Burkholderia vietnamiensis Genes Involved in Extracellular Medium-Chain-Length Polyhydroxyalkanoate Degradation

Bioplastics represent promising alternatives to petroleum-based plastics, yet their biodegradation remains insufficiently understood. Identifying bacteria capable of degrading bioplastics extracellularly could enhance end-of-life management practices. To investigate Burkholderia ’s capacities for the degradation of medium-chain-length polyhydroxyalkanoate (mcl-PHA), we screened a panel of Burkholderia strains and identified such capacity in strains of B. gladioli , B. multivorans, and B. vietnamiensis . To elucidate the genetic basis of this activity, we performed transposon mutagenesis followed by activity-based screening and Tn-seq on B. vietnamiensis LMG 16232. Disrupted genetic elements in transposon mutants with negative phenotypes were further investigated using a CRISPR-associated transposase (CAST) system. These included a lipase production gene cluster, encoding two putative triacylglycerol lipases and a chaperone, and genes coding for a a A24 family peptidase, a TetR/AcrR family transcriptional regulator and a type II secretion system (T2SS) protein. Complete loss or reduced extracellular mcl-PHA depolymerase activity was observed in the CAST mutants, validating their involvement in mcl-PHA degradation. Notably, only one of the two lipases encoded in the lipase production gene cluster was responsible for mcl-PHA degradation, suggesting that while lipases may show substrate promiscuity, lipase functional annotation does not necessarily imply mcl-PHA depolymerization. Docking experiments using the amino acid sequences of the two lipases supported these findings. Together, we identify a gene coding for an active mcl-PHA depolymerase in B. vietnamiensis and demonstrate the power of combining activity-based screening, Tn-seq, and CAST to rapidly establish gene-to-function links.