Kimitsuna Watanabe

Recent evidence for evolution of the genetic code.

The genetic code, formerly thought to be frozen, is now known to be in a state of evolution. This was first shown in 1979 by Barrell et al. (G. Barrell, A. T. Bankier, and J. Drouin, Nature [London] 282:189-194, 1979), who found that the universal codons AUA (isoleucine) and UGA (stop) coded for methionine and tryptophan, respectively, in human mitochondria. Subsequent studies have shown that UGA codes for tryptophan in Mycoplasma spp. and in all nonplant mitochondria that have been examined. Universal stop codons UAA and UAG code for glutamine in ciliated protozoa (except Euplotes octacarinatus) and in a green alga, Acetabularia. E. octacarinatus uses UAA for stop and UGA for cysteine. Candida species, which are yeasts, use CUG (leucine) for serine. Other departures from the universal code, all in nonplant mitochondria, are CUN (leucine) for threonine (in yeasts), AAA (lysine) for asparagine (in platyhelminths and echinoderms), UAA (stop) for tyrosine (in planaria), and AGR (arginine) for serine (in several animal orders) and for stop (in vertebrates). We propose that the changes are typically preceded by loss of a codon from all coding sequences in an organism or organelle, often as a result of directional mutation pressure, accompanied by loss of the tRNA that translates the codon. The codon reappears later by conversion of another codon and emergence of a tRNA that translates the reappeared codon with a different assignment. Changes in release factors also contribute to these revised assignments. We also discuss the use of UGA (stop) as a selenocysteine codon and the early history of the code.

Modified Uridines with C5-methylene Substituents at the First Position of the tRNA Anticodon Stabilize U·G Wobble Pairing during Decoding

Post-transcriptional modifications at the first (wobble) position of the tRNA anticodon participate in precise decoding of the genetic code. To decode codons that end in a purine (R) (i.e. NNR), tRNAs frequently utilize 5-methyluridine derivatives (xm5U) at the wobble position. However, the functional properties of the C5-substituents of xm5U in codon recognition remain elusive. We previously found that mitochondrial tRNAsLeu(UUR) with pathogenic point mutations isolated from MELAS (mitochondrial myopathy, encephalopathy, lactic acidosis, and stroke-like episodes) patients lacked the 5-taurinomethyluridine (τm5U) modification and caused a decoding defect. Here, we constructed Escherichia coli tRNAsLeu(UUR) with or without xm5U modifications at the wobble position and measured their decoding activities in an in vitro translation as well as by A-site tRNA binding. In addition, the decoding properties of tRNAArg lacking mnm5U modification in a knock-out strain of the modifying enzyme (ΔmnmE) were examined by pulse labeling using reporter constructs with consecutive AGR codons. Our results demonstrate that the xm5U modification plays a critical role in decoding NNG codons by stabilizing U·G pairing at the wobble position. Crystal structures of an anticodon stem-loop containing τm5U interacting with a UUA or UUG codon at the ribosomal A-site revealed that the τm5U·G base pair does not have classical U·G wobble geometry. These structures provide help to explain how the τm5U modification enables efficient decoding of UUG codons.

Unique features of animal mitochondrial translation systems: – The non-universal genetic code, unusual features of the translational apparatus and their relevance to human mitochondrial diseases –

In animal mitochondria, several codons are non-universal and their meanings differ depending on the species. In addition, the tRNA structures that decipher codons are sometimes unusually truncated. These features seem to be related to the shortening of mitochondrial (mt) genomes, which occurred during the evolution of mitochondria. These organelles probably originated from the endosymbiosis of an aerobic eubacterium into an ancestral eukaryote. It is plausible that these events brought about the various characteristic features of animal mt translation systems, such as genetic code variations, unusually truncated tRNA and rRNA structures, unilateral tRNA recognition mechanisms by aminoacyl-tRNA synthetases, elongation factors and ribosomes, and compensation for RNA deficits by enlarged proteins. In this article, we discuss molecular mechanisms for these phenomena. Finally, we describe human mt diseases that are caused by modification defects in mt tRNAs.

Existence of nuclear-encoded 5S-rRNA in bovine mitochondria.

A number of proteins functioning in mitochondria are synthesized in the cytoplasm and imported into the mitochondria via specific transport systems. In mammals, on the contrary, mitochondrial membranes have generally been considered to be impermeable to nucleic acids. However, here we show that an RNA with 120 nucleotides, the sequence of which is identical to that of the nuclear‐encoded 5S RNA, exists in bovine mitochondria, although the mitochondrial genome encodes no 5S RNA gene. This RNA molecule was found to be retained in purified bovine mitochondria as well as in the mitoplasts, even after extensive treatment with an RNase, demonstrating that the 5S RNA is actually located inside the mitochondrial inner membrane. The 5S rRNA molecule was also shown to exist in mitochondria from rabbit and chicken.

Common thiolation mechanism in the biosynthesis of tRNA thiouridine and sulphur-containing cofactors.

2‐Thioribothymidine (s2T), a modified uridine, is found at position 54 in transfer RNAs (tRNAs) from several thermophiles; s2T stabilizes the L‐shaped structure of tRNA and is essential for growth at higher temperatures. Here, we identified an ATPase (tRNA‐two‐thiouridine C, TtuC) required for the 2‐thiolation of s2T in Thermus thermophilus and examined in vitro s2T formation by TtuC and previously identified s2T‐biosynthetic proteins (TtuA, TtuB, and cysteine desulphurases). The C‐terminal glycine of TtuB is first activated as an acyl‐adenylate by TtuC and then thiocarboxylated by cysteine desulphurases. The sulphur atom of thiocarboxylated TtuB is transferred to tRNA by TtuA. In a ttuC mutant of T. thermophilus, not only s2T, but also molybdenum cofactor and thiamin were not synthesized, suggesting that TtuC is shared among these biosynthetic pathways. Furthermore, we found that a TtuB—TtuC thioester was formed in vitro, which was similar to the ubiquitin‐E1 thioester, a key intermediate in the ubiquitin system. The results are discussed in relation to the mechanism and evolution of the eukaryotic ubiquitin system.

Unusual anticodon loop structure found in E.coli lysine tRNA

Although both tRNA(Lys) and tRNA(Glu) of E. coli possess similar anticodon loop sequences, with the same hypermodified nucleoside 5-methylaminomethyl-2-thiouridine (mnm5s2U) at the first position of their anticodons, the anticodon loop structures of these two tRNAs containing the modified nucleoside appear to be quite different as judged from the following observations. (1) The CD band derived from the mnm5s2U residue is negative for tRNA(Glu), but positive for tRNA(Lys). (2) The mnm5s2U monomer itself and the mnm5s2U-containing anticodon loop fragment of tRNA(Lys) show the same negative CD bands as that of tRNA(Glu). (3) The positive CD band of tRNA(Lys) changes to negative when the temperature is raised. (4) The reactivity of the mnm5s2U residue toward H2O2 is much lower for tRNA(Lys) than for tRNA(Glu). These features suggest that tRNA(Lys) has an unusual anticodon loop structure, in which the mnm5s2U residue takes a different conformation from that of tRNA(Glu); whereas the mnm5s2U base of tRNA(Glu) has no direct bonding with other bases and is accessible to a solvent, that of tRNA(Lys) exists as if in some way buried in its anticodon loop. The limited hydrolysis of both tRNAs by various RNases suggests that some differences exist in the higher order structures of tRNA(Lys) and tRNA(Glu). The influence of the unusual anticodon loop structure observed for tRNA(Lys) on its function in the translational process is also discussed.

Taurine-containing Uridine Modifications in tRNA Anticodons Are Required to Decipher Non-universal Genetic Codes in Ascidian Mitochondria

Variations in the genetic code are found frequently in mitochondrial decoding systems. Four non-universal genetic codes are employed in ascidian mitochondria: AUA for Met, UGA for Trp, and AGA/AGG(AGR) for Gly. To clarify the decoding mechanism for the non-universal genetic codes, we isolated and analyzed mitochondrial tRNAs for Trp, Met, and Gly from an ascidian, Halocynthia roretzi. Mass spectrometric analysis identified 5-taurinomethyluridine (τm5U) at the anticodon wobble positions of tRNAMet(AUR), tRNATrp(UGR), and tRNAGly(AGR), suggesting that τm5U plays a critical role in the accurate deciphering of all four non-universal codes by preventing the misreading of pyrimidine-ending near-cognate codons (NNY) in their respective family boxes. Acquisition of the wobble modification appears to be a prerequisite for the genetic code alteration.

A NEW METHOD FOR IDENTIFYING THE AMINO ACID ATTACHED TO A PARTICULAR RNA IN THE CELL

To investigate the function of tRNAs or any other aminoacylable RNAs in vivo, it is important to be able to estimate the amounts and species of aminoacylated RNAs in living cells. We have developed a method of analyzing amino acids attached to particular tRNAs obtained from cells. After the ester bond between the amino acid and the 3′‐adenosine moiety of a specific aminoacyl‐tRNA is stabilized by acetylation of the amino acid with [14C]acetic anhydride, the aminoacyl‐tRNA can be fished out with a solid‐phase‐attached DNA probe. The 14C‐labeled acetylamino acid is then released from the thus purified acetyl‐aminoacyl‐tRNAs by alkaline treatment and detected by TLC analysis.

Folate-/FAD-dependent tRNA methyltransferase from Thermus thermophilus regulates other modifications in tRNA at low temperatures.

TrmFO is a N5, N10‐methylenetetrahydrofolate (CH2THF)‐/FAD‐dependent tRNA methyltransferase, which synthesizes 5‐methyluridine at position 54 (m5U54) in tRNA. Thermus thermophilus is an extreme‐thermophilic eubacterium, which grows in a wide range of temperatures (50–83 °C). In T. thermophilus, modified nucleosides in tRNA and modification enzymes form a network, in which one modification regulates the degrees of other modifications and controls the flexibility of tRNA. To clarify the role of m5U54 and TrmFO in the network, we constructed the trmFO gene disruptant (∆trmFO) strain of T. thermophilus. Although this strain did not show any growth retardation at 70 °C, it showed a slow‐growth phenotype at 50 °C. Nucleoside analysis showed increase in 2′‐O‐methylguanosine at position 18 and decrease in N1‐methyladenosine at position 58 in the tRNA mixture from the ∆trmFO strain at 50 °C. These in vivo results were reproduced by in vitro experiments with purified enzymes. Thus, we concluded that the m5U54 modification have effects on the other modifications in tRNA through the network at 50 °C. 35S incorporations into proteins showed that the protein synthesis activity of ∆trmFO strain was inferior to the wild‐type strain at 50 °C, suggesting that the growth delay at 50 °C was caused by the inferior protein synthesis activity.

Biochemical and structural characterization of oxygen-sensitive 2-thiouridine synthesis catalyzed by an iron-sulfur protein TtuA

Significance One of the posttranscriptional modifications of tRNA, 2-thiouridine (s2U), enhances thermostability. Although extensive studies have been conducted to understand the mechanism behind this modification, many ill-defined points remain, because the S-transfer enzyme 2-thiouridine synthetase TtuA has shown very low activity in previous in vitro experiments. Here we demonstrate that TtuA requires oxygen-labile [4Fe-4S] clusters for its activity. Furthermore, we determine the crystal structure of TtuA in complex with the Fe-S cluster and ATP analog and also with its S-donor protein, 2-thiouridine synthesis sulfur carrier protein (TtuB). The combined actions of TtuA and TtuB using the Fe-S cluster aid the S-transfer mechanism. Two-thiouridine (s2U) at position 54 of transfer RNA (tRNA) is a posttranscriptional modification that enables thermophilic bacteria to survive in high-temperature environments. s2U is produced by the combined action of two proteins, 2-thiouridine synthetase TtuA and 2-thiouridine synthesis sulfur carrier protein TtuB, which act as a sulfur (S) transfer enzyme and a ubiquitin-like S donor, respectively. Despite the accumulation of biochemical data in vivo, the enzymatic activity by TtuA/TtuB has rarely been observed in vitro, which has hindered examination of the molecular mechanism of S transfer. Here we demonstrate by spectroscopic, biochemical, and crystal structure analyses that TtuA requires oxygen-labile [4Fe-4S]-type iron (Fe)-S clusters for its enzymatic activity, which explains the previously observed inactivation of this enzyme in vitro. The [4Fe-4S] cluster was coordinated by three highly conserved cysteine residues, and one of the Fe atoms was exposed to the active site. Furthermore, the crystal structure of the TtuA-TtuB complex was determined at a resolution of 2.5 Å, which clearly shows the S transfer of TtuB to tRNA using its C-terminal thiocarboxylate group. The active site of TtuA is connected to the outside by two channels, one occupied by TtuB and the other used for tRNA binding. Based on these observations, we propose a molecular mechanism of S transfer by TtuA using the ubiquitin-like S donor and the [4Fe-4S] cluster.