Processing of bacteriophage T4 tRNAs: an RNAase III- strain contains a precursor for tRNAG1n and tRNALeu

The ribonuclease-III-processing site near the 5' end of an RNA precursor of bacteriophage T4 and its effect on termination

Infection of RNase III- (rnc) Escherichia coli cells with bacteriophage T4 delta 27, a deletion mutant missing seven out of the ten genes in the tRNA transcription unit, results in the accumulation of a tRNA precursor (10.5-S RNA) that contains the sequences of tRNAGln, tRNALeu and species 1 RNA [Pragai and Apirion (1981) J. Mol. Biol. 153, 619-630]. In vitro studies, using partially purified RNase III or cell extracts and 10.5-S RNA as substrate, have revealed a cleavage site at the 5' side of the molecule. A computerized secondary structure suggests that the RNase III cleavage site can be placed in a small bulge which could be part of a duplex structure and is adjacent to A-A-G and its complementary sequence U-U-U in the same relative relationships found for most RNase III cleavage sites were the adjacent sequences are (A-A-G/U-U-C). Under normal processing conditions (presence of RNase III) the 3' end of the processed intermediate precursors, 10.1-S and p2Sp1 RNAs, is C-U-U-(U1-2)-UOH, which is determined by a stem and loop structure that could serve as a rho-independent termination signal site. However, in the absence of RNase III, the accumulated 10.5-S precursor RNA does not terminate at the same site and its 3' end is shifted a few nucleotides downstream. Thus, RNase III, besides playing a role in processing of 10.5-S RNA, also affects the termination of that molecule, even though both sites, the RNase III cleavage site and the termination site, are about 390 nucleotides apart.

Processing of tRNA in prokaryotes and eukaryotes

Considerable progress has been made in defining the steps in the conversion of a tRNA precursor to a mature tRNA. These steps, which differ in different systems, include removal of precursor-specific residues from the 5' and 3' termini of the initial transcript, addition of the 3'-C-C-A terminus, splicing of intervening sequences, and modification of nucleotide residues. Despite these advances in defining the "pathways" of tRNA processing, relatively little is known about most of the enzymes actually involved in these processing steps. In this article I describe the sequence of reactions needed to convert the initial tRNA transcript to a functional, mature tRNA, and discuss the specificity and properties of enzymes known to be involved in this process. In addition, I speculate on the expected specificities of other enzymes involved in tRNA processing which have not yet been identified, and on the structural organization of the processing machinery.

Processing of procaryotic ribonucleic acid

Images