Abstract
The small subunit of U2AF, which functions in 3′ splice site recognition, is more highly conserved than its heterodimeric partner yet is less thoroughly investigated. Remarkably, we find that the small subunit of Schizosaccharomyces pombe U2AF (U2AFSM) can be replaced in vivo by its human counterpart, demonstrating that the conservation extends to function. Precursor mRNAs accumulate in S. pombe following U2AFSM depletion in a time frame consistent with a role in splicing. A comprehensive mutational analysis reveals that all three conserved domains are required for viability. Notably, however, a tryptophan in the pseudo-RNA recognition motif implicated in a key contact with the large subunit by crystallographic data is dispensable whereas amino acids implicated in RNA recognition are critical. Mutagenesis of the two zinc-binding domains demonstrates that they are neither equivalent nor redundant. Finally, two- and three-hybrid analyses indicate that mutations with effects on large-subunit interactions are rare whereas virtually all alleles tested diminished RNA binding by the heterodimer. In addition to demonstrating extraordinary conservation of U2AF small-subunit function, these results provide new insights into the roles of individual domains and residues.
We thank Joseph Bokar, James Bruzik, and John Woolford for materials and Nicole Sample for expert technical assistance. We are grateful to Jonatha Gott, Michael Harris, Hua Lou, David McPheeters, Helen Salz, and members of our laboratory for critical comments on the manuscript.
This research was supported by a grant to J.A.W. from the National Institutes of Health.