Identification of dehydrogenase, hydratase, and aldolase responsible for the propionyl residue removal in degradation of cholic acid C-17 side chain inTA441.

Bacterial steroid degradation is gaining attention for its diverse roles, such as's reliance on the degradation of the C17 side chain of cholesterol for survival in host environments. ORF40-44 ofTA441, previously characterized for its A-, B-, C-, and D-ring cleavage pathways, were hypothesized to correspond to theoperon of, encoding the dehydrogenase ChsE1E2, hydratase ChsH1H2, and aldolase Ltp2 ChsH2, responsible for propionyl residue removal in the degradation of the cholic acid C17 side chain. However, low amino acid identity between the corresponding enzymes precluded functional assignment without experimental evidence. In this study, we generated gene-disrupted mutants of ORF40-44 and demonstrated that ORF41/ORF44, ORF40/ORF42, and ORF43 encode the dehydrogenase, hydratase, and aldolase, respectively. ORF40 encodes a bifunctional protein comprising MaoC and DUF35 domains. The MaoC domain of ORF40 and the ORF42-encoded protein form the hydratase, while the DUF35 domain is essential for aldolase activity. A mutant expressing ORF40and ORF40separately exhibited both hydratase and aldolase activities, suggesting these activities do not require a strictly formed complex of hydratase and aldolase. However, efficient propionyl residue removal appears to depend on the proper formation of each enzymatic complex, including ChsE1E2, ChsH1H2, and Ltp2ChsH2. Although (ChsE1-ChsE2)does not form a stable complex with (ChsH1-ChsH2)-(Ltp2-ChsH2), some degree of interaction was suggested. AlphaFold-predicted three-dimensional structures of the TA441 enzymes and their complexes revealed striking similarities to those of, despite low amino acid identities. These findings shed light on the structural and functional conservation of bacterial steroid-degrading enzymes.IMPORTANCEResearch on bacterial steroid degradation began over 50 years ago, primarily to produce substrates for steroid drugs. Recently, the role of steroid-degrading bacteria in human health has garnered increasing attention.TA441 is a prominent model organism for studying aerobic steroid degradation, with its overall pathways for A-, B-, C-, and D-ring cleavage already elucidated. In this study, we identified the mechanism for removing the propionyl residue in the degradation of the cholic acid C17 side chain, a crucial step in degrading steroids with a C17 side chain, such as cholic acid, cholesterol, and other biologically significant compounds in animals and plants. The functions and structures of the identified enzymes show remarkable similarity to those in. These findings suggest that insights gained from TA441 could provide valuable clues for understandingsteroid metabolism and the broader ecological and health-related implications of bacterial steroid degradation.