Direct genome-scale screening of Gluconobacter oxydans B58 for rare earth element bioleaching

Direct genome-scale screening of Gluconobacter oxydans B58 for rare earth element bioleaching

Abstract The transition to a sustainable energy economy will require an enormous increase in the supply of rare earth elements (REEs). Bioleaching offers a promising alternative to conventional hydrometallurgical methods for REE extraction from low-grade ores. However, exploiting this potential rema...

Full description

Saved in:
Bibliographic Details
Main Authors: Sabrina Marecos, Brooke Pian, Sean A. Medin, Alexa Schmitz, Melinna Andrade, Mingming Wu, J. Brian Balta, Esteban Gazel, Megan Holycross, Matthew C. Reid, Buz Barstow
Format: Article
Language:English
Published: Nature Portfolio 2025-04-01
Series:Communications Biology
Online Access:https://doi.org/10.1038/s42003-025-08061-4
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Abstract The transition to a sustainable energy economy will require an enormous increase in the supply of rare earth elements (REEs). Bioleaching offers a promising alternative to conventional hydrometallurgical methods for REE extraction from low-grade ores. However, exploiting this potential remains challenging due to large gaps in our understanding of the genetics involved, and inadequate biological tools to address them. We generated a highly non-redundant whole-genome knockout collection for the bioleaching microbe Gluconobacter oxydans B58, reducing redundancy by 85% compared to the previous best collection. This new collection was directly screened for bioleaching neodymium from a synthetic monazite powder, identifying 89 genes important for bioleaching, 68 of which have not previously been associated with this mechanism. We conducted bench-scale experiments to validate the extraction efficiency of promising strains: 8 demonstrated significant increases in extraction by up to 111% (δGO_1598, disruption of the gene encoding the orotate phosphoribosyltransferase enzyme PyrE), and one strain significantly reduced it by 97% (δGO_1096, disruption of the gene encoding the GTP-binding protein TypA). Notable changes in pH were only observed for 3 strains, suggesting an important role for non-acid mechanisms in bioleaching. These findings provide valuable insights into further enhancing REE-bioleaching by G. oxydans through genetic engineering.
ISSN:2399-3642

Similar Items