RESUMEN
Ustiloxin B is a ribosomally synthesized and post-translationally modified peptide (RiPP) first reported in Ascomycetes. Its biosynthetic pathway was recently identified in the filamentous fungus Aspergillus flavus. The precursor protein of ustiloxin B, UstA, has a signal peptide to the endoplasmic reticulum at its N-terminal and a subsequent tandemly highly repeated segment cleaved at Lys-Arg dipeptides by Kex2 protease; such proteins are called Kex2-processed repeat proteins (KEPs). RiPP biosynthetic pathways using KEPs as precursor proteins are widely distributed in the Fungi kingdom, with high diversity of precursor protein sequences. UstA in A. flavus has a 16-fold tandemly repeated segment containing the core peptide Tyr-Ala-Ile-Gly, which forms the ustiloxin B backbone structure, but it is unknown why such a costly-to-maintain highly repeated sequence is retained. Here, we replaced ustA, the gene encoding the ustiloxin B precursor protein, with synthetic genes encoding 1-, 3-, 5-, 7-, and 11-fold tandem-repeat segments in A. flavus, to investigate the relationship between the repeat number and ustiloxin B production. Ustiloxin B production increased quadratically with increasing repeat number in ustA variants, although it dropped in a previously constructed ustA variant that had a substituted synthetic gene encoding a 16-fold repeat segment probably because of the presence of the many rare codons in the sequence. We also examined the transcript levels of substituted synthetic genes in ustA variants, and surprisingly we found that the transcript levels of the synthetic genes increased linearly with increasing repeat number. This result implies that an unknown mechanism stabilizes ustA transcripts via the highly repeated structure in a feedback manner. We also constructed a transformant without the intron in native ustA, but no effect of intron removal was observed on either ustiloxin B production or the precursor gene transcript level. The costly-to-maintain highly repeated sequence in KEPs probably serves the purpose of maintaining stable transcripts and thus increasing the amount of substrate.