Activation of the pyrrolysine suppressor tRNA requires formation of a ternary complex with class I and class II lysyl-tRNA synthetases

Monomethylamine methyltransferase of the archaeon Methanosarcina barkeri contains a rare amino acid, pyrrolysine, encoded by the termination codon UAG. Translation of this UAG requires the aminoacylation of the corresponding amber suppressor tRNAPyl. Previous studies reported that tRNAPyl could be aminoacylated by the synthetase-like protein PylS. We now show that tRNAPyl is efficiently aminoacylated in the presence of both the class I LysRS and class II LysRS of M. barkeri, but not by either enzyme acting alone or by PylS. In vitro studies show that both the class I and II LysRS enzymes must bind tRNAPyl in order for the aminoacylation reaction to proceed. Structural modeling and selective inhibition experiments indicate that the class I and II LysRSs form a ternary complex with tRNAPyl, with the aminoacylation activity residing in the class II enzyme.     

Specificity of Pyrrolysyl-tRNA Synthetase for Pyrrolysine and Pyrrolysine Analogs

Pyrrolysine, the 22nd amino acid, is encoded by amber (TAG = UAG) codons in certain methanogenic archaea and bacteria. PylS, the pyrrolysyl-tRNA synthetase, ligates pyrrolysine to tRNA^Pyl for amber decoding as pyrrolysine. PylS and tRNA^Pyl have potential utility in making tailored recombinant proteins. Here, we probed interactions necessary for recognition of substrates by archaeal PylS via synthesis of close pyrrolysine analogs and testing their reactivity in amino acid activation assays. Replacement of the methylpyrroline ring of pyrrolysine with cyclopentane indicated that solely hydrophobic interactions with the ring-binding pocket of PylS are sufficient for substrate recognition. However, a 100-fold increase in the specificity constant of PylS was observed with an analog, 2-amino-6-((R)-tetrahydrofuran-2-carboxamido)hexanoic acid (2Thf-lys), in which tetrahydrofuran replaced the pyrrolysine methylpyrroline ring. Other analogs in which the electronegative atom was moved to different positions suggested PylS preference for a hydrogen-bond-accepting group at the imine nitrogen position in pyrrolysine. 2Thf-lys was a preferred substrate over a commonly employed pyrrolysine analog, but the specificity constant for 2Thf-lys was 10-fold lower than for pyrrolysine itself, largely due to the change in K_m. The in vivo activity of the analogs in supporting UAG suppression in Escherichia coli bearing genes for PylS and tRNA^Pyl was similar to in vitro results, with l-pyrrolysine and 2Thf-lys supporting the highest amounts of UAG translation. Increasing concentrations of either PylS substrate resulted in a linear increase in UAG suppression, providing a facile method to assay bioactive pyrrolysine analogs. These results illustrate the relative importance of the H-bonding and hydrophobic interactions in the recognition of the methylpyrroline ring of pyrrolysine and provide a promising new series of easily synthesized pyrrolysine analogs that can serve as scaffolds for the introduction of novel functional groups into recombinant proteins.     

Structure of Desulfitobacterium hafniense PylSc, a pyrrolysyl-tRNA synthetase

Pyrrolysine, the 22nd genetically-encoded amino acid, is charged onto its specific tRNA by PylS, a pyrrolysyl-tRNA synthetase. While PylS is found as a single protein in certain archaeal methanogens, in the Gram-positive bacterium Desulfitobacterium hafniense, PylS is divided into two separate proteins, PylSn and PylSc, corresponding to the N-terminal and C-terminal domains of the single PylS protein found in methanogens. Previous crystallographic studies have provided the structure of a truncated C-terminal portion of the archaeal Methanosarcina mazei PylS associated with catalysis. Here, we report the apo 2.1 Å resolution structure of the intact D. hafniense PylSc protein and compare it to structures of the C-terminal truncated PylS from methanogenic species. In PylSc, the hydrophobic pocket binding the ring of pyrrolysine is more constrained than in the archaeal enzyme; other structural differences are also apparent.     

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.     

The direct genetic encoding of pyrrolysine

Pyrrolysine is an amino acid encoded by the amber codon in genes required for methylamine utilization by members of the Methanosarcinaceae. Pyrrolysine and selenocysteine share the distinction of being the only two non-canonical amino acids that have entered natural genetic codes. Recent experiments have shown that encoding of pyrrolysine, unlike that of selenocysteine, also shares an important trait of the original set of twenty amino acids. UAG is translated as pyrrolysine with the participation of a dedicated aminoacyl-tRNA synthetase. Expression of the genes encoding the pyrrolysyl-tRNA synthetase and its cognate tRNA is sufficient to add pyrrolysine to the genetic code of a recombinant organism. Thus, the recruitment of pyrrolysine into the genetic code involved evolution of the first non-canonical aminoacyl-tRNA synthetase and cognate tRNA to be described from nature.     

The residue mass of L-pyrrolysine in three distinct methylamine methyltransferases

Single in-frame amber (UAG) codons are found in the genes encoding MtmB, MtbB, or MttB, the methyltransferases initiating methane formation from monomethylamine, dimethylamine, or trimethylamine, respectively, in certain Archaea. The crystal structure of MtmB demonstrated that the amber codon codes for pyrrolysine, the 22nd genetically encoded amino acid found in nature. Previous attempts to visualize the amber-encoded residue by mass spectrometry identified only lysine, leaving information on the existence and structure of pyrrolysine resting entirely on crystallography of a single protein. Here we report successful mass spectral characterization of naturally occurring pyrrolysine and the first demonstration of the amber-encoded residue in proteins other than MtmB. The sequencing of chymotryptic fragments from acetonitrile-denatured proteins by tandem mass spectrometry revealed the mass of the amber-encoded residue in MtmB, MtbB, and MttB as 237.2 +/- 0.2 Da. Fourier transform ion cyclotron resonance mass spectrometry produced an accurate measurement for the pyrrolysyl-residue as 237.1456 Da, within error limits of the predicted mass based on the empirical formula C(12)H(19)N(3)O(2). These measurements support the structure of pyrrolysine in MtmB as 4-methylpyrroline-5-carboxylate in amide linkage with the (epsilon)N of lysine but not the alternative structure in which the 4-substituent of the pyrroline ring is an amine group. The presence of pyrrolysine with statistically identical mass in all three methyltransferases is in keeping with the proposed direct incorporation of pyrrolysine into protein during translation of the UAG codon and suggests that MtbB and MttB may exploit the unusual electrophilicity of pyrrolysine during catalysis.     

Aminoacyl-tRNA synthesis in archaea: different but not unique

Accurate aminoacyl-tRNA synthesis is essential for correct translation of the genetic code in all organisms. Whereas many aspects of this process are conserved, others display a surprisingly high level of divergence from the canonical Escherichia coli model system. These differences are most pronounced in archaea where novel mechanisms have recently been described for aminoacylating tRNAs with asparagine, cysteine, glutamine and lysine. Whereas these mechanisms were initially assumed to be uniquely archaeal, both the alternative asparagine and lysine pathways have subsequently been demonstrated in numerous bacteria. Similarly, studies of the means by which archaea insert the rare amino acid selenocysteine in response to UGA stop codons have helped provide a better understanding of both archaeal and eukaryal selenoprotein synthesis. Most recently a new co-translationally inserted amino acid, pyrrolysine, has been found in archaea although again there is some suggestion that it may also be present in bacteria. Thus, whereas archaea contain a preponderance of non-canonical aminoacyl-tRNA synthesis systems most are also found elsewhere albeit less frequently.     

Function of genetically encoded pyrrolysine in corrinoid-dependent methylamine methyltransferases

Methanogenesis from trimethylamine, dimethylamine or monomethylamine is initiated by a series of corrinoid-dependent methyltransferases. The non-homologous genes encoding the full-length methyltransferases each possess an in-frame UAG (amber) codon that does not terminate translation. The amber codon is decoded by a dedicated tRNA, and corresponds to the novel amino acid pyrrolysine in one of the methyltransferases, indicating pyrrolysine to be the 22nd genetically encoded amino acid. Pyrrolysine has the structure of lysine with the (epsilon)N in amide linkage with a pyrroline ring. The reactivity of the electrophilic imine bond is the basis for the proposed function of pyrrolysine in activating and optimally orienting methylamine for methyl transfer to the cobalt ion of a cognate corrinoid protein. This reaction is essential for methane formation from methylamines, and may underlie the retention of pyrrolysine in the genetic code of methanogens.     

PylSn and the Homologous N-terminal Domain of Pyrrolysyl-tRNA Synthetase Bind the tRNA That Is Essential for the Genetic Encoding of Pyrrolysine

Pyrrolysine is represented by an amber codon in genes encoding proteins such as the methylamine methyltransferases present in some Archaea and Bacteria. Pyrrolysyl-tRNA synthetase (PylRS) attaches pyrrolysine to the amber-suppressing tRNA^Pyl. Archaeal PylRS, encoded by pylS, has a catalytic C-terminal domain but an N-terminal region of unknown function and structure. In Bacteria, homologs of the N- and C-terminal regions of archaeal PylRS are respectively encoded by pylSn and pylSc. We show here that wild type PylS from Methanosarcina barkeri and PylSn from Desulfitobacterium hafniense bind tRNA^Pyl in EMSA with apparent K_d values of 0.12 and 0.13 μm, respectively. Truncation of the N-terminal region of PylS eliminated detectable tRNA^Pyl binding as measured by EMSA, but not catalytic activity. A chimeric protein with PylSn fused to the N terminus of truncated PylS regained EMSA-detectable tRNA^Pyl binding. PylSn did not bind other D. hafniense tRNAs, nor did the competition by the Escherichia coli tRNA pool interfere with tRNA^Pyl binding. Further indicating the specificity of PylSn interaction with tRNA^Pyl, substitutions of conserved residues in tRNA^Pyl in the variable loop, D stem, and T stem and loop had significant impact in binding, whereas those having base changes in the acceptor stem or anticodon stem and loop still retained the ability to complex with PylSn. PylSn and the N terminus of PylS comprise the protein superfamily TIGR03129. The members of this family are not similar to any known RNA-binding protein, but our results suggest their common function involves specific binding of tRNA^Pyl.     

New enzymes from environmental cassette arrays: functional attributes of a phosphotransferase and an RNA-methyltransferase

By targeting gene cassettes by polymerase chain reaction (PCR) directly from environmentally derived DNA, we are able to amplify entire open reading frames (ORFs) independently of prior sequence knowledge. Approximately 10% of the mobile genes recovered by these means can be attributed to known protein families. Here we describe the characterization of two ORFs which show moderate homology to known proteins: (1) an aminoglycoside phosphotransferase displaying 25% sequence identity with APH(7") from Streptomyces hygroscopicus, and (2) an RNA methyltransferase sharing 25%-28% identity with a group of recently defined bacterial RNA methyltransferases distinct from the SpoU enzyme family. Our novel genes were expressed as recombinant products and assayed for appropriate enzyme activity. The aminoglycoside phosphotransferase displayed ATPase activity, consistent with the presence of characteristic Mg(2+)-binding residues. Unlike related APH(4) or APH(7") enzymes, however, this activity was not enhanced by hygromycin B or kanamycin, suggesting the normal substrate to be a different aminoglycoside. The RNA methyltransferase contains sequence motifs of the RNA methyltransferase superfamily, and our recombinant version showed methyltransferase activity with RNA. Our data confirm that gene cassettes present in the environment encode folded enzymes with novel sequence variation and demonstrable catalytic activity. Our PCR approach (cassette PCR) may be used to identify a diverse range of ORFs from any environmental sample, as well as to directly access the gene pool found in mobile gene cassettes commonly associated with integrons. This gene pool can be accessed from both cultured and uncultured microbial samples as a source of new enzymes and proteins.     

Two Protein Lysine Methyltransferases Methylate Outer Membrane Protein B from Rickettsia

Rickettsia prowazekii, the etiologic agent of epidemic typhus, is a potential biological threat agent. Its outer membrane protein B (OmpB) is an immunodominant antigen and plays roles as protective envelope and as adhesins. The observation of the correlation between methylation of lysine residues in rickettsial OmpB and bacterial virulence has suggested the importance of an enzymatic system for the methylation of OmpB. However, no rickettsial lysine methyltransferase has been characterized. Bioinformatic analysis of genomic DNA sequences of Rickettsia identified putative lysine methyltransferases. The genes of the potential methyltransferases were synthesized, cloned, and expressed in Escherichia coli, and expressed proteins were purified by nickel-nitrilotriacetic acid (Ni-NTA) affinity chromatography. The methyltransferase activities of the purified proteins were analyzed by methyl incorporation of radioactively labeled S-adenosylmethionine into recombinant fragments of OmpB. Two putative recombinant methyltransferases (rRP789 and rRP027-028) methylated recombinant OmpB fragments. The specific activity of rRP789 is 10- to 30-fold higher than that of rRP027-028. Western blot analysis using specific antibodies against trimethyl lysine showed that both rRP789 and rRP027-028 catalyzed trimethylation of recombinant OmpB fragments. Liquid chromatography-tandem mass spectrometry (LC/MS-MS) analysis showed that rRP789 catalyzed mono-, di-, and trimethylation of lysine, while rRP027-028 catalyzed exclusively trimethylation. To our knowledge, rRP789 and rRP027-028 are the first biochemically characterized lysine methyltransferases of outer membrane proteins from Gram-negative bacteria. The production and characterization of rickettsial lysine methyltransferases provide new tools to investigate the mechanism of methylation of OmpB, effects of methylation on the structure and function of OmpB, and development of methylated OmpB-based diagnostic assays and vaccine candidates.     

Genetic code: introducing pyrrolysine

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.     

Aspartate carbamoyltransferase from the thermoacidophilic archaeon Sulfolobus acidocaldarius. Cloning, sequence analysis, enzyme purification and characterization.

The genes coding for aspartate carbamoyltransferase (ATCase) in the extremely thermophilic archaeon Sulfolobus acidocaldarius have been cloned by complementation of a pyrBI deletion mutant of Escherichia coli. Sequencing revealed the existence of an enterobacterial-like pyrBI operon encoding a catalytic chain of 299 amino acids (34 kDa) and a regulatory chain of 170 amino acids (17.9 kDa). The deduced amino acid sequences of the pyrB and pyrI genes showed 27.6-50% identity with archaeal and enterobacterial ATCases. The recombinant S. acidocaldarius ATCase was purified to homogeneity, allowing the first detailed studies of an ATCase isolated from a thermophilic organism. The recombinant enzyme displayed the same properties as the ATCase synthesized in the native host. It is highly thermostable and exhibits Michaelian saturation kinetics for carbamoylphosphate (CP) and positive homotropic cooperative interactions for the binding of L-aspartate. Moreover, it is activated by nucleoside triphosphates whereas the catalytic subunits alone are inhibited. The holoenzyme purified from recombinant E. coli cells or present in crude extract of the native host have an Mr of 340 000 as estimated by gel filtration, suggesting that it has a quaternary structure similar to that of E. coli ATCase. Only monomers could be found in extracts of recombinant E. coli or Saccharomyces cerevisiae cells expressing the pyrB gene alone. In the presence of CP these monomers assembled into trimers. The stability of S. acidocaldarius ATCase and the allosteric properties of the enzyme are discussed in function of a modeling study.     

Evolution of the syntrophic interaction between Desulfovibrio vulgaris and Methanosarcina barkeri: Involvement of an ancient horizontal gene transfer

The sulfate reducing bacteria Desulfovibrio vulgaris and the methanogenic archaea Methanosarcina barkeri can grow syntrophically on lactate. In this study, a set of three closely located genes, DVU2103, DVU2104, and DVU2108 of D. vulgaris, was found to be up-regulated 2- to 4-fold following the lifestyle shift from syntroph to sulfate reducer; moreover, none of the genes in this gene set were differentially regulated when comparing gene expression from various D. vulgaris pure culture experiments. Although exact function of this gene set is unknown, the results suggest that it may play roles related to the lifestyle change of D. vulgaris from syntroph to sulfate reducer. This hypothesis is further supported by phylogenomic analyses showing that homologies of this gene set were only narrowly present in several groups of bacteria, most of which are restricted to a syntrophic lifestyle, such as Pelobacter carbinolicus, Syntrophobacter fumaroxidans, Syntrophomonas wolfei, and Syntrophus aciditrophicus. Phylogenetic analysis showed that all three individual genes in the gene set tended to be clustered with their homologies from archaeal genera, and they were rooted on archaeal species in the phylogenetic trees, suggesting that they were horizontally transferred from archaeal methanogens. In addition, no significant bias in codon and amino acid usages was detected between these genes and the rest of the D. vulgaris genome, suggesting the gene transfer may have occurred early in the evolutionary history so that sufficient time has elapsed to allow an adaptation to the codon and amino acid usages of D. vulgaris. This report provides novel insights into the origin and evolution of bacterial genes linked to the lifestyle change of D. vulgaris from a syntrophic to a sulfate-reducing lifestyle.