X-ray structure of the orphan nuclear receptor RORbeta ligand-binding domain in the active conformation.

The retinoic acid-related orphan receptor beta (RORbeta) exhibits a highly restricted neuronal-specific expression pattern in brain, retina and pineal gland. So far, neither a natural RORbeta target gene nor a functional ligand have been identified, and the physiological role of the receptor is not well understood. We present the crystal structure of the ligand-binding domain (LBD) of RORbeta containing a bound stearate ligand and complexed with a coactivator peptide. In the crystal, the monomeric LBD adopts the canonical agonist-bound form. The fatty acid ligand-coactivator peptide combined action stabilizes the transcriptionally active conformation. The large ligand-binding pocket is strictly hydrophobic on the AF-2 side and more polar on the beta-sheet side where the carboxylate group of the ligand binds. Site-directed mutagenesis experiments validate the significance of the present structure. Homology modeling of the other isotypes will help to design isotype-selective agonists and antagonists that can be used to characterize the physiological functions of RORs. In addition, our crystallization strategy can be extended to other orphan nuclear receptors, providing a powerful tool to delineate their functions.

Structure of the fiber head of Ad3, a non-CAR-binding serotype of adenovirus.

Adenoviruses of serotype Ad3 (subgenus B) use a still-unknown host cell receptor for viral attachment, whereas viruses from all other known subgenera use the coxsackie and adenovirus receptor (CAR). The receptor binding domain (head) of the Ad3 fiber protein has been expressed in Escherichia coli inclusion bodies. After denaturation and renaturation using a rapid dilution method, crystals of trimeric head were obtained. The 1.6 A resolution X-ray structure shows a strict conservation of the beta-sheet scaffold of the protein very similar to the head structures of the CAR-binding serotypes Ad2, Ad5, and Ad12. The conformation of the loops is different, with the exception of the AB loop, which forms the center of the interface in the Ad12-CAR complex structure. The structure explains why a mutation in Ad5 of one residue in the AB loop to glutamic acid, as in Ad3, abrogates binding to CAR. It is possible that the Ad3 receptor binding site is nevertheless situated similar to the CAR binding site, although it cannot be excluded that other regions of the relatively hydrophobic head surface may be used.

Hierarchical assembly of the Alu domain of the mammalian signal recognition particle.

The mammalian signal recognition particle (SRP) catalytically promotes cotranslational translocation of signal sequence containing proteins across the endoplasmic reticulum membrane. While the S-domain of SRP binds the N-terminal signal sequence on the nascent polypeptide, the Alu domain of SRP temporarily interferes with the ribosomal elongation cycle until the translocation pore in the membrane is correctly engaged. Here we present biochemical and biophysical evidence for a hierarchical assembly pathway of the SRP Alu domain. The proteins SRP9 and SRP14 first heterodimerize and then initially bind to the Alu RNA 5' domain. This creates the binding site for the Alu RNA 3' domain. Alu RNA then undergoes a large conformational change with the flexibly linked 3' domain folding back by 180 degrees onto the 5' domain complex to form the final compact Alu ribonucleoprotein particle (Alu RNP). We discuss the possible mechanistic consequences of the likely reversibility of this final step with reference to translational regulation by the SRP Alu domain and with reference to the structurally similar Alu RNP retroposition intermediates derived from Alu elements in genomic DNA.

Evolutionary coadaptation of the motif 2--acceptor stem interaction in the class II prolyl-tRNA synthetase system.

Known crystal structures of class II aminoacyl-tRNA synthetases complexed to their cognate tRNAs reveal that critical acceptor stem contacts are made by the variable loop connecting the beta-strands of motif 2 located within the catalytic core of class II synthetases. To identify potential acceptor stem contacts made by Escherichia coli prolyl-tRNA synthetase (ProRS), an enzyme of unknown structure, we performed cysteine-scanning mutagenesis in the motif 2 loop. We identified an arginine residue (R144) that was essential for tRNA aminoacylation but played no role in amino acid activation. Cross-linking experiments confirmed that the end of the tRNA(Pro) acceptor stem is proximal to this motif 2 loop residue. Previous work had shown that the tRNA(Pro) acceptor stem elements A73 and G72 (both strictly conserved among bacteria) are important recognition elements for E. coli ProRS. We carried out atomic group "mutagenesis" studies at these two positions of E. coli tRNA(Pro) and determined that major groove functional groups at A73 and G72 are critical for recognition by ProRS. Human tRNA(Pro), which lacks these elements, is not aminoacylated by the bacterial enzyme. An analysis of chimeric tRNA(Pro) constructs showed that, in addition to A73 and G72, transplantation of the E. coli tRNA(Pro) D-domain was necessary and sufficient to convert the human tRNA into a substrate for the bacterial synthetase. In contrast to the bacterial system, base-specific acceptor stem recognition does not appear to be used by human ProRS. Alanine-scanning mutagenesis revealed that motif 2 loop residues are not critical for tRNA aminoacylation activity of the human enzyme. Taken together, our results illustrate how synthetases and tRNAs have coadapted to changes in protein-acceptor stem recognition through evolution.

Species-specific differences in the operational RNA code for aminoacylation of tRNAPro.

An operational RNA code relates amino acids to specific structural features located in tRNA acceptor stems. In contrast to the universal nature of the genetic code, the operational RNA code can vary in evolution due to coadaptations of the contacts between aminoacyl-tRNA synthetases and the acceptor stems of their cognate tRNA substrates. Here we demonstrate that, for class II prolyl-tRNA synthetase (ProRS), functional coadaptations have occurred in going from the bacterial to the human enzyme. Analysis of 20 ProRS sequences that cover all three taxonomic domains (bacteria, eucarya, and archaea) revealed that the sequences are divided into two evolutionarily distant groups. Aminoacylation assays showed that, while anticodon recognition has been maintained through evolution, significant changes in acceptor stem recognition have occurred. Whereas all tRNAPro sequences from bacteria strictly conserve A73 and C1.G72, all available cytoplasmic eukaryotic tRNAPro sequences have a C73 and a G1.C72 base pair. In contrast to the Escherichia coli synthetase, the human enzyme does not use these elements as major recognition determinants, since mutations at these positions have only small effects on cognate synthetase charging. Additionally, E. coli tRNAPro is a poor substrate for human ProRS, and the presence of the human anticodon-D stem biloop domain was necessary and sufficient to confer efficient aminoacylation by human ProRS on a chimeric tRNAPro containing the E. coli acceptor-TpsiC stem-loop domain. Our data suggest that the two ProRS groups may reflect coadaptations needed to accommodate changes in the operational RNA code for proline.

Mutational analysis of the active site of indoleglycerol phosphate synthase from Escherichia coli.

Indoleglycerol phosphate synthase catalyzes the ring closure of 1-(2-carboxyphenylamino)-1-deoxyribulose 5'-phosphate to indoleglycerol phosphate, the fifth step in the pathway of tryptophan biosynthesis from chorismate. Because chemical synthesis of indole derivatives from arylamino ketones requires drastic solvent conditions, it is interesting by what mechanism the enzyme catalyzes the same condensation reaction. Seven invariant polar residues in the active site of the enzyme from Escherichia coli have been mutated directly or randomly, to identify the catalytically essential ones. A strain of E. coli suitable for selecting and classifying active mutants by functional complementation was constructed by precise deletion of the trpC gene from the genome. Judged by growth rates of transformants on selective media, mutants with either S58 or S60 replaced by alanine were indistinguishable from the wild-type, but R186 replaced by alanine was still partially active. Saturation random mutagenesis of individual codons showed that E53 was partially replaceable by aspartate and cysteine, whereas K114, E163, and N184 could not be replaced by any other residue. Partially active mutant proteins were purified and their steady-state kinetic and inhibitor binding constants determined. Their relative catalytic efficiencies paralleled their relative complementation efficiencies. These results are compatible with the location of the essential residues in the active site of the enzyme and support a chemically plausible catalytic mechanism. It involves two enzyme-bound intermediates and general acid-base catalysis by K114 and E163 with the support of E53 and N184.

Chemical modification and site-directed mutagenesis of the single cysteine in motif 3 of class II Escherichia coli prolyl-tRNA synthetase.

Class II prolyl-tRNA synthetase (ProRS) from Escherichia coli contains all three of the conserved consensus motifs characteristic of class II aminoacyl-tRNA synthetases. In this study, chemical modification and site-directed mutagenesis of the single cysteine located at position 443 in motif 3 of Escherichia coli ProRS is carried out. We show that chemical modification of C443 blocks the ability of the enzyme to form the activated aminoacyl-adenylate, a prerequisite for tRNA(Pro) aminoacylation. Nearly complete protection from inactivation is achieved by preincubating the enzyme with ATP or ATP and proline, but not proline alone or tRNA(Pro). Mutagenesis of C443 to amino acids Ala, Gly, and Ser resulted in significant decreases (16-225-fold) in k(cat)/K(M)(Pro) as measured by the ATP-PP(i) exchange reaction. The Ala and Gly mutations have a relatively small effect (4-7-fold) on the overall aminoacylation reaction, while the activity of the C443S mutant in this same assay is substantially reduced (80-fold). A sequence comparison of the motif 3 region of class II synthetases shows that C443 aligns with residues that have been implicated in amino acid binding specificity. The results of our study suggest that while the thiol located at position 443 of Escherichia coli ProRS is not essential for catalysis, this residue is likely to be in a buried region that forms the prolyl-adenylate substrate binding pocket.

Deletion mutagenesis as a test of evolutionary relatedness of indoleglycerol phosphate synthase with other TIM barrel enzymes.

The role of the extra helix alpha zero in the N-terminal extension of the eight-fold beta alpha barrel of indoleglycerol phosphate synthase was probed by point mutation and truncation. Replacing invariant leucine 5 by valine of the enzyme from Escherichia coli affected neither kcat nor Km, but deletion of 8 N-terminal residues decreased solubility strongly. The similarly truncated variant from the hyperthermophile Sulfolobus solfataricus was soluble, and had the same kcat value as the wild-type protein but a 220-fold greater Km value. These results suggest that the N-terminal portion of helix alpha zero provides for strong binding of the substrate, but is not essential for stabilizing the bound transition state. Thus, three enzymes of tryptophan biosynthesis operate essentially as canonical eight-fold beta alpha barrels, as required for their divergent evolution.

Understanding species-specific differences in substrate recognition by Escherichia coli and human prolyl-tRNA synthetases.

Class II human prolyl-tRNA synthetase (ProRS) aminoacylates in vitro transcribed human tRNA(Pro) with kinetic parameters that are similar to those previously determined for aminoacylation of Escherichia coli tRNA(Pro) by its cognate synthetase. As in the bacterial system, large decreases in aminoacylation by human ProRS occur upon mutating anticodon positions G35 and G36 of human tRNA(Pro). The N73 'discriminator' base and the first and third base pairs of the acceptor stem vary between the E.coli and human isoacceptor groups. In contrast to the E. coli synthetase, the human enzyme does not appear to recognize these elements, since mutations at these positions do not significantly affect cognate synthetase charging. E. coli ProRS does not cross-aminoacylate human tRNA(Pro), and the bacterial tRNA(Pro) is a poor substrate for the human enzyme. Mutations in both the tRNAs and the synthetases have been made in an effort to identify elements in each system responsible for blocking cross-species aminoacylation. Alignment of all known ProRS primary sequences from different species reveals particularly low overall sequence homology, as well as two distinct groups of enzymes. The sequence divergence between E. coli and human ProRSs helps to explain the species-specific differences in the RNA code for aminoacylation of tRNA(Pro).

Use of semi-synthetic transfer RNAs to probe molecular recognition by Escherichia coli proline-tRNA synthetase.

BACKGROUND: The attachment of specific amino acids to the 3'-end of cognate transfer of RNAs (tRNAs) is catalyzed by a class of enzymes known as aminoacyl-tRNA synthetases (aaRS). We have previously demonstrated that Escherichia coli proline-tRNA synthetase (ProRS) can aminoacylate semi-synthetic tRNAs prepared by annealing two RNA oligonucleotides. We set out to examine the factors that are important in selective recognition of tRNAPro by ProRS, using semi-synthetic tRNAs and full-length tRNA transcripts. RESULTS: Deletion of nucleotides A58, A59, and U60 in the T psi C-loop of semi-synthetic tRNAs has no adverse effect on aminoacylation. Nucleotide deletions that extend into the T psi stem, particularly beyond C61, significantly reduce the efficiency of aminoacylation, however. Site-directed mutagenesis of full-length tRNAPro transcripts shows that, although there is no strict sequence requirement at base pair 52.62 in the T psi C stem, helix destabilizing purine-purine mismatches at this position result in decreased aminoacylation activity. Moreover, aminoacylation is severely affected when a DNA-RNA hybrid helix is incorporated into the acceptor-T psi C stem domain. CONCLUSIONS: At least three nucleotides in the T psi C-loop are dispensable for aminoacylation of E. coli tRNAPro. These results, combined with previous data, demonstrate that four out of five of the so-called 'variable pocket' nucleotides are not important for recognition of tRNAPro by E. coli ProRS. ProRS is also sensitive to changes that are likely to alter the helical conformation in the T psi C stem.

Molecular recognition of tRNA(Pro) by Escherichia coli proline-tRNA synthetase.

We have investigated the molecular recognition of tRNA(Pro) by Escherichia coli proline tRNA synthetase (ProRS) in vitro using semi-synthetic tRNAs and site-directed mutagenesis of full-length tRNA transcripts. These studies have led to an improved understanding of how this class II synthetase interacts with its tRNA substrate. The ability to efficiently aminoacylate a tRNA(Pro) molecule assembled by annealing together a shorter, chemically synthesized oligonucleotide and a 3/4 tRNA prepared enzymatically, has facilitated the identification of RNA structural features that are critical for aminoacylation by ProRS. This approach has been successful using either a 3'-3/4 tRNA annealed to a 5'-oligonucleotide or a 5'-3/4 tRNA annealed to a 3'-oligonucleotide. These studies show that ProRS appears to be particularly sensitive to mutations that result in structural changes in the core region of tRNA(Pro). Moreover, the so-called "variable pocket" nucleotides appear to be dispensable for aminoacylation. We have also identified a specific 2'-hydroxyl-base interaction between the ribose of U8 and the 2-amino group of G46 that makes a thermodynamically significant contribution to tRNA(Pro) aminoacylation by E. coli ProRS.