Evolutionary insights into bilin biosynthesis: Functional characterization of pre-PcyA enzymes

Biosynthesis of the linear tetrapyrrole phycocyanobilin (PCB) by the ferredoxin-dependent bilin reductase (FDBRs) PcyA is essential for light-harvesting and regulatory processes in diverse photosynthetic organisms, yet its evolutionary origins are not fully understood. PcyA evolved from pre-PcyA proteins found in diverse bacteria. Three lineages of pre-PcyA proteins were identified: Pre-1, Pre-2 and Pre-3. Using an in vivo co-expression assay, Pre-2 and Pre-3 proteins were shown to be active FDBRs that did not synthesize PCB, whereas Pre-1 activity was apparently low. In refining these results, we noted a discrepancy between phycoerythrobilin populations generated by Pre-3 and by the distantly related FDBR PebS. We therefore examined the properties of pre-PcyA enzymes in vitro, using an updated pre-PcyA phylogeny to select an alternative pre-1 target. Biochemical analyses revealed that Pre-1 and Pre-2 catalyze the two-electron reduction of biliverdin (BV) to 3E-phytochromobilin (3E-P[FE]B), in contrast to the known synthesis of 3Z-phytobilins by other FDBRs. Pre-3 can also carry out an additional two-electron reduction to yield 3E-phycoerythrobilin (3E-PEB), again distinct from the 3Z-PEB produced by PebS. We then used comparative sequence and structure analysis to target candidate catalytic residues for site-directed mutagenesis. Variant Pre-1 exhibited altered product stereochemistry, but no effects on Pre-2 were observed and Pre-3 variants unexpectedly gained the ability to bind cyclic tetrapyrroles. These findings underscore the plasticity and promiscuity of this enzyme family. Together, this work illustrates how the flexible catalytic potential of ancestral enzymes shaped the evolution and diversification of bilin biosynthetic pathways.