yaaJ, the tRNA-Specific Adenosine Deaminase, Is Dispensable in Bacillus subtilis.

Post-transcriptional modifications of tRNA are crucial for their core function. The inosine (I; 6-deaminated adenosine) at the first position in the anticodon of tRNAArg(ICG) modulates the decoding capability and is generally considered essential for reading CGU, CGC, and CGA codons in eubacteria. We report here that the Bacillus subtilis yaaJ gene encodes tRNA-specific adenosine deaminase and is non-essential for viability. A ß-galactosidase reporter assay revealed that the translational activity of CGN codons was not impaired in the yaaJ-deletion mutant. Furthermore, tRNAArg(CCG) responsible for decoding the CGG codon was dispensable, even in the presence or absence of yaaJ. These results strongly suggest that tRNAArg with either the anticodon ICG or ACG has an intrinsic ability to recognize all four CGN codons, providing a fundamental concept of non-canonical wobbling mediated by adenosine and inosine nucleotides in the anticodon. This is the first example of the four-way wobbling by inosine nucleotide in bacterial cells. On the other hand, the absence of inosine modification induced +1 frameshifting, especially at the CGA codon. Additionally, the yaaJ deletion affected growth and competency. Therefore, the inosine modification is beneficial for translational fidelity and proper growth-phase control, and that is why yaaJ has been actually conserved in B. subtilis.

Intron-Dependent or Independent Pseudouridylation of Precursor tRNA Containing Atypical Introns in Cyanidioschyzon merolae.

Eukaryotic precursor tRNAs (pre-tRNAs) often have an intron between positions 37 and 38 of the anticodon loop. However, atypical introns are found in some eukaryotes and archaea. In an early-diverged red alga Cyanidioschyzon merolae, the tRNAIle(UAU) gene contains three intron coding regions, located in the D-, anticodon, and T-arms. In this study, we focused on the relationship between the intron removal and formation of pseudouridine (Ψ), one of the most universally modified nucleosides. It had been reported that yeast Pus1 is a multiple-site-specific enzyme that synthesizes Ψ34 and Ψ36 in tRNAIle(UAU) in an intron-dependent manner. Unexpectedly, our biochemical experiments showed that the C. merolae ortholog of Pus1 pseudouridylated an intronless tRNAIle(UAU) and that the modification position was determined to be 55 which is the target of Pus4 but not Pus1 in yeast. Furthermore, unlike yeast Pus1, cmPus1 mediates Ψ modification at positions 34, 36, and/or 55 only in some specific intron-containing pre-tRNAIle(UAU) variants. cmPus4 was confirmed to be a single-site-specific enzyme that only converts U55 to Ψ, in a similar manner to yeast Pus4. cmPus4 did not catalyze the pseudouridine formation in pre-tRNAs containing an intron in the T-arm.

A leaderless mRNA including tRNA-like sequence encodes a small peptide that regulates the expression of GcvB small RNA in Escherichia coli.

A tRNA-like sequence conserved in the genomes of all Escherichia coli strains was found. The sequence resembles arginine-tRNA, which is present in E. coli pathogenic islands and phages. Expression experiments revealed that this sequence is a part of a leaderless mRNA encoding a short peptide (60 amino acids: XtpA). A deletion mutant of this gene is more sensitive than wild-type cell to several aminoglycoside antibiotics at low concentrations. Further analyses indicated that XtpA positively regulates the expression of GcvB small RNA, which is involved in the intrinsic resistance to aminoblycosides in E. coli.

Evolution of Ribosomal Protein S14 Demonstrated by the Reconstruction of Chimeric Ribosomes in Bacillus subtilis.

Ribosomal protein S14 can be classified into three types. The first, the C+ type has a Zn2+ binding motif and is ancestral. The second and third are the C- short and C- long types, neither of which contain a Zn2+ binding motif and which are ca. 90 residues and 100 residues in length, respectively. In the present study, the C+ type S14 from Bacillus subtilis ribosomes (S14BsC+) were completely replaced by the heterologous C- long type of S14 from Escherichia coli (S14Ec) or Synechococcus elongatus (S14Se). Surprisingly, S14Ec and S14Se were incorporated fully into 70S ribosomes in B. subtilis However, the growth rates as well as the sporulation efficiency of the mutants harboring heterologous S14 were significantly decreased. In these mutants, the polysome fraction was decreased and the 30S and 50S subunits accumulated unusually, indicating that cellular translational activity of these mutants was decreased. In vitro analysis showed a reduction in the translational activity of the 70S ribosome fraction purified from these mutants. The abundance of ribosomal proteins S2 and S3 in the 30S fraction in these mutants was reduced while that of S14 was not significantly decreased. It seems likely that binding of heterologous S14 changes the structure of the 30S subunit, which causes a decrease in the assembly efficiency of S2 and S3, which are located near the binding site of S14. Moreover, we found that S3 from S. elongatus cannot function in B. subtilis unless S14Se is present.IMPORTANCE S14, an essential ribosomal protein, may have evolved to adapt bacteria to zinc-limited environments by replacement of a zinc-binding motif with a zinc-independent sequence. It was expected that the bacterial ribosome would be tolerant to replacement of S14 because of the previous prediction that the spread of C- type S14 involved horizontal gene transfer. In this study, we completely replaced the C+ type of S14 in B. subtilis ribosome with the heterologous C- long type of S14 and characterized the resulting chimeric ribosomes. Our results suggest that the B. subtilis ribosome is permissive for the replacement of S14, but coevolution of S3 might be required to utilize the C- long type of S14 more effectively.

Acetate-dependent tRNA acetylation required for decoding fidelity in protein synthesis.

Modification of tRNA anticodons plays a critical role in ensuring accurate translation. N4-acetylcytidine (ac4C) is present at the anticodon first position (position 34) of bacterial elongator tRNAMet. Herein, we identified Bacillus subtilis ylbM (renamed tmcAL) as a novel gene responsible for ac4C34 formation. Unlike general acetyltransferases that use acetyl-CoA, TmcAL activates an acetate ion to form acetyladenylate and then catalyzes ac4C34 formation through a mechanism similar to tRNA aminoacylation. The crystal structure of TmcAL with an ATP analog reveals the molecular basis of ac4C34 formation. The ΔtmcAL strain displayed a cold-sensitive phenotype and a strong genetic interaction with tilS that encodes the enzyme responsible for synthesizing lysidine (L) at position 34 of tRNAIle to facilitate AUA decoding. Mistranslation of the AUA codon as Met in the ΔtmcAL strain upon tilS repression suggests that ac4C34 modification of tRNAMet and L34 modification of tRNAIle act cooperatively to prevent misdecoding of the AUA codon.

Small RNA Esr41 inversely regulates expression of LEE and flagellar genes in enterohaemorrhagic Escherichia coli.

Enterohaemorrhagic Escherichia coli (EHEC) is a life-threatening human pathogen worldwide. The locus of enterocyte effacement (LEE) in EHEC encodes a type three secretion system and effector proteins, all of which are essential for bacterial adherence to host cells. When LEE expression is activated, flagellar gene expression is down-regulated because bacterial flagella induce the immune responses of host cells at the infection stage. Therefore, this inverse regulation is also important for EHEC infection. We report here that a small regulatory RNA (sRNA), Esr41, mediates LEE repression and flagellar gene activation. Multiple copies of esr41 abolished LEE expression by down-regulating the expression of ler and pch, which encode positive regulators of LEE. This regulation led to reduced EHEC adhesion to host cells. Translational gene-reporter fusion experiments revealed that Esr41 regulates ler expression at a post-transcriptional level, and pch transcription, probably via an unknown target of Esr41. Esr41-mediated ler and pch repression was not observed in cells lacking hfq, which encodes an RNA-binding protein essential for most sRNA functions, indicating that Esr41 acts in an Hfq-dependent manner. We previously reported an increase in cell motility induced by Esr41. This motility enhancement was also observed in EHEC lacking ler, showing that Esr41-mediated enhancement of cell motility is in a ler-independent manner. In addition, Esr41 activated the expression of flagellar Class 3 genes by indirectly inducing the transcription of fliA, which encodes the sigma factor for flagellar synthesis. These results suggest that Esr41 plays important roles in the inverse regulation of LEE and flagellar gene expression.

Circularly permuted tRNA genes: their expression and implications for their physiological relevance and development.

A number of genome analyses and searches using programs that focus on the RNA-specific bulge-helix-bulge (BHB) motif have uncovered a wide variety of disrupted tRNA genes. The results of these analyses have shown that genetic information encoding functional RNAs is described in the genome cryptically and is retrieved using various strategies. One such strategy is represented by circularly permuted tRNA genes, in which the sequences encoding the 5'-half and 3'-half of the specific tRNA are separated and inverted on the genome. Biochemical analyses have defined a processing pathway in which the termini of tRNA precursors (pre-tRNAs) are ligated to form a characteristic circular RNA intermediate, which is then cleaved at the acceptor-stem to generate the typical cloverleaf structure with functional termini. The sequences adjacent to the processing site located between the 3'-half and the 5'-half of pre-tRNAs potentially form a BHB motif, which is the dominant recognition site for the tRNA-intron splicing endonuclease, suggesting that circularization of pre-tRNAs depends on the splicing machinery. Some permuted tRNAs contain a BHB-mediated intron in their 5'- or 3'-half, meaning that removal of an intron, as well as swapping of the 5'- and 3'-halves, are required during maturation of their pre-tRNAs. To date, 34 permuted tRNA genes have been identified from six species of unicellular algae and one archaeon. Although their physiological significance and mechanism of development remain unclear, the splicing system of BHB motifs seems to have played a key role in the formation of permuted tRNA genes. In this review, current knowledge of circularly permuted tRNA genes is presented and some unanswered questions regarding these species are discussed.

A novel small regulatory RNA enhances cell motility in enterohemorrhagic Escherichia coli.

Small regulatory RNAs (sRNAs) are conserved among a wide range of bacteria. They modulate the translational efficiency of target mRNAs through base-pairing with the help of RNA chaperone Hfq. The present study identified a novel sRNA, Esr41 (enterohemorrhagic Escherichia coli O157 small RNA #41), from an intergenic region of an enterohemorrhagic E. coli (EHEC) O157:H7 Sakai-specific sequence that is not present in the nonpathogenic E. coli K-12. Esr41 was detected as an RNA molecule approximately 70 nucleotides long with a 3' GC-rich palindrome sequence followed by a long poly(U), which is a characteristic of rho-independent terminators and is also a structural feature required for the action of Hfq. EHEC O157 harboring a multicopy plasmid carrying the esr41 gene increased cell motility and the expression of fliC, a gene encoding a major flagellar component. These results indicate that Esr41 stimulates fliC expression in EHEC O157. Furthermore, the increase in cell motility induced by Esr41 was also observed in the E. coli K-12, suggesting that target genes controlled by Esr41 are present in both EHEC O157 and K-12.

Identification of highly-disrupted tRNA genes in nuclear genome of the red alga, Cyanidioschyzon merolae 10D.

The limited locations of tRNA introns are crucial for eukaryal tRNA-splicing endonuclease recognition. However, our analysis of the nuclear genome of an early-diverged red alga, Cyanidioschyzon merolae, demonstrated the first evidence of nuclear-encoded tRNA genes that contain ectopic and/or multiple introns. Some genes exhibited both intronic and permuted structures in which the 3'-half of the tRNA coding sequence lies upstream of the 5'-half, and an intron is inserted into either half. These highly disrupted tRNA genes, which account for 63% of all nuclear tRNA genes, are expressed via the orderly and sequential processing of bulge-helix-bulge (BHB) motifs at intron-exon junctions and termini of permuted tRNA precursors, probably by a C. merolae tRNA-splicing endonuclease with an unidentified subunit architecture. The results revealed a considerable diversity in eukaryal tRNA intron properties and endonuclease architectures, which will help to elucidate the acquisition mechanism of the BHB-mediated disrupted tRNA genes.

Permuted tRNA genes expressed via a circular RNA intermediate in Cyanidioschyzon merolae.

A computational analysis of the nuclear genome of a red alga, Cyanidioschyzon merolae, identified 11 transfer RNA (tRNA) genes in which the 3' half of the tRNA lies upstream of the 5' half in the genome. We verified that these genes are expressed and produce mature tRNAs that are aminoacylated. Analysis of tRNA-processing intermediates for these genes indicates an unusual processing pathway in which the termini of the tRNA precursor are ligated, resulting in formation of a characteristic circular RNA intermediate that is then processed at the acceptor stem to generate the correct termini.

SPLITS: a new program for predicting split and intron-containing tRNA genes at the genome level.

In the archaea, some tRNA precursors contain intron(s) not only in the anticodon loop region but also in diverse sites of the gene (intron-containing tRNA or cis-spliced tRNA). The parasite Nanoarchaeum equitans, a member of the Nanoarchaeota kingdom, creates functional tRNA from separate genes, one encoding the 5'-half and the other the 3'-half (split tRNA or trans-spliced tRNA). Although recent genome projects have revealed a huge amount of nucleotide sequence data in the archaea, a comprehensive methodology for intron-containing and split tRNA searching is yet to be established. We therefore developed SPLITS, which is aimed at searching for any type of tRNA gene and is especially focused on intron-containing tRNAs or split tRNAs at the genome level. SPLITS initially predicts the bulge-helix-bulge splicing motif (a well-known, required structure in archaeal pre-tRNA introns) to determine and remove the intronic regions of tRNA genes. The intron-removed DNA sequences are automatically queried to tRNAscan-SE. SPLITS can predict known tRNAs with single introns located at unconventional sites on the genes (100%), tRNAs with double introns (85.7%), and known split tRNAs (100%). Our program will be very useful for identifying novel tRNA genes after completion of genome projects. The SPLITS source code is freely downloadable at http://splits.iab.keio.ac.jp/.

molecular mechanism of lysidine synthesis that determines tRNA identity and codon recognition.

Lysidine (2-lysyl cytidine) is a lysine-containing cytidine derivative commonly found at the wobble position of bacterial AUA codon-specific tRNA(Ile). This modification determines both codon and amino acid specificities of tRNA(Ile). We previously identified tRNA(Ile)-lysidine synthetase (tilS) that synthesizes lysidine, for which it utilizes ATP and lysine as substrates. Here, we show that lysidine synthesis consists of two consecutive reactions that involve an adenylated tRNA intermediate. A mutation study revealed that Escherichia coli TilS discriminates tRNA(Ile) from the structurally similar tRNA(Met) having the same anticodon loop by recognizing the anticodon loop, the anticodon stem, and the acceptor stem. TilS was shown to bind to the anticodon region and 3' side of the acceptor stem, which cover the recognition sites. These findings reveal a dedicated mechanism embedded in tRNA(Ile) that controls its recognition and discrimination by TilS, and indicate the significance of this enzyme in the proper deciphering of genetic information.

Structural basis for lysidine formation by ATP pyrophosphatase accompanied by a lysine-specific loop and a tRNA-recognition domain.

Lysidine, a lysine-combined modified cytidine, is exclusively located at the anticodon wobble position (position 34) of eubacterial tRNA(Ile)(2) and not only converts the codon specificity from AUG to AUA, but also converts the aminoacylation specificity from recognition by methionyl-tRNA synthetase to that by isoleucyl-tRNA synthetase (IleRS). Here, we report the crystal structure of lysidine synthetase (TilS) from Aquifex aeolicus at 2.42-A resolution. TilS forms a homodimer, and each subunit consists of the N-terminal dinucleotide-binding fold domain (NTD), with a characteristic central hole, and the C-terminal globular domain (CTD) connected by a long alpha-helical linker. The NTD shares striking structural similarity with the ATP-pyrophosphatase domain of GMP synthetase, which reminds us of the two-step reaction by TilS: adenylation of C34 and lysine attack on the C2 carbon. Conserved amino acid residues are clustered around the NTD central hole. Kinetic analyses of the conserved residues' mutants indicated that C34 of tRNA(Ile)(2) is adenylated by an ATP lying across the NTD central hole and that a lysine, which is activated at a loop appended to the NTD, nucleophilically attacks the C2 carbon from the rear. Escherichia coli TilS (called MesJ) has an additional CTD, which may recognize the tRNA(Ile)(2) acceptor stem. In contrast, a mutational study revealed that A. aeolicus TilS does not recognize the tRNA acceptor stem but recognizes the C29.G41 base pair in the anticodon stem. Thus, the two TilS enzymes discriminate tRNA(Ile)(2) from tRNA(Met) by strategies similar to that used by IleRS, but in distinct manners.

An RNA-modifying enzyme that governs both the codon and amino acid specificities of isoleucine tRNA.

The AUA codon-specific isoleucine tRNA (tRNA(Ile)) in eubacteria has the posttranscriptionally modified nucleoside lysidine (L) at the wobble position of the anticodon (position 34). This modification is a lysine-containing cytidine derivative that converts both the codon specificity of tRNA(Ile) from AUG to AUA and its amino acid specificity from methionine to isoleucine. We identified an essential gene (tilS; tRNA(Ile)-lysidine synthetase) that is responsible for lysidine formation in both Bacillus subtilis and Escherichia coli. The recombinant enzyme complexed specifically with tRNA(Ile) and synthesized L by utilizing ATP and lysine as substrates. The lysidine synthesis of this enzyme was shown to directly convert the amino acid specificity of tRNA(Ile) from methionine to isoleucine in vitro. Partial inactivation of tilS in vivo resulted in an AUA codon-dependent translational defect, which supports the notion that TilS is an RNA-modifying enzyme that plays a critical role in the accurate decoding of genetic information.

Site-specific incorporation of an unnatural amino acid into proteins in mammalian cells.

A suppressor tRNA(Tyr) and mutant tyrosyl-tRNA synthetase (TyrRS) pair was developed to incorporate 3-iodo-L-tyrosine into proteins in mammalian cells. First, the Escherichia coli suppressor tRNA(Tyr) gene was mutated, at three positions in the D arm, to generate the internal promoter for expression. However, this tRNA, together with the cognate TyrRS, failed to exhibit suppressor activity in mammalian cells. Then, we found that amber suppression can occur with the heterologous pair of E.coli TyrRS and Bacillus stearothermophilus suppressor tRNA(Tyr), which naturally contains the promoter sequence. Furthermore, the efficiency of this suppression was significantly improved when the suppressor tRNA was expressed from a gene cluster, in which the tRNA gene was tandemly repeated nine times in the same direction. For incorporation of 3-iodo-L-tyrosine, its specific E.coli TyrRS variant, TyrRS(V37C195), which we recently created, was expressed in mammalian cells, together with the B.stearothermophilus suppressor tRNA(Tyr), while 3-iodo-L-tyrosine was supplied in the growth medium. 3-Iodo-L-tyrosine was thus incorporated into the proteins at amber positions, with an occupancy of >95%. Finally, we demonstrated conditional 3-iodo-L-tyrosine incorporation, regulated by inducible expression of the TyrRS(V37C195) gene from a tetracycline-regulated promoter.

Improvement of gel properties of dried egg white by modification with galactomannan through the Maillard reaction.

The effects of Maillard reaction on gel properties of dried egg white (DEW) with galactomannan (GM) were investigated. Maillard-reacted DEW (MDEW) was prepared by dry-heating a mixture with a weight ratio of 1:4 of GM to DEW at 60 degrees C and 65% relative humidity. The modification of amino groups and polymerization of DEW proteins dry-heated with GM proceeded with increasing the dry-heating time. The covalent attachment of GM to DEW was confirmed from SDS-PAGE analysis. Gel strength and water-holding capacity of MDEW gels were higher than those of DEW dry-heated without GM (control DEW) and reached maximum after 3 days of dry-heating. The appearance of MDEW gels became transparent with increasing the dry-heating time, but control DEW gels were still turbid. MDEW dry-heated for 3 days was almost soluble even after heating of its solution at 90 degrees C, whereas control DEW proteins precipitated. The modification of DEW with GM through the Maillard reaction was an effective method to make a firm and transparent gel from DEW at broader range of pH and NaCl concentration of the medium.