Pulcherriminic acid biosynthesis and Transport: Insights from a heterologous system in Saccharomyces cerevisiae

Pulcherriminic acid is an iron chelator produced by some Kluyveromyces and Metschnikowia yeasts. Its biosynthesis is encoded by the four–gene PUL cluster, where PUL1 and PUL2 are the biosynthetic enzymes, PUL3 mediates the uptake of iron–bound pulcherrimin, and PUL4 is a putative regulator.

Pulcherriminic acid holds antifungal potential, as the growth of organisms unable to uptake pulcherrimin is inhibited by deficit of essential iron. Thus, a heterologous production system to further characterize and optimize its biosynthesis would be valuable.

Using our in–house yeast collection and genomes available in databases, we cloned PUL1 and PUL2 genes from K. lactis and one of our wild Metschnikowia isolates and built an effective production system in S. cerevisiae able to inhibit pathogenic growth. In this context, the K. lactis genes yielded faster pulcherriminic acid production than those from the Metschnikowia isolate and a combinatorial approach showed PUL1 to be the production bottleneck.

We further showed that Pul3 is an importer of pulcherrimin, but also mediates the export of pulcherriminic acid and that the growth of pathogens like Candidozyma auris and organisms encoding PUL3 in their genome, previously called “cheaters”, is inhibited by pulcherriminic acid, highlighting its potential as an antimicrobial agent.