Bacterial Metabolites and Particle Size Determine Cerium Oxide Nanomaterial Biotransformation

Environ Sci Technol. 2022 Dec 6;56(23):16838-16847. doi: 10.1021/acs.est.2c05280. Epub 2022 Nov 9.

Abstract

Soil is a major receptor of manufactured nanomaterials (NMs) following unintentional releases or intentional uses. Ceria NMs have been shown to undergo biotransformation in plant and soil organisms with a partial Ce(IV) reduction into Ce(III), but the influence of environmentally widespread soil bacteria is poorly understood. We used high-energy resolution fluorescence-detected X-ray absorption spectroscopy (HERFD-XAS) with an unprecedented detection limit to assess Ce speciation in a model soil bacterium (Pseudomonas brassicacearum) exposed to CeO2 NMs of different sizes and shapes. The findings revealed that the CeO2 NM's size drives the biotransformation process. No biotransformation was observed for the 31 nm CeO2 NMs, contrary to 7 and 4 nm CeO2 NMs, with a Ce reduction of 64 ± 14% and 70 ± 15%, respectively. This major reduction appeared quickly, from the early exponential bacterial growth phase. Environmentally relevant organic acid metabolites secreted by Pseudomonas, especially in the rhizosphere, were investigated. The 2-keto-gluconic and citric acid metabolites alone were able to induce a significant reduction in 4 nm CeO2 NMs. The high biotransformation measured for <7 nm NMs would affect the fate of Ce in the soil and biota.

Keywords: CeO2; Pseudomonas; X-ray absorption spectroscopy; biotransformation; metabolite; nanoparticle; organic acids; peak fitting.

Publication types

  • Research Support, Non-U.S. Gov't

MeSH terms

  • Bacteria
  • Cerium* / chemistry
  • Metal Nanoparticles* / chemistry
  • Nanostructures*
  • Particle Size
  • Soil / chemistry

Substances

  • ceric oxide
  • Cerium
  • Soil