Fidelity escape by the unnatural amino acid ß-hydroxynorvaline: an efficient substrate for Escherichia coli threonyl-tRNA synthetase with toxic effects on growth.

In all living systems, the fidelity of translation is maintained in part by the editing mechanisms of aminoacyl-tRNA synthetases (ARSs). Some nonproteogenic amino acids, including ß-hydroxynorvaline (HNV) are nevertheless efficiently aminoacylated and become incorporated into proteins. To investigate the basis of HNV's ability to function in protein synthesis, the utilization of HNV by Escherichia coli threonyl-tRNA synthetase (ThrRS) was investigated through both in vitro functional experiments and bacterial growth studies. The measured specificity constant (k(cat)/K(M)) for HNV was found to be only 20-30-fold less than that of cognate threonine. The rate of aminoacyl transfer (10.4 s(-1)) was 10-fold higher than the multiple turnover k(cat) value (1 s(-1)), indicating that, as for cognate threonine, amino acid activation is likely to be the rate-limiting step. Like noncognate serine, HNV enhances the ATPase function of the synthetic site, at a rate not increased by nonaminoacylatable (3'-dA76) tRNA. ThrRS also failed to exhibit posttransfer editing activity against HNV. In growing bacteria, the addition of HNV dramatically suppressed growth rates, which indicates either negative phenotypic consequences associated with its incorporation into protein or inhibition of an unidentified metabolic reaction. The inability of wild ThrRS to prevent utilization of HNV as a substrate illustrates that, for at least one ARS, the naturally occurring enzyme lacks the capability to effectively discriminate against nonproteogenic amino acids that are not encountered under normal physiological conditions. Other examples of "fidelity escape" in the ARSs may serve as useful starting points in the design of ARSs with specificity for unnatural amino acids.

Aminoacyl transfer rate dictates choice of editing pathway in threonyl-tRNA synthetase.

Aminoacyl-tRNA synthetases hydrolyze aminoacyl adenylates and aminoacyl-tRNAs formed from near-cognate amino acids, thereby increasing translational fidelity. The contributions of pre- and post-transfer editing pathways to the fidelity of Escherichia coli threonyl-tRNA synthetase (ThrRS) were investigated by rapid kinetics. In the pre-steady state, asymmetric activation of cognate threonine and noncognate serine was observed in the active sites of dimeric ThrRS, with similar rates of activation. In the absence of tRNA, seryl-adenylate was hydrolyzed 29-fold faster by the ThrRS catalytic domain than threonyl-adenylate. The rate of seryl transfer to cognate tRNA was only 2-fold slower than threonine. Experiments comparing the rate of ATP consumption to the rate of aminoacyl-tRNA(AA) formation demonstrated that pre-transfer hydrolysis contributes to proofreading only when the rate of transfer is slowed significantly. Thus, the relative contributions of pre- and post-transfer editing in ThrRS are subject to modulation by the rate of aminoacyl transfer.

RNA-assisted catalysis in a protein enzyme: The 2'-hydroxyl of tRNA(Thr) A76 promotes aminoacylation by threonyl-tRNA synthetase.

Aminoacyl-tRNA synthetases (aaRSs) join amino acids to 1 of 2 terminal hydroxyl groups of their cognate tRNAs, thereby contributing to the overall fidelity of protein synthesis. In class II histidyl-tRNA synthetase (HisRS) the nonbridging S(p)-oxygen of the adenylate is a potential general base for aminoacyl transfer. To test for conservation of this mechanism in other aaRSs and the role of terminal hydroxyls of tRNA in aminoacyl transfer, we investigated the class II Escherichia coli threonyl-tRNA synthetase (ThrRS). As with other class II aaRSs, the rate-determining step for ThrRS is amino acid activation. In ThrRS, however, the 2'-OH of A76 of tRNA(Thr) and a conserved active-site histidine (His-309) collaborate to catalyze aminoacyl transfer by a mechanism distinct from HisRS. Conserved residues in the ThrRS active site were replaced with alanine, and then the resulting mutant proteins were analyzed by steady-state and rapid kinetics. Nearly all mutants preferentially affected the amino acid activation step, with only a modest effect on aminoacyl transfer. By contrast, H309A ThrRS decreased transfer 242-fold and imposed a kinetic block to CCA accommodation. His-309 hydrogen bonds to the 2'-OH of A76, and substitution of the latter by hydrogen or fluorine decreased aminoacyl transfer by 763- and 94-fold, respectively. The proton relay mechanism suggested by these data to promote aminoacylation is reminiscent of the NAD(+)-dependent mechanisms of alcohol dehydrogenases and sirtuins and the RNA-mediated catalysis of the ribosomal peptidyl transferase center.

iDRiP for the systematic discovery of proteins bound directly to noncoding RNA.

More than 90% of the human genome is transcribed into noncoding RNAs, but their functional characterization has lagged behind. A major bottleneck in the understanding of their functions and mechanisms has been a dearth of systematic methods for identifying interacting protein partners. There now exist several methods, including identification of direct RNA interacting proteins (iDRiP), chromatin isolation by RNA purification (ChIRP), and RNA antisense purification, each previously applied towards identifying a proteome for the prototype noncoding RNA, Xist. iDRiP has recently been modified to successfully identify proteomes for two additional noncoding RNAs of interest, TERRA and U1 RNA. Here we describe the modified protocol in detail, highlighting technical differences that facilitate capture of various noncoding RNAs. The protocol can be applied to short and long RNAs in both cultured cells and tissues, and requires ~1 week from start to finish. Here we also perform a comparative analysis between iDRiP and ChIRP. We obtain partially overlapping profiles, but find that iDRiP yields a greater number of specific proteins and fewer mitochondrial contaminants. With an increasing number of essential long noncoding RNAs being described, robust RNA-centric protein capture methods are critical for the probing of noncoding RNA function and mechanism.

Chromosomes. A comprehensive Xist interactome reveals cohesin repulsion and an RNA-directed chromosome conformation.

The inactive X chromosome (Xi) serves as a model to understand gene silencing on a global scale. Here, we perform "identification of direct RNA interacting proteins" (iDRiP) to isolate a comprehensive protein interactome for Xist, an RNA required for Xi silencing. We discover multiple classes of interactors-including cohesins, condensins, topoisomerases, RNA helicases, chromatin remodelers, and modifiers-that synergistically repress Xi transcription. Inhibiting two or three interactors destabilizes silencing. Although Xist attracts some interactors, it repels architectural factors. Xist evicts cohesins from the Xi and directs an Xi-specific chromosome conformation. Upon deleting Xist, the Xi acquires the cohesin-binding and chromosomal architecture of the active X. Our study unveils many layers of Xi repression and demonstrates a central role for RNA in the topological organization of mammalian chromosomes.

tRNA as an active chemical scaffold for diverse chemical transformations.

During protein synthesis, tRNA serves as the intermediary between cognate amino acids and their corresponding RNA trinucleotide codons. Aminoacyl-tRNA is also a biosynthetic precursor and amino acid donor for other macromolecules. AA-tRNAs allow transformations of acidic amino acids into their amide-containing counterparts, and seryl-tRNA(Ser) donates serine for antibiotic synthesis. Aminoacyl-tRNA is also used to cross-link peptidoglycan, to lysinylate the lipid bilayer, and to allow proteolytic turnover via the N-end rule. These alternative functions may signal the use of RNA in early evolution as both a biological scaffold and a catalyst to achieve a wide variety of chemical transformations.