Parallel structural evolution of auxin response factors in the angiosperms.

Here we analyze the structural evolution of the paralogous transcription factors ETTIN (ETT/ARF3) and AUXIN RESPONSE FACTOR 4 (ARF4), which control the development of floral organs and leaves in the model angiosperm Arabidopsis. ETT is truncated at its C terminus, and consequently lacks two regulatory domains present in most other ARFs, including ARF4. Our analysis indicates ETT and ARF4 to have been generated by the duplication of a non-truncated ARF gene prior to the radiation of the extant angiosperms. We furthermore show that either ETT or ARF4 orthologs have become modified to encode truncated ARF proteins, lacking C-terminal regulatory domains, in representatives of three groups that separated early in angiosperm evolution: Amborellales, Nymphaeales and the remaining angiosperm clade. Interestingly, the production of truncated ARF4 transcripts in Amborellales occurs through an alternative splicing mechanism, rather than through a permanent truncation, as in the other groups studied. To gain insight into the potential functional significance of truncations to ETT and ARF4, we tested the capacity of native, truncated and chimeric coding sequences of these genes to restore a wild-type phenotype to Arabidopsis ett mutants. We discuss the results of this analysis in the context of the structural evolution of ARF genes in the angiosperms.

A role for the Psi-U mismatch in the recognition of the 5' splice site of yeast introns by the U1 small nuclear ribonucleoprotein particle.

The U1 small nuclear ribonucleoprotein particle (snRNP)/5' splice site (5'SS) interaction in yeast is essential for the splicing process and depends on the formation of a short RNA duplex between the 5' arm of U1 snRNA and the 1st intronic nucleotides. This RNA/RNA interaction is characterized by the presence of a mismatch that occurs with almost all yeast introns and concerns nucleotides 4 on the pre-mRNA (a U) and 5 on U1 snRNA (a Psi). The latter nucleotide is well conserved from yeast to vertebrates, but its role in yeast and the significance of the associated mismatch in the U1 snRNA/5'SS interaction have never been fully explained. We report here that the presence of this mismatch is a determinant of stability that mainly affects the off rate of the interaction. To our knowledge this is the first report assigning a function to this noncanonical interaction. We also performed SELEX (systematic evolution of ligands by exponential enrichment) experiments by immunoprecipitating U1 snRNP and the associated RNA. The artificial phylogeny derived from these experiments allows the isolation of the selective pressure due to U1 snRNP binding on the 5'SS of yeast introns.