ABSTRACT: Vitamins mediate a web of cross-feeding interactions in the human gut. Many Gram-positive gut microbes, in particular, are predicted to be vitamin auxotrophs. Previous studies of these microbes, however, have tended to use rich media, precluding controlled perturbations of low abundance nutrients. We tested the ability of diverse Lachnospiraceae, the most common Gram-positives in the gut, to grow on a chemically defined medium. Even though this medium contained riboflavin, we found that predicted riboflavin auxotrophs grew poorly, including the bile metabolizer Clostridium scindens. Riboflavin supplementation increased C. scindens final density in a concentration-dependent manner up to at least 200μM. Surprisingly, despite being an auxotroph, C. scindens also catabolized riboflavin into lumichrome. The only previously described catabolic pathway for riboflavin requires oxygen and has no homologs in C. scindens. In 200µM riboflavin, a single gene neighborhood with an aldolase, oxidoreductases, and a riboflavin kinase/adenylyltransferase was upregulated, suggesting an alternative anaerobic degradation or overflow pathway. Similar neighborhoods were detected in several other Lachnospiraceae, including Faecalicatena fissicatena, the only other anaerobe reported to degrade riboflavin. Reanalysis of published metabolomic data showed that in vivo, both riboflavin and lumichrome were more abundant in colonized (vs. germ-free) mouse ceca, and that in vitro, Lachnospiraceae isolates depleted riboflavin while certain Gram-negative isolates overproduced it. These results demonstrate that a member of the Lachnospiraceae can anaerobically convert an essential B vitamin into lumichrome, a molecule recently shown to have anti-inflammatory properties. Vitamin catabolism may both structure cross-feeding interactions in the gut and affect host health.