Universal rules and idiosyncratic features in tRNA identity

Structural and mutational studies of the recognition of the arginine tRNA-specific major identity element, A20, by arginyl-tRNA synthetase

Arginyl-tRNA synthetase (ArgRS) recognizes two major identity elements of tRNA(Arg): A20, located at the outside corner of the L-shaped tRNA, and C35, the second letter of the anticodon. Only a few exceptional organisms, such as the yeast Saccharomyces cerevisiae, lack A20 in tRNA(Arg). In the present study, we solved the crystal structure of a typical A20-recognizing ArgRS from Thermus thermophilus at 2.3 A resolution. The structure of the T. thermophilus ArgRS was found to be similar to that of the previously reported S. cerevisiae ArgRS, except for short insertions and a concomitant conformational change in the N-terminal domain. The structure of the yeast ArgRS.tRNA(Arg) complex suggested that two residues in the unique N-terminal domain, Tyr(77) and Asn(79), which are phylogenetically invariant in the ArgRSs from all organisms with A20 in tRNA(Arg)s, are involved in A20 recognition. However, in a docking model constructed based on the yeast ArgRS.tRNA(Arg) and T. thermophilus ArgRS structures, Tyr(77) and Asn(79) are not close enough to make direct contact with A20, because of the conformational change in the N-terminal domain. Nevertheless, the replacement of Tyr(77) or Asn(79) by Ala severely reduced the arginylation efficiency. Therefore, some conformational change around A20 is necessary for the recognition. Surprisingly, the N79D mutant equally recognized A20 and G20, with only a slight reduction in the arginylation efficiency as compared with the wild-type enzyme. Other mutants of Asn(79) also exhibited broader specificity for the nucleotide at position 20 of tRNA(Arg). We propose a model of A20 recognition by the ArgRS that is consistent with the present results of the mutational analyses.

Post-transcriptional modification in archaeal tRNAs: identities and phylogenetic relations of nucleotides from mesophilic and hyperthermophilic Methanococcales

Post-transcriptional modifications in archaeal RNA are known to be phylogenetically distinct but relatively little is known of tRNA from the Methanococci, a lineage of methanogenic marine euryarchaea that grow over an unusually broad temperature range. Transfer RNAs from Methanococcus vannielii, Methanococcus maripaludis, the thermophile Methanococcus thermolithotrophicus, and hyperthermophiles Methanococcus jannaschii and Methanococcus igneus were studied to determine whether modification patterns reflect the close phylogenetic relationships inferred from small ribosomal subunit RNA sequences, and to examine modification differences associated with temperature of growth. Twenty-four modified nucleosides were characterized, including the complex tricyclic nucleoside wyosine characteristic of position 37 in tRNA(Phe) and known previously only in eukarya, plus two new wye family members of presently unknown structure. The hypermodified nucleoside 5-methylaminomethyl-2-thiouridine, reported previously only in bacterial tRNA at the first position of the anticodon, was identified by liquid chromatography-electrospray ionization mass spectrometry in four of the five organisms. The ribose-methylated nucleosides, 2'-O-methyladenosine, N(2),2'-O-dimethylguanosine and N(2),N(2),2'-O-trimethylguanosine, were found only in hyperthermophile tRNA, consistent with their proposed roles in thermal stabilization of tRNA.

Study on construction of a cDNA library corresponding to an amino acid-specific tRNA and influence of the modified nucleotide upon nucleotide misincorporations in reverse transcription

The construction of a cDNA library corresponding to an amino acid-specific tRNA and the influence of the modified nucleotide in the tRNA upon misincorporation in reverse transcription were investigated. The distinctive feature of the constructive strategy is that the cDNA library was prepared in connection with the charging activity of the tRNA. The aminoacyl-tRNA was captured selectively by using a biotin-avidin system. After hydrolysis of the ester bond, the tRNA was collected as an amino acid-specific tRNA pool, and a poly(A) tail was attached to the CCA terminus for reverse transcription. To the 3'-terminus of the transcribed cDNA, poly (dC) was added by terminal deoxynucleotidyl transferase, and the cDNA was amplified by PCR. The double-stranded cDNA was used for transformation of Escherichia coli JM109. Sequence analyses of the obtained clones bearing the tRNA genes revealed that a few nucleotide substitutions occurred at the location where the modified nucleotides exist. Among them, it was noteworthy that 1-methyladenosine (m(1)A22) in the D-loop of Bacillus subtilis tRNA(Ser) was recognized as G in the reverse transcription and the result revealed different tendency of the misincorporation, which has been shown in the study of HIV-1 reverse transcription.

HIV-1 nucleocapsid protein zinc finger structures induce tRNA(Lys,3) structural changes but are not critical for primer/template annealing

Retroviral reverse transcriptases use host cellular tRNAs as primers to initiate reverse transcription. In the case of human immunodeficiency virus type 1 (HIV-1), the 3' 18 nucleotides of human tRNA(Lys,3) are annealed to a complementary sequence on the RNA genome known as the primer binding site (PBS). The HIV-1 nucleocapsid protein (NC) facilitates this annealing. To understand the structural changes that are induced upon NC binding to the tRNA alone, we employed a chemical probing method using the lanthanide metal terbium. At low concentrations of NC, the strong terbium cleavage observed in the core region of the tRNA is significantly attenuated. Thus, NC binding first results in disruption of the tRNA's metal binding pockets, including those that stabilize the D-TPsiC tertiary interaction. When NC concentrations approach the amount needed for complete primer/template annealing, NC further destabilizes the tRNA acceptor-TPsiC stem minihelix, as evidenced by increased terbium cleavage in this domain. A mutant form of NC (SSHS NC), which lacks the zinc finger structures, is able to anneal tRNA(Lys,3) efficiently to the PBS, and to destabilize the tRNA tertiary core, albeit less effectively than wild-type NC. This mutant form of NC does not affect cleavage significantly in the helical regions, even when bound at high concentrations. These results, as well as experiments conducted in the presence of polyLys, suggest that in the absence of the zinc finger structures, NC acts as a polycation, neutralizing the highly negative phosphodiester backbone. The presence of an effective multivalent cationic peptide is sufficient for efficient tRNA primer annealing to the PBS.

Does the evolutionary history of aminoacyl-tRNA synthetases explain the loss of mitochondrial tRNA genes?

The importation of cytosolic tRNAs is required for protein synthesis in the mitochondria of the wide variety of eukaryotes that lack a complete set of mitochondrial tRNA genes. The evolutionary history of the process, however, is still enigmatic. The analysis presented here suggests that the loss of distinct mitochondrial tRNA genes was not random and that it might be explained by the differential capabilities of mitochondrial aminoacyl-tRNA synthetases to charge imported eukaryotic-type tRNAs with amino acid.

A general approach for the generation of orthogonal tRNAs

BACKGROUND

The addition of new amino acids to the genetic code of Escherichia coli requires an orthogonal suppressor tRNA that is uniquely acylated with a desired unnatural amino acid by an orthogonal aminoacyl-tRNA synthetase. A tRNA(Tyr)(CUA)-tyrosyl-tRNA synthetase pair imported from Methanococcus jannaschii can be used to generate such a pair. In vivo selections have been developed for selecting mutant suppressor tRNAs with enhanced orthogonality, which can be used to site-specifically incorporate unnatural amino acids into proteins in E. coli.

RESULTS

A library of amber suppressor tRNAs derived from M. jannaschii tRNA(Tyr) was generated. tRNA(Tyr)(CUA)s that are substrates for endogenous E. coli aminoacyl-tRNA synthetases were deleted from the pool by a negative selection based on suppression of amber nonsense mutations in the barnase gene. The remaining tRNA(Tyr)(CUA)s were then selected for their ability to suppress amber nonsense codons in the beta-lactamase gene in the presence of the cognate M. jannaschii tyrosyl-tRNA synthetase (TyrRS). Four mutant suppressor tRNAs were selected that are poorer substrates for E. coli synthetases than M. jannaschii tRNA(Tyr)(CUA), but still can be charged efficiently by M. jannaschii TyrRS.

CONCLUSIONS

The mutant suppressor tRNA(Tyr)(CUA) together with the M. jannaschii TyrRS is an excellent orthogonal tRNA-synthetase pair for the in vivo incorporation of unnatural amino acids into proteins. This general approach may be expanded to generate additional orthogonal tRNA-synthetase pairs as well as probe the interactions between tRNAs and their cognate synthetases.

Specific tyrosylation of the bulky tRNA-like structure of brome mosaic virus RNA relies solely on identity nucleotides present in its amino acid-accepting domain

Residues specifying aminoacylation by yeast tyrosyl-tRNA synthetase (TyrRS) of the tRNA-like structure present at the 3'-end of brome mosaic virus (BMV) RNA were determined by the in vitro approach using phage T7 transcripts. They correspond to nucleotides equivalent to base-pair C1-G72 and discriminator base A73 in the amino acid-acceptor branch of the molecule. No functional equivalents of the tyrosine anticodon residues, shown to be weakly involved in tyrosine identity of canonical tRNA(Tyr), were found in the BMV tRNA-like structure. This indicates a behaviour of this large and intricate molecule reminiscent of that of a minihelix derived from an amino acid-acceptor branch. Furthermore, iodine footprinting experiments performed on a tyrosylable BMV RNA transcript of 196 nt complexed to yeast TyrRS indicate that the amino acid-acceptor branch of the viral RNA is protected against cleavages as well as a hairpin domain, which is possibly located perpendicularly to its accepting branch. This domain without the canonical anticodon loop or the tyrosine anticodon acts as an anchor for TyrRS interaction leading to a better efficiency of tyrosylation.

Active site of an aminoacyl-tRNA synthetase dissected by energy-transfer-dependent fluorescence

Aminoacyl-tRNA synthetases establish the rules of the genetic code by catalyzing attachment of amino acids to specific transfer RNAs (tRNAs) that bear the anticodon triplets of the code. Each of the 20 amino acids has its own distinct aminoacyl-tRNA synthetase. Here we use energy-transfer-dependent fluorescence from the nucleotide probe N-methylanthraniloyl dATP (mdATP) to investigate the active site of a specific aminoacyl-tRNA synthetase. Interaction of the enzyme with the cognate amino acid and formation of the aminoacyl adenylate intermediate were detected. In addition to providing a convenient tool to characterize enzymatic parameters, the probe allowed investigation of the role of conserved residues within the active site. Specifically, a residue that is critical for binding could be distinguished from one that is important for the transition state of adenylate formation. Amino acid binding and adenylate synthesis by two other aminoacyl-tRNA synthetases was also investigated with mdATP. Thus, a key step in the synthesis of aminoacyl-tRNA can in general be dissected with this probe.

Divergent adaptation of tRNA recognition by Methanococcus jannaschii prolyl-tRNA synthetase

Analysis of prolyl-tRNA synthetase (ProRS) across all three taxonomic domains (Eubacteria, Eucarya, and Archaea) reveals that the sequences are divided into two distinct groups. Recent studies show that Escherichia coli ProRS, a member of the "prokaryotic-like" group, recognizes specific tRNA bases at both the acceptor and anticodon ends, whereas human ProRS, a member of the "eukaryotic-like" group, recognizes nucleotide bases primarily in the anticodon. The archaeal Methanococcus jannaschii ProRS is a member of the eukaryotic-like group, although its tRNA(Pro) possesses prokaryotic features in the acceptor stem. We show here that, in some respects, recognition of tRNA(Pro) by M. jannaschii ProRS parallels that of human, with a strong emphasis on the anticodon and only weak recognition of the acceptor stem. However, our data also indicate differences in the details of the anticodon recognition between these two eukaryotic-like synthetases. Although the human enzyme places a stronger emphasis on G35, the M. jannaschii enzyme places a stronger emphasis on G36, a feature that is shared by E. coli ProRS. These results, interpreted in the context of an extensive sequence alignment, provide evidence of divergent adaptation by M. jannaschii ProRS; recognition of the tRNA acceptor end is eukaryotic-like, whereas the details of the anticodon recognition are prokaryotic-like. This divergence may be a reflection of the unusual dual function of this enzyme, which catalyzes specific aminoacylation with proline as well as with cysteine.

Disease-related versus polymorphic mutations in human mitochondrial tRNAs. Where is the difference?

A number of point mutations in human mitochondrial (mt) tRNA genes are correlated with a variety of neuromuscular and other severe disorders including encephalopathies, myopathies, cardiopathies and diabetes. The complexity of the genotype/phenotype relationships, the diversity of possible molecular impacts of the different mutations at the tRNA structure/function levels, and the exponential discovery of new mutations call for the search for unifying features. Here, the basic features (at the levels of primary and secondary structure) of 68 'pathogenic' mutations are compared with those of 64 'polymorphic' neutral mutations, revealing that these standard parameters for mutant analysis are not sufficient to predict the pathogenicity of mt tRNA mutations. Thus, case by case molecular investigation remains the only means of assessing the growing family of pathogenic mutations in mt tRNAs. New lines of research are suggested.

Overlapping destinations for two dual targeted glycyl-tRNA synthetases in Arabidopsis thaliana and Phaseolus vulgaris

In plant mitochondria, some of the tRNAs are encoded by the mitochondrial genome and resemble their prokaryotic counterparts, whereas the remaining tRNAs are encoded by the nuclear genome and imported from the cytosol. Generally, mitochondrial isoacceptor tRNAs all have the same genetic origin. One known exception to this rule is the group of tRNA(Gly) isoacceptors in dicotyledonous plants. A mitochondrion-encoded tRNA(Gly) and at least one nucleus-encoded tRNA(Gly) coexist in the mitochondria of these plants, and both are required to allow translation of all four GGN glycine codons. We have taken advantage of this atypical situation to address the problem of tRNA/aminoacyl-tRNA synthetase coevolution in plants. In this work, we show that two different nucleus-encoded glycyl-tRNA synthetases (GlyRSs) are imported into Arabidopsis thaliana and Phaseolus vulgaris mitochondria. The first one, GlyRS-1, is similar to human or yeast glycyl-tRNA synthetase, whereas the second, GlyRS-2, is similar to Escherichia coli glycyl-tRNA synthetase. Both enzymes are dual targeted, GlyRS-1 to mitochondria and to the cytosol and GlyRS-2 to mitochondria and chloroplasts. Unexpectedly, GlyRS-1 seems to be active in the cytosol but inactive in mitochondrial fractions, whereas GlyRS-2 is likely to glycylate both the organelle-encoded tRNA(Gly) and the imported tRNA(Gly) present in mitochondria.

Identity elements in tRNA-mediated transcription antitermination: implication of tRNA D- and T-arms in mRNA recognition

tRNA-mediated transcription antitermination has been shown to control the expression of several amino acid biosynthesis operons and aminoacyl-tRNA-synthetase-encoding genes in Gram-positive bacteria. A model originally put forward by Grundy & Henkin describes the conserved structural features of the leader sequences of these operons and genes. Two sequences of 3 and 4 nt, respectively, take a central position in this model and are thought to be responsible for the binding of the system-specific uncharged tRNA, an interaction which would stabilize the antiterminator conformation of the leader. Here a further evolution of this model is presented based on an analysis of trp regulation in Lactococcus lactis in which a function is assigned to hitherto unexplained conserved structures in the leader sequence. It is postulated that the mRNA-tRNA interaction involves various parts of the tRNA in addition to the anticodon and the acceptor in the original model and that these additional interactions contribute to the recognition of a specific tRNA, and hence to the specificity and efficacy of the regulatory response.

Determination of tRNA(Phe) nucleotides contacting the subunits of Thermus thermophilus phenylalanyl-tRNA synthetase by photoaffinity crosslinking

The nucleotides of tRNA(Phe) interacting with the subunits of Thermus thermophilus phenylalanyl-tRNA synthetase (the alpha(2)beta(2) heterotetramer) have been determined by photoaffinity crosslinking of randomly s(4)U-monosubstituted tRNA(Phe) transcripts which retain aminoacylation parameters closely similar to those of the native tRNA(Phe). The thiolated transcripts have been fractionated by affinity electrophoresis and separately crosslinked to the enzyme. Sites of crosslinking to the beta subunit have been identified at positions 33 and 39 and crosslinking sites to the alpha subunit have been localized at positions 20, 45 and 47, using alkaline hydrolysis analysis of the crosslinked proteinase K-treated tRNAs. An additional crosslink to the beta subunit, not identified in the full-length crosslinked tRNAs, has been deduced to occur at position 12, based on the analysis of an unusual (fast migrating) crosslinked product. Nucleotide s(4)U8 of native tRNA(Phe) has been shown to form a minor crosslink to the alpha subunit. Four of the seven crosslinking sites, namely nucleotides 8, 12, 20 and 39, are among those shown to be protected against cleavage by iodine in footprinting experiments; in contrast, only nucleotide 12 is among the contact sites defined in the crystal structure. The data of independent biochemical approaches strongly suggest conformational flexibility of the complex under functional conditions, thus reflecting the importance of macromolecular dynamics for the interaction.

Aminoacyl-tRNA synthesis

Aminoacyl-tRNAs are substrates for translation and are pivotal in determining how the genetic code is interpreted as amino acids. The function of aminoacyl-tRNA synthesis is to precisely match amino acids with tRNAs containing the corresponding anticodon. This is primarily achieved by the direct attachment of an amino acid to the corresponding tRNA by an aminoacyl-tRNA synthetase, although intrinsic proofreading and extrinsic editing are also essential in several cases. Recent studies of aminoacyl-tRNA synthesis, mainly prompted by the advent of whole genome sequencing and the availability of a vast body of structural data, have led to an expanded and more detailed picture of how aminoacyl-tRNAs are synthesized. This article reviews current knowledge of the biochemical, structural, and evolutionary facets of aminoacyl-tRNA synthesis.

Major tyrosine identity determinants in Methanococcus jannaschii and Saccharomyces cerevisiae tRNA(Tyr) are conserved but expressed differently

Using in vitro tRNA transcripts and minihelices it was shown that the tyrosine identity for tRNA charging by tyrosyl-tRNA synthetase (TyrRS) from the archaeon Methanococcus jannaschii is determined by six nucleotides: the discriminator base A73 and the first base-pair C1-G72 in the acceptor stem together with the anticodon triplet. The anticodon residues however, participate only weakly in identity determination, especially residues 35 and 36. The completeness of the aforementioned identity set was verified by its tranfer into several tRNAs which then become as efficiently tyrosylatable as the wild-type transcript from M. jannaschii. Temperature dependence experiments on both the structure and the tyrosylation properties of M. jannaschii and yeast tRNA(Tyr) transcripts show that the archaeal transcript has greater structural stability and enhanced aminoacylation behaviour than the yeast transcript. Tyrosine identity in M. jannaschii is compared to that in yeast, and the conservation of the major determinant in both organisms, namely the C1-G72 pair, gives additional support to the existence of a functional connection between archaeal and eukaryotic aminoacylation systems.

Specific interaction between anticodon nuclease and the tRNA(Lys) wobble base

The bacterial tRNA(Lys)-specific PrrC-anticodon nuclease cleaves its natural substrate 5' to the wobble base, yielding 2',3'-cyclic phosphate termini. Previous work has implicated the anticodon of tRNA(Lys) as a specificity element and a cluster of amino acid residues at the carboxy-proximal half of PrrC in its recognition. We further examined these assumptions by assaying unmodified and hypomodified derivatives of tRNA(Lys) as substrates of wild-type and mutant alleles of PrrC. The data show, first, that the anticodon sequence and wobble base modifications of tRNA(Lys) play major roles in the interaction with anticodon nuclease. Secondly, a specific contact between the substrate recognition site of PrrC and the tRNA(Lys) wobble base is revealed by PrrC missense mutations that suppress the inhibitory effects of wobble base modification mutations. Thirdly, the data distinguish between the anticodon recognition mechanisms of PrrC and lysyl-tRNA synthetase.

Codon reassignment and the evolving genetic code: problems and pitfalls in post-genome analysis

The in silico translation of open reading frames, using the 'universal genetic code', must be approached with caution. The uncovering of a number of codon reassignments in nuclear and organellar genomes highlights the importance of experimentally confirming the assignments of all 64 codons for the species whose genome is under investigation. Such alterations to codon meaning also suggest that the genetic code is not 'frozen' and continues to evolve.

Rewiring the keyboard: evolvability of the genetic code

The genetic code evolved in two distinct phases. First, the 'canonical' code emerged before the last universal ancestor; subsequently, this code diverged in numerous nuclear and organelle lineages. Here, we examine the distribution and causes of these secondary deviations from the canonical genetic code. The majority of non-standard codes arise from alterations in the tRNA, with most occurring by post-transcriptional modifications, such as base modification or RNA editing, rather than by substitutions within tRNA anticodons.

Transfer RNA-mediated editing in threonyl-tRNA synthetase. The class II solution to the double discrimination problem

Threonyl-tRNA synthetase, a class II synthetase, uses a unique zinc ion to discriminate against the isosteric valine at the activation step. The crystal structure of the enzyme with an analog of seryl adenylate shows that the noncognate serine cannot be fully discriminated at that step. We show that hydrolysis of the incorrectly formed ser-tRNA(Thr) is performed at a specific site in the N-terminal domain of the enzyme. The present study suggests that both classes of synthetases use effectively the ability of the CCA end of tRNA to switch between a hairpin and a helical conformation for aminoacylation and editing. As a consequence, the editing mechanism of both classes of synthetases can be described as mirror images, as already seen for tRNA binding and amino acid activation.

Structural basis for double-sieve discrimination of L-valine from L-isoleucine and L-threonine by the complex of tRNA(Val) and valyl-tRNA synthetase

Valyl-tRNA synthetase (ValRS) strictly discriminates the cognate L-valine from the larger L-isoleucine and the isosteric L-threonine by the tRNA-dependent "double sieve" mechanism. In this study, we determined the 2.9 A crystal structure of a complex of Thermus thermophilus ValRS, tRNA(Val), and an analog of the Val-adenylate intermediate. The analog is bound in a pocket, where Pro(41) allows accommodation of the Val and Thr moieties but precludes the Ile moiety (the first sieve), on the aminoacylation domain. The editing domain, which hydrolyzes incorrectly synthesized Thr-tRNA(Val), is bound to the 3' adenosine of tRNA(Val). A contiguous pocket was found to accommodate the Thr moiety, but not the Val moiety (the second sieve). Furthermore, another Thr binding pocket for Thr-adenylate hydrolysis was suggested on the editing domain.

tRNA aminoacylation by arginyl-tRNA synthetase: induced conformations during substrates binding

The 2.2 A crystal structure of a ternary complex formed by yeast arginyl-tRNA synthetase and its cognate tRNA(Arg) in the presence of the L-arginine substrate highlights new atomic features used for specific substrate recognition. This first example of an active complex formed by a class Ia aminoacyl-tRNA synthetase and its natural cognate tRNA illustrates additional strategies used for specific tRNA selection. The enzyme specifically recognizes the D-loop and the anticodon of the tRNA, and the mutually induced fit produces a conformation of the anticodon loop never seen before. Moreover, the anticodon binding triggers conformational changes in the catalytic center of the protein. The comparison with the 2.9 A structure of a binary complex formed by yeast arginyl-tRNA synthetase and tRNA(Arg) reveals that L-arginine binding controls the correct positioning of the CCA end of the tRNA(Arg). Important structural changes induced by substrate binding are observed in the enzyme. Several key residues of the active site play multiple roles in the catalytic pathway and thus highlight the structural dynamics of the aminoacylation reaction.

Alternative designs for construction of the class II transfer RNA tertiary core

The structural requirements for assembly of functional class II transfer RNA core regions have been examined by sequence analysis and tested by reconstruction of alternative folds into the tertiary domain of Escherichia coli tRNA(2)Gln. At least four distinct designs have been identified that permit stable folding and efficient synthetase recognition, as assessed by thermal melting profiles and glutaminylation kinetics. Although most large variable-arm tRNAs found in nature possess an enlarged D-loop, lack of this feature can be compensated for by insertion of nucleotides either 3' to the variable loop or within the short acceptor/D-stem connector region. Rare pyrimidines at nt 9 in the core region can be accommodated in the class II framework, but only if specific nucleotides are present either in the D-loop or 3' to the variable arm. Glutaminyl-tRNA synthetase requires one or two unpaired uridines 3' to the variable arm to efficiently aminoacylate several of the class II frameworks. Because there are no specific enzyme contacts in the tRNAGln core region, these data suggest that tRNA discrimination by GlnRS depends in part on indirect readout of RNA sequence information.

Search for characteristic structural features of mammalian mitochondrial tRNAs

A number of mitochondrial (mt) tRNAs have strong structural deviations from the classical tRNA cloverleaf secondary structure and from the conventional L-shaped tertiary structure. As a consequence, there is a general trend to consider all mitochondrial tRNAs as "bizarre" tRNAs. Here, a large sequence comparison of the 22 tRNA genes within 31 fully sequenced mammalian mt genomes has been performed to define the structural characteristics of this specific group of tRNAs. Vertical alignments define the degree of conservation/variability of primary sequences and secondary structures and search for potential tertiary interactions within each of the 22 families. Further horizontal alignments ascertain that, with the exception of serine-specific tRNAs, mammalian mt tRNAs do fold into cloverleaf structures with mostly classical features. However, deviations exist and concern large variations in size of the D- and T-loops. The predominant absence of the conserved nucleotides G18G19 and T54T55C56, respectively in these loops, suggests that classical tertiary interactions between both domains do not take place. Classification of the tRNA sequences according to their genomic origin (G-rich or G-poor DNA strand) highlight specific features such as richness/poorness in mismatches or G-T pairs in stems and extremely low G-content or C-content in the D- and T-loops. The resulting 22 "typical" mammalian mitochondrial sequences built up a phylogenetic basis for experimental structural and functional investigations. Moreover, they are expected to help in the evaluation of the possible impacts of those point mutations detected in human mitochondrial tRNA genes and correlated with pathologies.

Hydrolytic editing by a class II aminoacyl-tRNA synthetase

Editing reactions catalyzed by aminoacyl-tRNA synthetases are critical for accurate translation of the genetic code. To date, this activity, whereby misactivated amino acids are hydrolyzed either before or after transfer to noncognate tRNAs, has been characterized extensively only in the case of class I synthetases. Class II synthetases have an active-site architecture that is completely distinct from that of class I. Thus, findings on editing by class I synthetases may not be applicable generally to class II enzymes. Class II Escherichia coli proline-tRNA synthetase is shown here to misactivate alanine and to hydrolyze the noncognate amino acid before transfer to tRNA(Pro). This enzyme also is capable of rapidly deacylating a mischarged Ala-tRNA(Pro) variant. A single cysteine residue (C443) that is located within the class II-specific motif 3 consensus sequence was shown previously to be dispensable for proline-tRNA synthetase aminoacylation activity. We show here that C443 is critical for the hydrolytic editing of Ala-tRNA(Pro) by this class II synthetase.

Importance of discriminator base stacking interactions: molecular dynamics analysis of A73 microhelix(Ala) variants

Transfer of alanine from Escherichia coli alanyl-tRNA synthetase (AlaRS) to RNA minihelices that mimic the amino acid acceptor stem of tRNA(Ala) has been shown, by analysis of variant minihelix aminoacylation activities, to involve a transition state sensitive to changes in the 'discriminator' base at position 73. Solution NMR has indicated that this single-stranded nucleotide is predominantly stacked onto G1 of the first base pair of the alanine acceptor stem helix. We report the activity of a new variant with the adenine at position 73 substituted by its non-polar isostere 4-methylindole (M). Despite lacking N7, this analog is well tolerated by AlaRS. Molecular dynamics (MD) simulations show that the M substitution improves position 73 base stacking over G1, as measured by a stacking lifetime analysis. Additional MD simulations of wild-type microhelix(Ala) and six variants reveal a positive correlation between N73 base stacking propensity over G1 and aminoacylation activity. For the two DeltaN7 variants simulated we found that the propensity to stack over G1 was similar to the analogous variants that contain N7 and we conclude that the decrease in aminoacylation efficiency observed upon deletion of N7 is likely due to loss of a direct stabilizing interaction with the synthetase.

The free yeast aspartyl-tRNA synthetase differs from the tRNA(Asp)-complexed enzyme by structural changes in the catalytic site, hinge region, and anticodon-binding domain

Aminoacyl-tRNA synthetases catalyze the specific charging of amino acid residues on tRNAs. Accurate recognition of a tRNA by its synthetase is achieved through sequence and structural signalling. It has been shown that tRNAs undergo large conformational changes upon binding to enzymes, but little is known about the conformational rearrangements in tRNA-bound synthetases. To address this issue the crystal structure of the dimeric class II aspartyl-tRNA synthetase (AspRS) from yeast was solved in its free form and compared to that of the protein associated to the cognate tRNA(Asp). The use of an enzyme truncated in N terminus improved the crystal quality and allowed us to solve and refine the structure of free AspRS at 2.3 A resolution. For the first time, snapshots are available for the different macromolecular states belonging to the same tRNA aminoacylation system, comprising the free forms for tRNA and enzyme, and their complex. Overall, the synthetase is less affected by the association than the tRNA, although significant local changes occur. They concern a rotation of the anticodon binding domain and a movement in the hinge region which connects the anticodon binding and active-site domains in the AspRS subunit. The most dramatic differences are observed in two evolutionary conserved loops. Both are in the neighborhood of the catalytic site and are of importance for ligand binding. The combination of this structural analysis with mutagenesis and enzymology data points to a tRNA binding process that starts by a recognition event between the tRNA anticodon loop and the synthetase anticodon binding module.

Translational control of viral gene expression in eukaryotes

As obligate intracellular parasites, viruses rely exclusively on the translational machinery of the host cell for the synthesis of viral proteins. This relationship has imposed numerous challenges on both the infecting virus and the host cell. Importantly, viruses must compete with the endogenous transcripts of the host cell for the translation of viral mRNA. Eukaryotic viruses have thus evolved diverse mechanisms to ensure translational efficiency of viral mRNA above and beyond that of cellular mRNA. Mechanisms that facilitate the efficient and selective translation of viral mRNA may be inherent in the structure of the viral nucleic acid itself and can involve the recruitment and/or modification of specific host factors. These processes serve to redirect the translation apparatus to favor viral transcripts, and they often come at the expense of the host cell. Accordingly, eukaryotic cells have developed antiviral countermeasures to target the translational machinery and disrupt protein synthesis during the course of virus infection. Not to be outdone, many viruses have answered these countermeasures with their own mechanisms to disrupt cellular antiviral pathways, thereby ensuring the uncompromised translation of virion proteins. Here we review the varied and complex translational programs employed by eukaryotic viruses. We discuss how these translational strategies have been incorporated into the virus life cycle and examine how such programming contributes to the pathogenesis of the host cell.

tRNA leucine identity and recognition sets

Transfer RNAs (tRNAs) are grouped into two classes based on the structure of their variable loop. In Escherichia coli, tRNAs from three isoaccepting groups are classified as type II. Leucine tRNAs comprise one such group. We used both in vivo and in vitro approaches to determine the nucleotides that are required for tRNA(Leu) function. In addition, to investigate the role of the tRNA fold, we compared the in vivo and in vitro characteristics of type I tRNA(Leu) variants with their type II counterparts.A minimum of six conserved tRNA(Leu) nucleotides were required to change the amino acid identity and recognition of a type II tRNA(Ser) amber suppressor from a serine to a leucine residue. Five of these nucleotides affect tRNA tertiary structure; the G15-C48 tertiary "Levitt base-pair" in tRNA(Ser) was changed to A15-U48; the number of nucleotides in the alpha and beta regions of the D-loop was changed to achieve the positioning of G18 and G19 that is found in all tRNA(Leu); a base was inserted at position 47n between the base-paired extra stem and the T-stem; in addition the G73 "discriminator" base of tRNA(Ser) was changed to A73. This minimally altered tRNA(Ser) exclusively inserted leucine residues and was an excellent in vitro substrate for LeuRS. In a parallel experiment, nucleotide substitutions were made in a glutamine-inserting type I tRNA (RNA(SerDelta); an amber suppressor in which the tRNA(Ser) type II extra-stem-loop is replaced by a consensus type I loop). This "type I" swap experiment was successful both in vivo and in vitro but required more nucleotide substitutions than did the type II swap. The type I and II swaps revealed differences in the contributions of the tRNA(Leu) acceptor stem base-pairs to tRNA(Leu) function: in the type I, but not the type II fold, leucine specificity was contingent on the presence of the tRNA(Leu) acceptor stem sequence. The type I and II tRNAs used in this study differed only in the sequence and structure of the variable loop. By altering this loop, and thereby possibly introducing subtle changes into the overall tRNA fold, it became possible to detect otherwise cryptic contributions of the acceptor stem sequence to recognition by LeuRS. Possible reasons for this effect are discussed.

Transfer RNA recognition by aminoacyl-tRNA synthetases

The aminoacyl-tRNA synthetases are an ancient group of enzymes that catalyze the covalent attachment of an amino acid to its cognate transfer RNA. The question of specificity, that is, how each synthetase selects the correct individual or isoacceptor set of tRNAs for each amino acid, has been referred to as the second genetic code. A wealth of structural, biochemical, and genetic data on this subject has accumulated over the past 40 years. Although there are now crystal structures of sixteen of the twenty synthetases from various species, there are only a few high resolution structures of synthetases complexed with cognate tRNAs. Here we review briefly the structural information available for synthetases, and focus on the structural features of tRNA that may be used for recognition. Finally, we explore in detail the insights into specific recognition gained from classical and atomic group mutagenesis experiments performed with tRNAs, tRNA fragments, and small RNAs mimicking portions of tRNAs.

Misactivated amino acids translocate at similar rates across surface of a tRNA synthetase

Certain aminoacyl-tRNA synthetases have a second active site that destroys (by hydrolysis) errors of amino acid activation. For example, isoleucyl-tRNA synthetase misactivates valine (to produce valyl adenylate or Val-tRNA(Ile)) at its active site. The misactivated amino acid is then translocated to an editing site located >25 A away. The role of the misactivated amino acid in determining the rate of translocation is not known. Valyl-tRNA synthetase, a close homolog of isoleucyl-tRNA synthetase, misactivates threonine, alpha-aminobutyrate, and cysteine. In this paper, we use a recently developed fluorescence-energy-transfer assay to study translocation of misactivated threonine, alpha-aminobutyrate, and cysteine. Although their rates of misactivation are clearly distinct, their rates of translocation are similar. Thus, the rate of translocation is independent of the nature of the misactivated amino acid. This result suggests that the misactivated amino acid per se has little or no role in directing translocation.

Transfer RNA identity change in anticodon variants of E. coli tRNA(Phe) in vivo

The anticodon sequence is a major recognition element for most aminoacyl-tRNA synthetases. We investigated the in vivo effects of changing the anticodon on the aminoacylation specificity in the example of E. coli tRNA(Phe). Constructing different anticodon mutants of E. coli tRNA(Phe) by site-directed mutagenesis, we isolated 22 anticodon mutant tRNA(Phe); the anticodons corresponded to 16 amino acids and an opal stop codon. To examine whether the mutant tRNAs had changed their amino acid acceptor specificity in vivo, we tested the viability of E. coli strains containing these tRNA(Phe) genes in a medium which permitted tRNA induction. Fourteen mutant tRNA genes did not affect host viability. However, eight mutant tRNA genes were toxic to the host and prevented growth, presumably because the anticodon mutants led to translational errors. Many mutant tRNAs which did not affect host viability were not aminoacylated in vivo. Three mutant tRNAs containing anticodon sequences corresponding to lysine (UUU), methionine (CAU) and threonine (UGU) were charged with the amino acid corresponding to their anticodon, but not with phenylalanine. These three tRNAs and tRNA(Phe) are located in the same cluster in a sequence similarity dendrogram of total E. coli tRNAs. The results support the idea that such tRNAs arising from in vivo evolution are derived by anticodon change from the same ancestor tRNA.

Probing a tRNA core that contributes to aminoacylation

The contribution of the tRNA "core" to aminoacylation is beginning to be recognized. One example is the core region of Escherichia coli tRNA(Cys), which has been shown by biochemical studies to be important for aminoacylation. This core has several layers of unusual base-pairs, which are revealed by the recent crystal structure of the tRNA complexed with the elongation factor EF-Tu and an analog of GTP. One of these layers consists of a 9:[13:22] base-triple, rather than the 46:[13:22] or 45:[13:22] base-triple that is commonly observed in tRNA structure. Because 13:22 is an important element in aminoacylation of E. coli tRNA(Cys), a better understanding of its structure in the tRNA core will shed light on its role in aminoacylation. In this study, we used the phage T7 transcript of the tRNA as a substrate. We probed the structure of 13:22 by dimethyl sulfate and tested its partner in a base-triple by generating mutations that could be assayed for aminoacylation. The results of this study in general are in a better agreement with a 46:[13:22] base-triple that we previously proposed. Although these results are not interpreted as direct proof for the 46:[13:22] base-triple, they shed new light on features of the tRNA core that are important for aminoacylation.

Identification of discriminator base atomic groups that modulate the alanine aminoacylation reaction

Specific aminoacylation of tRNAs involves activation of an amino acid with ATP followed by amino acid transfer to the tRNA. Previous work showed that the transfer of alanine from Escherichia coli alanyl-tRNA synthetase to a cognate RNA minihelix involves a transition state sensitive to changes in the tRNA acceptor stem. Specifically, the "discriminator" base at position 73 of minihelix(Ala) is a critical determinant of the transfer step of aminoacylation. This single-stranded nucleotide has previously been shown by solution NMR to be stacked predominantly onto G(1) of the first base pair of the alanine acceptor stem helix. In this work, RNA duplex(Ala) variants were prepared to investigate the role of specific discriminator base atomic groups in aminoacylation catalytic efficiency. Results indicate that the purine structure appears to be important for stabilization of the transition state and that major groove elements are more critical than those located in the minor groove. This result is in accordance with the predicted orientation of a class II synthetase at the end of the acceptor helix. In particular, substitution of the exocyclic amino group of A(73) with a keto-oxygen resulted in negative discrimination at this site. Taken together, these new results are consistent with the involvement of major groove atomic groups of the discriminator base in the formation of the transition state for the amino acid transfer step.

Major anticodon-binding region missing from an archaebacterial tRNA synthetase

The small size of the archaebacterial Methanococcus jannaschii tyrosyl-tRNA synthetase may give insights into the historical development of tRNAs and tRNA synthetases. The L-shaped tRNA has two major arms-the acceptor.TpsiC minihelix with the amino acid attachment site and the anticodon-containing arm. The structural organization of the tRNA synthetases parallels that of tRNAs. The more ancient synthetase domain contains the active site and insertions that interact with the minihelix portion of the tRNA. A second, presumably more recent, domain interacts with the anticodon-containing section of tRNA. The small size of the M. jannaschii enzyme is due to the absence of most of the second domain, including a segment thought to bind to the anticodon. Consistent with the absence of an anticodon-binding motif, a mutation of the central base of the anticodon had a relatively small effect on the aminoacylation efficiency of the M. jannaschii enzyme. In contrast, others showed earlier that the same mutation severely reduced charging by a normal-sized bacterial enzyme that has the aforementioned anticodon-binding motif. However, the M. jannaschii enzyme has a peptide insertion into its catalytic domain. This insertion is shared with all other tyrosyl-tRNA synthetases and is needed for a critical minihelix interaction. We show that the M. jannaschii enzyme is active on minihelix substrates over a wide temperature range and has preserved the same peptide-dependent minihelix specificity seen in other tyrosine enzymes. These findings are consistent with the concept that anticodon interactions of tRNA synthetases were later adaptations to the emerging synthetase-tRNA complex that was originally framed around the minihelix.

Quality control mechanisms during translation

Translation uses the genetic information in messenger RNA (mRNA) to synthesize proteins. Transfer RNAs (tRNAs) are charged with an amino acid and brought to the ribosome, where they are paired with the corresponding trinucleotide codon in mRNA. The amino acid is attached to the nascent polypeptide and the ribosome moves on to the next codon. The cycle is then repeated to produce a full-length protein. Proofreading and editing processes are used throughout protein synthesis to ensure the faithful translation of genetic information. The maturation of tRNAs and mRNAs is monitored, as is the identity of amino acids attached to tRNAs. Accuracy is further enhanced during the selection of aminoacyl-tRNAs on the ribosome and their base pairing with mRNA. Recent studies have begun to reveal the molecular mechanisms underpinning quality control and go some way to explaining the phenomenal accuracy of translation first observed over three decades ago.

Effect of modified nucleotides on Escherichia coli tRNAGlu structure and on its aminoacylation by glutamyl-tRNA synthetase. Predominant and distinct roles of the mnm5 and s2 modifications of U34

Overproducing Escherichia coli tRNAGlu in its homologous host results in the presence of several distinctly modified forms of this molecule that we name modivariants. The predominant tRNAGlu modivariant in wild-type E. coli contains five modified nucleosides: Psi13, mnm5s2U34, m2A37, T54 and Psi55. Four other overproduced modivariants differ from it by, respectively, either the presence of an additional Psi, or the presence of s2U34, or the lack of A37 methylation combined with either s2U34 or U34. Chemical probing reveals that the anticodon loop of the predominant modivariant is less reactive to the probes than that of the four others. Furthermore, the modivariant with neither mnm5s2U34 nor m2A37 has additional perturbations in the D- and T-arms and in the variable region. The lack of a 2-thio group in nucleoside 34, which is mnm5s2U in the predominant tRNAGlu modivariant, decreases by 520-fold the specificity of E. coli glutamyl-tRNA synthetase for tRNAGlu in the aminoacylation reaction, showing that this thio group is the identity element in the modified wobble nucleotide of E. coli tRNAGlu. The modified nucleosides content also influences the recognition of ATP and glutamate by this enzyme, and in this case also, the predominant modivariant is the one that allows the best specificity for these two substrates. These structural and kinetic properties of tRNAGlu modivariants indicate that the modification system of tRNAGlu optimizes the stability of tRNAGlu and its action as cofactor of the glutamyl-tRNA synthetase for the recognition of glutamate and ATP.

Pyrophosphate mediates the effect of certain tRNA mutations on aminoacylation of yeast tRNA(Phe)

The influence of pyrophosphate hydrolysis by inorganic pyrophosphatase on homologous aminoacylation of different yeast tRNA(Phe) mutants was studied. The addition of pyrophosphatase significantly improved the aminoacylation efficiency of tRNA(Phe) structural mutants as well as the mutant with substitution at position 20, while having no effect on the charge of wild-type tRNA(Phe). Aminoacylation of tRNA(Phe) anticodon and discriminator base (N(73)) mutants was not affected by pyrophosphatase. Activation of wild-type tRNA(Phe) transcript aminoacylation by inorganic pyrophosphatase was observed only at low Mg(2+) concentrations due to distortion of the tRNA(Phe) structure under these conditions. Our results demonstrate that pyrophosphate dissociation becomes a rate-limiting step of the reaction in yeast phenylalanyl-tRNA synthetase catalyzed aminoacylation of tRNA(Phe) variants with altered tertiary structure. A possible mechanism of pyrophosphate-mediated inhibition of tRNA mutants aminoacylation is discussed.

Unique recognition style of tRNA(Leu) by Haloferax volcanii leucyl-tRNA synthetase

The recognition manner of tRNA(Leu), a class II tRNA characterized by a long variable arm, by leucyl-tRNA synthetase from an extreme halophilic archaea, Haloferax volcanii, was studied using the in vitro transcription system. It was found that the discriminator base (A73) and the long variable arm, especially the specific loop sequence A47CG47D and U47H at the base of this helix, are significant for recognition by LeuRS. An appropriate stem length of the variable arm was also required. Base substitutions in the anticodon arm did not affect the leucylation activity. Transplantation of both the discriminator base and the variable arm of tRNA(Leu) was not sufficient to introduce leucylation activity to tRNA(Ser). Insertion of an additional nucleotide into the D-loop, which is not involved in the direct interaction with LeuRS, converted tRNA(Ser) to an efficient leucine acceptor. This suggests that differences in the tertiary structure play a key role in eliminating tRNA(Ser). The sequence-specific recognition of the long variable arm of tRNA(Leu) has not been observed in any of other organisms reported, such as Escherichia coli, yeast or human. On the other hand, the mode of discrimination from non-cognate tRNAs is similar to that in E. coli in that differences in the tertiary structure play a key role. Similarity extends to the substrate stringency, exemplified by a cross-species aminoacylation study showing that no class II tRNAs from E. coli or yeast can be leucylated by H. volcanii LeuRS. Our results have implications for the understanding of the evolution of the recognition system of class II tRNA.

Transfer RNA-dependent translocation of misactivated amino acids to prevent errors in protein synthesis

Misactivation of amino acids by aminoacyl-tRNA synthetases can lead to significant errors in protein synthesis that are prevented by editing reactions. As an example, discrete sites in isoleucyl-tRNA synthetase for amino acid activation and editing are about 25 A apart. The details of how misactivated valine is translocated from one site to the other are unknown. Here, we present a kinetic study in which a fluorescent probe is used to monitor translocation of misactivated valine from the active site to the editing site. Isoleucine-specific tRNA, and not other tRNAs, is essential for translocation of misactivated valine. Misactivation and translocation occur on the same enzyme molecule, with translocation being rate limiting for editing. These results illustrate a remarkable capacity for a specific tRNA to enhance amino acid fine structure recognition by triggering a unimolecular translocation event.

Singly and bifurcated hydrogen-bonded base-pairs in tRNA anticodon hairpins and ribozymes

The tRNA anticodon loops always comprise seven nucleotides and is involved in many recognition processes with proteins and RNA fragments. We have investigated the nature and the possible interactions between the first (32) and last (38) residues of the loop on the basis of the available sequences and crystal structures. The data demonstrate the conservation of a bifurcated hydrogen bond interaction between residues 32 and 38, located at the stem/loop junction. This interaction leads to the formation of a non-canonical base-pair which is preserved in the known crystal structures of tRNA/synthetase complexes. Among the tRNA and tDNA sequences, 93 % of the 32.38 oppositions can be assigned to two families of isosteric base-pairs, one with a large (86 %) and the other with a much smaller (7 %) population. The remainder (7 %) of the oppositions have been assigned to a third family due to the lack of evidence for assigning them into the first two sets. In all families, the Y32.R38 base-pairs are not isosteric upon reversal (like the sheared G.A or wobble G.U pairs), explaining the strong conservation of a pyrimidine at position 32. Thus, the 32.38 interaction extends the sequence signature of the anticodon loop beyond the conserved U-turn at position 33 and the usually modified purine at position 37. A comparison with other loops containing both a singly hydrogen-bonded base-pair and a U-turn suggests that the 32.38 pair could be involved in the formation of a base triple with a residue in a ribosomal RNA component. It is also observed that two crystal structures of ribozymes (hammerhead and leadzyme) present similar base-pairs at the cleavage site.

Transfer RNA identity contributes to transition state stabilization during aminoacyl-tRNA synthesis

Sequence-specific interactions between aminoacyl-tRNA synthetases and their cognate tRNAs ensure both accurate RNA recognition and the efficient catalysis of aminoacylation. The effects of tRNA(Trp)variants on the aminoacylation reaction catalyzed by wild-type Escherichia coli tryptophanyl-tRNA synthe-tase (TrpRS) have now been investigated by stopped-flow fluorimetry, which allowed a pre-steady-state analysis to be undertaken. This showed that tRNA(Trp)identity has some effect on the ability of tRNA to bind the reaction intermediate TrpRS-tryptophanyl-adenylate, but predominantly affects the rate at which trypto-phan is transferred from TrpRS-tryptophanyl adenylate to tRNA. Use of the binding ( K (tRNA)) and rate constants ( k (4)) to determine the energetic levels of the various species in the aminoacylation reaction showed a difference of approximately 2 kcal mol(-1)in the barrier to transition state formation compared to wild-type for both tRNA(Trp)A-->C73 and. These results directly show that tRNA identity contributes to the degree of complementarity to the transition state for tRNA charging in the active site of an aminoacyl-tRNA synthetase:aminoacyl-adenylate:tRNA complex.

Magnesium-dependent alternative foldings of active and inactive Escherichia coli tRNA(Glu) revealed by chemical probing

A stable conformer of Escherichia coli tRNA(Glu), obtained in the absence of Mg(2+), is inactive in the aminoacylation reaction. Probing it with diethylpyrocarbonate, dimethyl sulfate and ribonuclease V1 revealed that it has a hairpin structure with two internal loops; the helical segments at both extremities have the same structure as the acceptor stem and the anticodon arm of the native conformer of tRNA(Glu)and the middle helix is formed of nucleotides from the D-loop (G15-C20:2) and parts of the T-loop and stem (G51-C56), with G19 bulging out. This model is consistent with other known properties of this inactive conformer, including its capacity to dimerize. Therefore, this tRNA requires magnesium to acquire a conformation that can be aminoacylated, as others require a post-transcriptional modification to reach this active conformation.

Aminoacyl-tRNA synthetases: a new image for a classical family

The aminoacyl-tRNA synthetases (aaRSs) are a family of enzymes well known for their role in protein synthesis. More recent investigations have discovered that this classic family of enzymes is actually capable of a broad repertoire of functions which not only impact protein synthesis, but extend to a number of other critical cellular activities. Specific aaRSs play roles in cellular fidelity, tRNA processing, RNA splicing, RNA trafficking, apoptosis, transcriptional and translational regulation. A recent EMBO workshop entitled 'Structure and Function of Aminoacyl-tRNA Synthetases' (Mittelwihr, France, October 10-15, 1998), highlighted the diversity of the aaRSs' role within the cell. These novel activities as well as significant advances in delineating mechanisms of substrate specificity and the aminoacylation reaction affirm the family of aaRSs as pharmaceutical targets.