The cellular translational machinery (TM) synthesizes proteins using exclusively L-or achiral aminoacyl-tRNAs (aa-tRNAs), despite the presence of D-amino acids in nature and their ability to be aminoacylated onto tRNAs by aa-tRNA synthetases. The ubiquity of L-amino acids in proteins has led to the hypothesis that D-amino acids are not substrates for the TM. Supporting this view, protein engineering efforts to incorporate D-amino acids into proteins using the TM have thus far been unsuccessful. Nonetheless, a mechanistic understanding of why D-aa-tRNAs are poor substrates for the TM is lacking. To address this deficiency, we have systematically tested the translation activity of D-aa-tRNAs using a series of biochemical assays. We find that the TM can effectively, albeit slowly, accept D-aa-tRNAs into the ribosomal aa-tRNA binding (A) site, use the A-site D-aa-tRNA as a peptidyl-transfer acceptor, and translocate the resulting peptidyl-D-aa-tRNA into the ribosomal peptidyl-tRNA binding (P) site. During the next round of continuous translation, however, we find that ribosomes carrying a P-site peptidyl-D-aatRNA partition into subpopulations that are either translationally arrested or that can continue translating. Consistent with its ability to arrest translation, chemical protection experiments and molecular dynamics simulations show that P site-bound peptidyl-D-aa-tRNA can trap the ribosomal peptidyl-transferase center in a conformation in which peptidyl transfer is impaired. Our results reveal a novel mechanism through which D-aa-tRNAs interfere with translation, provide insight into how the TM might be engineered to use D-aa-tRNAs, and increase our understanding of the physiological role of a widely distributed enzyme that clears D-aa-tRNAs from cells.A lthough the ribosome catalyzes protein synthesis using more than 20 chemically diverse natural amino acids, these natural amino acids are all of L-or achiral configurations. As a consequence, the ability of the ribosome to incorporate L-aminoacyltRNAs (L-aa-tRNAs) with both a high degree of speed and accuracy has been the focus of decades of intense mechanistic and structural investigations (1-3). In contrast, the response of the ribosome to D-aa-tRNAs has not been as well characterized. Nonetheless, a comprehensive mechanistic understanding of how the translational machinery (TM) responds to D-aa-tRNAs is of interest for several reasons. First, improved incorporation of D-amino acids by the TM would be useful for protein engineering applications that seek to use the synthetic power of the ribosome to create novel polymers (4) as well as for mechanistic applications that seek to probe protein structure and folding with unnatural amino acids (5). Second, there is growing evidence that ribosomes may have to contend with D-aa-tRNAs in vivo: D-amino acids are synthesized by racemase enzymes (6) and can be found at high concentrations in cells (7), and a growing number of aa-tRNA synthetase (aaRS) enzymes exhibit the ability to misacylate tRNAs with D-amino acids (8...
DNA catalysts (deoxyribozymes) for a variety of reactions have been identified by in vitro selection. However, for certain reactions this identification has not been achieved. One important example is DNA-catalyzed amide hydrolysis, for which a previous selection experiment instead led to DNA-catalyzed DNA phosphodiester hydrolysis. Subsequent efforts in which the selection strategy deliberately avoided phosphodiester hydrolysis led to DNA-catalyzed ester and aromatic amide hydrolysis, but aliphatic amide hydrolysis has been elusive. In the present study, we show that including modified nucleotides that bear protein-like functional groups (any one of primary amino, carboxyl, or primary hydroxyl) enables identification of amide-hydrolyzing deoxyribozymes. In one case, the same deoxyribozyme sequence without the modifications still retains substantial catalytic activity. Overall, these findings establish the utility of introducing protein-like functional groups into deoxyribozymes for identifying new catalytic function. The results also suggest the longer-term feasibility of deoxyribozymes as artificial proteases.
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