Conservation of substrate recognition mechanisms by tRNA splicing endonucleases.

Accuracy in transfer RNA (tRNA) splicing is essential for the formation of functional tRNAs, and hence for gene expression, in both Eukaryotes and Archaea. The specificity for recognition of the tRNA precursor (pre-tRNA) resides in the endonuclease, which removes the intron by making two independent endonucleolytic cleavages. Although the eukaryal and archaeal enzymes appear to use different features of pre-tRNAs to determine the sites of cleavage, analysis of hybrid pre-tRNA substrates containing eukaryal and archaeal sequences, described here, reveals that the eukaryal enzyme retains the ability to use the archaeal recognition signals. This result indicates that there may be a common ancestral mechanism for recognition of pre-tRNA by proteins.

The eucaryal tRNA splicing endonuclease recognizes a tripartite set of RNA elements.

The tRNA splicing endonuclease cleaves intron-containing tRNA precursors on both sides of the intron. The prevailing belief has been that the enzyme binds only to the mature domain through the invariant bases. We show instead that, for recognition, the endonuclease utilizes distinct sets of structural elements, several of which are within the intron. One subset of recognition elements, localized in the mature domain, is needed for recognition of both cleavage sites, while two other subsets, localized at the exon-intron boundaries, are used for recognition of either one or the other cleavage site. The two cleavage sites are essentially independent: neither is required by the other for cleavage to take place. These results support a two-active-site model for the eucaryal endonuclease.

In vitro genetic analysis of the structural features of the pre-tRNA required for determination of the 3' splice site in the intron excision reaction.

During processing of intron-containing pre-tRNAs, the Xenopus laevis splicing endonuclease binds the precursor and cleaves it at both the 5' and 3' splice sites. In vitro selection was used to determine structural features characteristic of precursor tRNA molecules that are active in this reaction. We performed two types of selection, one for molecules that are not cut, the other for molecules that are cut at only one site. The results shed light on various aspects of the intron excision reaction, including the importance of the three-dimensional structure of the mature domain for recognition and binding of the enzyme, the active role played by the single-stranded region of the intron, and the importance of the cardinal positions which, although not necessarily occupied by the same base in all precursors, nevertheless play a fundamental role in the splicing reaction. A precursor can be cut at the 3' site if a base in the single-stranded loop of the intron is allowed to pair (A-I pair) with the base of the 5' exon situated at the position immediately following the anticodon stem [first cardinal position (CP1)]. The nature of the bases involved in the A-I pair is important, as is the position of the base in the single-stranded loop of the intron. We discuss the role of the cardinal positions in the reaction.

Participation of the intron in the reaction catalyzed by the Xenopus tRNA splicing endonuclease.

Introns have generally been assumed to be passive in the transfer RNA splicing reaction. Experiments have now been done showing that the endonuclease is able to cut a precursor provided that a base in the single-stranded loop of the intron can pair with the base of the 5' exon situated at the position that immediately follows the anticodon stem (position 33 in the yeast tRNA isoacceptor pre-tRNA(Leu)3, position 32 in yeast pre-tRNA(Phe)). The elucidation of the role of the intron reveals that in addition to the conserved bases, there are positions in the mature domain which, although not necessarily occupied by the same base in all pre-tRNA's, nevertheless have a fundamental role in the splicing reaction. These positions are termed cardinal positions.