Prokaryotic genetic code

The prokaryotic genetic code has been influenced by directional mutation pressure (GC/AT pressure) that has been exerted on the entire genome. This pressure affects the synonymous codon choice, the amino acid composition of proteins and tRNA anticodons. Unassigned codons would have been produced in bacteria with extremely high GC or AT genomes by deleting certain codons and the corresponding tRNAs. A high AT pressure together with genomic economization led to a change in assignment of the UGA codon, from stop to tryptophan, in Mycoplasma.

The organization and evolution of transfer RNA genes in Mycoplasma capricolum

The genes for presumably all the tRNA species in Mycoplasma capricolum, a derivative of Gram-positive eubacteria, have been cloned and sequenced. There are 30 genes encoding 29 tRNA species. This number is the smallest in all the known genetic systems except for mitochondria. The sequences of 9 tRNA genes of them have been previously reported (1-3). Twenty-two genes are organized in 5 clusters consisting of nine, five, four and two genes (2 sets), respectively. The other eight genes exist as a single transcription unit. All the tRNAs are encoded each by a single gene, except for the occurrence of two tRNA(Lys)(TTT) genes. The arrangement of tRNA genes in the 9-gene cluster, the 5-gene cluster, the 4-gene cluster and one of the 2-gene clusters reveals extensive similarity with a part of the 21-tRNA gene cluster and/or the 16-tRNA gene cluster in Bacillus subtilis, respectively. The results suggest that the present M. capricolum tRNA genes have evolved from large tRNA gene clusters in the ancestral Gram-positive bacterial genome common to M. capricolum and B. subtilis, by discarding genes for redundant as well as non-obligate tRNAs, so that all the codons may be translated by as small a number of tRNAs as possible.

Codon recognition patterns as deduced from sequences of the complete set of transfer RNA species in Mycoplasma capricolum. Resemblance to mitochondria

The nucleotide sequences of the complete set of tRNA species in Mycoplasma capricolum, a derivative of Gram-positive eubacteria, have been determined. This bacterium represents the first genetic system in which the sequences of all the tRNA species have been determined at the RNA level. There are 29 tRNA species: three for Leu, two each for Arg, Ile, Lys, Met, Ser, Thr and Trp, and one each for the other 12 amino acids as judged from aminoacylation and the anticodon nucleotide sequences. The number of tRNA species is the smallest among all known genetic systems except for mitochondria. The tRNA anticodon sequences have revealed several features characteristic of M. capricolum. (1) There is only one tRNA species each for Ala, Gly, Leu, Pro, Ser and Val family boxes (4-codon boxes), and these tRNAs all have an unmodified U residue at the first position of the anticodon. (2) There are two tRNAThr species having anticodons UGU and AGU; the first positions of these anticodons are unmodified. (3) There is only one tRNA with anticodon ICG in the Arg family box (CGN); this tRNA can translate codons CGU, CGC and CGA. No tRNA capable of translating codon CGG has been detected, suggesting that CGG is an unassigned codon in this bacterium. (4) A tRNATrp with anticodon UCA is present, and reads codon UGA as Trp. On the basis of these and other observations, novel codon recognition patterns in M. capricolum are proposed. A comparatively small total, 13, of modified nucleosides is contained in all M. capricolum tRNAs. The 5' end nucleoside of the T psi C-loop (position 54) of all tRNAs is uridine, not modified to ribothymidine. The anticodon composition, and hence codon recognition patterns, of M. capricolum tRNAs resemble those of mitochondrial tRNAs.

Mischarging mutants of Su+2 glutamine tRNA in E. coli. I. Mutations near the anticodon cause mischarging

In order to select the mischarging mutants of Su+2 glutamine tRNA, auxotrophic amber mutants of E. coli K12 which cannot be suppressed particularly by Su+2 were screened. By utilizing these mutants, cysam235 and metam3, several tens of mischarging mutants of Su+2 were isolated, as those conferring altered suppression patterns for a set of tester amber mutants of bacteria and phages. Nucleotide sequence analysis revealed that the mutation sites were found to be exclusively at psi 37 residue located at the 3'-end of anticodon loop, changing it to either A37 or C37. These mutants were obtained as those suppressing cysam235, and not metam3. From these, secondary mutants were selected. In these mutants suppression patterns were further altered by the additional base substitutions, capable of suppressing metam3. Such mutants were obtained exclusively from A37 and not from C37 mutant tRNA. Additional mutations to A37 were found to be either A29 or C38, which are located at the lowermost two base pairs in anticodon stem. The mischarging sites in Su+2 glutamine tRNA locate in the newly detected region of tRNA, differing from the previous case of Su+3 tyrosine or Su+7 tryptophan tRNAs. Implication of this finding is discussed on L-shaped tRNA molecule in relation to aminoacyl-tRNA synthetase recognition. Suppression patterns given by the double-mutants, A37A29 and A37C38, were consistent with the observation that the mutant tRNAs interact with tryptophanyl-tRNA synthetase.

Mischarging mutants of Su+2 glutamine tRNA in E. coli. II. Amino acid specificities of the mutant tRNAs

Among the mischarging mutants isolated from strains with Su+2 glutamine tRNA, two double-mutants, A37A29 and A37C38, have been suggested to insert tryptophan at the UAG amber mutation site as determined by the suppression patterns of a set of tester mutants of bacteria and phages (Yamao et al., 1988). In this paper, we screened temperature sensitive mutants of E. coli in which the mischarging suppression was abolished even at the permissive temperature. Four such mutants were obtained and they were identified as the mutants of a structural gene for tryptophanyl-tRNA synthetase (trpS). Authentic trpS mutations, such as trpS5 or trpS18, also restricted the mischarging suppression. These results strongly support the previous prediction that the mutant tRNAs of Su+2, A37A29 and A37C38, are capable of interacting with tryptophanyl-tRNA synthetase and being misaminoacylated with tryptophan in vivo. However, in an assay to determine the specificity of the mutant glutamin tRNAs, we detected predominantly glutamine, but not any other amino acid, being inserted at an amber codon in vivo to any significant degree. We conclude that the mutant tRNAs still accept mostly glutamine, but can accept tryptophan in an extent for mischarging suppression. Since the amber suppressors of Su+7 tryptophan tRNA and the mischarging mutants of Su+3 tyrosine tRNA are charged with glutamine, structural similarity among the tRNAs for glutamine, tryptophan and tyrosine is discussed.

Evolutionary dynamics of tryptophan tRNAs in Mycoplasma capricolum

Mycoplasma capricolum uses two tryptophan codons, the "universal" nonsense codon UGA and the universal codon UGG. The bacterium contains two tryptophan tRNAs, one with anticodon UCA, (U: 2'-O-methyl U derivative), and the other with CCA (5'-C: partially 2'-O-methylated). tRNAUCA would translate codons UGA and probably UGG by wobbling. tRNACCA is much less charged by tryptophan in the cells than tRNAUCA, and the intracellular amount of tRNACCA is 5-10 times lower than that of tRNAUCA. The genes for these two tRNAs are separated by a terminator-like structure in a single operon. In vitro transcription experiments suggest that the predominance of tRNAUCA over tRNACCA results from the attenuation of transcription by this terminator-like structure.

Directional mutation pressure and transfer RNA in choice of the third nucleotide of synonymous two-codon sets

Bacterial species have diverged into a series of families, some with high G + C content in their DNA, and other with high A + T content, resulting, respectively, from G.C- and A.T-directional mutation pressures. Such mutation pressure (G.C/A.T pressure) may be an important determinant for codon usage. It has also been suggested that tRNA acts as a selective constraint for determining codon usage. We have studied the relation between G.C/A.T pressure and tRNA constraints in determining choice of the third nucleotide of eight two-codon sets, using codon usage data obtained from protein genes in four bacterial species, Mycoplasma capricolum, Bacillus subtilis, Escherichia coli, and Micrococcus luteus, and in liverwort (Marchantia polymorpha) chloroplasts. The genomic G + C contents of these range from 25% to 74%. The results demonstrate that tRNA levels act additively to A.T and G.C pressure in affecting contents of A (pairing with *UNN anticodons, in which *U indicates a 2-thiouridine derivative) and C (pairing with GNN anticodons) or G (pairing with CNN anticodons), respectively, in third nucleotide positions of codons.

The ribosomal protein gene cluster of Mycoplasma capricolum

The DNA sequence of the part of the Mycoplasma capricolum genome that contains the genes for 20 ribosomal proteins and two other proteins has been determined. The organization of the gene cluster is essentially the same as that in the S10 and spc operons of Escherichia coli. The deduced amino acid sequence of each protein is also well conserved in the two bacteria. The G + C content of the M. capricolum genes is 29%, which is much lower than that of E. coli (51%). The codon usage pattern of M. capricolum is different from that of E. coli and extremely biased to use of A and U(T): about 91% of codons have A or U in the third position. UGA, which is a stop codon in the "universal" code, is used more abundantly than UGG to dictate tryptophan.

Occurrence of unmodified adenine and uracil at the first position of anticodon in threonine tRNAs in Mycoplasma capricolum

Codon usage pattern in the threonine four-codon (ACN) box in Mycoplasma capricolum is strongly biased towards adenine and uracil for the third base of codons. Codons ending in uracil or adenine, especially ACU, predominate over ACC and ACG. This bacterium contains two isoacceptor threonine tRNAs having anticodon sequences AGU and UGU, both with unmodified first nucleotides. It would thus appear that ACN codons are translated in an unusual way; tRNA(Thr)(AGU) would translate the most abundantly used codon ACU exclusively, because adenine at the first anticodon position can, according to the wobble rule, pair only with uracil of the third codon position. The tRNA(Thr)(UGU) would mainly be responsible for translation of three other codons, ACA, ACG, and ACC. Anticodon UGU would also be used for reading codon ACU as a redundancy of tRNA(Thr)-(AGU), as deduced from the mitochondrial code where unmodified uracil at the first anticodon position can pair with adenine, cytosine, guanine, and uracil by four-way wobble. The tRNA(Thr)(AGU) has much higher sequence homology to tRNA(Thr)(UGU) from M. capricolum (88%), Bacillus subtilis (77%) and Escherichia coli (86%) than to tRNA(Thr)(GGU) from B. subtilis (66%) and E. coli (63%), suggesting that tRNA(Thr)-(AGU) has been derived from tRNA(Thr)(UGU), but not from tRNA(Thr)(GGU).

Organization and codon usage of the streptomycin operon in Micrococcus luteus, a bacterium with a high genomic G + C content

The DNA sequence of the Micrococcus luteus str operon, which includes genes for ribosomal proteins S12 (str or rpsL) and S7 (rpsG) and elongation factors (EF) G (fus) and Tu (tuf), has been determined and compared with the corresponding sequence of Escherichia coli to estimate the effect of high genomic G + C content (74%) of M. luteus on the codon usage pattern. The gene organization in this operon and the deduced amino acid sequence of each corresponding protein are well conserved between the two species. The mean G + C content of the M. luteus str operon is 67%, which is much higher than that of E. coli (51%). The codon usage pattern of M. luteus is very different from that of E. coli and extremely biased to the use of G and C in silent positions. About 95% (1,309 of 1,382) of codons have G or C at the third position. Codon GUG is used for initiation of S12, EF-G, and EF-Tu, and AUG is used only in S7, whereas GUG initiates only one of the EF-Tu's in E. coli. UGA is the predominant termination codon in M. luteus, in contrast to UAA in E. coli.

UGA is read as tryptophan in Mycoplasma capricolum

UGA is a nonsense or termination (opal) codon throughout prokaryotes and eukaryotes. However, mitochondria use not only UGG but also UGA as a tryptophan codon. Here, we show that UGA also codes for tryptophan in Mycoplasma capricolum, a wall-less bacterium having a genome only 20-25% the size of the Escherichia coli genome. This conclusion is based on the following evidence. First, the nucleotide sequence of the S3 and L16 ribosomal protein genes from M. capricolum includes UGA codons in the reading frames; they appear at positions corresponding to tryptophan in E. coli S3 and L16. Second, a tRNATrp gene and its product tRNA found in M. capricolum have the anticodon sequence 5' U-C-A 3', which can form a complementary base-pairing interaction with UGA.

Misaminoacylation by glutaminyl-tRNA synthetase: relaxed specificity in wild-type and mutant enzymes

Escherichia coli glutaminyl-tRNA synthetase (GlnRS) (EC 6.1.1.18) is a monomeric polypeptide of 553 amino acids. Its amino acid sequence and its gene (glnS) sequence are known. A structural gene mutation, glnS7, codes for a mischarging GlnRS, which acylates some noncognate tRNA species (e.g., su+3 tRNATyr) with glutamine. The mutant enzyme was shown to catalyze in vitro the acylation of glutamine to su+3 tRNATyr, but not to wild-type tRNATyr. The mutation responsible produces an amino acid change in the amino-terminal half of the enzyme. Unexpectedly, overproduction of wild-type GlnRS also leads to in vivo mischarging of su+3 tRNATyr. In vitro and in vivo studies have not revealed evidence for an attenuation or autogenous regulation mechanism for GlnRS, but have implicated transcriptional and translational control in the expression of this enzyme.

Preferential use of A- and U-rich codons for Mycoplasma capricolum ribosomal proteins S8 and L6

The nucleotide sequence of the 1.3 kilobase-pair DNA segment, which contains the genes for ribosomal proteins S8 and L6, and a part of L18 of Mycoplasma capricolum, has been determined and compared with the corresponding sequence in Escherichia coli (Cerretti et al., Nucl. Acids Res. 11, 2599, 1983). Identities of the predicted amino acid sequences of S8 and L6 between the two organisms are 54% and 42%, respectively. The A + T content of the M. capricolum genes is 71%, which is much higher than that of E. coli (49%). Comparisons of codon usage between the two organisms have revealed that M. capricolum preferentially uses A- and U-rich codons. More than 90% of the codon third positions and 57% of the first positions in M. capricolum is either A or U, whereas E. coli uses A or U for the third and the first positions at a frequency of 51% and 36%, respectively. The biased choice of the A- and U-rich codons in this organism has been also observed in the codon replacements for conservative amino acid substitutions between M. capricolum and E. coli. These facts suggest that the codon usage of M. capricolum is strongly influenced by the high A + T content of the genome.

Organization of ribosomal RNA genes in Mycoplasma capricolum

DNA segments carrying rRNA genes of Mycoplasma capricolum have been cloned and characterized by restriction endonuclease mapping, DNA-RNA hybridization and nucleotide sequencing. The M. capricolum genome has two sets of rRNA gene clusters, where the arrangement is in the order of (5')16S-23S-5S(3'). The spacer region between 16S and 23S rDNA is extremely rich in AT and does not carry any tRNA genes.

Molecular cloning of ribosomal protein genes from Mycoplasma capricolum

A Bg/II-fragment from the Mycoplasma capricolum DNA cloned into pBR322 has been found to contain a cluster of ribosomal protein genes. The recombinant plasmid, pMCB1088, includes a 9 kilobase-pair insert that codes for at least eight ribosomal proteins of M. capricolum. The protein genes are expressed in Escherichia coli cells.

Nucleotide sequence of the rrnB 16S ribosomal RNA gene from Mycoplasma capricolum

The nucleotide sequences of the rrnB 16S ribosomal RNA gene and its 5'-and 3'-flanking regions from Mycoplasma capricolum have been determined. The coding sequence is 1521 base pairs long, being 21 base pairs shorter than that of the Escherichia coli 16S rRNA gene. The 16S rRNA sequence of M. capricolum reveals 74% and 76% identify with that of E. coli and Anacystis nidulans, respectively. The secondary structure model constructed from the M. capricolum 16S rRNA gene sequence resembles that proposed for E. coli 16S rRNA. A large stem structure can be constructed between the 5'- and 3'-flanking sequences of the 16S rRNA gene. The flanking regions are extremely rich in AT.

Transfer RNA mischarging mediated by a mutant Escherichia coli glutaminyl-tRNA synthetase

We have isolated mutations in the Escherichia coli glnS gene encoding glutaminyl-tRNA synthetase [GlnS; L-glutamine:tRNAGln ligase (AMP-forming), EC 6.1.1.18] that give rise to gene products with altered specificity for tRNA and are designated "mischarging" enzymes. These were produced by nitrosoguanine mutagenesis of the glnS gene carried on a transducing phage (lambda pglnS+). We then selected for mischarging of su+3 tRNATyr with glutamine by requiring suppression of a glutamine-requiring beta-galactosidase amber mutation (lacZ1000). Three independently isolated mutants (glnS7, glnS8, and glnS9) were characterized by genetic and biochemical means. The enzymes encoded by glnS7, glnS8, and glnS9 appear to be highly selective for su+3 tRNATyr, because in vivo mischarging of other amber suppressor tRNAs was not detected. The GlnS mutants described here retain their capacity to correctly aminoacylate tRNAGln. All three independently isolated mutant genes encode proteins with isoelectric points that differ from those of the wild-type enzyme but are identical to each other. This suggests that only a single site in the enzyme structure is altered to give the observed mischarging properties. In vitro aminoacylation reactions with purified GlnS7 protein show that this enzyme can also mischarge some tRNA species lacking the amber anticodon. This is an example of mischarging phenotype conferred by a mutation in an aminoacyl-tRNA synthetase gene; the results are discussed in the context of earlier genetic studies with mutant tRNAs.

Six Schizosaccharomyces pombe tRNA genes including a gene for a tRNALys with an intervening sequence which cannot base-pair with the anticodon

We report the sequences of six S. pombe tRNA genes including two genes for tRNAArg, and one gene each for tRNAGlu, tRNAHis, tRNALys and tRNAPhe. All tRNA genes are found independently in the genome and represent individual transcription units. The gene for tRNALys has an 8 bp long intervening sequence which cannot base-pair with the tRNA anticodon. In vitro transcription studies indicate that all genes are faithfully transcribed in a yeast extract. Sequence comparison of the 5' flanking regions of the tRNA genes did not show significant homologies; however, they are very rich in AT base pairs.

The ribosomal genes of Mycoplasma capricolum

The nucleotide sequence of 5S rRNA from Mycoplasma capricolum is more similar to that of the gram-positive bacteria than that of the gram-negative bacteria. The presence of two copies of rRNA genes in M. capricolum genome has been demonstrated. The two different rRNA gene clusters have been cloned in E. coli plasmid vectors and analyzed for the rRNA gene organizations, demonstrating that the gene arrangement is in the order of 16S, 23S, and 5S rDNA. The ribosomes of M. capricolum contain about 30 species of proteins in 50S and 20 in 30S subunits. The number and size of the ribosomal proteins are not significantly different from those of other eubacterial ribosomes.

Nonsense suppression in Schizosaccharomyces pombe: the S. pombe Sup3-e tRNASerUGA gene is active in S. cerevisiae

The gene encoding the efficient UGA suppressor sup3-e of Schizosaccharomyces pombe was isolated by in vivo transformation of Saccharomyces cerevisiae UGA mutants with S. pombe sup3-e DNA. DNA from a clone bank of EcoRI fragments from a S. pombe sup3-e strain in the hybrid yeast vector YRp17 was used to transform the S. cerevisiae multiple auxotroph his4-260 leu2-2 trp1-1 to prototrophy. Transformants were isolated at a low frequency; they lost the ability to grow in minimal medium after passaging in non-selective media. This suggested the presence of the suppressor gene on the non-integrative plasmid. Plasmid DNA, isolated from the transformed S. cerevisiae cells and subsequently amplified in E. coli, transformed S. cerevisiae his4-260 leu2-2 trp1-1 to prototrophy. In this way a 2.4 kb S. pombe DNA fragment carrying the sup3-e gene was isolated. Sequence analysis revealed the presence of two tRNA coding regions separated by a spacer of only seven nucleotides. The sup3-e tRNASerUGA tRNA gene is followed by a sequence coding for the initiator tRNAMet. The transformation results demonstrate that the cloned S. pombe UGA suppressor is active in S. cerevisiae UGA mutant strains.

Escherichia coli glutaminyl-tRNA synthetase. II. Characterization of the glnS gene product

Glutaminyl-tRNA synthetase has been purified by a simple, two-column procedure from an Escherichia coli K12 strain carrying the glnS structural gene on plasmid pBR322. The primary sequence of this enzyme as derived from the DNA sequence (see accompanying paper) has been confirmed. Manual Edman degradation was used to identify the NH2-terminal sequence of the protein. Oligopeptides scattered throughout the primary sequence of glutaminyl-tRNA synthetase were sequenced by the gas chromatographic-mass spectrometric method and matched to the theoretical peptides derived from the translated DNA sequence. The expected carboxyl terminus at position 550 was verified by carboxypeptidase B digestion. The primary sequence of glutaminyl-tRNA synthetase contains no extensive sequence repeats. A search was made for sequence homologies between this enzyme and the few other aminoacyl-tRNA synthetases for which primary sequences are available. A single homologous region is shared by at least three of the synthetases examined here.