AI Article Synopsis
- Benzene degradation under anoxic conditions has been studied for over 25 years, but the activation mechanism remains unclear due to challenges in cultivating anaerobic benzene-degrading cultures.
- Our lab has maintained a slow-growing methanogenic enrichment culture named ORM2, which is a unique benzene fermenter related to other known degraders, but it has a long doubling time and lag phase.
- We created a FISH probe to visualize ORM2 cells, discovering they cluster with methanogens and may produce substances that promote aggregation; higher benzene concentrations seem to hinder this aggregation, shedding light on the community dynamics to improve ORM2's growth rate.
Article Abstract
Benzene degradation under anoxic conditions was first reported more than 25 years ago; however, the activation mechanism in the absence of oxygen remains elusive. Progress has been hindered by the difficulty in cultivating anaerobic benzene-degrading enrichment cultures. Our laboratory has sustained a methanogenic enrichment culture harboring ORM2, a benzene fermenter distinct from any known genus but related to other known or predicted benzene degraders. ORM2's slow doubling time (∼30 days) and extended lag phase after inoculation complicate its study. We developed a fluorescent in situ hybridization (FISH) probe for ORM2, revealing rod-shaped cells of variable length that tend to cluster with other organisms, particularly methanogens. Microscopy and genomic evidence suggest that ORM2 may produce extracellular polymeric substances, facilitating cell aggregation and possibly consuming energy that contributes to the lag phase. Interestingly, higher benzene concentrations (90-120 mg/L) appeared to reduce cell aggregation. This study visualized the cells of ORM2 within a methanogenic community, offering insights into spatial organization and potential strategies to enhance its growth rate.
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Article Synopsis
- Benzene degradation under anoxic conditions has been studied for over 25 years, but the activation mechanism remains unclear due to challenges in cultivating anaerobic benzene-degrading cultures.
- Our lab has maintained a slow-growing methanogenic enrichment culture named ORM2, which is a unique benzene fermenter related to other known degraders, but it has a long doubling time and lag phase.
- We created a FISH probe to visualize ORM2 cells, discovering they cluster with methanogens and may produce substances that promote aggregation; higher benzene concentrations seem to hinder this aggregation, shedding light on the community dynamics to improve ORM2's growth rate.
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