12, mutations in which perturb the translational error frequency. The 530 loop is also thought to be located at or near the site of interaction of elongation factor Tu on the 30 S subunit, a location that is distinct from the decoding site. This study monitors the response of these two A-site-related regions of 16 S rRNA to a variety of translational miscoding agents. Several of these agents, including streptomycin, neomycin and ethanol, selectively potentiate tRNA-dependent protection of residue G530 from kethoxal modification; in contrast, little change in reactivity of residues A1492 and A1493 is observed. These results are consistent with the previously demonstrated importance of G530 for A-site function and, moreover, suggest a common mechanism of action for these miscoding agents, even though they appear to have distinctly different modes of interaction with 16 S rRNA. In contrast to the miscoding agents, we find that a streptomycin-dependence (SmD) mutation in protein S12, which causes ribosomes to be hyperaccurate, antagonizes tRNA-dependent protection of G530. The possibility that 5' or 3' flanking regions of mRNA could be involved in tRNA-dependent protection of G530 was tested by using different lengths of oligo(U) to promote binding of tRNA(Phe) to the A site. The relative levels of protection of G530, A1492 and A1493 were unchanged as the size of the mRNA fragment was decreased from 16 to 6 bases in length. We conclude, therefore, that for protection of G530 to be the result of direct contact with message, it must necessarily be located directly at the decoding site; otherwise, its protection is best explained by allosteric interactions, either with mRNA, or with the codon-anticodon complex. These results are discussed in terms of a model wherein the conformation of the 530 loop is correlated with the affinity of the ribosome for elongation factor Tu.

Alteration of the Saccharomyces cerevisiae COX2 mRNA 5'-untranslated leader by mitochondrial gene replacement and functional interaction with the translational activator protein PET111

The ability to replace wild-type mitochondrial DNA sequences in yeast with in vitro-generated mutations has been exploited to study the mechanism by which the nuclearly encoded PET111 protein specifically activates translation of the mitochondrially coded COX2 mRNA. We have generated three mutations in vitro that alter the COX2 mRNA 5'-untranslated leader (UTL) and introduced them into the mitochondrial genome, replacing the wild-type sequence. None of the mutations significantly affected the steady-state level of COX2 mRNA. Deletion of a single base at position -24 (relative to the translation initiation codon) in the 5'-UTL (cox2-11) reduced COX2 mRNA translation and respiratory growth, whereas insertion of four bases in place of the deleted base (cox2-12) and deletion of bases -30 to -2 (cox2-13) completely blocked both. Six spontaneous nuclear mutations were selected as suppressors of the single-base 5'-UTL deletion, cox2-11. One of these mapped to PET111 and was shown to be a missense mutation that changed residue 652 from Ala to Thr. This suppressor, PET111-20, failed to suppress the 29-base deletion, cox2-13, but very weakly suppressed the insertion mutation, cox2-12. PET111-20 also enhanced translation of a partially functional COX2 mRNA with a wild-type 5'-UTL but a mutant initiation codon. Although overexpression of the wild-type PET111 protein caused weak suppression of the single-base deletion, cox2-11, the PET111-20 suppressor mutation did not function simply by increasing the level of the protein. These results demonstrate an intimate functional interaction between the translational activator protein and the mRNA 5'-UTL and suggest that they may interact directly.

Single point mutations in domain II of the yeast mitochondrial release factor mRF-1 affect ribosome binding

We have recently described two yeast strains that are mutated in the MRF1 gene encoding the mitochondrial release factor mRF-1. Both mutants provoke gene-specific defects in mitochondrial translational termination. In the present study we report the cloning, sequencing, as well as an analysis of residual activities of both mutant mrf1 alleles. Each allele specifies a different single amino acid substitution located one amino acid apart. The amino acid changes do not affect the level or cellular localization of the mutant proteins, since equal amounts of wild type and mutant mRF-1 were detected in the mitochondrial compartment. Over-expression of the mutant alleles in wild type and mrf1 mutant yeast strains produces a phenotype consistent with a reduced affinity of the mutant release factors for the ribosome, indicating that the mutations map in a release factor domain involved in ribosome binding. We also demonstrate that nonsense suppression caused by a mutation in the mitochondrial homolog of the E. coli small ribosomal protein S4 can be reversed by a slight over-expression of the MRF1 gene.

Evidence for functional interaction between elongation factor Tu and 16S ribosomal RNA

Translation of the genetic code requires the accurate selection of elongation factor (EF)-Tu.GTP.tRNA ternary complexes at the ribosomal acceptor site, or A site. Several independent lines of evidence have implicated the universally conserved 530 loop of 16S rRNA in this process; yet its precise role has not been identified. Using an allele-specific chemical probing strategy, we have examined the functional defect caused by a dominant lethal G-->A substitution at position 530. We find that mutant ribosomes are impaired in EF-Tu-dependent binding of aminoacyl-tRNA in vitro; in contrast, nonenzymatic binding of tRNA to the A and P sites is unaffected, indicating that the defect involves an EF-Tu-related function rather than tRNA-ribosome interactions per se. In vivo, the mutant ribosomes are found in polysomes at low levels and contain reduced amounts of A-site-bound tRNA, but normal levels of P-site tRNA, in agreement with the in vitro results; thus the dominant lethal phenotype of mutations at G530 can be explained by impaired interaction of mutant ribosomes with ternary complex. These results provide evidence for a newly defined function of 16S rRNA--namely, modulation of EF-Tu activity during translation.

The yeast nuclear gene MRF1 encodes a mitochondrial peptide chain release factor and cures several mitochondrial RNA splicing defects

We report the molecular cloning, sequencing and genetic characterization of the first gene encoding an organellar polypeptide chain release factor, the MRF1 gene of the yeast Saccharomyces cerevisiae. The MRF1 gene was cloned by genetic complementation of a respiratory deficient mutant disturbed in the expression of the mitochondrial genes encoding cytochrome c oxidase subunit 1 and 2, COX1 and COX2. For COX1 this defect has been attributed to an impaired processing of several introns. Sequence analysis of the MRF1 gene revealed that it encodes a protein highly similar to prokaryotic peptide chain release factors, especially RF-1. Disruption of the gene results in a high instability of the mitochondrial genome, a hallmark for a strict lesion in mitochondrial protein synthesis. The respiratory negative phenotype of mrf1 mutants lacking all known mitochondrial introns and the reduced synthesis of mitochondrial translation products encoded by unsplit genes confirm a primary defect in mitochondrial protein synthesis. Over-expression of the MRF1 gene in a mitochondrial nonsense suppressor strain reduces suppression in a dosage-dependent manner, shedding new light on the role of the '530 region' of 16S-like ribosomal RNA in translational fidelity.

A ribosomal ambiguity mutation in the 530 loop of E. coli 16S rRNA

A series of base substitution and deletion mutations were constructed in the highly conserved 530 stem and loop region of E. coli 16S rRNA involved in binding of tRNA to the ribosomal A site. Base substitution and deletion of G517 produced significant effects on cell growth rate and translational fidelity, permitting readthrough of UGA, UAG and UAA stop codons as well as stimulating +1 and -1 frameshifting in vivo. By contrast, mutations at position 534 had little or no effect on growth rate or translational fidelity. The results demonstrate the importance of G517 in maintaining translational fidelity but do not support a base pairing interaction between G517 and U534.

Mutations in E.coli 16s rRNA that enhance and decrease the activity of a suppressor tRNA

The in vivo expression of mutations constructed within helix 34 of 16S rRNA has been examined together with a nonsense tRNA suppressor for their action at stop codons. The data revealed two novel results: in contrast to previous findings, some of the rRNA mutations affected suppression at UAA and UAG nonsense codons. Secondly, both an increase and a decrease in the efficiency of the suppressor tRNA were induced by the mutations. This is the first report that rRNA mutations decreased the efficiency of a suppressor tRNA. The data are interpreted as there being competition between the two release factors (RF-1 and RF-2) for an overlapping domain and that helix 34 influences this interaction.

Structure-function correlations (and discrepancies) in the 16S ribosomal RNA from Escherichia coli

The published model for the three-dimensional arrangement of E coli 16S RNA is re-examined in the light of new experimental information, in particular cross-linking data with functional ligands and cross-links between the 16S and 23S RNA molecules. A growing body of evidence suggests that helix 18 (residues 500-545), helix 34 (residues 1046-1067/1189-1211) and helix 44 (residues 1409-1491) are incorrectly located in the model. It now appears that the functional sites in helices 18 and 34 may be close to the decoding site of the 30S subunit, rather than being on the opposite side of the 'head' of the subunit, as hitherto supposed. Helix 44 is now clearly located at the interface between the 30S and 50S subunits. Furthermore, almost all of the modified bases in both 16S and 23S RNA appear to form a tight cluster near to the upper end of this helix, surrounding the decoding site.

A functional pseudoknot in 16S ribosomal RNA

Several lines of evidence indicate that the universally conserved 530 loop of 16S ribosomal RNA plays a crucial role in translation, related to the binding of tRNA to the ribosomal A site. Based upon limited phylogenetic sequence variation, Woese and Gutell (1989) have proposed that residues 524-526 in the 530 hairpin loop are base paired with residues 505-507 in an adjoining bulge loop, suggesting that this region of 16S rRNA folds into a pseudoknot structure. Here, we demonstrate that Watson-Crick interactions between these nucleotides are essential for ribosomal function. Moreover, we find that certain mild perturbations of the structure, for example, creation of G-U wobble pairs, generate resistance to streptomycin, an antibiotic known to interfere with the decoding process. Chemical probing of mutant ribosomes from streptomycin-resistant cells shows that the mutant ribosomes have a reduced affinity for streptomycin, even though streptomycin is thought to interact with a site on the 30S subunit that is distinct from the 530 region. Data from earlier in vitro assembly studies suggest that the pseudoknot structure is stabilized by ribosomal protein S12, mutations in which have long been known to confer streptomycin resistance and dependence.

Mutations in 16S rRNA that affect UGA (stop codon)-directed translation termination

Site-directed mutagenesis was performed on a sequence motif within the 3' major domain of Escherichia coli 16S rRNA shown previously to be important for peptide chain termination. Analysis of stop codon suppression by the various mutants showed an exclusive response to UGA stop signals, which was correlated directly with the continuity of one or the other of two tandem complementary UCA sequences (bases 1199-1204). Since no other structural features of the mutated ribosomes were hampered and the translation initiation and elongation events functioned properly, we propose that a direct interaction occurs between the UGA stop codon on the mRNA and the 16S rRNA UCA motif as one of the initial events of UGA-dependent peptide chain termination. These results provide evidence that base pairing between rRNA and mRNA plays a direct role in termination, as it has already been shown to do for initiation and elongation.

Mutations in the 915 region of Escherichia coli 16S ribosomal RNA reduce the binding of streptomycin to the ribosome

The nine possible single-base substitutions were produced at positions 913 to 915 of the 16S ribosomal RNA of Escherichia coli, a region known to be protected by streptomycin [Moazed, D. and Noller, H.F. (1987) Nature, 327, 389-394]. When the mutations were introduced into the expression vector pKK3535, only two of them (913A----G and 915A----G) permitted recovery of viable transformants. Ribosomes were isolated from the transformed bacteria and were assayed for their response to streptomycin in poly(U)- and MS2 RNA-directed assays. They were resistant to the stimulation of misreading and to the inhibition of protein synthesis by streptomycin, and this correlated with a decreased binding of the drug. These results therefore demonstrate that, in line with the footprinting studies of Moazed and Noller, mutations in the 915 region alter the interaction between the ribosome and streptomycin.

A single base substitution in 16S ribosomal RNA suppresses streptomycin dependence and increases the frequency of translational errors

A C to U substitution at position 1469 of 16S ribosomal RNA (rRNA) from Escherichia coli suppresses streptomycin dependence and causes increased translational error frequencies. Strains containing the rpsL252 or StrM287 streptomycin-dependent alleles are able to grow in the absence of streptomycin when transformed with plasmids containing the U1469 mutation in 16S rRNA. Ribosomes containing wild-type proteins and U1469 mutant 16S rRNA misincorporate leucine in vitro at elevated levels, comparable to that of some typical S4 ram ribosomes. These results provide additional support for the participation of 16S rRNA in maintaining translational accuracy.

A rRNA-mRNA base pairing model for UGA-dependent termination

A series of site-directed mutations has been constructed in E coli 16S rRNA and shown to suppress UGA-dependent translational termination. With the exception of the C726 to G base change, all were constructed in helix 34. Characterization of these mutations is reviewed here and from these data and mRNA-rRNA base pairing model for the termination event is presented. The interaction functions via antiparallel base pairing between either 1 of the 2 UCA motifs in helix 34 and the complementary UGA stop codon on the message, thus forming a quasicontinuous A-type helical structure that is further stabilized by stacking enthalpy. Finally, rRNA motifs potentially required for UAA and UAG-dependent translational termination are discussed.

The signal for a leaky UAG stop codon in several plant viruses includes the two downstream codons

Expression of the RNA replicase domain of tobacco mosaic virus (TMV) and certain protein-coding regions in other plant viruses, is mediated by translational readthrough of a leaky UAG stop codon. It has been proposed that normal tobacco tyrosine tRNAs are able to read the UAG codon of TMV by non-conventional base-pairing but recent findings that stop codons can also be bypassed as a result of extended translocational shifts (tRNA hopping) have encouraged a re-examination. In light of the alternatives, we investigated the sequences flanking the leaky UAG codon using an in vivo assay in which bypass of the stop codon is coupled to the transient expression of beta-glucuronidase (GUS) reporter genes in tobacco protoplasts. Analysis of GUS constructions in which codons flanking the stop were altered allowed definition of the minimal sequence required for read through as UAG-CAA-UUA. The effects of all possible single-base mutations in the codons flanking the stop indicated that 3' contexts of the form CAR-YYA confer leakiness and that the 3' context permits read through of UAA and UGA stop codons as well as UAG. Our studies demonstrate a major role for the 3' context in the read through process and do not support a model in which teh UAG is bypassed exclusively as a result of anticodon-codon interactions. No evidence for tRNA hopping was obtained. The 3' context apparently represents a unique sequence element that affects translation termination.

The involvement of base 1054 in 16S rRNA for UGA stop codon dependent translational termination

The deletion of the highly conserved cytidine nucleotide at position 1054 in E. coli 16S rRNA has been characterized to confer an UGA stop codon specific suppression activity which suggested a functional participation of small subunit rRNA in translational termination. Based on this structure-function correlation we constructed the three point mutations at site 1054, changing the wild-type C residue to an A, G or U base. The mutations were expressed from a complete plasmid encoded rRNA operon (rrnB) using a conditional expression system with the lambda PL-promoter. All three altered 16S rRNA molecules were expressed and incorporated into 70S ribosomal particles. Structural analysis of the protein and 16S rRNA moieties of the mutant ribosomes showed no differences when compared to wild-type particles. The phenotypic analysis revealed that only the 1054G base change led to a significantly reduced generation time of transformed cells, which could be correlated with the inability of the mutant ribosomes to specifically stop at UGA stop codons in vivo. The response towards UAA and UAG termination codons was not altered. Furthermore, in vitro RF-2 termination factor binding experiments indicated that the association behaviour of mutant ribosomes was not changed, enforcing the view that the UGA stop codon suppression is a direct consequence of the rRNA mutation. Taken together, these results argue for a direct participation of that 16S rRNA motif in UGA dependent translational termination and furthermore, suggest that termination factor binding and stop codon recognition are two separate steps of the termination event.

Analysis of leaky viral translation termination codons in vivo by transient expression of improved beta-glucuronidase vectors

Plant RNA viruses commonly exploit leaky translation termination signals in order to express internal protein coding regions. As a first step to elucidate the mechanism(s) by which ribosomes bypass leaky stop codons in vivo, we have devised a system in which readthrough is coupled to the transient expression of beta-glucuronidase (GUS) in tobacco protoplasts. GUS vectors that contain the stop codons and surrounding nucleotides from the readthrough regions of several different RNA viruses were constructed and the plasmids were tested for the ability to direct transient GUS expression. These studies indicated that ribosomes bypass the leaky termination sites at efficiencies ranging from essentially 0 to ca. 5% depending upon the viral sequence. The results suggest that the efficiency of readthrough is determined by the sequence surrounding the stop codon. We describe improved GUS expression vectors and optimized transfection conditions which made it possible to assay low-level translational events.

Dominant lethal mutations in a conserved loop in 16S rRNA

The 530 stem-loop region in 16S rRNA is among the most phylogenetically conserved structural elements in all rRNAs, yet its role in protein synthesis remains mysterious. G-530 is protected from kethoxal attack when tRNA, or its 15-nucleotide anticodon stem-loop fragment, is bound to the ribosomal A site. Based on presently available evidence, however, this region is believed to be too remote from the decoding site for this protection to be the result of direct contact. In this study, we use a conditional rRNA expression system to demonstrate that plasmid-encoded 16S rRNA genes carrying A, C, and T point mutations at position G-530 confer a dominant lethal phenotype when expressed in Escherichia coli. Analysis of the distribution of plasmid-encoded 16S rRNA in ribosomal particles, following induction of the A-530 mutation, shows that mutant rRNA is present both in 30S subunits and in 70S ribosomes. Little mutant rRNA is found in polyribosomes, however, indicating that the mutant ribosomes are severely impaired at the stage of polysome formation and/or stability. Detailed chemical probing of mutant ribosomal particles reveals no evidence of structural perturbation within the 16S rRNA. Taken together, these results argue for the direct participation of G-530 in ribosomal function and, furthermore, suggest that the dominant lethal phenotype caused by these mutations is due primarily to the mutant ribosomes blocking a crucial step in protein synthesis after translational initiation.