Paralogous guanine deaminases likely acquired from bacteria by horizontal gene transfer promote purine homeostasis in Caenorhabditis elegans

Disruptions in purine metabolism contribute to a range of human diseases, from rare genetic disorders such as Lesch-Nyhan syndrome and xanthinuria to common conditions including gout and cancer. To better understand the metabolic networks that regulate purine homeostasis, we developed a Caenorhabditis elegans model of xanthine dehydrogenase (xdh-1) deficiency. Remarkably, xdh-1 mutant animals form rare xanthine stones, recapitulating a hallmark of human xanthinuria. To uncover genetic regulators of purine homeostasis, we performed a forward genetic screen for mutations that exacerbate xanthine stone formation in xdh-1 mutants. This approach identified multiple loss-of-function alleles in a previously uncharacterized gene, which we named gda-1. We show that gda-1 encodes an intestinal guanine deaminase that mediates a key enzymatic step in purine catabolism. The C. elegans genome also encodes a paralog, gda-2, which shares guanine deaminase activity but is expressed in distinct tissues. While gda-2 can compensate for gda-1 loss in guanine metabolism, the two genes exhibit non-redundant roles in regulating xanthine accumulation and stone formation. Interestingly, our evolutionary analyses suggest that gda-2 was acquired by nematodes via horizontal gene transfer from bacteria. These findings reveal a spatially regulated purine catabolism pathway in C. elegans and suggest that acquisition of bacterial genes has shaped a core nematode metabolic network.