A protein required for splicing group I introns in Neurospora mitochondria is mitochondrial tyrosyl-tRNA synthetase or a derivative thereof

Mitochondrial DNA of cytoplasmic male-sterile Triticum timopheevi: rearrangement of upstream sequences of the atp6 and orf25 genes

The organization of mitochondrial DNA (mtDNA) and transcript patterns of the atp6 and orf25 genes were examined in cytoplasmic male-sterile (CMS) and fertile Triticum lines. Major differences are observed between CMS T. timopheevi and fertile T. aestivum for both mitochondrial genes. The T. aestivum mt genome carries two atp6 gene copies, whereas only a single copy of the atp6 gene is present in T. timopheevi mtDNA. Sequence data suggest that identical sequences upstream of the atp6 gene and the orf25 gene are involved in homologous recombination in both cytoplasms. The differences in the upstream sequences of the atp6 or the orf25 genes affect transcript sizes in both cytoplasms. Transcription initiation may occur at conserved promoter elements located at variable distances upstream of the aminoacid coding sequences. The correlation between the gene rearrangements and the CMS phenomenon in T. timopheevi is discussed.

A mobile group I intron from Physarum polycephalum can insert itself and induce point mutations in the nuclear ribosomal DNA of saccharomyces cerevisiae

Pp LSU3 is a mobile group I intron in the extrachromosomal nuclear ribosomal DNA (rDNA) of Physarum polycephalum. As found for other mobile introns, Pp LSU3 encodes a site-specific endonuclease, I-Ppo, which mediates "homing" to unoccupied target sites in Physarum rDNA. The recognition sequence for this enzyme is conserved in all eucaryotic nuclear rDNAs. We have introduced this intron into a heterologous species, Saccharomyces cerevisiae, in which nuclear group I introns have not been detected. The expression of Pp LSU3, under control of the inducible GAL10 promoter, was found to be lethal as a consequence of double-strand breaks in the rDNA. However, surviving colonies that are resistant to the lethal effects of I-Ppo because of alterations in the rDNA at the cleavage site were recovered readily. These survivors are of two classes. The first comprises cells that acquired one of three types of point mutations. The second comprises cells in which Pp LSU3 became inserted into the rDNA. In both cases, each resistant survivor appears to carry the same alterations in all approximately 150 rDNA repeats. When it is embedded in yeast rDNA, Pp LSU3 leads to the synthesis of I-Ppo and appears to be mobile in appropriate genetic crosses. The existence of yeast cells carrying a mobile intron should allow dissection of the steps that allow expression of the highly unusual I-Ppo gene.

A mobile group I intron from Physarum polycephalum can insert itself and induce point mutations in the nuclear ribosomal DNA of saccharomyces cerevisiae

Pp LSU3 is a mobile group I intron in the extrachromosomal nuclear ribosomal DNA (rDNA) of Physarum polycephalum. As found for other mobile introns, Pp LSU3 encodes a site-specific endonuclease, I-Ppo, which mediates "homing" to unoccupied target sites in Physarum rDNA. The recognition sequence for this enzyme is conserved in all eucaryotic nuclear rDNAs. We have introduced this intron into a heterologous species, Saccharomyces cerevisiae, in which nuclear group I introns have not been detected. The expression of Pp LSU3, under control of the inducible GAL10 promoter, was found to be lethal as a consequence of double-strand breaks in the rDNA. However, surviving colonies that are resistant to the lethal effects of I-Ppo because of alterations in the rDNA at the cleavage site were recovered readily. These survivors are of two classes. The first comprises cells that acquired one of three types of point mutations. The second comprises cells in which Pp LSU3 became inserted into the rDNA. In both cases, each resistant survivor appears to carry the same alterations in all approximately 150 rDNA repeats. When it is embedded in yeast rDNA, Pp LSU3 leads to the synthesis of I-Ppo and appears to be mobile in appropriate genetic crosses. The existence of yeast cells carrying a mobile intron should allow dissection of the steps that allow expression of the highly unusual I-Ppo gene.

RNA processing in prokaryotic cells

RNA processing in Escherichia coli and some of its phages is reviewed here, with primary emphasis on rRNA and tRNA processing. Three enzymes, RNase III, RNase E and RNase P are responsible for most of the primary endonucleolytic RNA processing events. The first two are proteins, while RNase P is a ribozyme. These three enzymes have unique functions and in their absence, the cleavage events they catalyze are not performed. On the other hand a relatively large number of exonucleases participate in the trimming of the 3' ends of tRNA precursor molecules and they can substitute for each other. Primary processing is the first event that happens to the nascent RNA molecule, while in secondary RNA processing, the substrate is a product of a primary processing event. Although most RNA processing occurs in RNP particles, it seems that only in secondary RNA processing is the RNP particle required for the reaction. Bacteria and especially bacteriophages contain self-splicing introns which in cases were probably acquired from other species.

Sequence-specific binding of transfer RNA by glyceraldehyde-3-phosphate dehydrogenase

A transfer RNA (tRNA) binding protein present in HeLa cell nuclear extracts was purified and identified as the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase (GAPDH). Studies with mutant tRNAs indicated that GAPDH recognizes both sequence and structural features in the RNA. GAPDH discriminated between wild-type tRNA and two tRNA mutants that are defective in nuclear export, which suggests that the protein may participate in RNA export. The cofactor nicotinamide adenine dinucleotide disrupted complex formation between tRNA and GAPDH and thus may share a common binding site with the RNA. Indirect immunofluorescence experiments showed that GAPDH is present in the nucleus as well as in the cytoplasm.

The asparaginyl-tRNA synthetase gene encodes one of the complementing factors for thermosensitive translation in the Escherichia coli mutant strain, N4316

Escherichia coli strain N4316 is a mutant that exhibits temperature-sensitive growth at 43 degrees C and temperature-sensitive translation in vivo and in vitro. Extracts of the mutant produce an aberrant pattern of translation products of MS2 bacteriophage RNA. Previous work has shown that a protein, called 'rescue', isolated from the parental strain partly corrects the defective translation in vitro. Here we report the purification to homogeneity of a second factor from ribosomal eluates of the wild-type parental strain; the purified protein is a homodimer of 54 kDa. The partial sequence of the second protein was determined, and a recombinant plasmid was isolated based on its ability to complement the temperature-sensitive growth phenotype of the mutant at the non-permissive temperatures. The cloned gene was sequenced, mapped to the 20.9-min region of the E. coli chromosome and shown to code for a 466-amino-acid protein with a molecular mass of 52 kDa. Analysis of the DNA sequence and the correspondence to that of the partial protein sequence has identified the complementing factor as asparaginyl-tRNA synthetase. Marker rescue experiments indicate that the asnS mutation in N4316 resides within the motif 2 domain of the synthetase. A potential role of this synthetase in restoring normal protein synthesis with respect to ribosomal frameshifting, read-through of nonsense codons and protein copy number is discussed.

Experimental studies on the origin of the genetic code and the process of protein synthesis: a review update

This article is an update of our earlier review (Lacey and Mullins, 1983) in this journal on the origin of the genetic code and the process of protein synthesis. It is our intent to discuss only experimental evidence published since then although there is the necessity to mention the old enough to place the new in context. We do not include theoretical nor hypothetical treatments of the code or protein synthesis. Relevant data regarding the evolution of tRNAs and the recognition of tRNAs by aminoacyl-tRNA-synthetases are discussed. Our present belief is that the code arose based on a core of early assignments which were made on a physico-chemical and anticodonic basis and this was expanded with new assignments later. These late assignments do not necessarily show an amino acid-anticodon relatedness. In spite of the fact that most data suggest a code origin based on amino acid-anticodon relationships, some new data suggesting preferential binding of Arg to its codons are discussed. While information regarding coding is not increasing very rapidly, information regarding the basic chemistry of the process of protein synthesis has increased significantly, principally relating to aminoacylation of mono- and polyribonucleotides. Included in those studies are several which show stereoselective reactions of L-amino acids with nucleotides having D-sugars. Hydrophobic interactions definitely play a role in the preferences which have been observed.

A tyrosyl-tRNA synthetase binds specifically to the group I intron catalytic core

The Neurospora CYT-18 protein, the mitochondrial tyrosyl-tRNA synthetase, functions in splicing group I introns in mitochondria. Here, we show that CYT-18 binds strongly to diverse group I introns that have minimal sequence homology and recognizes highly conserved structural features of the catalytic core of these introns. Inhibition experiments indicate that the intron RNA and tRNA(Tyr) compete for the same or overlapping binding sites in the CYT-18 protein. Considered together with functional analysis, our results indicate that the CYT-18 protein promotes splicing by binding to the intron core and stabilizing it in a conformation required for catalytic activity. Furthermore, the specific binding of the synthetase suggests that the group I intron catalytic core has structural similarities to tRNAs, which could reflect either convergent evolution or an evolutionary relationship between group I introns and tRNAs.

In vitro mutagenesis of the mitochondrial leucyl-tRNA synthetase of S. cerevisiae reveals residues critical for its in vivo activities

The mitochondrial leucyl-tRNA synthetase (mLRS) of Saccharomyces cerevisiae is involved in both mitochondrial protein synthesis and pre-mRNA splicing. We have created mutations in the regions HIGH, GWD and KMSKS, which are involved in ATP-, amino acid- and tRNA-binding respectively, and which have been conserved in the evolution of group I tRNA synthetases. The mutants GRD and NMSKS have no discernible phenotype. The mutants AWD and ARD act as null alleles and lead to the production of 100% cytoplasmic petites. The mutants HIGN, NIGH and KMSNS are unable to grow on glycerol even in the presence of an intronless mitochondrial genome and accumulate petites to a greater extent than the wild-type but less than 40%. Experiments with an imported bI4 maturase indicate that the lesion in these mutations primarily affects the synthetase and not the splicing functions.

Adenylosuccinate lyase of Bacillus subtilis regulates the activity of the glutamyl-tRNA synthetase

In Bacillus subtilis, the glutamyl-tRNA synthetase [L-glutamate:tRNA(Glu) ligase (AMP-forming), EC 6.1.1.17] is copurified with a polypeptide of M(r) 46,000 that influences its affinity for its substrates and increases its thermostability. The gene encoding this regulatory factor was cloned with the aid of a 41-mer oligonucleotide probe corresponding to the amino acid sequence of an NH2-terminal segment of this factor. The nucleotide sequence of this gene and the physical map of the 1475-base-pair fragment on which it was cloned are identical to those of purB, which encodes the adenylosuccinate lyase (adenylosuccinate AMP-lyase, EC 4.3.2.2), an enzyme involved in the de novo synthesis of purines. This gene complements the purB mutation of Escherichia coli JK268, and its presence on a multicopy plasmid behind the trc promoter in the purB- strain gives an adenylosuccinate lyase level comparable to that in wild-type B. subtilis. A complex between the adenylosuccinate lyase and the glutamyl-tRNA synthetase was detected by centrifugation on a density gradient. The interaction between these enzymes may play a role in the coordination of purine metabolism and protein biosynthesis.

The neurospora CYT-18 protein suppresses defects in the phage T4 td intron by stabilizing the catalytically active structure of the intron core

The Neurospora CYT-18 protein, a tyrosyl-tRNA synthetase, which functions in splicing group I introns in mitochondria, promotes splicing of mutants of the distantly related bacteriophage T4 td intron. In an in vivo assay, wild-type CYT-18 protein expressed in E. coli suppressed mutations in the td intron's catalytic core. CYT-18-suppressible mutations were also suppressed by high Mg2+ or spermidine in vitro, suggesting they affect intron structure. Both the N- and C-terminal domains of CYT-18 are required for efficient splicing, but CYT-18 with a large C-terminal truncation retains some activity. Our results indicate that CYT-18 interacts with conserved structural features of group I introns, and they provide direct evidence that a protein promotes splicing by stabilizing the catalytically active structure of the intron RNA.

A protein required for RNA processing and splicing in Neurospora mitochondria is related to gene products involved in cell cycle protein phosphatase functions

The Neurospora crassa cyt-4 mutants have pleiotropic defects in mitochondrial RNA splicing, 5' and 3' end processing, and RNA turnover. Here, we show that the cyt-4+ gene encodes a 120-kDa protein with significant similarity to the SSD1/SRK1 protein of Saccharomyces cerevisiae and the DIS3 protein of Schizosaccharomyces pombe, which have been implicated in protein phosphatase functions that regulate cell cycle and mitotic chromosome segregation. The CYT-4 protein is present in mitochondria and is truncated or deficient in two cyt-4 mutants. Assuming that the CYT-4 protein functions in a manner similar to the SSD1/SRK1 and DIS3 proteins, we infer that the mitochondrial RNA splicing and processing reactions defective in the cyt-4 mutants are regulated by protein phosphorylation and that the defects in the cyt-4 mutants result from failure to normally regulate this process. Our results provide evidence that RNA splicing and processing reactions may be regulated by protein phosphorylation.

The mitochondrial tyrosyl-tRNA synthetase of Podospora anserina is a bifunctional enzyme active in protein synthesis and RNA splicing

The Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (mt tyrRS), which is encoded by the nuclear gene cyt-18, functions not only in aminoacylation but also in the splicing of group I introns. Here, we isolated the cognate Podospora anserina mt tyrRS gene, designated yts1, by using the N. crassa cyt-18 gene as a hybridization probe. DNA sequencing of the P. anserina gene revealed an open reading frame (ORF) of 641 amino acids which has significant similarity to other tyrRSs. The yts1 ORF is interrupted by two introns, one near its N terminus at the same position as the single intron in the cyt-18 gene and the other downstream in a region corresponding to the nucleotide-binding fold. The P. anserina yts1+ gene transformed the N. crassa cyt-18-2 mutant at a high frequency and rescued both the splicing and protein synthesis defects. Furthermore, the YTS1 protein synthesized in Escherichia coli was capable of splicing the N. crassa mt large rRNA intron in vitro. Together, these results indicate that YTS1 is a bifunctional protein active in both splicing and protein synthesis. The P. anserina YTS1 and N. crassa CYT-18 proteins share three blocks of amino acids that are not conserved in bacterial or yeast mt tyrRSs which do not function in splicing. One of these blocks corresponds to the idiosyncratic N-terminal domain shown previously to be required for splicing activity of the CYT-18 protein. The other two are located in the putative tRNA-binding domain toward the C terminus of the protein and also appear to be required for splicing. Since the E. coli and yeast mt tyrRSs do not function in splicing, the adaptation of the Neurospora and Podospora spp. mt tyrRSs to function in splicing most likely occurred after the divergence of their common ancestor from yeast.

Connections between RNA splicing and DNA intron mobility in yeast mitochondria: RNA maturase and DNA endonuclease switching experiments

The intron-encoded proteins bI4 RNA maturase and aI4 DNA endonuclease can be faithfully expressed in yeast cytoplasm from engineered forms of their mitochondrial coding sequences. In this work we studied the relationships between these two activities associated with two homologous intron-encoded proteins: the bI4 RNA maturase encoded in the fourth intron of the cytochrome b gene and the aI4 DNA endonuclease (I-SceII) encoded in the fourth intron of the gene coding for the subunit I of cytochrome oxidase. Taking advantage of both the high recombinogenic properties of yeast and the similarities between the two genes, we constructed in vivo a family of hybrid genes carrying parts of both RNA maturase and DNA endonuclease coding sequences. The presence of a sequence coding for a mitochondrial targeting peptide upstream from these hybrid genes allowed us to study the properties of their translation products within the mitochondria in vivo. We thus could analyze the ability of the recombinant proteins to complement RNA maturase deficiencies in different strains. Many combinations of the two parental intronic sequences were found in the recombinants. Their structural and functional analysis revealed the following features. (i) The N-terminal half of the bI4 RNA maturase could be replaced in total by its equivalent from the aI4 DNA endonuclease without affecting the RNA maturase activity. In contrast, replacing the C-terminal half of the bI4 RNA maturase with its equivalent from the aI4 DNA endonuclease led to a very weak RNA maturase activity, indicating that this region is more differentiated and linked to the maturase activity. (ii) None of the hybrid proteins carrying an RNA maturase activity kept the DNA endonuclease activity, suggesting that the latter requires the integrity of the aI4 protein. These observations are interesting because the aI4 DNA endonuclease is known to promote the propagation, at the DNA level, of the aI4 intron, whereas the bI4 RNA maturase, which is required for the splicing of its coding intron, also controls the splicing process of the aI4 intron. We propose a scenario for the evolution of these intronic proteins that relies on a switch from DNA endonuclease to RNA maturase activity.

Role of residue Glu152 in the discrimination between transfer RNAs by tyrosyl-tRNA synthetase from Bacillus stearothermophilus

Residue Glu152 of tyrosyl-tRNA synthetase (TyrTS) from Bacillus stearothermophilus is close to phosphate groups 73 and 74 of tRNATyr in the structural model of their complex. TyrTS(E152A), a mutant synthetase carrying the change of Glu152 to Ala, was toxic when overproduced in Escherichia coli. The toxicity strongly increased with the growth temperature. It was measured by the ratios of the efficiencies with which the producing cells plated in induced or repressed conditions and at 30 degrees C or 37 degrees C. TyrTS(E152Q), TyrTS(E152D) and the wild-type synthetase were not toxic in conditions where TyrTS(E152A) was toxic. The toxicity of TyrTS(E152A) was abolished by additional mutations of the synthetase that prevent the binding of tRNATyr but not by a mutation that prevents the formation of Tyr-AMP. Because TyrTS(E152A) was active for the aminoacylation of tRNATyr, its toxicity could only be due to faulty interactions with non-cognate tRNAs, either their non-productive binding or their mischarging with tyrosine. TyrTS(E152A) and TyrTS(E152Q) mischarged tRNAPhe and tRNAVal in vitro with tyrosine unlike TyrTS(E152D) or the wild-type enzyme. Thus, several features of the side-chain in position 152 of TyrTS, including its negative charge, are important for the rejection of non-cognate tRNAs. TyrTS(E152A), TyrTS(E152D) and TyrTS(E152Q) had similar steady-state kinetics parameters for the charging of tRNATyr with tyrosine in vitro, with kcat/KM ratios improved 2.5 times relative to the wild-type synthetase. We conclude that the side-chain of residue Glu152 weakens the binding of TyrTS to tRNATyr and prevents its interaction with non-cognate tRNAs.

Connections between RNA splicing and DNA intron mobility in yeast mitochondria: RNA maturase and DNA endonuclease switching experiments

The intron-encoded proteins bI4 RNA maturase and aI4 DNA endonuclease can be faithfully expressed in yeast cytoplasm from engineered forms of their mitochondrial coding sequences. In this work we studied the relationships between these two activities associated with two homologous intron-encoded proteins: the bI4 RNA maturase encoded in the fourth intron of the cytochrome b gene and the aI4 DNA endonuclease (I-SceII) encoded in the fourth intron of the gene coding for the subunit I of cytochrome oxidase. Taking advantage of both the high recombinogenic properties of yeast and the similarities between the two genes, we constructed in vivo a family of hybrid genes carrying parts of both RNA maturase and DNA endonuclease coding sequences. The presence of a sequence coding for a mitochondrial targeting peptide upstream from these hybrid genes allowed us to study the properties of their translation products within the mitochondria in vivo. We thus could analyze the ability of the recombinant proteins to complement RNA maturase deficiencies in different strains. Many combinations of the two parental intronic sequences were found in the recombinants. Their structural and functional analysis revealed the following features. (i) The N-terminal half of the bI4 RNA maturase could be replaced in total by its equivalent from the aI4 DNA endonuclease without affecting the RNA maturase activity. In contrast, replacing the C-terminal half of the bI4 RNA maturase with its equivalent from the aI4 DNA endonuclease led to a very weak RNA maturase activity, indicating that this region is more differentiated and linked to the maturase activity. (ii) None of the hybrid proteins carrying an RNA maturase activity kept the DNA endonuclease activity, suggesting that the latter requires the integrity of the aI4 protein. These observations are interesting because the aI4 DNA endonuclease is known to promote the propagation, at the DNA level, of the aI4 intron, whereas the bI4 RNA maturase, which is required for the splicing of its coding intron, also controls the splicing process of the aI4 intron. We propose a scenario for the evolution of these intronic proteins that relies on a switch from DNA endonuclease to RNA maturase activity.

The mitochondrial tyrosyl-tRNA synthetase of Podospora anserina is a bifunctional enzyme active in protein synthesis and RNA splicing

The Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (mt tyrRS), which is encoded by the nuclear gene cyt-18, functions not only in aminoacylation but also in the splicing of group I introns. Here, we isolated the cognate Podospora anserina mt tyrRS gene, designated yts1, by using the N. crassa cyt-18 gene as a hybridization probe. DNA sequencing of the P. anserina gene revealed an open reading frame (ORF) of 641 amino acids which has significant similarity to other tyrRSs. The yts1 ORF is interrupted by two introns, one near its N terminus at the same position as the single intron in the cyt-18 gene and the other downstream in a region corresponding to the nucleotide-binding fold. The P. anserina yts1+ gene transformed the N. crassa cyt-18-2 mutant at a high frequency and rescued both the splicing and protein synthesis defects. Furthermore, the YTS1 protein synthesized in Escherichia coli was capable of splicing the N. crassa mt large rRNA intron in vitro. Together, these results indicate that YTS1 is a bifunctional protein active in both splicing and protein synthesis. The P. anserina YTS1 and N. crassa CYT-18 proteins share three blocks of amino acids that are not conserved in bacterial or yeast mt tyrRSs which do not function in splicing. One of these blocks corresponds to the idiosyncratic N-terminal domain shown previously to be required for splicing activity of the CYT-18 protein. The other two are located in the putative tRNA-binding domain toward the C terminus of the protein and also appear to be required for splicing. Since the E. coli and yeast mt tyrRSs do not function in splicing, the adaptation of the Neurospora and Podospora spp. mt tyrRSs to function in splicing most likely occurred after the divergence of their common ancestor from yeast.

Integration of a group I intron into a ribosomal RNA sequence promoted by a tyrosyl-tRNA synthetase

Group I and II introns are mobile elements that propagate by insertion into different genes. Some introns of both types self-splice in vitro by transesterification reactions catalysed by the intron RNA. These transesterifications are reversible, and it has been suggested that reverse splicing followed by reverse transcription and recombination with genomic DNA may be a mechanism for intron transposition. In vivo the splicing of many, if not all, group I and II introns requires protein factors, which may facilitate correct folding of the intron RNAs. Here we show that the Neurospora mitochondrial large rRNA intron, a group I intron that is not self-splicing in vitro, undergoes reverse splicing in a reaction promoted by the CYT-18 protein, the Neurospora mitochondrial tyrosyl-tRNA synthetase, which is required for splicing the intron in vivo. In contrast to known RNA-catalysed reverse splicing reactions, this protein-assisted reverse splicing is sufficiently rapid to compete with forward splicing at low RNA concentrations under physiologically relevant conditions, including high GTP and low Mg2+ concentrations. Our results indicate that proteins that promote splicing could contribute to intron mobility by promoting reverse splicing in vivo.

Binding of the CBP2 protein to a yeast mitochondrial group I intron requires the catalytic core of the RNA

The yeast CBP2 gene product is required for the splicing of the terminal intron (bI5) of the mitochondrial cytochrome b pre-mRNA in vivo. In vitro, bI5 RNA self-splices efficiently only at high MgCl2 concentrations (50 mM); at 5 mM MgCl2, efficient splicing requires purified CBP2 protein. To determine the sequences within bI5 recognized by the protein, we have constructed deletion and substitution mutants of the RNA. Their binding to CBP2 was assessed by their ability to inhibit protein-dependent splicing of the wild-type bI5 RNA. Several regions, including the large L1 and L8 loops, can be deleted without affecting binding. They can therefore be eliminated from consideration as critical recognition elements. In contrast, other changes prevent the RNA from binding CBP2 and also impair self-splicing. Thus, either the catalytic core contacts the protein directly, or the integrity of the core is required for proper display of other RNA sequences that bind the protein. The results are consistent with a model in which the CBP2 protein facilitates splicing by binding to and stabilizing the active structure of the RNA. However, a more specific model is proposed in which the protein specifically enhances Mg2+ binding required for catalysis.

Antibiotic inhibition of group I ribozyme function

The discovery of catalytically active RNA has provided the basis for the evolutionary concept of an RNA world. It has been proposed that during evolution the functions of ancient catalytic RNA were modulated by low molecular weight effectors, related to antibiotics, present in the primordial soup. Antibiotics and RNA may have coevolved in the formation of the modern ribosome. Here we report that a set of aminoglycoside antibiotics, which are known to interact with the decoding region of the 16S ribosomal RNA of Escherichia coli, inhibit the second step of splicing of the T4 phage-derived td intron. Thus catalytic RNA seems to interact not only with a mononucleotide and an amino acid, but also with another class of biomolecules, the sugars. Splicing of other group I introns but not group II introns was inhibited. The similarity in affinity and specificity of these antibiotics for group I introns and rRNAs may result from recognition of evolutionarily conserved structures.

Evidence that gene G7a in the human major histocompatibility complex encodes valyl-tRNA synthetase

At least 36 genes have now been located in a 680 kb segment of DNA between the class I and class II multigene families within the class III region of the human major histocompatibility complex on chromosome 6p21.3. The complete nucleotide sequence of the 4.3 kb mRNA of one of these genes, G7a (or BAT6), has been determined from cDNA and genomic clones. The single-copy G7a gene encodes a 1265-amino-acid protein of molecular mass 140,457 Da. Comparison of the derived amino acid sequence of the G7a protein with the National Biomedical Research Foundation protein databases revealed 42% identity in a 250-amino-acid overlap with Bacillus stearothermophilus valyl-tRNA synthetase, 38.0% identity in a 993-amino-acid overlap with Escherichia coli valyl-tRNA synthetase (val RS), and 48.3% identity in a 1043-amino-acid overlap with Saccharomyces cerevisiae valyl-tRNA synthetase. The protein sequence of G7a contains two short consensus sequences, His-Ile-Gly-His and Lys-Met-Ser-Lys-Ser, which is the typical signature structure of class I tRNA synthetases and indicative of the presence of the Rossman fold. In addition, the molecular mass of the G7a protein is the same as that of other mammalian valyl-tRNA synthetases. These features and the high sequence identity with yeast valyl-tRNA synthetase strongly support the fact that the G7a gene, located within the major histocompatibility complex, encodes the human valyl-tRNA synthetase.

A mammalian tryptophanyl-tRNA synthetase shows little homology to prokaryotic synthetases but near identity with mammalian peptide chain release factor

Determination of the amino acid sequence of beef pancreas tryptophanyl-tRNA synthetase was undertaken through both cDNA and direct peptide sequencing. A full-length cDNA clone containing a 475 amino acid open reading frame was obtained. The molecular mass of the corresponding peptide chain, 53,728 Da, was in agreement with that of beef tryptophanyl-tRNA synthetase, as determined by physicochemical methods (54 kDa). Expression of this clone in Escherichia coli led to tryptophanyl-tRNA synthetase activity in cell extracts. The open reading frame included two sequences analogous to the consensus sequences, HIGH and KMSKS, found in class I aminoacyl-tRNA synthetases. The homology with prokaryotic and yeast mitochondrial tryptophanyl-tRNA synthetases was low and was limited to the regions of the consensus sequences. However, a 90% homology was observed with the recently described rabbit peptide chain release factor (eRF) [Lee et al. (1990) Proc. Natl. Acad. Sci. 87, 3508-3512]. Such a strong homology may reveal a new group of genes deriving from a common ancestor, the products of which could be involved in tRNA aminoacylation (tryptophanyl-tRNA synthetase) or translation termination (eRF).

A severely truncated form of translational initiation factor 2 supports growth of Escherichia coli

We have constructed strains carrying null mutations in the chromosomal copy of the gene for translational initiation factor (IF) 2 (infB). A functional copy of the infB gene is supplied in trans by a thermosensitive lysogenic lambda phage integrated at att lambda. These strains enabled us to test in vivo the importance of different structural elements of IF2 expressed from genetically engineered plasmid constructs. We found that, as expected, the gene for IF2 is essential. However, a protein consisting of the C-terminal 55,000 Mr fragment of the wild-type IF2 protein is sufficient to allow growth when supplied in excess. This result suggests that the catalytic properties are localized in the C-terminal half of the protein, which includes the G-domain, and that this fragment is sufficient to complement the IF2 deficiency in the infB deletion strain.

The Neurospora mitochondrial tyrosyl-tRNA synthetase is sufficient for group I intron splicing in vitro and uses the carboxy-terminal tRNA-binding domain along with other regions

Neurospora mitochondrial tyrosyl-tRNA synthetase (mt tyrRS), which is encoded by nuclear gene cyt-18, functions in splicing of group I introns in mitochondria. Here, we overproduced functional cyt-18 protein in Escherichia coli and purified it to near homogeneity. The purified protein has splicing and tyrRS activities similar to those of cyt-18 protein isolated from mitochondria and is by itself sufficient to splice the mitochondrial large rRNA intron in vitro. Structure-function relationships in the cyt-18 protein were analyzed by in vitro mutagenesis. We confirmed that a small amino-terminal domain not found in bacterial tyrRSs is required for splicing activity, but not tyrRS activity. Two linker insertion mutations, which disrupt the predicted ATP-binding site, completely inhibit tyrRS activity but leave substantial splicing activity. Finally, deletions or linker insertion mutations in the putative carboxy-terminal tRNA-binding domain inhibit both tyrRS and splicing activities, although some have differential effects on the two activities. Our results show that the normal catalytic activity of the cyt-18 protein is not required for splicing and are consistent with the hypothesis that the protein functions by binding to the precursor RNA and facilitating formation of the correct RNA structure. Regions required for splicing are distributed throughout the cyt-18 protein and overlap, but are not identical to, regions required for tyrRS activity. The finding that the putative carboxy-terminal tRNA-binding domain is required for both tyrRS and splicing activities suggests that the mechanism for binding the intron has similarities to the mechanism for binding tRNA(Tyr).

The nuclear coded mitoribosomal proteins YmL27 and YmL31 are both essential for mitochondrial function in yeast

Using synthetic oligonucleotides deduced from the N-terminal amino acid sequence of purified mitoribosomal protein (mt r-protein) YmL27, the corresponding nuclear gene MRP-L27 of the yeast Saccharomyces cerevisiae has been cloned and sequenced. The MRP-L27 gene codes for 146 amino acids and is located on chromosome X. The mature YmL27 protein consists of 130 amino acids - after cleaving the putative mitochondrial signal peptide - with a net charge of +17 and a calculated relative molecular mass of 14,798 Da. The YmL27 protein as well as the yeast mitoribosomal protein YmL31, which had been characterized and its gene (MRP-L31) cloned previously, is essential for mitochondrial function as shown by the inability of gene disrupted mutants for the MRP-L27 or MRP-L31 genes to grow on non-fermentable carbon sources.

A site-specific deletion in mitochondrial DNA of Podospora is under the control of nuclear genes

In the filamentous fungus Podospora anserina, the association of two nuclear genes inevitably leads to a "premature death" phenotype consisting of an early end of vegetative growth a few days after ascospore germination. Mycelia showing this phenotype contain a mitochondrial chromosome that always bears the same deletion. One of the break points is exactly at the 5' splice site of a particular mitochondrial intron, suggesting that the deletion event could result from molecular mechanisms also involved in intron mobility. One of the nuclear genes involved in triggering this site-specific event belongs to the mating-type minus haplotype; the other is a mutant allele of a gene encoding a cytosolic ribosomal protein.

Structure and evolution of a group of related aminoacyl-tRNA synthetases

A yeast nuclear gene, designated MSK1, has been selected from a yeast genomic library by transformation of a respiratory deficient mutant impaired in acylation of mitochondrial lysine tRNA. This gene confers a respiratory competent phenotype and restores the mutant's ability to acylate the mitochondrial lysine tRNA. The amino acid sequence of the protein encoded by MSK1 is homologous to yeast cytoplasmic lysyl-tRNA synthetase and to the product of the herC gene, which has recently been suggested to code for the Escherichia coli enzyme. These observations indicate that MSK1 codes for the lysyl-tRNA synthetase of yeast mitochondria. Several regions of high primary sequence conservation have been identified in the bacterial and yeast lysyl-tRNA synthetases. These domains are also present in the aspartyl- and asparaginyl-tRNA synthetases, further confirming the notion that all three present-day enzymes originated from a common ancestral gene. The most conserved domain, located near the carboxyl terminal ends of this group of synthetases is characterized by a cluster of glycines and is also highly homologous to the carboxyl-terminal region of the E. coli ammonia-dependent asparagine synthetase. A catalytic function of the carboxyl terminal domain is indicated by in vitro mutagenesis of the yeast mitochondrial lysyl-tRNA synthetase. Replacement of any one of three glycine residues by alanine and in one case by aspartic acid completely suppresses the activity of the enzymes, as evidenced by the inability of the mutant genes to complement an msk1 mutant, even when present in high copy. Other mutations result in partial loss of activity. Only one glycine replacement affects the stability of the protein in vivo. The observed presence of a homologous domain in asparagine synthetase, which, like the aminoacyl-tRNA synthetases, catalyzes the formation of an aminoacyladenylate, suggests that the glycine-rich sequence is part of a catalytic site involved in binding of ATP and of the aminoacyladenylate intermediate.

MRS3 and MRS4, two suppressors of mtRNA splicing defects in yeast, are new members of the mitochondrial carrier family

When present in high copy number plasmids, the nuclear genes MRS3 and MRS4 from Saccharomyces cerevisiae can suppress the mitochondrial RNA splicing defects of several mit- intron mutations. Both genes code for closely related proteins of about Mr 32,000; they are 73% identical. Sequence comparisons indicate that MRS3 and MRS4 may be related to the family of mitochondrial carrier proteins. Support for this notion comes from a structural analysis of these proteins. Like the ADP/ATP carrier protein (AAC), the mitochondrial phosphate carrier protein (PiC) and the uncoupling protein (UCP), the two MRS proteins have a tripartite structure; each of the three repeats consists of two hydrophobic domains that are flanked by specific amino acid residues. The spacing of these specific residues is identical in all domains of all proteins of the family, whereas spacing between the hydrophobic domains is variable. Like the AAC protein, the MRS3 and MRS4 proteins are imported into mitochondria in vitro and without proteolytic cleavage of a presequence and they are located in the inner mitochondrial membrane. In vivo studies support this mitochondrial localization of the MRS proteins. Overexpression of the MRS3 and MRS4 proteins causes a temperature-dependent petite phenotype; this is consistent with a mitochondrial function of these proteins. Disruption of these genes affected neither mitochondrial functions nor cellular viability. Their products thus have no essential function for mitochondrial biogenesis or for whole yeast cells that could not be taken over by other gene products. The findings are discussed in relation to possible functions of the MRS proteins in mitochondrial solute translocation and RNA splicing.

A gene encoding a tyrosine tRNA synthetase is located near sacS in Bacillus subtilis

Within the frame of an attempt to sequence the whole Bacillus subtilis genome, a region of 5.5 kbp of the B. subtilis chromosome near the sacS locus has been sequenced. It contains five complete coding sequences, including the sequence of sacY, three unknown CDS and a sequence coding for a tyrosine tRNA synthetase. That the corresponding CDS encodes a functional synthetase has been demonstrated by complementation of an Escherichia coli mutant possessing a thermosensitive tRNA synthetase. Insertion of a kanamycin resistance cassette in the B. subtilis chromosome at the corresponding locus resulted, however, in no apparent phenotype, demonstrating that this synthetase is dispensable. Finally phylogenetic relationships between known tyrosine and tryptophan tRNA synthetases are discussed.

Interferon selectively inhibits the expression of mitochondrial genes: a novel pathway for interferon-mediated responses

As an approach to identifying genes involved in physiological actions of interferons we used differential probes to screen a cDNA library from mouse L-929 cells treated with interferon alpha/beta. We identified two negatively regulated mRNA species which have been examined by analysis of the corresponding mRNAs and by DNA sequencing. Comparison with the GenBank database showed that these cDNA clones corresponded to mitochondrially encoded genes for cytochrome b and subunit I of cytochrome c oxidase. A further cDNA encompassing three mitochondrial genes was used as a probe to show that a third mRNA, NADH dehydrogenase subunit 5, was also down-regulated by interferon while a fourth, NADH dehydrogenase subunit 6, was unaffected. Expression of cytochrome b was also inhibited in mouse NIH 3T3 cells treated with interferon alpha/beta and in human Daudi lymphoblastoid cells treated with interferon alpha. The ability of interferon to reduce mitochondrial mRNA levels could be blocked by cycloheximide suggesting that these effects are mediated by an interferon-responsive nuclear gene which encodes a product capable of regulating mitochondrial gene expression. Analysis of proteins synthesized in the presence of emetine, a specific inhibitor of cytoplasmic translation, showed that the synthesis of several mitochondrial translation products, including cytochrome b, was reduced after treatment with interferon. Our results reveal a novel effect of interferon on cellular physiology which could have important consequences for understanding the effects of interferons as well as suggesting new mechanisms for the regulation of mitochondrial biogenesis and function.

Tryptophanyl-tRNA synthetase-like immunoreactivity in the central nervous system and midgut of the migratory locust. Comparisons with gastrin-cholecystokinin-like and octopamine-like immunoreactivity

A tryptophanyl-tRNA synthetase (TrpRS)-immunoreactivity is localized in various neurosecretory cells of all ganglia of the central nervous system of the Orthoptera Locusta migratoria, except in deutocerebrum, and in endocrine cells of the midgut. It has been observed that TrpRS-like material never co-localizes either with CCK-like or octopamine-like material. TrpRS immunoreactive perikarya and processes that ramify extensively throughout the neuropiles have been detected in the protocerebrum, optic lobes, tritocerebrum, suboesophageal, thoracic and abdominal ganglia. In the lateral protocerebrum, a particular TrpRS pathway different from the lateral gastrin cholecystokinin (CCK-8(s] pathway is revealed, certain of these processes terminating in the glandular part of the corpora cardiaca. In the metathoracic ganglion, have been observed numerous immunoreactive cell bodies and processes in the neuropiles. Some of them constitute a major pathway and which are distinct from octopamine (OA) cells but in close vicinity with the latter. In the midgut immunopositive TrpRS-like cells are dispersed among the regenerative and digestive cells of the epithelium; they are different from gastrin-cholecystokinin positive cells. The various TrpRS-like immunoreactivities identified in Locusta indicate that TrpRS-like material may occur in different tissues of organisms other than Vertebrates. These results suggest also that TrpRS-like enzyme could be involved in functions other than aminoacylation, as in Vertebrates.

Transfer RNA-like structure of the human Alu family: implications of its generation mechanism and possible functions

Structural resemblance of the human Alu family with a subset of vertebrate tRNAs was detected. Of four tRNAs, tRNA(Lys), tRNA(Ile), tRNA(Thr), and tRNA(Tyr), which comprise a structurally related family, tRNA(Lys) is the most similar to the human Alu family. Of the 76 nucleotides in lysine tRNA (including the CCA tail), 47 are similar to the human Alu family (60% identity). The secondary structure of the human Alu family corresponding to the D-stem and anticodon stem regions of the tRNA appears to be very stable. The 7SL RNA, which is a progenitor of the human Alu family, is less similar to lysine tRNA (55% identity), and the secondary structure of the 7SL RNA folded like a tRNA is less stable than that of the human Alu family folded likewise. Insertion of the tetranucleotide GAGA, which is an important region of the second promoter for RNA polymerase III in the Alu sequence, occurred during the deletion and ligation process to generate the Alu sequence from the parental 7SL RNA. These results suggest that the human Alu family was generated from the 7SL RNA by deletion, insertion, and mutations, which thus modified the ancestral 7SL sequence so that it could form a structure more closely resembling lysine tRNA. The similarities of several short interspersed sequences to the lysine tRNA were also examined. The Galago type 2 family, which was reported to be derived from a methionine initiator tRNA, was also found to be similar to the lysine tRNA. Thus lysine tRNA-like structures are widespread in genomes in the animal kingdom. The implications of these findings in relation to the mechanism of generation of the human Alu family and its possible functions are discussed.

The accuracy of aminoacylation--ensuring the fidelity of the genetic code

The fidelity of protein biosynthesis rests not only on the proper interaction of the messenger RNA codon with the anticodon of the tRNA, but also on the correct attachment of amino acids to their corresponding (cognate) transfer RNA (tRNA) species. This process is catalyzed by the aminoacyl-tRNA synthetases which discriminate with remarkable selectivity amongst many structurally similar tRNAs. The basis for this highly specific recognition of tRNA by these enzymes (also referred to as 'tRNA identity') is currently being elucidated by genetic, biochemical and biophysical techniques. At least two factors are important in determining the accuracy of aminoacylation: a) 'identity elements' in tRNA denote nucleotides in certain positions crucial for protein interactions determining specificity, and b) the occurrence in vivo of competition between synthetases for a particular tRNA which may have ambiguous identity.

The yeast mitochondrial leucyl-tRNA synthetase is a splicing factor for the excision of several group I introns

The Saccharomyces cerevisiae nuclear gene NAM2 codes for mitochondrial leucyl-tRNA synthetase (mLRS). Herbert et al. (1988, EMBO J 7:473-483) proposed that this protein is involved in mitochondrial RNA splicing. Here we present the construction and analyses of nine mutations obtained by creating two-codon insertions within the NAM2 gene. Three of these prevent respiration while maintaining the mitochondrial genome. These three mutants: (1) display in vitro a mLRS activity ranging from 0%-50% that of the wild type: (2) allow in vivo the synthesis of several mitochondrially encoded proteins; (3) prevent the synthesis of the COXII protein but not of its mRNA; (4) abolish the splicing of the group I introns bI4 and aI4; and (5) affect significantly the excision of the group I introns bI2, bI3 and aI3. Importation of the bI4 maturase from the cytoplasm into mitochondria in a nam2- mutant strain does not restore the excision of the introns bI4 and aI4 implying that the splicing deficiency does not result from the absence of the bI4 maturase. We conclude that the mLRS is a splicing factor essential for the excision of the group I introns bI4 and aI4 and probably important for the excision of other group I introns.

Involvement of aminoacyl-tRNA synthetases and other proteins in group I and group II intron splicing

Group I and group II introns catalyse their own splicing, but depend on protein factors for efficient splicing in vivo. Some of these proteins, termed maturases, are encoded by the introns themselves and may also function in intron mobility. Other proteins are encoded by host chromosomal genes and include aminoacyl-tRNA synthetases and various proteins that function in protein synthesis. The splicing factors identified thus far appear to be idiosyncratic, even in closely related organisms. We suggest that some of these protein-assisted splicing reactions evolved relatively recently, possibly reflecting the recent dispersal of the introns themselves.

Trans-splicing mutants of Chlamydomonas reinhardtii

In Chlamydomonas reinhardtii the three exons of the psaA gene are widely scattered on the chloroplast genome: exons 1 and 2 are in opposite orientations and distant from each other and from exon 3. The mature mRNA, encoding a core polypeptide of photosystem I, is thus probably assembled from separate precursors by splicing in trans. We have isolated and characterized a set of mutants that are deficient in the maturation of psaA mRNA. The mutants belong to 14 nuclear complementation groups and one chloroplast locus that are required for the assembly of psaA mRNA. The chloroplast locus, tscA, is remote from any of the exons and must encode a factor required in trans. The mutants all show one of only three phenotypes that correspond to defects in one or other or both of the joining reactions. These phenotypes, and those of double mutants, are consistent with the existence of two alternative splicing pathways.

Function of Neurospora mitochondrial tyrosyl-tRNA synthetase in RNA splicing requires an idiosyncratic domain not found in other synthetases

Neurospora mitochondrial tyrosyl-tRNA synthetase (mt TyrRS), which is encoded by nuclear gene cyt-18, functions in splicing group I introns. Analysis of intragenic partial revertants of the cyt-18-2 mutant and in vitro mutants of the cyt-18 protein expressed in E. coli showed that splicing activity of the cyt-18 protein is dependent on a small N-terminal domain that has no homolog in bacterial or yeast mt TyrRSs. This N-terminal splicing domain apparently acts together with other regions of the protein to promote splicing. Our findings support the hypothesis that idiosyncratic sequences in aminoacyl-tRNA synthetase may function in processes other than aminoacylation. Furthermore, they suggest that splicing activity of the Neurospora mt TyrRs was acquired after the divergence of Neurospora and yeast, and they demonstrate one mechanism whereby splicing factors may evolve from cellular RNA binding proteins.

Closely spaced and divergent promoters for an aminoacyl-tRNA synthetase gene and a tRNA operon in Escherichia coli. Transcriptional and post-transcriptional regulation of gltX, valU and alaW

The transcription of the gltX gene encoding the glutamyl-tRNA synthetase and of the adjacent valU and alaW tRNA operons of Escherichia coli K-12 has been studied. The alaW operon containing two tRNA(GGCAla) genes, is 800 base-pairs downstream from the gltX terminator and is transcribed from the same strand. The valU operon, containing three tRNA(UACVal) and one tRNA(UUULys) (the wild-type allele of supN) genes, is adjacent to gltX and is transcribed from the opposite strand. Its only promoter is upstream from the gltX promoters. The gltX gene transcript is monocistronic and its transcription initiates at three promoters, P1, P2 and P3. The transcripts from one or more of these promoters are processed by RNase E to generate two major species of gltX mRNA, which are stable and whose relative abundance varies with growth conditions. The stability of gltX mRNA decreases in an RNase E- strain and its level increases with growth rate about three times more than that of the glutamyl-tRNA synthetase. The 5' region of these mRNAs can adopt a stable secondary structure (close to the ribosome binding site) that is similar to the anticodon and part of the dihydroU stems and loops of tRNA(Glu), and which might be involved in translational regulation of GluRS synthesis. The gltX and valU promoters share the same AT-rich and bent upstream region, whose position coincides with the position of the upstream activating sequences of tRNA and rRNA promoters to which they are similar. This suggests that gltX and valU share transcriptional regulatory mechanisms.

Recognition of tRNA(Tyr) by tyrosyl-tRNA synthetase

In this review, I have brought together and compared the available data on the interaction between tRNA(Tyr) and tyrosyl-tRNA synthetases (TyrTS) of prokaryotic origins. The amino acid sequences of the heterologous TyrTS that can charge Escherichia coli tRNA(Tyr), show that the residues involved in the binding and recognition of tyrosine are strictly conserved whereas those involved in the interaction with tRNA(Tyr) are only weakly similar. The results of in vivo genetic complementation experiments indicate that the identity elements of tRNAs and the recognition mechanisms of such elements by the synthetases have been conserved during evolution. Heterologous or mutant tRNA(Tyr) are quantitatively charged by E coli TyrTS; the set of their common residues contains less than 10 elements if one excludes the invariant and semi-invariant residues of tRNAs. The residues of this set are candidates for a specific recognition by TyrTS. So far, adenosine-73 is the only residue for which a specific recognition of the base has been demonstrated. The residues that might serve as identity elements for E coli tRNA(Tyr) [McClain WH, Nicholas Jr HB (1987) J Mol Biol 194, 635-642] do not belong to the above set of conserved residues and therefore probably play negative roles, enabling tRNA(Tyr) to avoid non-cognate synthetases. Comparison of the charging and stability properties of mutant tRNA(Tyr) su +3 shows that bases 1 and 72 must pair (either by Watson-Crick or non-canonical hydrogen bonds) and adopt a geometry which is compatible with the helical structure of the acceptor stem in order for the mutant tRNA(Tyr) to be charged with tyrosine. If bases 1 and 72 or bases 2 and 71 cannot form such pairings, the suppressor phenotype of the mutant tRNA(Tyr)su +3 becomes thermosensitive. The weakening of base pair 1/72 by mutation or the change of adenosine-73 into guanosine results in the charging of tRNA(Tyr)su +3 with glutamine. Comparison of the structural model of the TyrTS/tRNA(Tyr) complex with the crystallographic structure of the GlnTS/tRNA(Gln) complex indicates that the mechanisms for the recognition of the acceptor arm are different in the 2 cases. Chemical attack and molecular modeling experiments have indicated that the acceptor end of tRNA(Tyr) ... CCCA3'-OH, remains mobile after the initial binding of tRNA(Tyr) to TyrTS.

Conformation of an RNA pseudoknot

The structure of the 5' GCGAUUUCUGACCGCUUUUUUGUCAG 3' RNA oligonucleotide was investigated using biochemical and chemical probes and nuclear magnetic resonance spectroscopy. Formation of a pseudoknot is indicated by the imino proton spectrum. Imino protons are observed consistent with formation of two helical stem regions; nuclear Overhauser enhancements between imino protons show that the two stem regions stack to form a continuous helix. In the stem regions, nucleotide conformations (3'-endo, anti) and internucleotide distances, derived from two-dimensional correlated, spectroscopy and two-dimensional nuclear Overhauser effect spectra, are characteristic of A-form geometry. The data suggest minor distortion in helical stacking at the junctions of stems and loops. The model of the pseudoknot is consistent with the structure originally proposed by Pleij et al.