Crystal structure of trbp111: a structure-specific tRNA-binding protein

Trbp111 is a 111 amino acid Aquifex aeolicus structure-specific tRNA-binding protein that has homologous counterparts distributed throughout evolution. A dimer is the functional unit for binding a single tRNA. Here we report the 3D structures of the A.aeolicus protein and its Escherichia coli homolog at resolutions of 2.50 and 1.87 A, respectively. The structure shows a symmetrical dimer of two core domains and a central dimerization domain where the N- and C-terminal regions of Trbp111 form an extensive dimer interface. The core of the monomer is a classical oligonucleotide/oligosaccharide-binding (OB) fold with a five-stranded ss-barrel and a small capping helix. This structure is similar to that seen in the anticodon-binding domain of three class II tRNA synthetases and several other proteins. Mutational analysis identified sites important for interactions with tRNA. These residues line the inner surfaces of two clefts formed between the ss-barrel of each monomer and the dimer interface. The results are consistent with a proposed model for asymmetrical docking of the convex side of tRNA to the dimer.     

Structure-specific tRNA-binding protein from the extreme thermophile Aquifex aeolicus.

The genome of the bacterium Aquifex aeolicus encodes a polypeptide which is related to a small portion of a sequence found in one prokaryotic and two eukaryotic tRNA synthetases. It also is related to a portion of Arc1p, a tRNA-binding protein believed to be important for nuclear trafficking of tRNAs. Here we cloned, expressed and purified the 111 amino acid polypeptide (designated Trbp111) and showed by ultracentrifugation analysis that it is a stable dimer in solution. The protein was also crystallized in a monoclinic lattice. X-ray diffraction analysis at 2.8 A resolution revealed a prominent non-crystallographic 2-fold axis, consistent with the presence of a symmetric homodimeric structure. Band-shift analysis with polyacrylamide gels showed that the dimer binds tRNAs, but not RNA duplexes, RNA hairpins, single-stranded RNA nor 5S rRNA. Complex formation with respect to tRNA is non-specific, with a single tRNA bound per dimer. Thus, Trbp111 is a structure-specific tRNA-binding protein. These results and other considerations raise the possibility that Trbp111 is a tRNA-specific chaperone which stabilizes the native L-shaped fold in the extreme thermophile and which has been incorporated into much larger tRNA-binding proteins of higher organisms.     

Phenylalanyl-tRNA synthetase contains a dispensable RNA-binding domain that contributes to the editing of noncognate aminoacyl-tRNA

Phenylalanyl-tRNA synthetase (PheRS) is a multidomain (alphabeta)2 heterotetrameric protein responsible for synthesizing Phe-tRNA(Phe) during protein synthesis. Previous studies showed that the alpha subunit forms the catalytic core of the enzyme, while the beta subunit contains a number of autonomous structural modules with a wide range of functions including tRNA anticodon binding and editing of the misaminoacylated species Tyr-tRNA(Phe). The B2 domain of the beta subunit is a structural homologue of the EMAPII/OB fold, which has been shown in other systems to contribute to tRNA binding. Structural studies of PheRS indicated that the B2 domain is distant from bound tRNA(Phe), leaving the role of this module in question. On the basis of homology modeling with other EMAPII domain-containing proteins, the 110 amino acid B2 domain was deleted to produce PheRS deltaB2. Full-length PheRS and PheRS deltaB2 showed comparable kinetics for in vitro aminoacylation, and both enzymes complemented a defect in phenylalanylation in vivo. PheRS deltaB2 showed a 2-fold drop compared to full-length PheRS in the catalytic efficiency (kcat/KM) of Tyr-tRNA(Phe) hydrolysis, suggesting a role for the B2 domain in post-transfer editing. A comparison of tRNA binding by full-length PheRS and PheRS deltaB2 indicated that the B2 domain acts as a secondary tRNA-binding site that could contribute to editing by promoting the translocation of mischarged tRNA to the editing site of PheRS. This proposed role for the B2 domain of PheRS is consistent with previous studies, suggesting that the highly conserved EMAPII fold is able to modulate the affinity of tRNA for its primary binding site.     

Structure and function of the C-terminal domain of methionyl-tRNA synthetase

The minimal polypeptide supporting full methionyl-tRNA synthetase (MetRS) activity is composed of four domains: a catalytic Rossmann fold, a connective peptide, a KMSKS domain, and a C-terminal alpha helix bundle domain. The minimal MetRS behaves as a monomer. In several species, MetRS is a homodimer because of a C-terminal domain appended to the core polypeptide. Upon truncation of this C-terminal domain, subunits dissociate irreversibly. Here, the C-terminal domain of dimeric MetRS from Pyrococcus abyssi was isolated and studied. It displays nonspecific tRNA-binding properties and has a crystalline structure closely resembling that of Trbp111, a dimeric tRNA-binding protein found in many bacteria and archaea. The obtained 3D model was used to direct mutations against dimerization of Escherichia coli MetRS. Comparison of the resulting mutants to native and C-truncated MetRS shows that the presence of the appended C-domain improves tRNA(Met) binding affinity. However, dimer formation is required to evidence the gain in affinity.     

A recurrent general RNA binding domain appended to plant methionyl-tRNA synthetase acts as a cis-acting cofactor for aminoacylation

The cDNA encoding rice methionyl-tRNA synthetase was isolated. The protein exhibited a C-terminal polypeptide appended to a classical MetRS domain. This supplementary domain is related to endothelial monocyte activating polypeptide II (EMAPII), a cytokine produced in mammals after cleavage of p43, a component of the multisynthetase complex. It is also related to Arc1p and Trbp111, two tRNA binding proteins. We expressed rice MetRS and a derivative with a deletion of its EMAPII-like domain. Band-shift analysis showed that this extra-domain provides MetRS with non-specific tRNA binding properties. The EMAPII-like domain contributed a 10-fold decrease in K:(M) for tRNA in the aminoacylation reaction catalyzed by the native enzyme, as compared with the C-terminally truncated MetRS. Consequently, the EMAPII domain provides MetRS with a better catalytic efficiency at the free tRNA concentration prevailing in vivo. This domain binds the acceptor minihelix of tRNA(Met) and facilitates its aminoacylation. These results suggest that the EMAPII module could be a relic of an ancient tRNA binding domain that was incorporated into primordial synthetases for aminoacylation of RNA minihelices taken as the ancestor of modern tRNA.     

The crystal structure of the ttCsaA protein: an export-related chaperone from Thermus thermophilus

The CsaA protein was first characterized in Bacillus subtilis as a molecular chaperone with export-related activities. Here we report the 2.0 Angstrom-resolution crystal structure of the Thermus thermophilus CsaA protein, designated ttCsaA. Atomic structure and experiments in solution revealed a homodimer as the functional unit. The structure of the ttCsaA monomer is reminiscent of the well known oligonucleotide-binding fold, with the addition of extensions at the N- and C-termini that form an extensive dimer interface. The two identical, large, hydrophobic cavities on the protein surface are likely to constitute the substrate binding sites. The CsaA proteins share essential sequence similarity with the tRNA-binding protein Trbp111. Structure-based sequence analysis suggests a close structural resemblance between these proteins, which may extend to the architecture of the binding sites at the atomic level. These results raise the intriguing possibility that CsaA proteins possess a second, tRNA-binding activity in addition to their export-related function.     

Simultaneous binding of two proteins to opposite sides of a single transfer RNA

Transfer RNA (tRNA) is a small nucleic acid (typically 76 nucleotides) that forms binary complexes with proteins, such as aminoacyl tRNA synthetases (RS) and Trbp111. The latter is a widely distributed structure-specific tRNA-binding protein that is incorporated into cell signaling molecules. The structure of Trbp111 was modeled onto to the outer, convex side of the L-shaped tRNA. Here we present RNA footprints that are consistent with this model. This binding mode is in contrast to that of tRNA synthetases, which bind to the inside, or concave side, of tRNA. These opposite locations of binding for these two proteins suggest the possibility of a ternary complex. The formation of a tRNA synthetase--tRNA--Trbp111 ternary complex was detected by two independent methods. The results indicate that the tRNA is sandwiched between the two protein molecules. A thermodynamic and functional analysis is consistent with the tRNA retaining its native structure in the ternary complex. These results may have implications for how the translation apparatus is linked to other cellular machinery.     

An Src homology 3-like domain is responsible for dimerization of the repressor protein KorB encoded by the promiscuous IncP plasmid RP4.

KorB is a regulatory protein encoded by the conjugative plasmid RP4 and a member of the ParB family of bacterial partitioning proteins. The protein regulates the expression of plasmid genes whose products are involved in replication, transfer, and stable inheritance of RP4 by binding to palindromic 13-bp DNA sequences (5'-TTTAGC(G/C)GCTAAA-3') present 12 times in the 60-kb plasmid. Here we report the crystal structure of KorB-C, the C-terminal domain of KorB comprising residues 297-358. The structure of KorB-C was solved in two crystal forms. Quite unexpectedly, we find that KorB-C shows a fold closely resembling the Src homology 3 (SH3) domain, a fold well known from proteins involved in eukaryotic signal transduction. From the arrangement of molecules in the asymmetric unit, it is concluded that two molecules form a functionally relevant dimer. The detailed analysis of the dimer interface and a chemical cross-linking study suggest that the C-terminal domain is responsible for stabilizing the dimeric form of KorB in solution to facilitate binding to the palindromic operator sequence. The KorB-C crystal structure extends the range of protein-protein interactions known to be promoted by SH3 and SH3-like domains.     

Mammalian SCAN domain dimer is a domain-swapped homolog of the HIV capsid C-terminal domain

Retroviral assembly is driven by multiple interactions mediated by the Gag polyprotein, the main structural component of the forming viral shell. Critical determinants of Gag oligomerization are contained within the C-terminal domain (CTD) of the capsid protein, which also harbors a conserved sequence motif, the major homology region (MHR), in the otherwise highly variable Gag. An unexpected clue about the MHR function in retroviral assembly emerges from the structure of the zinc finger-associated SCAN domain we describe here. The SCAN dimer adopts a fold almost identical to that of the retroviral capsid CTD but uses an entirely different dimerization interface caused by swapping the MHR-like element between the monomers. Mutations in retroviral capsid proteins and functional data suggest that a SCAN-like MHR-swapped CTD dimer forms during immature particle assembly. In the SCAN-like dimer, the MHR contributes the major part of the large intertwined dimer interface explaining its functional significance.     

Structure of alanine dehydrogenase from Archaeoglobus: active site analysis and relation to bacterial cyclodeaminases and mammalian mu crystallin

The hyperthermophilic archaeon Archaeoglobus fulgidus contains an L-Ala dehydrogenase (AlaDH, EC 1.4.1.1) that is not homologous to known bacterial dehydrogenases and appears to represent a previously unrecognized archaeal group of NAD-dependent dehydrogenases. The gene (Genbank; TIGR AF1665) was annotated initially as an ornithine cyclodeaminase (OCD) on the basis of strong homology with the mu crystallin/OCD protein family. We report the structure of the NAD-bound AF1665 AlaDH (AF-AlaDH) at 2.3 A in a C2 crystal form with the 70 kDa dimer in the asymmetric unit, as the first structural representative of this family. Consistent with its lack of homology to bacterial AlaDH proteins, which are mostly hexameric, the archaeal dimer has a novel structure. Although both types of AlaDH enzyme include a Rossmann-type NAD-binding domain, the arrangement of strands in the C-terminal half of this domain is novel, and the other (catalytic) domain in the archaeal protein has a new fold. The active site presents a cluster of conserved Arg and Lys side-chains over the pro-R face of the cofactor. In addition, the best ordered of the 338 water molecules in the structure is positioned well for mechanistic interaction. The overall structure and active site are compared with other dehydrogenases, including the AlaDH from Phormidium lapideum. Implications for the catalytic mechanism and for the structures of homologs are considered. The archaeal AlaDH represents an ancient and previously undescribed subclass of Rossmann-fold proteins that includes bacterial ornithine and lysine cyclodeaminases, marsupial lens proteins and, in man, a thyroid hormone-binding protein that exhibits 30% sequence identity with AF1665.     

A novel solenoid fold in the cell wall anchoring domain of the pneumococcal virulence factor LytA.

Choline binding proteins are virulence determinants present in several Gram-positive bacteria. Because anchorage of these proteins to the cell wall through their choline binding domain is essential for bacterial virulence, their release from the cell surface is considered a powerful target for a weapon against these pathogens. The first crystal structure of a choline binding domain, from the toxin-releasing enzyme pneumococcal major autolysin (LytA), reveals a novel solenoid fold consisting exclusively of beta-hairpins that stack to form a left-handed superhelix. This unique structure is maintained by choline molecules at the hydrophobic interface of consecutive hairpins and may be present in other choline binding proteins that share high homology to the repeated motif of the domain.     

High-affinity RNA binding by a hyperthermophilic single-stranded DNA-binding protein

Single-stranded DNA-binding proteins (SSBs), including replication protein A (RPA) in eukaryotes, play a central role in DNA replication, recombination, and repair. SSBs utilise an oligonucleotide/oligosaccharide-binding (OB) fold domain to bind DNA, and typically oligomerise in solution to bring multiple OB fold domains together in the functional SSB. SSBs from hyperthermophilic crenarchaea, such as Sulfolobus solfataricus, have an unusual structure with a single OB fold coupled to a flexible C-terminal tail. The OB fold resembles those in RPA, whilst the tail is reminiscent of bacterial SSBs and mediates interaction with other proteins. One paradigm in the field is that SSBs bind specifically to ssDNA and much less strongly to RNA, ensuring that their functions are restricted to DNA metabolism. Here, we use a combination of biochemical and biophysical approaches to demonstrate that the binding properties of S. solfataricus SSB are essentially identical for ssDNA and ssRNA. These features may represent an adaptation to a hyperthermophilic lifestyle, where DNA and RNA damage is a more frequent event.

     

Crystal structure of circadian clock protein KaiA from Synechococcus elongatus

The circadian clock found in Synechococcus elongatus, the most ancient circadian clock, is regulated by the interaction of three proteins, KaiA, KaiB, and KaiC. While the precise function of these proteins remains unclear, KaiA has been shown to be a positive regulator of the expression of KaiB and KaiC. The 2.0-A structure of KaiA of S. elongatus reported here shows that the protein is composed of two independently folded domains connected by a linker. The NH(2)-terminal pseudo-receiver domain has a similar fold with that of bacterial response regulators, whereas the COOH-terminal four-helix bundle domain is novel and forms the interface of the 2-fold-related homodimer. The COOH-terminal four-helix bundle domain has been shown to contain the KaiC binding site. The structure suggests that the KaiB binding site is covered in the dimer interface of the KaiA "closed" conformation, observed in the crystal structure, which suggests an allosteric regulation mechanism.     

Structural studies of the Cpx pathway activator NlpE on the outer membrane of Escherichia coli

NlpE, an outer membrane lipoprotein, functions during envelope stress responses in Gram-negative bacteria. In Escherichia coli, adhesion to abiotic surfaces has been reported to activate the Cpx pathway in an NlpE-dependent manner. External copper ions are also thought to activate the Cpx pathway mediated by NlpE. We determined the crystal structure of NlpE from E. coli at 2.6 A resolution. The structure showed that NlpE consists of two beta barrel domains. The N-terminal domain resembles the bacterial lipocalin Blc, and the C-terminal domain has an oligonucleotide/oligosaccharide-binding (OB) fold. From both biochemical analyses and the crystal structure, it can be deduced that the cysteine residues in the CXXC motif may be chemically active. Furthermore, two monomers in the asymmetric unit form an unusual 3D domain-swapped dimer. These findings indicate that tertiary and/or quaternary structural instability may be responsible for Cpx pathway activation.     

Structures of tryptophanyl-tRNA synthetase II from Deinococcus radiodurans bound to ATP and tryptophan. Insight into subunit cooperativity and domain motions linked to catalysis

An auxiliary tryptophanyl tRNA synthetase (drTrpRS II) that interacts with nitric-oxide synthase in the radiation-resistant bacterium Deinococcus radiodurans charges tRNA with tryptophan and 4-nitrotryptophan, a specific nitration product of nitric-oxide synthase. Crystal structures of drTrpRS II, empty of ligands or bound to either Trp or ATP, reveal that drTrpRS II has an overall structure similar to standard bacterial TrpRSs but undergoes smaller amplitude motions of the helical tRNA anti-codon binding (TAB) domain on binding substrates. TAB domain loop conformations that more closely resemble those of human TrpRS than those of Bacillus stearothermophilus TrpRS (bsTrpRS) indicate different modes of tRNA recognition by subclasses of bacterial TrpRSs. A compact state of drTrpRS II binds ATP, from which only minimal TAB domain movement is necessary to bring nucleotide in contact with Trp. However, the signature KMSKS loop of class I synthetases does not completely engage the ATP phosphates, and the adenine ring is not well ordered in the absence of Trp. Thus, progression of the KMSKS loop to a high energy conformation that stages acyl-adenylation requires binding of both substrates. In an asymmetric drTrpRS II dimer, the closed subunit binds ATP, whereas the open subunit binds Trp. A crystallographically symmetric dimer binds no ligands. Half-site reactivity for Trp binding is confirmed by thermodynamic measurements and explained by an asymmetric shift of the dimer interface toward the occupied active site. Upon Trp binding, Asp68 propagates structural changes between subunits by switching its hydrogen bonding partner from dimer interface residue Tyr139 to active site residue Arg30. Since TrpRS IIs are resistant to inhibitors of standard TrpRSs, and pathogens contain drTrpRS II homologs, the structure of drTrpRS II provides a framework for the design of potentially useful antibiotics.     

Crystal structure of the tRNA 3' processing endoribonuclease tRNase Z from Thermotoga maritima

The maturation of the tRNA 3' end is catalyzed by a tRNA 3' processing endoribonuclease named tRNase Z (RNase Z or 3'-tRNase) in eukaryotes, Archaea, and some bacteria. The tRNase Z generally cuts the 3' extra sequence from the precursor tRNA after the discriminator nucleotide. In contrast, Thermotoga maritima tRNase Z cleaves the precursor tRNA precisely after the CCA sequence. In this study, we determined the crystal structure of T. maritima tRNase Z at 2.6-A resolution. The tRNase Z has a four-layer alphabeta/betaalpha sandwich fold, which is classified as a metallo-beta-lactamase fold, and forms a dimer. The active site is located at one edge of the beta-sandwich and is composed of conserved motifs. Based on the structure, we constructed a docking model with the tRNAs that suggests how tRNase Z may recognize the substrate tRNAs.     

COG4849 is a novel family of nucleotidyltransferases

Only a minority of currently known protein families is characterized structurally. This makes homology-based structure modeling an essential instrument that can be viewed as the first approximation to experimental determination of protein structure. Using sequence similarity searches, we detected a distant similarity between a family of uncharacterized hypothetical proteins, COG4849, and the family of tRNA nucleotidyltransferases. The suggested remote homology between the N-terminal domain of COG4849 and the catalytic domain of tRNA nucleotidyltransferase was further supported by comparison of sequence profiles, methods for fold recognition and structure modeling. The combined multiple alignment of the two families reveals shared conservation of functionally important motifs and suggests the similarity in catalytic mechanisms of the performed reactions. Our results suggest that (i) the N-terminal domain of proteins from COG4849 shares structural similarity with the catalytic domain of tRNA nucleotidyltransferase, and (ii) this domain catalyzes the nucleotidyl transfer reaction involving two metal ions.     

Substrate tRNA recognition mechanism of a multisite-specific tRNA methyltransferase, Aquifex aeolicus Trm1, based on the X-ray crystal structure

Archaeal and eukaryotic tRNA (N(2),N(2)-guanine)-dimethyltransferase (Trm1) produces N(2),N(2)-dimethylguanine at position 26 in tRNA. In contrast, Trm1 from Aquifex aeolicus, a hyper-thermophilic eubacterium, modifies G27 as well as G26. Here, a gel mobility shift assay revealed that the T-arm in tRNA is the binding site of A. aeolicus Trm1. To address the multisite specificity, we performed an x-ray crystal structure study. The overall structure of A. aeolicus Trm1 is similar to that of archaeal Trm1, although there is a zinc-cysteine cluster in the C-terminal domain of A. aeolicus Trm1. The N-terminal domain is a typical catalytic domain of S-adenosyl-l-methionine-dependent methyltransferases. On the basis of the crystal structure and amino acid sequence alignment, we prepared 30 mutant Trm1 proteins. These mutant proteins clarified residues important for S-adenosyl-l-methionine binding and enabled us to propose a hypothetical reaction mechanism. Furthermore, the tRNA-binding site was also elucidated by methyl transfer assay and gel mobility shift assay. The electrostatic potential surface models of A. aeolicus and archaeal Trm1 proteins demonstrated that the distribution of positive charges differs between the two proteins. We constructed a tRNA-docking model, in which the T-arm structure was placed onto the large area of positive charge, which is the expected tRNA-binding site, of A. aeolicus Trm1. In this model, the target G26 base can be placed near the catalytic pocket; however, the nucleotide at position 27 gains closer access to the pocket. Thus, this docking model introduces a rational explanation of the multisite specificity of A. aeolicus Trm1.     

Structure of crystalline Escherichia coli methionyl-tRNA(f)Met formyltransferase: comparison with glycinamide ribonucleotide formyltransferase.

Formylation of the methionyl moiety esterified to the 3' end of tRNA(f)Met is a key step in the targeting of initiator tRNA towards the translation start machinery in prokaryotes. Accordingly, the presence of methionyl-tRNA(f)Met formyltransferase (FMT), the enzyme responsible for this formylation, is necessary for the normal growth of Escherichia coli. The present work describes the structure of crystalline E.coli FMT at 2.0 A, resolution. The protein has an N-terminal domain containing a Rossmann fold. This domain closely resembles that of the glycinamide ribonucleotide formyltransferase (GARF), an enzyme which, like FMT, uses N-10 formyltetrahydrofolate as formyl donor. However, FMT can be distinguished from GARF by a flexible loop inserted within its Rossmann fold. In addition, FMT possesses a C-terminal domain with a beta-barrel reminiscent of an OB fold. This latter domain provides a positively charged side oriented towards the active site. Biochemical evidence is presented for the involvement of these two idiosyncratic regions (the flexible loop in the N-terminal domain, and the C-terminal domain) in the binding of the tRNA substrate.