Sequence Divergence of Seryl-tRNA Synthetases in Archaea

The genomic sequences of Methanococcus jannaschii and Methanobacterium thermoautotrophicum contain a structurally uncommon seryl-tRNA synthetase (SerRS) sequence and lack an open reading frame (ORF) for the canonical cysteinyl-tRNA synthetase (CysRS). Therefore, it is not clear if Cys-tRNA^Cys is formed by direct aminoacylation or by a transformation of serine misacylated to tRNA^Cys. To address this question, we prepared SerRS from two methanogenic archaea and measured the enzymatic properties of these proteins. SerRS was purified from M. thermoautotrophicum; its N-terminal peptide sequence matched the sequence deduced from the relevant ORF in the genomic data of M. thermoautotrophicum and M. jannaschii. In addition, SerRS was expressed from a cloned Methanococcus maripaludis serS gene. The two enzymes charged serine to their homologous tRNAs and also accepted Escherichia coli tRNA as substrate for aminoacylation. Gel shift experiments showed that M. thermoautotrophicum SerRS did not mischarge tRNA^Cys with serine. This indicates that Cys-tRNA^Cys is formed by direct acylation in these organisms.     

Effect of glycl-tRNA concentration on in vitro serine incorporation into the peptidoglycan of S. epidermidis

Seven species of seryl-tRNA have been isolated from $\text{S. epidermidis}$ strain Texas 26 by the use of Plaskon CTFE powder as the support for Adogen 464 in reversed-phase chromatography. All but one of these seven seryl-tRNA incorporated ¹⁴C-serine into $\text{in vitro}$ biosynthesized peptidoglycan. This suggested that at least one of the functional roles of six of the seven seryl-tRNA peaks isolated may be involved in $\text{in vivo}$ cell wall synthesis. It has also been shown that the ratio of glycine to serine in the pentapeptide bridge depended upon the concentration of glycyl-tRNA in the assay mixture. By increasing the concentration of glycyl-tRNA the amount of serine inserted into the bridge is increased. Thus the amount of serine incorporated into the pentapeptide bridge appears to be dependent upon the concentration of glycyl-tRNA.     

Maize mitochondrial seryl-tRNA synthetase recognizes Escherichia coli tRNASer in vivo and in vitro

In our studies to analyze the structure/function relationships among cytoplasmic and organellar seryl-tRNA synthetases (SerRS), we have characterized a Zea mays cDNA (SerZMm) encoding a protein with significant similarity to prokaryotic SerRS enzymes. To demonstrate the functional identity of SerZMm, the gene sequence encoding the putative mature protein was cloned. This construct complemented in vivo a temperature-sensitive Escherichia coli serS mutant strain. The mature SerZMm protein overexpressed in Escherichia coli efficiently aminoacylated bacterial tRNA^Ser in vitro, while yeast tRNA was a poor substrate. These data identify SerZMm as an organellar maize seryl-tRNA synthetase, the first plant organellar SerRS to be cloned. The analysis of its N-terminal targeting signal suggests a mitochondrial function for the SerZMm protein in maize.     

Selective degradation of tRNASer(AGY) is the primary driver for mitochondrial seryl-tRNA synthetase-related disease

Mitochondrial translation is of high significance for cellular energy homeostasis. Aminoacyl-tRNA synthetases (aaRSs) are crucial translational components. Mitochondrial aaRS variants cause various human diseases. However, the pathogenesis of the vast majority of these diseases remains unknown. Here, we identified two novel SARS2 (encoding mitochondrial seryl-tRNA synthetase) variants that cause a multisystem disorder. c.654–14T > A mutation induced mRNA mis-splicing, generating a peptide insertion in the active site; c.1519dupC swapped a critical tRNA-binding motif in the C-terminus due to stop codon readthrough. Both mutants exhibited severely diminished tRNA binding and aminoacylation capacities. A marked reduction in mitochondrial tRNA^Ser(AGY) was observed due to RNA degradation in patient-derived induced pluripotent stem cells (iPSCs), causing impaired translation and comprehensive mitochondrial function deficiencies. These impairments were efficiently rescued by wild-type SARS2 overexpression. Either mutation caused early embryonic fatality in mice. Heterozygous mice displayed reduced muscle tissue-specific levels of tRNA^Sers. Our findings elucidated the biochemical and cellular consequences of impaired translation mediated by SARS2, suggesting that reduced abundance of tRNA^Ser(AGY) is a key determinant for development of SARS2-related diseases.     

Tertiary structure of bacterial selenocysteine tRNA

Selenocysteine (Sec) is translationally incorporated into proteins in response to the UGA codon. The tRNA specific to Sec (tRNA^Sec) is first ligated with serine by seryl-tRNA synthetase (SerRS). In the present study, we determined the 3.1 Å crystal structure of the tRNA^Sec from the bacterium Aquifex aeolicus, in complex with the heterologous SerRS from the archaeon Methanopyrus kandleri. The bacterial tRNA^Sec assumes the L-shaped structure, from which the long extra arm protrudes. Although the D-arm conformation and the extra-arm orientation are similar to those of eukaryal/archaeal tRNA^Secs, A. aeolicus tRNA^Sec has unique base triples, G14:C21:U8 and C15:G20a:G48, which occupy the positions corresponding to the U8:A14 and R15:Y48 tertiary base pairs of canonical tRNAs. Methanopyrus kandleri SerRS exhibited serine ligation activity toward A. aeolicus tRNA^Sec in vitro. The SerRS N-terminal domain interacts with the extra-arm stem and the outer corner of tRNA^Sec. Similar interactions exist in the reported tRNA^Ser and SerRS complex structure from the bacterium Thermus thermophilus. Although the catalytic C-terminal domain of M. kandleri SerRS lacks interactions with A. aeolicus tRNA^Sec in the present complex structure, the conformational flexibility of SerRS is likely to allow the CCA terminal region of tRNA^Sec to enter the SerRS catalytic site.     

Divergence of selenocysteine tRNA recognition by archaeal and eukaryotic O-phosphoseryl-tRNASec kinase

Selenocysteine (Sec) biosynthesis in archaea and eukaryotes requires three steps: serylation of tRNA^Sec by seryl-tRNA synthetase (SerRS), phosphorylation of Ser-tRNA^Sec by O-phosphoseryl-tRNA^Sec kinase (PSTK), and conversion of O-phosphoseryl-tRNA^Sec (Sep-tRNA^Sec) by Sep-tRNA:Sec-tRNA synthase (SepSecS) to Sec-tRNA^Sec. Although SerRS recognizes both tRNA^Sec and tRNA^Ser species, PSTK must discriminate Ser-tRNA^Sec from Ser-tRNA^Ser. Based on a comparison of the sequences and secondary structures of archaeal tRNA^Sec and tRNA^Ser, we introduced mutations into Methanococcus maripaludis tRNA^Sec to investigate how Methanocaldococcus jannaschii PSTK distinguishes tRNA^Sec from tRNA^Ser. Unlike eukaryotic PSTK, the archaeal enzyme was found to recognize the acceptor stem rather than the length and secondary structure of the D-stem. While the D-arm and T-loop provide minor identity elements, the acceptor stem base pairs G2-C71 and C3-G70 in tRNA^Sec were crucial for discrimination from tRNA^Ser. Furthermore, the A5-U68 base pair in tRNA^Ser has some antideterminant properties for PSTK. Transplantation of these identity elements into the tRNA^Ser_UGA scaffold resulted in phosphorylation of the chimeric Ser-tRNA. The chimera was able to stimulate the ATPase activity of PSTK albeit at a lower level than tRNA^Sec, whereas tRNA^Ser did not. Additionally, the seryl moiety of Ser-tRNA^Sec is not required for enzyme recognition, as PSTK efficiently phosphorylated Thr-tRNA^Sec.     

Dimer–Dimer Interaction of the Bacterial Selenocysteine Synthase SelA Promotes Functional Active-Site Formation and Catalytic Specificity

The 21st amino acid, selenocysteine (Sec), is incorporated translationally into proteins and is synthesized on its specific tRNA (tRNA^Sec). In Bacteria, the selenocysteine synthase SelA converts Ser-tRNA^Sec, formed by seryl-tRNA synthetase, to Sec-tRNA^Sec. SelA, a member of the fold-type-I pyridoxal 5′-phosphate-dependent enzyme superfamily, has an exceptional homodecameric quaternary structure with a molecular mass of about 500 kDa. Our previously determined crystal structures of Aquifex aeolicus SelA complexed with tRNA^Sec revealed that the ring-shaped decamer is composed of pentamerized SelA dimers, with two SelA dimers arranged to collaboratively interact with one Ser-tRNA^Sec. The SelA catalytic site is close to the dimer–dimer interface, but the significance of the dimer pentamerization in the catalytic site formation remained elusive. In the present study, we examined the quaternary interactions and demonstrated their importance for SelA activity by systematic mutagenesis. Furthermore, we determined the crystal structures of “depentamerized” SelA variants with mutations at the dimer–dimer interface that prevent pentamerization. These dimeric SelA variants formed a distorted and inactivated catalytic site and confirmed that the pentamer interactions are essential for productive catalytic site formation. Intriguingly, the conformation of the non-functional active site of dimeric SelA shares structural features with other fold-type-I pyridoxal 5′-phosphate-dependent enzymes with native dimer or tetramer (dimer-of-dimers) quaternary structures.     

Role of guanosine tetraphosphate in gene expression and the survival of glucose or seryl-tRNA starved cells of Escherichia coli K12

The concentration of guanosine 3′,5′-bispyrophosphate (ppGpp) increases in bacteria in response to amino acid or carbon/energy source starvation. An Escherichia coli K12 ΔrelAΔspoT mutant lacking the ability to synthesize ppGpp lost viability at an increased rate during both glucose and seryl-tRNA starvation. Also, the deleterious effect of chloramphenicol on starved wild-type cells could be overcome by inducing expression of RelA from a plasmid carrying the relA gene transcribed from a tac promoter, prior to starvation and chloramphenicol treatment. As demonstrated by two dimensional gel electrophoresis, this induction of the RelA protein resulted in global alterations in gene expression including increased synthesis of some rpoS-dependent proteins. The ΔrelAΔspoT mutant maintained high expression of several ribosomal proteins during starvation and appeared to exhibit significantly decreased translational fidelity, as demonstrated by an unusual heterogeneity in the isoelectric point of several proteins and the failure to express higher molecular weight proteins during starvation. Moreover, both rpoS-dependent and independent genes failed to exhibit increased expression in the mutant. It is suggested that the deleterious effects on the cells of the relA, spoT deletions are not due solely to the inability of these cells to induce the sigma factor σ^s, but also to deficiencies in translational fidelity and failure to exert classical stringent regulation.     

Exclusive cytosolic localization and broad tRNA<Superscript>Ser</Superscript> specificity of <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> seryl-tRNA synthetase

Aminoacyl-tRNA synthetases (aaRSs) decipher the genetic code, covalently linking amino acids to cognate tRNAs, thus preparing substrates for the process of translation. Although aaRSs funtion primarily in translation and are localized in cytosol, mitochondria and chloroplasts there are many reports on their additional functions and subcellular destinations beyond translation. However, data on plant aaRSs are scarce. Initial analysis of amino acid sequence of Arabidopsis thaliana seryl-tRNA synthetase (SerRS) suggested that protein contains putative nuclear localization signals. GFP-localization experiments in transiently transformed epidermal onion cells and Arabidopsis protoplasts gave ambiguous results because in some cells SerRS appeared to be dually localized to both cytosol and nucleus. However, data obtained on transgenic lines expressing SerRS-TAP and GFP-SerRS revealed exclusive cytosolic location of SerRS. Subcellular distribution of SerRS did not change during stress. Cytosolic Arabidopsis SerRS was expressed and purified. The enzyme efficiently aminoacylated eukaryotic and bacterial tRNAs^Ser, that are structurally very different. Given the fact that the same behavior was previously shown for monocot maize SerRS, it seems that plant SerRSs exhibit unusually broad tRNA^Ser specificity, unlike SerRSs from other organisms. Possible functional implications of this unique characteristic of plant SerRSs are discussed.     

Molecular basis for human mitochondrial tRNA m3C modification by alternatively spliced METTL8

METTL8 has recently been identified as the methyltransferase catalyzing 3-methylcytidine biogenesis at position 32 (m³C32) of mitochondrial tRNAs. METTL8 also potentially participates in mRNA methylation and R-loop biogenesis. How METTL8 plays multiple roles in distinct cell compartments and catalyzes mitochondrial tRNA m³C formation remain unclear. Here, we discovered that alternative mRNA splicing generated several isoforms of METTL8. One isoform (METTL8-Iso1) was targeted to mitochondria via an N-terminal pre-sequence, while another one (METTL8-Iso4) mainly localized to the nucleolus. METTL8-Iso1-mediated m³C32 modification of human mitochondrial tRNA^Thr (hmtRNA^Thr) was not reliant on t⁶A modification at A37 (t⁶A37), while that of hmtRNA^Ser(UCN) critically depended on i⁶A modification at A37 (i⁶A37). We clarified the hmtRNA^Thr substrate recognition mechanism, which was obviously different from that of hmtRNA^Ser(UCN), in terms of requiring a G35 determinant. Moreover, SARS2 (mitochondrial seryl-tRNA synthetase) interacted with METTL8-Iso1 in an RNA-independent manner and modestly accelerated m³C modification activity. We further elucidated how nonsubstrate tRNAs in human mitochondria were efficiently discriminated by METTL8-Iso1. In summary, our results established the expression pattern of METTL8, clarified the molecular basis for m³C32 modification by METTL8-Iso1 and provided the rationale for the involvement of METTL8 in tRNA modification, mRNA methylation or R-loop biogenesis.     

Regulation of the biosynthesis of aminoacyl-tRNA synthetases and of tRNA in Escherichia coli. IV. Mutants with increased levels of leucyl- or seryl-tRNA synthetase.

Summary Spontaneous revertants of a temperature-sensitive Escherichia coli strain harboring a thermolabile leucyl-tRNA synthetase and seryl-tRNA synthetase were selected for growth at 40°C. Among these, strains were found with increased levels of both thermolabile synthetases. Two distinct genetic loci were found responsible for enzyme overproduction. leuR, located near xyl, causes elevated levels of leucyl-tRNA synthetase; while serR, located near leu, causes elevated levels of seryl-tRNA synthetase.The preceding paper in this series is by R. LaRossa, J. Mao, K.B. Low and D. Söll. J. Mol. Biol. 117, 1049 (1977)     

Peroxin Pex21p interacts with the C-terminal noncatalytic domain of yeast seryl-tRNA synthetase and forms a specific ternary complex with tRNA(Ser)

The seryl-tRNA synthetase from Saccharomyces cerevisiae interacts with the peroxisome biogenesis-related factor Pex21p. Several deletion mutants of seryl-tRNA synthetase were constructed and inspected for their ability to interact with Pex21p in a yeast two-hybrid assay, allowing mapping of the synthetase domain required for complex assembly. Deletion of the 13 C-terminal amino acids abolished Pex21p binding to seryl-tRNA synthetase. The catalytic parameters of purified truncated seryl-tRNA synthetase, determined in the serylation reaction, were found to be almost identical to those of the native enzyme. In vivo loss of interaction with Pex21p was confirmed in vitro by coaffinity purification. These data indicate that the C-terminally appended domain of yeast seryl-tRNA synthetase does not participate in substrate binding, but instead is required for association with Pex21p. We further determined that Pex21p does not directly bind tRNA, and nor does it possess a tRNA-binding motif, but it instead participates in the formation of a specific ternary complex with seryl-tRNA synthetase and tRNA(Ser), strengthening the interaction of seryl-tRNA synthetase with its cognate tRNA(Ser).     

New Developments in Selenium Biochemistry: Selenocysteine Biosynthesis in Eukaryotes and Archaea

We used comparative genomics and experimental analyses to show that (1) eukaryotes and archaea, which possess the selenocysteine (Sec) protein insertion machinery contain an enzyme, O-phosphoseryl-transfer RNA (tRNA)^[Ser]Sec kinase (designated PSTK), which phosphorylates seryl-tRNA^[Ser]Sec to form O-phosphoseryl-tRNA^[Ser]Sec and (2) the Sec synthase (SecS) in mammals is a pyridoxal phosphate-containing protein previously described as the soluble liver antigen (SLA). SecS uses the product of PSTK, O-phosphoseryl-tRNA^[Ser]Sec, and selenophosphate as substrates to generate selenocysteyl-tRNA^[Ser]Sec. Sec could be synthesized on tRNA^[Ser]Sec from selenide, adenosine triphosphate (ATP), and serine using tRNA^[Ser]Sec, seryl-tRNA synthetase, PSTK, selenophosphate synthetase, and SecS. The enzyme that synthesizes monoselenophosphate is a previously identified selenoprotein, selenophosphate synthetase 2 (SPS2), whereas the previously identified mammalian selenophosphate synthetase 1 did not serve this function. Monoselenophosphate also served directly in the reaction replacing ATP, selenide, and SPS2, demonstrating that this compound was the active selenium donor. Conservation of the overall pathway of Sec biosynthesis suggests that this pathway is also active in other eukaryotes and archaea that contain selenoproteins. X.-M. Xu and B. A. Carlson contributed equally to the studies described herein.     

SerRS-tRNASec complex structures reveal mechanism of the first step in selenocysteine biosynthesis

Selenocysteine (Sec) is found in the catalytic centers of many selenoproteins and plays important roles in living organisms. Malfunctions of selenoproteins lead to various human disorders including cancer. Known as the 21st amino acid, the biosynthesis of Sec involves unusual pathways consisting of several stages. While the later stages of the pathways are well elucidated, the molecular basis of the first stage—the serylation of Sec-specific tRNA (tRNA^Sec) catalyzed by seryl-tRNA synthetase (SerRS)—is unclear. Here we present two cocrystal structures of human SerRS bound with tRNA^Sec in different stoichiometry and confirm the formation of both complexes in solution by various characterization techniques. We discovered that the enzyme mainly recognizes the backbone of the long variable arm of tRNA^Sec with few base-specific contacts. The N-terminal coiled-coil region works like a long-range lever to precisely direct tRNA 3′ end to the other protein subunit for aminoacylation in a conformation-dependent manner. Restraints of the flexibility of the coiled-coil greatly reduce serylation efficiencies. Lastly, modeling studies suggest that the local differences present in the D- and T-regions as well as the characteristic U20:G19:C56 base triple in tRNA^Sec may allow SerRS to distinguish tRNA^Sec from closely related tRNA^Ser substrate.     

Structural and functional investigation of a putative archaeal selenocysteine synthase

Bacterial selenocysteine synthase converts seryl-tRNA(Sec) to selenocysteinyl-tRNA(Sec) for selenoprotein biosynthesis. The identity of this enzyme in archaea and eukaryotes is unknown. On the basis of sequence similarity, a conserved open reading frame has been annotated as a selenocysteine synthase gene in archaeal genomes. We have determined the crystal structure of the corresponding protein from Methanococcus jannaschii, MJ0158. The protein was found to be dimeric with a distinctive domain arrangement and an exposed active site, built from residues of the large domain of one protomer alone. The shape of the dimer is reminiscent of a substructure of the decameric Escherichia coli selenocysteine synthase seen in electron microscopic projections. However, biochemical analyses demonstrated that MJ0158 lacked affinity for E. coli seryl-tRNA(Sec) or M. jannaschii seryl-tRNA(Sec), and neither substrate was directly converted to selenocysteinyl-tRNA(Sec) by MJ0158 when supplied with selenophosphate. We then tested a hypothetical M. jannaschii O-phosphoseryl-tRNA(Sec) kinase and demonstrated that the enzyme converts seryl-tRNA(Sec) to O-phosphoseryl-tRNA(Sec) that could constitute an activated intermediate for selenocysteinyl-tRNA(Sec) production. MJ0158 also failed to convert O-phosphoseryl-tRNA(Sec) to selenocysteinyl-tRNA(Sec). In contrast, both archaeal and bacterial seryl-tRNA synthetases were able to charge both archaeal and bacterial tRNA(Sec) with serine, and E. coli selenocysteine synthase converted both types of seryl-tRNA(Sec) to selenocysteinyl-tRNA(Sec). These findings demonstrate that a number of factors from the selenoprotein biosynthesis machineries are cross-reactive between the bacterial and the archaeal systems but that MJ0158 either does not encode a selenocysteine synthase or requires additional factors for activity.     

Methyltransferase METTL8 is required for 3-methylcytosine modification in human mitochondrial tRNAs

A subset of eukaryotic tRNAs is methylated in the anticodon loop, forming 3-methylcytosine (m³C) modifications. In mammals, the number of tRNAs containing m³C modifications has been expanded to include mitochondrial (mt) tRNA-Ser-UGA and mt-tRNA-Thr-UGU. However, whereas the enzymes catalyzing m³C formation in nuclear-encoded tRNAs have been identified, the proteins responsible for m³C modification in mt-tRNAs are unknown. Here, we show that m³C formation in human mt-tRNAs is dependent upon the methyltransferase-Like 8 (METTL8) enzyme. We find that METTL8 is a mitochondria-associated protein that interacts with mitochondrial seryl-tRNA synthetase, as well as with mt-tRNAs containing m³C. We demonstrate that human cells deficient in METTL8 exhibit loss of m³C modification in mt-tRNAs, but not nuclear-encoded tRNAs. Consistent with the mitochondrial import of METTL8, the formation of m³C in METTL8-deficient cells could be rescued by re-expression of WT METTL8, but not by a METTL8 variant lacking the N-terminal mitochondrial localization signal. Notably, we found METTL8-deficiency in human cells causes alterations in the native migration pattern of mt-tRNA-Ser-UGA, suggesting a role for m³C in tRNA folding. Altogether, these findings demonstrate that METTL8 is required for m³C formation in mt-tRNAs and uncover a potential function for m³C modification in mitochondrial tRNA structure.