Christian Jacoby, Kaylie Scorza, Lia Ecker, Paola Nol Bernardino, Alexander S Little, Mary McMillin, Ramanujam Ramaswamy, Anitha Sundararajan, Ashley M Sidebottom, Huaiying Lin, Keith Dufault-Thompson, Brantley Hall, Xiaofang Jiang, Samuel H Light
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Abstract
Steroid hormone metabolism by the gut microbiome affects host physiology, however, the underlying microbial pathways remain incompletely understood. Here, we isolate a gut bacterial species, which we designate Clostridium steroidoreducens, that reduces cortisol and related steroid hormones to 3β,5β-tetrahydrosteroid products. Through transcriptomics and enzymatic discovery, we establish the C. steroidoreducens OsrABC steroid hormone pathway. OsrA is a 3-oxo-Δ1-steroid hormone reductase that targets synthetic glucocorticoids, including prednisolone-a frontline Crohn's disease therapy. OsrB is a 3-oxo-Δ⁴-steroid reductase that converts steroid hormones to 5β-dihydrosteroid intermediates, which OsrC subsequently reduces to 3β,5β-tetrahydro products. Homologs of osrA and osrB predict steroid-reducing activity across gut bacteria and are enriched in metagenomes of Crohn's disease patients. Consistent with a role in modulating drug efficacy, C. steroidoreducens colonization decreases prednisolone bioavailability in gnotobiotic mice. These findings thus define a previously unrecognized pathway for microbial steroid hormone inactivation and establish a mechanistic basis for bacterial interference with anti-inflammatory therapies.
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