Pyrrolysine analogs as substrates for bacterial pyrrolysyl-tRNA synthetase in vitro and in vivo

Pyrrolysine-tRNA(Pyl) complex is produced by pyrrolysyl-tRNA synthetase (PylRS). In this study, we investigated the substrate specificity of Desulfitobacterium hafnience PylRS. PylRS incorporated various L-lysine derivatives into tRNA(Pyl) in vitro. In addition, the PylRS/tRNA(Pyl) pair introduced these lysine derivatives into the recombinant protein by the Escherichia coli expression system, indicating that this PylRS/tRNA(Pyl) pair can be used in protein engineering technology.     

The amino-terminal domain of pyrrolysyl-tRNA synthetase is dispensable in vitro but required for in vivo activity

Pyrrolysine (Pyl) is co-translationally inserted into a subset of proteins in the Methanosarcinaceae and in Desulfitobacterium hafniense programmed by an in-frame UAG stop codon. Suppression of this UAG codon is mediated by the Pyl amber suppressor tRNA, tRNA(Pyl), which is aminoacylated with Pyl by pyrrolysyl-tRNA synthetase (PylRS). We compared the behavior of several archaeal and bacterial PylRS enzymes towards tRNA(Pyl). Equilibrium binding analysis revealed that archaeal PylRS proteins bind tRNA(Pyl) with higher affinity (K(D)=0.1-1.0 microM) than D. hafniense PylRS (K(D)=5.3-6.9 microM). In aminoacylation the archaeal PylRS enzymes did not distinguish between archaeal and bacterial tRNA(Pyl) species, while the bacterial PylRS displays a clear preference for the homologous cognate tRNA. We also show that the amino-terminal extension present in archaeal PylRSs is dispensable for in vitro activity, but required for PylRS function in vivo.     

Recognition of pyrrolysine tRNA by the Desulfitobacterium hafniense pyrrolysyl-tRNA synthetase

Pyrrolysine (Pyl), the 22nd co-translationally inserted amino acid, is incorporated in response to a UAG amber stop codon. Pyrrolysyl-tRNA synthetase (PylRS) attaches Pyl to its cognate tRNA, the special amber suppressor tRNA(Pyl). The genes for tRNA(Pyl) (pylT) and PylRS (pylS) are found in all members of the archaeal family Methanosarcinaceae, and in Desulfitobacterium hafniense. The activation and aminoacylation properties of D. hafniense PylRS and the nature of the tRNA(Pyl) identity elements were determined by measuring the ability of 24 mutant tRNA(Pyl) species to be aminoacylated with the pyrrolysine analog N-epsilon-cyclopentyloxycarbonyl-l-lysine. The discriminator base G73 and the first base pair (G1.C72) in the acceptor stem were found to be major identity elements. Footprinting analysis showed that PylRS binds tRNA(Pyl) predominantly along the phosphate backbone of the T-loop, the D-stem and the acceptor stem. Significant contacts with the anticodon arm were not observed. The tRNA(Pyl) structure contains the highly conserved T-loop contact U54.A58 and position 57 is conserved as a purine, but the canonical T- to D-loop contact between positions 18 and 56 was not present. Unlike most tRNAs, the tRNA(Pyl) anticodon was shown not to be important for recognition by bacterial PylRS.     

Adding pyrrolysine to the Escherichia coli genetic code

Pyrrolysyl-tRNA synthetase and its cognate suppressor tRNA(Pyl) mediate pyrrolysine (Pyl) insertion at in frame UAG codons. The presence of an RNA hairpin structure named Pyl insertion structure (PYLIS) downstream of the suppression site has been shown to stimulate the insertion of Pyl in archaea. We study here the impact of the presence of PYLIS on the level of Pyl and the Pyl analog N-epsilon-cyclopentyloxycarbonyl-l-lysine (Cyc) incorporation using a quantitative lacZ-luc tandem reporter system in an Escherichia coli context. We show that PYLIS has no effect on the level of neither Pyl nor Cyc incorporation. Exogenously supplying our reporter system with d-ornithine significantly increases suppression efficiency, indicating that d-ornithine is a direct precursor to Pyl.     

Misacylation of pyrrolysine tRNA in vitro and in vivo

Methanosarcina barkeri inserts pyrrolysine (Pyl) at an in-frame UAG codon in its monomethylamine methyltransferase gene. Pyrrolysyl-tRNA synthetase acylates Pyl onto tRNAPyl, the amber suppressor pyrrolysine Pyl tRNA. Here we show that M. barkeri Fusaro tRNAPyl can be misacylated with serine by the M. barkeri bacterial-type seryl-tRNA synthetase in vitro and in vivo in Escherichia coli. Compared to the M. barkeri Fusaro tRNA, the M. barkeri MS tRNAPyl contains two base changes; a G3:U70 pair, the known identity element for E. coli alanyl-tRNA synthetase (AlaRS). While M. barkeri MS tRNAPyl cannot be alanylated by E. coli AlaRS, mutation of the MS tRNAPyl A4:U69 pair into C4:G69 allows aminoacylation by E. coli AlaRS both in vitro and in vivo.     

Probing the allosteric mechanism in pyrrolysyl-tRNA synthetase using energy-weighted network formalism

Pyrrolysyl-tRNA synthetase (PylRS) is an atypical enzyme responsible for charging tRNA(Pyl) with pyrrolysine, despite lacking precise tRNA anticodon recognition. This dimeric protein exhibits allosteric regulation of function, like any other tRNA synthetases. In this study we examine the paths of allosteric communication at the atomic level, through energy-weighted networks of Desulfitobacterium hafniense PylRS (DhPylRS) and its complexes with tRNA(Pyl) and activated pyrrolysine. We performed molecular dynamics simulations of the structures of these complexes to obtain an ensemble conformation-population perspective. Weighted graph parameters relevant to identifying key players and ties in the context of social networks such as edge/node betweenness, closeness index, and the concept of funneling are explored in identifying key residues and interactions leading to shortest paths of communication in the structure networks of DhPylRS. Further, the changes in the status of important residues and connections and the costs of communication due to ligand induced perturbations are evaluated. The optimal, suboptimal, and preexisting paths are also investigated. Many of these parameters have exhibited an enhanced asymmetry between the two subunits of the dimeric protein, especially in the pretransfer complex, leading us to conclude that encoding of function goes beyond the sequence/structure of proteins. The local and global perturbations mediated by appropriate ligands and their influence on the equilibrium ensemble of conformations also have a significant role to play in the functioning of proteins. Taking a comprehensive view of these observations, we propose that the origin of many functional aspects (allostery and half-sites reactivity in the case of DhPylRS) lies in subtle rearrangements of interactions and dynamics at a global level.     

Pyrrolysyl-tRNA synthetase: An ordinary enzyme but an outstanding genetic code expansion tool

The genetic incorporation of the 22nd proteinogenic amino acid, pyrrolysine (Pyl) at amber codon is achieved by the action of pyrrolysyl-tRNA synthetase (PylRS) together with its cognate tRNA^Pyl. Unlike most aminoacyl-tRNA synthetases, PylRS displays high substrate side chain promiscuity, low selectivity toward its substrate α-amine, and low selectivity toward the anticodon of tRNA^Pyl. These unique but ordinary features of PylRS as an aminoacyl-tRNA synthetase allow the Pyl incorporation machinery to be easily engineered for the genetic incorporation of more than 100 non-canonical amino acids (NCAAs) or α-hydroxy acids into proteins at amber codon and the reassignment of other codons such as ochre UAA, opal UGA, and four-base AGGA codons to code NCAAs.     

Crystallographic studies on multiple conformational states of active-site loops in pyrrolysyl-tRNA synthetase

Pyrrolysine, a lysine derivative with a bulky pyrroline ring, is the “22nd” genetically encoded amino acid. In the present study, the carboxy-terminal catalytic fragment of Methanosarcina mazei pyrrolysyl-tRNA synthetase (PylRS) was analyzed by X-ray crystallography and site-directed mutagenesis. The catalytic fragment ligated tRNA^Pyl with pyrrolysine nearly as efficiently as the full-length PylRS. We determined the crystal structures of the PylRS catalytic fragment in the substrate-free, ATP analogue (AMPPNP)-bound, and AMPPNP/pyrrolysine-bound forms, and compared them with the previously-reported PylRS structures. The ordering loop and the motif-2 loop undergo conformational changes from the “open” states to the “closed” states upon AMPPNP binding. On the other hand, the β7-β8 hairpin exhibits multiple conformational states, the open, intermediate (β7-open/β8-open and β7-closed/β8-open), and closed states, which are not induced upon substrate binding. The PylRS structures with a docked tRNA suggest that the active-site pocket can accommodate the CCA terminus of tRNA when the motif-2 loop is in the closed state and the β7-β8 hairpin is in the open or intermediate state. The entrance of the active-site pocket is nearly closed in the closed state of the β7-β8 hairpin, which may protect the pyrrolysyladenylate intermediate in the absence of tRNA^Pyl. Moreover, a structure-based mutational analysis revealed that hydrophobic residues in the amino acid-binding tunnel are important for accommodating the pyrrolysine side chain and that Asn346 is essential for anchoring the side-chain carbonyl and α-amino groups of pyrrolysine. In addition, a docking model of PylRS with tRNA was constructed based on the aspartyl-tRNA synthetase/tRNA structure, and was confirmed by a mutational analysis.     

Rationally evolving tRNAPyl for efficient incorporation of noncanonical amino acids

Genetic encoding of noncanonical amino acids (ncAAs) into proteins is a powerful approach to study protein functions. Pyrrolysyl-tRNA synthetase (PylRS), a polyspecific aminoacyl-tRNA synthetase in wide use, has facilitated incorporation of a large number of different ncAAs into proteins to date. To make this process more efficient, we rationally evolved tRNA^Pyl to create tRNA^Pyl-opt with six nucleotide changes. This improved tRNA was tested as substrate for wild-type PylRS as well as three characterized PylRS variants (N^ϵ-acetyllysyl-tRNA synthetase [AcKRS], 3-iodo-phenylalanyl-tRNA synthetase [IFRS], a broad specific PylRS variant [PylRS-AA]) to incorporate ncAAs at UAG codons in super-folder green fluorescence protein (sfGFP). tRNA^Pyl-opt facilitated a 5-fold increase in AcK incorporation into two positions of sfGFP simultaneously. In addition, AcK incorporation into two target proteins (Escherichia coli malate dehydrogenase and human histone H3) caused homogenous acetylation at multiple lysine residues in high yield. Using tRNA^Pyl-opt with PylRS and various PylRS variants facilitated efficient incorporation of six other ncAAs into sfGFP. Kinetic analyses revealed that the mutations in tRNA^Pyl-opt had no significant effect on the catalytic efficiency and substrate binding of PylRS enzymes. Thus tRNA^Pyl-opt should be an excellent replacement of wild-type tRNA^Pyl for future ncAA incorporation by PylRS enzymes.     

Aminoacylation of tRNA 2′- or 3′-hydroxyl by phosphoseryl- and pyrrolysyl-tRNA synthetases

Class I and II aminoacyl-tRNA synthetases (AARSs) attach amino acids to the 2′- and 3′-OH of the tRNA terminal adenosine, respectively. One exception is phenylalanyl-tRNA synthetase (PheRS), which belongs to Class II but attaches phenylalanine to the 2′-OH. Here we show that two Class II AARSs, O-phosphoseryl- (SepRS) and pyrrolysyl-tRNA (PylRS) synthetases, aminoacylate the 2′- and 3′-OH, respectively. Structure-based-phylogenetic analysis reveals that SepRS is more closely related to PheRS than PylRS, suggesting that the idiosyncratic feature of 2′-OH acylation evolved after the split between PheRS and PylRS. Our work completes the understanding of tRNA aminoacylation positions for the 22 natural AARSs.     

Transferability of N-terminal mutations of pyrrolysyl-tRNA synthetase in one species to that in another species on unnatural amino acid incorporation efficiency

Genetic code expansion is a powerful technique for site-specific incorporation of an unnatural amino acid into a protein of interest. This technique relies on an orthogonal aminoacyl-tRNA synthetase/tRNA pair and has enabled incorporation of over 100 different unnatural amino acids into ribosomally synthesized proteins in cells. Pyrrolysyl-tRNA synthetase (PylRS) and its cognate tRNA from Methanosarcina species are arguably the most widely used orthogonal pair. Here, we investigated whether beneficial effect in unnatural amino acid incorporation caused by N-terminal mutations in PylRS of one species is transferable to PylRS of another species. It was shown that conserved mutations on the N-terminal domain of MmPylRS improved the unnatural amino acid incorporation efficiency up to five folds. As MbPylRS shares high sequence identity to MmPylRS, and the two homologs are often used interchangeably, we examined incorporation of five unnatural amino acids by four MbPylRS variants at two temperatures. Our results indicate that the beneficial N-terminal mutations in MmPylRS did not improve unnatural amino acid incorporation efficiency by MbPylRS. Knowledge from this work contributes to our understanding of PylRS homologs which are needed to improve the technique of genetic code expansion in the future.

     

Fidelity in the aminoacylation of tRNA(Val) with hydroxy analogues of valine, leucine, and isoleucine by valyl-tRNA synthetases from Saccharomyces cerevisiae and Escherichia coli

Several analogues of valine, leucine, and isoleucine carrying hydroxyl groups in the gamma- or delta-position have been tested in the aminoacylation of tRNA by valyl-tRNA synthetases from Saccharomyces cerevisiae and Escherichia coli. Results of the ATP/PPi exchange and of the aminoacylation reactions indicate that the amino acid analogues not only can form the aminoacyl adenylate intermediate but are also transferred to tRNA. However, the fact that the reaction consumes an excess of ATP indicates that the misactivated amino acid analogue is hydrolytically removed. Thus, valyl-tRNA synthetase from S. cerevisiae shows a high fidelity in forming valyl-tRNA. Although the much bulkier amino acid analogues allo- and iso-gamma-hydroxyvaline and allo- and iso-gamma-hydroxyisoleucine are initially charged to tRNA, the misaminoacylated tRNA(Val) is enzymatically deacylated. This cleavage reaction is mediated by the hydroxyl groups of the amino acid analogues which are converted into the corresponding lactones.     

Is there a twenty third amino acid in the genetic code?

The universal genetic code includes 20 common amino acids. In addition, selenocysteine (Sec) and pyrrolysine (Pyl), known as the twenty first and twenty second amino acids, are encoded by UGA and UAG, respectively, which are the codons that usually function as stop signals. The discovery of Sec and Pyl suggested that the genetic code could be further expanded by reprogramming stop codons. To search for the putative twenty third amino acid, we employed various tRNA identification programs that scanned 16 archaeal and 130 bacterial genomes for tRNAs with anticodons corresponding to the three stop signals. Our data suggest that the occurrence of additional amino acids that are widely distributed and genetically encoded is unlikely.     

Effect of diadenosine oligophosphates (Ap4A and Ap3A) and their phosphonate analogs on catalytic properties of phenylalanyl-tRNA synthetase from E. coli

The influence of P1,P3-bis(5'-adenosyl)triphosphate (Ap3A), P1,P4-bis(5'-adenosyl)tetraphosphate (Ap4A) and its analogues, containing a residue of methylenediphosphonic acid in various positions of the oligophosphate chain, on the reactions catalysed by phenylalanyl-tRNA synthetase from E. coli MRE-600 has been studied. The compounds do not affect significantly the rate of ATP-[32P]PPi-exchange nor maintain this reaction in the absence of ATP. The diadenosineoligophosphates are shown to be noncompetitive inhibitors of ATP in the tRNA aminoacylation by phenylalanine (for Ap4A Ki = 1,45.10(-3) M). The phosphonate analogues of Ap4A inhibit the synthesis of Ap3A depending on their structure. The conclusion is thus drawn that the E. coli MRE-600 phenylalanyl-tRNA synthetase does not interact property with Ap4A and its phosphonate analogues.     

Recognition of Non-α-amino Substrates by Pyrrolysyl-tRNA Synthetase

Pyrrolysyl-tRNA synthetase (PylRS), an aminoacyl-tRNA synthetase (aaRS) recently found in some methanogenic archaea and bacteria, recognizes an unusually large lysine derivative, l-pyrrolysine, as the substrate, and attaches it to the cognate tRNA (tRNA^Pyl). The PylRS-tRNA^Pyl pair interacts with none of the endogenous aaRS-tRNA pairs in Escherichia coli, and thus can be used as a novel aaRS-tRNA pair for genetic code expansion. The crystal structures of the Methanosarcina mazei PylRS revealed that it has a unique, large pocket for amino acid binding, and the wild type M. mazei PylRS recognizes the natural lysine derivative as well as many lysine analogs, including N^?-(tert-butoxycarbonyl)-l-lysine (Boc-lysine), with diverse side chain sizes and structures. Moreover, the PylRS only loosely recognizes the α-amino group of the substrate, whereas most aaRSs, including the structurally and genetically related phenylalanyl-tRNA synthetase (PheRS), strictly recognize the main chain groups of the substrate. We report here that wild type PylRS can recognize substrates with a variety of main-chain α-groups: α-hydroxyacid, non-α-amino-carboxylic acid, N_α-methyl-amino acid, and d-amino acid, each with the same side chain as that of Boc-lysine. In contrast, PheRS recognizes none of these amino acid analogs. By expressing the wild type PylRS and its cognate tRNA^Pyl in E. coli in the presence of the α-hydroxyacid analog of Boc-lysine (Boc-LysOH), the amber codon (UAG) was recoded successfully as Boc-LysOH, and thus an ester bond was site-specifically incorporated into a protein molecule. This PylRS-tRNA^Pyl pair is expected to expand the backbone diversity of protein molecules produced by both in vivo and in vitro ribosomal translation.     

Preparation of Escherichia coli tRNAs terminating of modified nucleosides by the use of CTP(ATP):tRNA nucleotidyltransferase and polynucleotide phosphorylase.

Two procedures were investigated for the modification of tRNAs at the 3'-terminal nucleoside. The first involved the incubation of an enzymatically abreviated tRNA (tRNA-C-COH) with appropriate nucleoside triphosphates in the presence of CTP(ATP):tRNA nucleotidyltransferase from Escherichia coli and yeast. The E. coli enzyme did not utilize 2'- or 3'-deoxyadenosine 5'-triphosphate as substrates, but affected incorporation of the 2'- and 3'-O-methyladenosine triphosphates onto tRNA-C-Cou to the extent of 30 and 37%, respectively. Although incorporation of the deoxynucleotides could not be effected using the E. coli enzyme, yeast CTP(ATP:tRNA nucleotidyltransferase produced the desired tRNAs in yields of 45-65%. The second modification procedure involved incubation of tRNA-C-COH with (appropriately blocked) nucleoside diphosphates in the presence of polynucleotide phosphorylase. This procedure afforded the tRNAs terminating in 2'- and 3'-deoxyadenosine in yields of 4% (and the yield of the former was increased to 36% when the incubation was carried out in the presence of 20% methanol). The yields of tRNAs terminating in 2'- and 3'-O-methyladenosing produced by this procedure were 55 and 17%, respectively. Because only single isomers of most of the tRNAs terminating in 2'- and 3'-deoxy- and O-methyladenosine are aminoacylated, attempts were made to obtain the other isomericaminoacyl-tRNA by enzymatic introduction of chemically preaminoacylated nucleotides onto tRNA-C-COH. Although incubation of tRNA-C-COH with three aminoacylated nucleoside 5'-triphosphates and E. coli CTP(ATP):tRNA nucleotidyltransferase did not result in production of the desired tRNAs to a detectable extent, incubation with 2'-deoxy-3'-O-L-phenylalanyladenosine 5'-diphosphate and polynucleotide phosphorylase afforded E. coli tRNA terminating with the corresponding aminoacylated deoxynucleoside.