A region of group I introns that contains universally conserved residues but is not essential for self-splicing.

The catalytic core of the self-splicing group I intron RNAs is composed of six paired regions together with their connecting sequences; these are thought to form two elongated domains, with paired regions P5, P4, and P6 aligned along one axis and P8, P3, and P7 along the other. Most of the very highly conserved residues of the group I introns lie in or near P7, but two occur in L4, the internal loop connecting P4 and P5. It is generally believed that such bases are conserved because they are essential for splicing. Mutants were created in a member of each of the two major subclasses of group I introns, in which P5, L4, and the distal portion of P4 were deleted. Splicing activity was still detected in these mutants, albeit substantially weakened; splicing was accurate and occurred by the normal group I mechanism, with addition of a guanosine molecule to the intron. Thus the deleted region, containing two universally conserved bases, is not essential but facilitates splicing. Another reaction characteristic of group I introns, hydrolysis of the 3' splice site, was less severely affected by the deletions. The results are discussed in terms of the prevailing three-dimensional model for the core structure of the group I introns.