Proceedings of the National Academy of Sciences, 1999
Lysyl-tRNA synthetases (LysRSs) are unique amongst the aminoacyl-tRNA synthetases in being compos... more Lysyl-tRNA synthetases (LysRSs) are unique amongst the aminoacyl-tRNA synthetases in being composed of unrelated class I and class II enzymes. To allow direct comparison between the two types of LysRS, substrate recognition by class I LysRSs was examined. Genes encoding both an archaeal and a bacterial class I enzyme were able to rescue an Escherichia coli strain deficient in LysRS, indicating their ability to functionally substitute for a class II LysRS in vivo. In vitro characterization showed lysine activation and recognition to be tRNAdependent, an attribute of several class I, but not class II, aminoacyl-tRNA synthetases. Examination of tRNA recognition showed that class I LysRSs recognize the same elements in tRNA Lys as their class II counterparts, namely the discriminator base (N73) and the anticodon. This sequence-specific recognition of the same nucleotides in tRNA Lys by the two unrelated types of enzyme suggests that tRNA Lys predates at least one of the LysRSs in the evolution of the translational apparatus. The only observed variation in recognition was that the G2⅐U71 wobble pair of spirochete tRNA Lys acts as antideterminant for class II LysRS but does not alter class I enzyme recognition. This difference in tRNA recognition strongly favors the use of a class I-type enzyme to aminoacylate particular tRNA Lys species and provides a molecular basis for the observed displacement of class II by class I LysRSs in certain bacteria.
Proceedings of the National Academy of Sciences, 1996
Sequence-specific interactions between aminoacyl-tRNA synthetases and their cognate tRNAs both en... more Sequence-specific interactions between aminoacyl-tRNA synthetases and their cognate tRNAs both ensure accurate RNA recognition and prevent the binding of noncognate substrates. Here we show for Escherichia coli glutaminyl-tRNA synthetase (GlnRS; EC 6.1.1.18) that the accuracy of tRNA recognition also determines the efficiency of cognate amino acid recognition. Steady-state kinetics revealed that interactions between tRNA identity nucleotides and their recognition sites in the enzyme modulate the amino acid affinity of GlnRS. Perturbation of any of the protein-RNA interactions through mutation of either component led to considerable changes in glutamine affinity with the most marked effects seen at the discriminator base, the 10:25 base pair, and the anticodon. Reexamination of the identity set of tRNAGIn in the light of these results indicates that its constituents can be differentiated based upon biochemical function and their contribution to the apparent Gibbs' free energy of tRNA binding. Interactions with the acceptor stem act as strong determinants of tRNA specificity, with the discriminator base positioning the 3' end. The 10:25 base pair and U35 are apparently the major binding sites to GlnRS, with G36 contributing both to binding and recognition. Furthermore, we show that E. coli tryptophanyl-tRNA synthetase also displays tRNA-dependent changes in tryptophan affinity when charging a noncognate tRNA. The ability of tRNA to optimize amino acid recognition reveals a novel mechanism for maintaining translational fidelity and also provides a strong basis for the coevolution of tRNAs and their cognate synthetases.
The role of tRNA as the adaptor in protein synthesis has held an enduring fascination for molecul... more The role of tRNA as the adaptor in protein synthesis has held an enduring fascination for molecular biologists. Over four decades of study, taking in numerous milestones in molecular biology, led to what was widely held to be a fairly complete picture of how tRNAs and amino acids are paired prior to protein synthesis. However, recent developments in genomics and structural biology have revealed an unexpected array of new enzymes, pathways and mechanisms involved in aminoacyl-tRNA synthesis. As a more complete picture of aminoacyl-tRNA synthesis now begins to emerge, the high degree of evolutionary diversity in this universal and essential process is becoming clearer.
Proceedings of the National Academy of Sciences, 2004
Threonyl-tRNA synthetase (ThrRS) participates in protein synthesis quality control by selectively... more Threonyl-tRNA synthetase (ThrRS) participates in protein synthesis quality control by selectively editing the misacylated species Ser-tRNA Thr . In bacteria and eukaryotes the editing function of ThrRS resides in a highly conserved N-terminal domain distant from the active site. Most archaeal ThrRS proteins are devoid of this editing domain, suggesting evolutionary divergence of quality-control mechanisms. Here we show that archaeal editing of Ser-tRNA Thr is catalyzed by a domain unrelated to, and absent from, bacterial and eukaryotic ThrRSs. Despite the lack of sequence homology, the archaeal and bacterial editing domains are both reliant on a pair of essential histidine residues suggestive of a common catalytic mechanism. Whereas the archaeal editing module is most commonly part of full-length ThrRS, several crenarchaeal species contain individual genes encoding the catalytic (ThrRS-cat) and editing domains (ThrRS-ed). Sulfolobus solfataricus ThrRS-cat was shown to synthesize both Thr-tRNA Thr and Ser-tRNA Thr and to lack editing activity against Ser-tRNA Thr . In contrast, ThrRS-ed lacks aminoacylation activity but can act as an autonomous protein in trans to hydrolyze specifically Ser-tRNA Thr , or it can be fused to ThrRS-cat to provide the same function in cis. Deletion analyses indicate that ThrRS-ed is dispensable for growth of S. solfataricus under standard conditions but is required for normal growth in media with elevated serine levels. The growth phenotype of the ThrRS-ed deletion strain suggests that retention of the discontinuous ThrRS quaternary structure relates to specific physiological requirements still evident in certain Archaea.
Lysyl-tRNA can be synthesized by both a class I (LysRS-I) and a class II (LysRS-II) lysyl-tRNA sy... more Lysyl-tRNA can be synthesized by both a class I (LysRS-I) and a class II (LysRS-II) lysyl-tRNA synthetase. The crystal structure of LysRS-I from Pyrococcus horikoshii at 2.6 A resolution reveals extensive similarity with glutamyl-tRNA synthetase (GluRS). A comparison of the structures of LysRS-I and LysRS-II in complex with lysine shows that both enzymes use similar strategies for substrate recognition within unrelated active site topologies. A docking model based upon the GluRS-tRNA complex suggests how LysRS-I and LysRS-II can recognize the same molecular determinants in tRNALys, as shown by biochemical results, while approaching the acceptor helix of the tRNA from opposite sides.
Monomethylamine methyltransferase of the archaebacterium Methanosarcina barkeri contains a novel ... more Monomethylamine methyltransferase of the archaebacterium Methanosarcina barkeri contains a novel amino acid, pyrrolysine, encoded by the termination codon UAG. Initial studies suggest that pyrrolysine may be co-translationally inserted during protein synthesis, probably by a mechanism analogous to that operating during selenocysteine incorporation.
The only difference between our genesilenced transgenic plants that were resistant to high temper... more The only difference between our genesilenced transgenic plants that were resistant to high temperature and the respective wildtype plants was that the chloroplasts of the transgenic plants contained a reduced level of trienoic fatty acids and an elevated level of dienoic fatty acids, which is controlled by chloroplast -3 fatty acid desaturase. Of the six different higher plant desaturases whose genes have been cloned, only the expression of the chloroplast FAD8 -3 fatty acid desaturase gene changes in response to a change in ambient temperature (22).
The lysyl-tRNA synthetase paralog PoxA modifies elongation factor P (EF-P) with α-lysine at low e... more The lysyl-tRNA synthetase paralog PoxA modifies elongation factor P (EF-P) with α-lysine at low efficiency. Cell-free extracts contained non-α-lysine substrates of PoxA that modified EF-P by a change in mass consistent with β-lysine, a substrate also predicted by genomic analyses. EF-P was efficiently, functionally, modified with (R)-β-lysine but not (S)-β-lysine or genetically encoded αamino acids, indicating that PoxA has evolved an activity orthogonal to that of the canonical aminoacyl-tRNA synthetases.
The Trojan horse antibiotic albomycin, produced by Streptomyces sp. strain ATCC 700974, contains ... more The Trojan horse antibiotic albomycin, produced by Streptomyces sp. strain ATCC 700974, contains a thioribosyl nucleoside moiety linked to a hydroxamate siderophore through a serine residue. The seryl nucleoside structure (SB-217452) is a potent inhibitor of seryl-tRNA synthetase (SerRS) in the pathogenic bacterium Staphylococcus aureus, with a 50% inhibitory concentration (IC 50 ) of ϳ8 nM. In the albomycinproducing Streptomyces sp., a bacterial SerRS homolog (Alb10) was found to be encoded in a biosynthetic gene cluster in addition to another serRS gene (serS1) at a different genetic locus. Alb10, named SerRS2 herein, is significantly divergent from SerRS1, which shows high homology to the housekeeping SerRS found in other Streptomyces species. We genetically and biochemically characterized the two genes and the proteins encoded. Both genes were able to complement a temperature-sensitive serS mutant of Escherichia coli and allowed growth at a nonpermissive temperature. serS2 was shown to confer albomycin resistance, with specific amino acid residues in the motif 2 signature sequences of SerRS2 playing key roles. SerRS1 and SerRS2 are comparably efficient in vitro, but the K m of serine for SerRS2 measured during tRNA aminoacylation is more than 20-fold higher than that for SerRS1. SB-217452 was also enzymatically generated and purified by two-step chromatography. Its IC 50 against SerRS1 was estimated to be 10-fold lower than that against SerRS2. In contrast, both SerRSs displayed comparable inhibition kinetics for serine hydroxamate, indicating that SerRS2 was specifically resistant to SB-217452. These data suggest that mining Streptomyces genomes for duplicated aminoacyl-tRNA synthetase genes could provide a novel approach for the identification of natural products targeting aminoacyl-tRNA synthetases.
Translation of the genetic code requires attachment of tRNAs to their cognate amino acids. Errors... more Translation of the genetic code requires attachment of tRNAs to their cognate amino acids. Errors during amino-acid activation and tRNA esterification are corrected by aminoacyl-tRNA synthetase-catalyzed editing reactions, as extensively described for aliphatic amino acids. The contribution of editing to aromatic amino-acid discrimination is less well understood. We show that phenylalanyl-tRNA synthetase misactivates tyrosine and that it subsequently corrects such errors through hydrolysis of tyrosyl-adenylate and Tyr-tRNA Phe . Structural modeling combined with an in vivo genetic screen identified the editing site in the B3/B4 domain of the b subunit, 40 Å from the active site in the a subunit. Replacements of residues within the editing site had no effect on Phe-tRNA Phe synthesis, but abolished hydrolysis of Tyr-tRNA Phe in vitro. Expression of the corresponding mutants in Escherichia coli significantly slowed growth, and changed the activity of a recoded b-galactosidase variant by misincorporating tyrosine in place of phenylalanine. This loss in aromatic amino-acid discrimination in vivo revealed that editing by phenylalanyl-tRNA synthetase is essential for faithful translation of the genetic code.
Aminoacyl-tRNA synthetases are normally found in one of two mutually exclusive structural classes... more Aminoacyl-tRNA synthetases are normally found in one of two mutually exclusive structural classes, the only known exception being lysyl-tRNA synthetase which exists in both classes I (LysRS1) and II (LysRS2). Differences in tRNA acceptor stem recognition between LysRS1 and LysRS2 do not drastically impact cellular aminoacylation levels, focusing attention on the mechanism of tRNA anticodon recognition by LysRS1. On the basis of structure-based sequence alignments, seven tRNA Lys anticodon variants and seven LysRS1 anticodon binding site variants were selected for analysis of the Pyrococcus horikoshii LysRS1-tRNA Lys docking model. LysRS1 specifically recognized the bases at positions 35 and 36, but not that at position 34. Aromatic residues form stacking interactions with U34 and U35, and aminoacylation kinetics also identified direct interactions between Arg502 and both U35 and U36. Tyr491 was also found to interact with U36, and the Y491E variant exhibited significant improvement compared to the wild type in aminoacylation of a tRNA Lys UUG mutant. Refinement of the LysRS1-tRNA Lys docking model based upon these data suggested that anticodon recognition by LysRS1 relies on considerably fewer interactions than that by LysRS2, providing a structural basis for the more significant role of the anticodon in tRNA recognition by the class II enzyme. To date, only glutamyl-tRNA synthetase (GluRS) has been found to contain an α-helix cage anticodon binding domain homologous to that of LysRS1, and these data now suggest that specificity for the anticodon of tRNA Lys could have been acquired through relatively few changes to the corresponding domain of an ancestral GluRS enzyme.
Several methanogenic archaea lack cysteinyl-transfer RNA (tRNA) synthetase (CysRS), the essential... more Several methanogenic archaea lack cysteinyl-transfer RNA (tRNA) synthetase (CysRS), the essential enzyme that provides Cys-tRNA(Cys) for translation in most organisms. Partial purification of the corresponding activity from Methanocaldococcus jannaschii indicated that tRNA(Cys) becomes acylated with O-phosphoserine (Sep) but not with cysteine. Further analyses identified a class II-type O-phosphoseryl-tRNA synthetase (SepRS) and Sep-tRNA:Cys-tRNA synthase (SepCysS). SepRS specifically forms Sep-tRNA(Cys), which is then converted to Cys-tRNA(Cys) by SepCysS. Comparative genomic analyses suggest that this pathway, encoded in all organisms lacking CysRS, can also act as the sole route for cysteine biosynthesis. This was proven for Methanococcus maripaludis, where deletion of the SepRS-encoding gene resulted in cysteine auxotrophy. As the conversions of Sep-tRNA to Cys-tRNA or to selenocysteinyl-tRNA are chemically analogous, the catalytic activity of SepCysS provides a means by which both cysteine and selenocysteine may have originally been added to the genetic code.
Proceedings of the National Academy of Sciences, 2008
Multiple peptide resistance (MprF) virulence factors control cellular permeability to cationic an... more Multiple peptide resistance (MprF) virulence factors control cellular permeability to cationic antibiotics by aminoacylating inner membrane lipids. It has been shown previously that one class of MprF can use Lys-tRNA Lys to modify phosphatidylglycerol (PG), but the mechanism of recognition and possible role of other MprFs are unknown. Here, we used an in vitro reconstituted lipid aminoacylation system to investigate the two phylogenetically distinct MprF paralogs (MprF1 and MprF2) found in the bacterial pathogen Clostridium perfringens. Although both forms of MprF aminoacylate PG, they do so with different amino acids; MprF1 is specific for Ala-tRNA Ala , and MprF2 utilizes Lys-tRNA Lys . This provides a mechanism by which the cell can fine tune the charge of the inner membrane by using the neutral amino acid alanine, potentially providing resistance to a broader range of antibiotics than offered by lysine modification alone. Mutation of tRNA Ala and tRNA Lys had little effect on either MprF activity, indicating that the aminoacyl moiety is the primary determinant for aminoacyl-tRNA recognition. The lack of discrimination of the tRNA is consistent with the role of MprF as a virulence factor, because species-specific differences in tRNA sequence would not present a barrier to horizontal gene transfer. Taken together, our findings reveal how the MprF proteins provide a potent virulence mechanism by which pathogens can readily acquire resistance to chemically diverse antibiotics.
Proceedings of the National Academy of Sciences, 2007
Protein synthesis requires the pairing of amino acids with tRNAs catalyzed by the aminoacyl-tRNA ... more Protein synthesis requires the pairing of amino acids with tRNAs catalyzed by the aminoacyl-tRNA synthetases. The synthetases are highly specific, but errors in amino acid selection are occasionally made, opening the door to inaccurate translation of the genetic code. The fidelity of protein synthesis is maintained by the editing activities of synthetases, which remove noncognate amino acids from tRNAs before they are delivered to the ribosome. Although editing has been described in numerous synthetases, the reaction mechanism is unknown. To define the mechanism of editing, phenylalanyl-tRNA synthetase was used to investigate different models for hydrolysis of the noncognate product Tyr-tRNA Phe . Deprotonation of a water molecule by the highly conserved residue His-265, as proposed for threonyl-tRNA synthetase, was excluded because replacement of this and neighboring residues had little effect on editing activity. Model building suggested that, instead of directly catalyzing hydrolysis, the role of the editing site is to discriminate and properly position noncognate substrate for nucleophilic attack by water. In agreement with this model, replacement of certain editing site residues abolished substrate specificity but only reduced the catalytic efficiency of hydrolysis 2to 10-fold. In contrast, substitution of the 3-OH group of tRNA Phe severely impaired editing and revealed an essential function for this group in hydrolysis. The phenylalanyl-tRNA synthetase editing mechanism is also applicable to threonyl-tRNA synthetase and provides a paradigm for synthetase editing.
Proceedings of the National Academy of Sciences, 2007
Human mitochondrial tRNA (hmt-tRNA) mutations are associated with a variety of diseases including... more Human mitochondrial tRNA (hmt-tRNA) mutations are associated with a variety of diseases including mitochondrial myopathies, diabetes, encephalopathies, and deafness. Because the current understanding of the precise molecular mechanisms of these mutations is limited, there is no efficient method to treat their associated mitochondrial diseases. Here, we use a variety of known mutations in hmt-tRNA Phe to investigate the mechanisms that lead to malfunctions. We tested the impact of hmt-tRNA Phe mutations on aminoacylation, structure, and translation elongation-factor binding. The majority of the mutants were pleiotropic, exhibiting defects in aminoacylation, global structure, and elongation-factor binding. One notable exception was the G34A anticodon mutation of hmt-tRNA Phe (mitochondrial DNA mutation G611A), which is associated with MERRF (myoclonic epilepsy with ragged red fibers). In vitro, the G34A mutation decreases aminoacylation activity by 100-fold, but does not affect global folding or recognition by elongation factor. Furthermore, G34A hmt-tRNA Phe does not undergo adenosine-to-inosine (A-to-I) editing, ruling out miscoding as a possible mechanism for mitochondrial malfunction. To improve the aminoacylation state of the mutant tRNA, we modified the tRNA binding domain of the nucleus-encoded human mitochondrial phenylalanyl-tRNA synthetase, which aminoacylates hmt-tRNA Phe with cognate phenylalanine. This variant enzyme displayed significantly improved aminoacylation efficiency for the G34A mutant, suggesting a general strategy to treat certain classes of mitochondrial diseases by modification of the corresponding nuclear gene.
Proceedings of the National Academy of Sciences, 2010
Protein synthesis has an overall error rate of approximately 10 −4 for each mRNA codon translated... more Protein synthesis has an overall error rate of approximately 10 −4 for each mRNA codon translated. The fidelity of translation is mainly determined by two events: synthesis of cognate amino acid:tRNA pairs by aminoacyl-tRNA synthetases (aaRSs) and accurate selection of aminoacyl-tRNAs (aa-tRNAs) by the ribosome. To ensure faithful aa-tRNA synthesis, many aaRSs employ a proofreading ("editing") activity, such as phenylalanyl-tRNA synthetases (PheRS) that hydrolyze mischarged Tyr-tRNA Phe . Eukaryotes maintain two distinct PheRS enzymes, a cytoplasmic (ctPheRS) and an organellar form. CtPheRS is similar to bacterial enzymes in that it consists of a heterotetramer in which the α-subunits contain the active site and the β-subunits harbor the editing site. In contrast, mitochondrial PheRS (mtPheRS) is an α-subunit monomer that does not edit Tyr-tRNA Phe , and a comparable transacting activity does not exist in organelles. Although mtPheRS does not edit, it is extremely specific as only one Tyr-tRNA Phe is synthesized for every ∼7; 300 Phe-tRNA Phe , compatible with an error rate in translation of ∼10 −4 . When the error rate of mtPheRS was increased 17-fold, the corresponding strain could not grow on respiratory media and the mitochondrial genome was rapidly lost. In contrast, error-prone mtPheRS, editing-deficient ctPheRS, and their wildtype counterparts all supported cytoplasmic protein synthesis and cell growth. These striking differences reveal unexpectedly divergent requirements for quality control in different cell compartments and suggest that the limits of translational accuracy may be largely determined by cellular physiology.
Proceedings of the National Academy of Sciences, 1999
Lysyl-tRNA synthetases (LysRSs) are unique amongst the aminoacyl-tRNA synthetases in being compos... more Lysyl-tRNA synthetases (LysRSs) are unique amongst the aminoacyl-tRNA synthetases in being composed of unrelated class I and class II enzymes. To allow direct comparison between the two types of LysRS, substrate recognition by class I LysRSs was examined. Genes encoding both an archaeal and a bacterial class I enzyme were able to rescue an Escherichia coli strain deficient in LysRS, indicating their ability to functionally substitute for a class II LysRS in vivo. In vitro characterization showed lysine activation and recognition to be tRNAdependent, an attribute of several class I, but not class II, aminoacyl-tRNA synthetases. Examination of tRNA recognition showed that class I LysRSs recognize the same elements in tRNA Lys as their class II counterparts, namely the discriminator base (N73) and the anticodon. This sequence-specific recognition of the same nucleotides in tRNA Lys by the two unrelated types of enzyme suggests that tRNA Lys predates at least one of the LysRSs in the evolution of the translational apparatus. The only observed variation in recognition was that the G2⅐U71 wobble pair of spirochete tRNA Lys acts as antideterminant for class II LysRS but does not alter class I enzyme recognition. This difference in tRNA recognition strongly favors the use of a class I-type enzyme to aminoacylate particular tRNA Lys species and provides a molecular basis for the observed displacement of class II by class I LysRSs in certain bacteria.
Proceedings of the National Academy of Sciences, 1996
Sequence-specific interactions between aminoacyl-tRNA synthetases and their cognate tRNAs both en... more Sequence-specific interactions between aminoacyl-tRNA synthetases and their cognate tRNAs both ensure accurate RNA recognition and prevent the binding of noncognate substrates. Here we show for Escherichia coli glutaminyl-tRNA synthetase (GlnRS; EC 6.1.1.18) that the accuracy of tRNA recognition also determines the efficiency of cognate amino acid recognition. Steady-state kinetics revealed that interactions between tRNA identity nucleotides and their recognition sites in the enzyme modulate the amino acid affinity of GlnRS. Perturbation of any of the protein-RNA interactions through mutation of either component led to considerable changes in glutamine affinity with the most marked effects seen at the discriminator base, the 10:25 base pair, and the anticodon. Reexamination of the identity set of tRNAGIn in the light of these results indicates that its constituents can be differentiated based upon biochemical function and their contribution to the apparent Gibbs' free energy of tRNA binding. Interactions with the acceptor stem act as strong determinants of tRNA specificity, with the discriminator base positioning the 3' end. The 10:25 base pair and U35 are apparently the major binding sites to GlnRS, with G36 contributing both to binding and recognition. Furthermore, we show that E. coli tryptophanyl-tRNA synthetase also displays tRNA-dependent changes in tryptophan affinity when charging a noncognate tRNA. The ability of tRNA to optimize amino acid recognition reveals a novel mechanism for maintaining translational fidelity and also provides a strong basis for the coevolution of tRNAs and their cognate synthetases.
The role of tRNA as the adaptor in protein synthesis has held an enduring fascination for molecul... more The role of tRNA as the adaptor in protein synthesis has held an enduring fascination for molecular biologists. Over four decades of study, taking in numerous milestones in molecular biology, led to what was widely held to be a fairly complete picture of how tRNAs and amino acids are paired prior to protein synthesis. However, recent developments in genomics and structural biology have revealed an unexpected array of new enzymes, pathways and mechanisms involved in aminoacyl-tRNA synthesis. As a more complete picture of aminoacyl-tRNA synthesis now begins to emerge, the high degree of evolutionary diversity in this universal and essential process is becoming clearer.
Proceedings of the National Academy of Sciences, 2004
Threonyl-tRNA synthetase (ThrRS) participates in protein synthesis quality control by selectively... more Threonyl-tRNA synthetase (ThrRS) participates in protein synthesis quality control by selectively editing the misacylated species Ser-tRNA Thr . In bacteria and eukaryotes the editing function of ThrRS resides in a highly conserved N-terminal domain distant from the active site. Most archaeal ThrRS proteins are devoid of this editing domain, suggesting evolutionary divergence of quality-control mechanisms. Here we show that archaeal editing of Ser-tRNA Thr is catalyzed by a domain unrelated to, and absent from, bacterial and eukaryotic ThrRSs. Despite the lack of sequence homology, the archaeal and bacterial editing domains are both reliant on a pair of essential histidine residues suggestive of a common catalytic mechanism. Whereas the archaeal editing module is most commonly part of full-length ThrRS, several crenarchaeal species contain individual genes encoding the catalytic (ThrRS-cat) and editing domains (ThrRS-ed). Sulfolobus solfataricus ThrRS-cat was shown to synthesize both Thr-tRNA Thr and Ser-tRNA Thr and to lack editing activity against Ser-tRNA Thr . In contrast, ThrRS-ed lacks aminoacylation activity but can act as an autonomous protein in trans to hydrolyze specifically Ser-tRNA Thr , or it can be fused to ThrRS-cat to provide the same function in cis. Deletion analyses indicate that ThrRS-ed is dispensable for growth of S. solfataricus under standard conditions but is required for normal growth in media with elevated serine levels. The growth phenotype of the ThrRS-ed deletion strain suggests that retention of the discontinuous ThrRS quaternary structure relates to specific physiological requirements still evident in certain Archaea.
Lysyl-tRNA can be synthesized by both a class I (LysRS-I) and a class II (LysRS-II) lysyl-tRNA sy... more Lysyl-tRNA can be synthesized by both a class I (LysRS-I) and a class II (LysRS-II) lysyl-tRNA synthetase. The crystal structure of LysRS-I from Pyrococcus horikoshii at 2.6 A resolution reveals extensive similarity with glutamyl-tRNA synthetase (GluRS). A comparison of the structures of LysRS-I and LysRS-II in complex with lysine shows that both enzymes use similar strategies for substrate recognition within unrelated active site topologies. A docking model based upon the GluRS-tRNA complex suggests how LysRS-I and LysRS-II can recognize the same molecular determinants in tRNALys, as shown by biochemical results, while approaching the acceptor helix of the tRNA from opposite sides.
Monomethylamine methyltransferase of the archaebacterium Methanosarcina barkeri contains a novel ... more Monomethylamine methyltransferase of the archaebacterium Methanosarcina barkeri contains a novel amino acid, pyrrolysine, encoded by the termination codon UAG. Initial studies suggest that pyrrolysine may be co-translationally inserted during protein synthesis, probably by a mechanism analogous to that operating during selenocysteine incorporation.
The only difference between our genesilenced transgenic plants that were resistant to high temper... more The only difference between our genesilenced transgenic plants that were resistant to high temperature and the respective wildtype plants was that the chloroplasts of the transgenic plants contained a reduced level of trienoic fatty acids and an elevated level of dienoic fatty acids, which is controlled by chloroplast -3 fatty acid desaturase. Of the six different higher plant desaturases whose genes have been cloned, only the expression of the chloroplast FAD8 -3 fatty acid desaturase gene changes in response to a change in ambient temperature (22).
The lysyl-tRNA synthetase paralog PoxA modifies elongation factor P (EF-P) with α-lysine at low e... more The lysyl-tRNA synthetase paralog PoxA modifies elongation factor P (EF-P) with α-lysine at low efficiency. Cell-free extracts contained non-α-lysine substrates of PoxA that modified EF-P by a change in mass consistent with β-lysine, a substrate also predicted by genomic analyses. EF-P was efficiently, functionally, modified with (R)-β-lysine but not (S)-β-lysine or genetically encoded αamino acids, indicating that PoxA has evolved an activity orthogonal to that of the canonical aminoacyl-tRNA synthetases.
The Trojan horse antibiotic albomycin, produced by Streptomyces sp. strain ATCC 700974, contains ... more The Trojan horse antibiotic albomycin, produced by Streptomyces sp. strain ATCC 700974, contains a thioribosyl nucleoside moiety linked to a hydroxamate siderophore through a serine residue. The seryl nucleoside structure (SB-217452) is a potent inhibitor of seryl-tRNA synthetase (SerRS) in the pathogenic bacterium Staphylococcus aureus, with a 50% inhibitory concentration (IC 50 ) of ϳ8 nM. In the albomycinproducing Streptomyces sp., a bacterial SerRS homolog (Alb10) was found to be encoded in a biosynthetic gene cluster in addition to another serRS gene (serS1) at a different genetic locus. Alb10, named SerRS2 herein, is significantly divergent from SerRS1, which shows high homology to the housekeeping SerRS found in other Streptomyces species. We genetically and biochemically characterized the two genes and the proteins encoded. Both genes were able to complement a temperature-sensitive serS mutant of Escherichia coli and allowed growth at a nonpermissive temperature. serS2 was shown to confer albomycin resistance, with specific amino acid residues in the motif 2 signature sequences of SerRS2 playing key roles. SerRS1 and SerRS2 are comparably efficient in vitro, but the K m of serine for SerRS2 measured during tRNA aminoacylation is more than 20-fold higher than that for SerRS1. SB-217452 was also enzymatically generated and purified by two-step chromatography. Its IC 50 against SerRS1 was estimated to be 10-fold lower than that against SerRS2. In contrast, both SerRSs displayed comparable inhibition kinetics for serine hydroxamate, indicating that SerRS2 was specifically resistant to SB-217452. These data suggest that mining Streptomyces genomes for duplicated aminoacyl-tRNA synthetase genes could provide a novel approach for the identification of natural products targeting aminoacyl-tRNA synthetases.
Translation of the genetic code requires attachment of tRNAs to their cognate amino acids. Errors... more Translation of the genetic code requires attachment of tRNAs to their cognate amino acids. Errors during amino-acid activation and tRNA esterification are corrected by aminoacyl-tRNA synthetase-catalyzed editing reactions, as extensively described for aliphatic amino acids. The contribution of editing to aromatic amino-acid discrimination is less well understood. We show that phenylalanyl-tRNA synthetase misactivates tyrosine and that it subsequently corrects such errors through hydrolysis of tyrosyl-adenylate and Tyr-tRNA Phe . Structural modeling combined with an in vivo genetic screen identified the editing site in the B3/B4 domain of the b subunit, 40 Å from the active site in the a subunit. Replacements of residues within the editing site had no effect on Phe-tRNA Phe synthesis, but abolished hydrolysis of Tyr-tRNA Phe in vitro. Expression of the corresponding mutants in Escherichia coli significantly slowed growth, and changed the activity of a recoded b-galactosidase variant by misincorporating tyrosine in place of phenylalanine. This loss in aromatic amino-acid discrimination in vivo revealed that editing by phenylalanyl-tRNA synthetase is essential for faithful translation of the genetic code.
Aminoacyl-tRNA synthetases are normally found in one of two mutually exclusive structural classes... more Aminoacyl-tRNA synthetases are normally found in one of two mutually exclusive structural classes, the only known exception being lysyl-tRNA synthetase which exists in both classes I (LysRS1) and II (LysRS2). Differences in tRNA acceptor stem recognition between LysRS1 and LysRS2 do not drastically impact cellular aminoacylation levels, focusing attention on the mechanism of tRNA anticodon recognition by LysRS1. On the basis of structure-based sequence alignments, seven tRNA Lys anticodon variants and seven LysRS1 anticodon binding site variants were selected for analysis of the Pyrococcus horikoshii LysRS1-tRNA Lys docking model. LysRS1 specifically recognized the bases at positions 35 and 36, but not that at position 34. Aromatic residues form stacking interactions with U34 and U35, and aminoacylation kinetics also identified direct interactions between Arg502 and both U35 and U36. Tyr491 was also found to interact with U36, and the Y491E variant exhibited significant improvement compared to the wild type in aminoacylation of a tRNA Lys UUG mutant. Refinement of the LysRS1-tRNA Lys docking model based upon these data suggested that anticodon recognition by LysRS1 relies on considerably fewer interactions than that by LysRS2, providing a structural basis for the more significant role of the anticodon in tRNA recognition by the class II enzyme. To date, only glutamyl-tRNA synthetase (GluRS) has been found to contain an α-helix cage anticodon binding domain homologous to that of LysRS1, and these data now suggest that specificity for the anticodon of tRNA Lys could have been acquired through relatively few changes to the corresponding domain of an ancestral GluRS enzyme.
Several methanogenic archaea lack cysteinyl-transfer RNA (tRNA) synthetase (CysRS), the essential... more Several methanogenic archaea lack cysteinyl-transfer RNA (tRNA) synthetase (CysRS), the essential enzyme that provides Cys-tRNA(Cys) for translation in most organisms. Partial purification of the corresponding activity from Methanocaldococcus jannaschii indicated that tRNA(Cys) becomes acylated with O-phosphoserine (Sep) but not with cysteine. Further analyses identified a class II-type O-phosphoseryl-tRNA synthetase (SepRS) and Sep-tRNA:Cys-tRNA synthase (SepCysS). SepRS specifically forms Sep-tRNA(Cys), which is then converted to Cys-tRNA(Cys) by SepCysS. Comparative genomic analyses suggest that this pathway, encoded in all organisms lacking CysRS, can also act as the sole route for cysteine biosynthesis. This was proven for Methanococcus maripaludis, where deletion of the SepRS-encoding gene resulted in cysteine auxotrophy. As the conversions of Sep-tRNA to Cys-tRNA or to selenocysteinyl-tRNA are chemically analogous, the catalytic activity of SepCysS provides a means by which both cysteine and selenocysteine may have originally been added to the genetic code.
Proceedings of the National Academy of Sciences, 2008
Multiple peptide resistance (MprF) virulence factors control cellular permeability to cationic an... more Multiple peptide resistance (MprF) virulence factors control cellular permeability to cationic antibiotics by aminoacylating inner membrane lipids. It has been shown previously that one class of MprF can use Lys-tRNA Lys to modify phosphatidylglycerol (PG), but the mechanism of recognition and possible role of other MprFs are unknown. Here, we used an in vitro reconstituted lipid aminoacylation system to investigate the two phylogenetically distinct MprF paralogs (MprF1 and MprF2) found in the bacterial pathogen Clostridium perfringens. Although both forms of MprF aminoacylate PG, they do so with different amino acids; MprF1 is specific for Ala-tRNA Ala , and MprF2 utilizes Lys-tRNA Lys . This provides a mechanism by which the cell can fine tune the charge of the inner membrane by using the neutral amino acid alanine, potentially providing resistance to a broader range of antibiotics than offered by lysine modification alone. Mutation of tRNA Ala and tRNA Lys had little effect on either MprF activity, indicating that the aminoacyl moiety is the primary determinant for aminoacyl-tRNA recognition. The lack of discrimination of the tRNA is consistent with the role of MprF as a virulence factor, because species-specific differences in tRNA sequence would not present a barrier to horizontal gene transfer. Taken together, our findings reveal how the MprF proteins provide a potent virulence mechanism by which pathogens can readily acquire resistance to chemically diverse antibiotics.
Proceedings of the National Academy of Sciences, 2007
Protein synthesis requires the pairing of amino acids with tRNAs catalyzed by the aminoacyl-tRNA ... more Protein synthesis requires the pairing of amino acids with tRNAs catalyzed by the aminoacyl-tRNA synthetases. The synthetases are highly specific, but errors in amino acid selection are occasionally made, opening the door to inaccurate translation of the genetic code. The fidelity of protein synthesis is maintained by the editing activities of synthetases, which remove noncognate amino acids from tRNAs before they are delivered to the ribosome. Although editing has been described in numerous synthetases, the reaction mechanism is unknown. To define the mechanism of editing, phenylalanyl-tRNA synthetase was used to investigate different models for hydrolysis of the noncognate product Tyr-tRNA Phe . Deprotonation of a water molecule by the highly conserved residue His-265, as proposed for threonyl-tRNA synthetase, was excluded because replacement of this and neighboring residues had little effect on editing activity. Model building suggested that, instead of directly catalyzing hydrolysis, the role of the editing site is to discriminate and properly position noncognate substrate for nucleophilic attack by water. In agreement with this model, replacement of certain editing site residues abolished substrate specificity but only reduced the catalytic efficiency of hydrolysis 2to 10-fold. In contrast, substitution of the 3-OH group of tRNA Phe severely impaired editing and revealed an essential function for this group in hydrolysis. The phenylalanyl-tRNA synthetase editing mechanism is also applicable to threonyl-tRNA synthetase and provides a paradigm for synthetase editing.
Proceedings of the National Academy of Sciences, 2007
Human mitochondrial tRNA (hmt-tRNA) mutations are associated with a variety of diseases including... more Human mitochondrial tRNA (hmt-tRNA) mutations are associated with a variety of diseases including mitochondrial myopathies, diabetes, encephalopathies, and deafness. Because the current understanding of the precise molecular mechanisms of these mutations is limited, there is no efficient method to treat their associated mitochondrial diseases. Here, we use a variety of known mutations in hmt-tRNA Phe to investigate the mechanisms that lead to malfunctions. We tested the impact of hmt-tRNA Phe mutations on aminoacylation, structure, and translation elongation-factor binding. The majority of the mutants were pleiotropic, exhibiting defects in aminoacylation, global structure, and elongation-factor binding. One notable exception was the G34A anticodon mutation of hmt-tRNA Phe (mitochondrial DNA mutation G611A), which is associated with MERRF (myoclonic epilepsy with ragged red fibers). In vitro, the G34A mutation decreases aminoacylation activity by 100-fold, but does not affect global folding or recognition by elongation factor. Furthermore, G34A hmt-tRNA Phe does not undergo adenosine-to-inosine (A-to-I) editing, ruling out miscoding as a possible mechanism for mitochondrial malfunction. To improve the aminoacylation state of the mutant tRNA, we modified the tRNA binding domain of the nucleus-encoded human mitochondrial phenylalanyl-tRNA synthetase, which aminoacylates hmt-tRNA Phe with cognate phenylalanine. This variant enzyme displayed significantly improved aminoacylation efficiency for the G34A mutant, suggesting a general strategy to treat certain classes of mitochondrial diseases by modification of the corresponding nuclear gene.
Proceedings of the National Academy of Sciences, 2010
Protein synthesis has an overall error rate of approximately 10 −4 for each mRNA codon translated... more Protein synthesis has an overall error rate of approximately 10 −4 for each mRNA codon translated. The fidelity of translation is mainly determined by two events: synthesis of cognate amino acid:tRNA pairs by aminoacyl-tRNA synthetases (aaRSs) and accurate selection of aminoacyl-tRNAs (aa-tRNAs) by the ribosome. To ensure faithful aa-tRNA synthesis, many aaRSs employ a proofreading ("editing") activity, such as phenylalanyl-tRNA synthetases (PheRS) that hydrolyze mischarged Tyr-tRNA Phe . Eukaryotes maintain two distinct PheRS enzymes, a cytoplasmic (ctPheRS) and an organellar form. CtPheRS is similar to bacterial enzymes in that it consists of a heterotetramer in which the α-subunits contain the active site and the β-subunits harbor the editing site. In contrast, mitochondrial PheRS (mtPheRS) is an α-subunit monomer that does not edit Tyr-tRNA Phe , and a comparable transacting activity does not exist in organelles. Although mtPheRS does not edit, it is extremely specific as only one Tyr-tRNA Phe is synthesized for every ∼7; 300 Phe-tRNA Phe , compatible with an error rate in translation of ∼10 −4 . When the error rate of mtPheRS was increased 17-fold, the corresponding strain could not grow on respiratory media and the mitochondrial genome was rapidly lost. In contrast, error-prone mtPheRS, editing-deficient ctPheRS, and their wildtype counterparts all supported cytoplasmic protein synthesis and cell growth. These striking differences reveal unexpectedly divergent requirements for quality control in different cell compartments and suggest that the limits of translational accuracy may be largely determined by cellular physiology.
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Papers by Michael Ibba