Dependence of M1 RNA substrate specificity on magnesium ion concentration.

We have constructed a plasmid expressing E. coli M1 RNA, the catalytic RNA subunit of ribonuclease P, under the control of a phage T7 promoter. The active M1 RNA species synthesized in vitro by T7 RNA polymerase from this vector was reacted with the tRNA(Gln) - tRNA(Leu) precursor RNA (Band K) encoded by phage T4. Only the tRNA(Leu) moiety of this dimeric precursor RNA contains the 3' terminal C-C-A sequence common to all tRNAs. We observed that protein-free M1 RNA was capable of processing the precursor RNA at the 5' ends of both tRNA tRNA sequences. The rate of cleavage of the tRNA(Gln) sequence was more strongly dependent on [Mg2+] than that of tRNA(Leu), increasing severalfold between 100 and 500 mM Mg2+, conditions under which the rate of cleavage at the tRNA(Leu) sequence was constant.     

A "gain of function" mutation in a protein mediates production of novel modified nucleosides

The mutation sufY204 mediates suppression of a +1 frameshift mutation in the histidine operon of Salmonella enterica serovar Typhimurium and synthesis of two novel modified nucleosides in tRNA. The sufY204 mutation, which results in an amino-acid substitution in a protein, is, surprisingly, dominant over its wild-type allele and thus it is a "gain of function" mutation. One of the new nucleosides is 5-methylaminomethyl-2-thiouridine (mnm(5)s(2)U34) modified by addition of a C(10)H(17) side chain of unknown structure. Increased amounts of both nucleosides in tRNA are correlated to gene dosage of the sufY204 allele, to an increased efficiency of frameshift suppression, and to a decreased amount of the wobble nucleoside mnm(5)s(2)U34 in tRNA. Purified tRNA(Gln)(cmnm(5)s(2)UUG) in the mutant strain contains a modified nucleoside similar to the novel nucleosides and the level of aminoacylation of tRNA(Gln)(cmnm(5)s(2)UUG) was reduced to 26% compared to that found in the wild type (86%). The results are discussed in relation to the mechanism of reading frame maintenance and the evolution of modified nucleosides in tRNA.     

The synthesis and functional evaluation of RNA and DNA polymers having the sequence of Escherichia coli tRNA(fMet)

Stepwise, solid-phase chemical synthesis has provided long RNA and DNA polymers related to the sequence of Escherichia coli tRNA(fMet). The 34-ribonucleotide oligomer corresponding to the sequence of the 5'-half tRNA molecule has been synthesized and then characterized by gel purification, terminal nucleotide determinations and sequence analysis. This 34-nucleotide oligomer serves as an acceptor in the RNA-ligase-catalyzed reaction with a phosphorylated 43-ribonucleotide oligomer corresponding to the sequence of the 3'-half molecule of tRNA(fMet). The DNA molecule having the sequence of tRNA(fMet) is a 76-deoxyribonucleotide oligomer with a 3'-terminal riboadenosine residue and all U residues replaced by T. These polymers have been compared with an oligodeoxyribonucleotide lacking all 2'-hydroxyl groups except for the 3'-terminal 2'-OH, an oligoribonucleotide lacking modified nucleosides and E. coli tRNA(fMet). The all-RNA 77-nucleotide oligomer can be aminoacylated by E. coli methionyl-tRNA synthetase preparation from E. coli with methionine and threonylated in the A37 position using a yeast extract. In agreement with work by Khan and Roe using tDNA(Phe) and tDNA(Lys), the rA77-DNA(fMet) can be aminoacylated, and preliminary evidence suggests that it can be threonylated to a small extent. Kinetic data support the notion that aminoacylation of tRNA(fMet) does not depend on the presence of 2'-hydroxyl groups with the exception of that in the 3'-terminal nucleotide.     

Enzymatic tRNA acylation by acid and alpha-hydroxy acid analogues of amino acids

Incorporation of unnatural amino acids with unique chemical functionalities has proven to be a valuable tool for expansion of the functional repertoire and properties of proteins as well as for structure-function analysis. Incorporation of alpha-hydroxy acids (primary amino group is substituted with hydroxyl) leads to the synthesis of proteins with peptide bonds being substituted by ester bonds. Practical application of this modification is limited by the necessity to prepare corresponding acylated tRNA by chemical synthesis. We investigated the possibility of enzymatic incorporation of alpha-hydroxy acid and acid analogues (lacking amino group) of amino acids into tRNA using aminoacyl-tRNA synthetases (aaRSs). We studied direct acylation of tRNAs by alpha-hydroxy acid and acid analogues of amino acids and corresponding chemically synthesized analogues of aminoacyl-adenylates. Using adenylate analogues we were able to enzymatically acylate tRNA with amino acid analogues which were otherwise completely inactive in direct aminoacylation reaction, thus bypassing the natural mechanisms ensuring the selectivity of tRNA aminoacylation. Our results are the first demonstration that the use of synthetic aminoacyl-adenylates as substrates in tRNA aminoacylation reaction may provide a way for incorporation of unnatural amino acids into tRNA, and consequently into proteins.