Ilka U. Heinemann

Enhanced phosphoserine insertion during Escherichia coli protein synthesis via partial UAG codon reassignment and release factor 1 deletion

Genetically encoded phosphoserine incorporation programmed by the UAG codon was achieved by addition of engineered elongation factor and an archaeal aminoacyl‐tRNA synthetase to the normal Escherichia coli translation machinery (Park et al., 2011) Science 333, 1151) [2]. However, protein yield suffers from expression of the orthogonal phosphoserine translation system and competition with release factor 1 (RF‐1). In a strain lacking RF‐1, phosphoserine phosphatase, and where seven UAG codons residing in essential genes were converted to UAA, phosphoserine incorporation into GFP and WNK4 was significantly elevated, but with an accompanying loss in cellular fitness and viability.

Near-cognate suppression of amber, opal and quadruplet codons competes with aminoacyl-tRNAPyl for genetic code expansion

Over 300 amino acids are found in proteins in nature, yet typically only 20 are genetically encoded. Reassigning stop codons and use of quadruplet codons emerged as the main avenues for genetically encoding non‐canonical amino acids (NCAAs). Canonical aminoacyl‐tRNAs with near‐cognate anticodons also read these codons to some extent. This background suppression leads to ‘statistical protein’ that contains some natural amino acid(s) at a site intended for NCAA. We characterize near‐cognate suppression of amber, opal and a quadruplet codon in common Escherichia coli laboratory strains and find that the PylRS/tRNAPyl orthogonal pair cannot completely outcompete contamination by natural amino acids.

The appearance of pyrrolysine in tRNAHis guanylyltransferase by neutral evolution

tRNAHis guanylyltransferase (Thg1) post-transcriptionally adds a G (position −1) to the 5′-terminus of tRNAHis. The Methanosarcina acetivorans Thg1 (MaThg1) gene contains an in-frame TAG (amber) codon. Although a UAG codon typically directs translation termination, its presence in Methanosarcina mRNA may lead to pyrrolysine (Pyl) incorporation achieved by Pyl-tRNAPyl, the product of pyrrolysyl-tRNA synthetase. Sequencing of the MaThg1 gene and transcript confirmed the amber codon. Translation of MaThg1 mRNA led to a full-length, Pyl-containing, active enzyme as determined by immunoblotting, mass spectrometry, and biochemical analysis. The nature of the inserted amino acid at the position specified by UAG is not critical, as Pyl or Trp insertion yields active MaThg1 variants in M. acetivorans and equal amounts of full-length protein. These data suggest that Pyl insertion is akin to natural suppression and unlike the active stop codon reassignment that is required for selenocysteine insertion. Only three Pyl-containing proteins have been characterized previously, a set of methylamine methyltransferases in which Pyl is assumed to have specifically evolved to be a key active-site constituent. In contrast, Pyl in MaThg1 is a dispensable residue that appears to confer no selective advantage. Phylogenetic analysis suggests that Thg1 is becoming dispensable in the archaea, and furthermore supports the hypothesis that Pyl appeared in MaThg1 as the result of neutral evolution. This indicates that even the most unusual amino acid can play an ordinary role in proteins.

Carbon source-dependent expansion of the genetic code in bacteria

Despite the fact that the genetic code is known to vary between organisms in rare cases, it is believed that in the lifetime of a single cell the code is stable. We found Acetohalobium arabaticum cells grown on pyruvate genetically encode 20 amino acids, but in the presence of trimethylamine (TMA), A. arabaticum dynamically expands its genetic code to 21 amino acids including pyrrolysine (Pyl). A. arabaticum is the only known organism that modulates the size of its genetic code in response to its environment and energy source. The gene cassette pylTSBCD, required to biosynthesize and genetically encode UAG codons as Pyl, is present in the genomes of 24 anaerobic archaea and bacteria. Unlike archaeal Pyl-decoding organisms that constitutively encode Pyl, we observed that A. arabaticum controls Pyl encoding by down-regulating transcription of the entire Pyl operon under growth conditions lacking TMA, to the point where no detectable Pyl-tRNAPyl is made in vivo. Pyl-decoding archaea adapted to an expanded genetic code by minimizing TAG codon frequency to typically ∼5% of ORFs, whereas Pyl-decoding bacteria (∼20% of ORFs contain in-frame TAGs) regulate Pyl-tRNAPyl formation and translation of UAG by transcriptional deactivation of genes in the Pyl operon. We further demonstrate that Pyl encoding occurs in a bacterium that naturally encodes the Pyl operon, and identified Pyl residues by mass spectrometry in A. arabaticum proteins including two methylamine methyltransferases.

3′–5′ tRNAHis guanylyltransferase in bacteria

The identity of the histidine specific transfer RNA (tRNAHis) is largely determined by a unique guanosine residue at position −1. In eukaryotes and archaea, the tRNAHis guanylyltransferase (Thg1) catalyzes 3′–5′ addition of G to the 5′‐terminus of tRNAHis. Here, we show that Thg1 also occurs in bacteria. We demonstrate in vitro Thg1 activity for recombinant enzymes from the two bacteria Bacillus thuringiensis and Myxococcus xanthus and provide a closer investigation of several archaeal Thg1. The reaction mechanism of prokaryotic Thg1 differs from eukaryotic enzymes, as it does not require ATP. Complementation of a yeast thg1 knockout strain with bacterial Thg1 verified in vivo activity and suggests a relaxed recognition of the discriminator base in bacteria.

Transfer RNA processing in Archaea: unusual pathways and enzymes

Transfer RNA (tRNA) molecules are highly conserved in length, sequence and structure in order to be functional in the ribosome. However, mostly in archaea, the short genes encoding tRNAs can be found disrupted, fragmented, with permutations or with non‐functional mutations of conserved nucleotides. Here, we give an overview of recently discovered tRNA maturation pathways that require intricate processing steps to finally generate the standard tRNA from these unusual tRNA genes.

tRNAHis-guanylyltransferase establishes tRNAHis identity.

Histidine transfer RNA (tRNA) is unique among tRNA species as it carries an additional nucleotide at its 5′ terminus. This unusual G−1 residue is the major tRNAHis identity element, and essential for recognition by the cognate histidyl-tRNA synthetase to allow efficient His-tRNAHis formation. In many organisms G−1 is added post-transcriptionally as part of the tRNA maturation process. tRNAHis guanylyltransferase (Thg1) specifically adds the guanylyate residue by recognizing the tRNAHis anticodon. Thg1 homologs from all three domains of life have been the subject of exciting research that gave rise to a detailed biochemical, structural and phylogenetic enzyme characterization. Thg1 homologs are phylogenetically classified into eukaryal- and archaeal-type enzymes differing characteristically in their cofactor requirements and specificity. Yeast Thg1 displays a unique but limited ability to add 2–3 G or C residues to mutant tRNA substrates, thus catalyzing a 3′ → 5′ RNA polymerization. Archaeal-type Thg1, which has been horizontally transferred to certain bacteria and few eukarya, displays a more relaxed substrate range and may play additional roles in tRNA editing and repair. The crystal structure of human Thg1 revealed a fascinating structural similarity to 5′ → 3′ polymerases, indicating that Thg1 derives from classical polymerases and evolved to assume its specific function in tRNAHis processing.

Structural basis of reverse nucleotide polymerization

Significance Template-dependent RNA and DNA polymerization is a vital reaction in the cell and is believed to occur exclusively in the forward direction (5′-3′), which poses significant challenges to the cell in, for example, lagging strand synthesis. Although cells are mostly limited to unidirectional polymerization, we find that reverse polymerization is structurally and chemically possible utilizing the same structural core, the conserved palm domain of canonical polymerases. The structure of a unique reverse nucleotide polymerase-tRNA complex revealed that the direction of polymerization is determined by the orientation of approach of the polynucleotide substrate. Phylogenetic analysis indicates that reverse nucleotide polymerization is a primordial activity of the polymerase family. Nucleotide polymerization proceeds in the forward (5′-3′) direction. This tenet of the central dogma of molecular biology is found in diverse processes including transcription, reverse transcription, DNA replication, and even in lagging strand synthesis where reverse polymerization (3′-5′) would present a “simpler” solution. Interestingly, reverse (3′-5′) nucleotide addition is catalyzed by the tRNA maturation enzyme tRNAHis guanylyltransferase, a structural homolog of canonical forward polymerases. We present a Candida albicans tRNAHis guanylyltransferase-tRNAHis complex structure that reveals the structural basis of reverse polymerization. The directionality of nucleotide polymerization is determined by the orientation of approach of the nucleotide substrate. The tRNA substrate enters the enzyme’s active site from the opposite direction (180° flip) compared with similar nucleotide substrates of canonical 5′-3′ polymerases, and the finger domains are on opposing sides of the core palm domain. Structural, biochemical, and phylogenetic data indicate that reverse polymerization appeared early in evolution and resembles a mirror image of the forward process.

Alanyl-phosphatidylglycerol synthase: mechanism of substrate recognition during tRNA-dependent lipid modification in Pseudomonas aeruginosa

Bacterial lipid homeostasis plays an important role for the adaptation to changing environments and under conditions of antimicrobial treatment. The tRNA‐dependent aminoacylation of the phospholipid phosphatidylglycerol catalysed by aminoacyl‐phosphatidylglycerol synthases was shown to render various organisms less susceptible to antibacterial agents. Therefore, this type of enzyme might provide a new target to potentiate the efficacy of existing antimicrobials. This study makes use of the Pseudomonas aeruginosa alanyl‐phosphatidylglycerol synthase to identify the minimal core domain of this transmembrane protein, which is capable of alanyl‐phosphatidylglycerol biosynthesis. Using this catalytic fragment we established a reliable activity assay that was used to study the enzymatic mechanism by analysing an overall of 33 mutant proteins in vitro. Substrate recognition was analysed by using aminoacylated microhelices as analogues of the natural tRNA substrate. The enzyme even tolerated mutated versions of this minimal substrate, which indicates that neither the intact tRNA, nor the individual sequence of the acceptor stem is a determinant for substrate recognition. Furthermore, the analysis of derivatives of phosphatidylglycerol indicated that the polar head group of the phospholipid is specifically recognized by the enzyme, whereas modification of an individual fatty acid or even the deletion of a single fatty acid did not abolish A‐PG synthesis.

Reducing the genetic code induces massive rearrangement of the proteome

Significance Expanding the genetic code is an important aim of synthetic biology, but some organisms developed naturally expanded genetic codes over the course of evolution. To understand the selective advantage of genetically encoding more than 20 amino acids, we investigated the proteome-wide response to reducing the genetic code of Methanosarcina acetivorans from 21 to 20 amino acids. The data show how a natural proteome adapts to genetic code reduction and indicate that the selective value of an expanded genetic code is related to carbon source range and metabolic efficiency. Expanding the genetic code is an important aim of synthetic biology, but some organisms developed naturally expanded genetic codes long ago over the course of evolution. Less than 1% of all sequenced genomes encode an operon that reassigns the stop codon UAG to pyrrolysine (Pyl), a genetic code variant that results from the biosynthesis of Pyl-tRNAPyl. To understand the selective advantage of genetically encoding more than 20 amino acids, we constructed a markerless tRNAPyl deletion strain of Methanosarcina acetivorans (ΔpylT) that cannot decode UAG as Pyl or grow on trimethylamine. Phenotypic defects in the ΔpylT strain were evident in minimal medium containing methanol. Proteomic analyses of wild type (WT) M. acetivorans and ΔpylT cells identified 841 proteins from >7,000 significant peptides detected by MS/MS. Protein production from UAG-containing mRNAs was verified for 19 proteins. Translation of UAG codons was verified by MS/MS for eight proteins, including identification of a Pyl residue in PylB, which catalyzes the first step of Pyl biosynthesis. Deletion of tRNAPyl globally altered the proteome, leading to >300 differentially abundant proteins. Reduction of the genetic code from 21 to 20 amino acids led to significant down-regulation in translation initiation factors, amino acid metabolism, and methanogenesis from methanol, which was offset by a compensatory (100-fold) up-regulation in dimethyl sulfide metabolic enzymes. The data show how a natural proteome adapts to genetic code reduction and indicate that the selective value of an expanded genetic code is related to carbon source range and metabolic efficiency.