Activity of Desulfitobacterium sp.
Strain Viet1 Demonstrates
Bioavailability of 2,4-Dichlorophenol
Previously Sequestered by the
Aquatic Plant Lemna minor
posted on 2006-01-15, 00:00authored byJacqueline M. Tront, Benjamin K. Amos, Frank E. Löffler, F. Michael Saunders
Aquatic plants take up and sequester organic contaminants
such as chlorophenols through incorporation in cell
wall materials and storage in vacuoles. The ultimate fate
of plant-sequestered chlorophenols, however, remains
unclear. This research investigated 2,4-dichlorophenol (2,4-DCP) sequestration by the aquatic plant Lemna minor
and evaluated contaminant release and bioavailability after
plant death and cellular disruption. 14C-labeled 2,4-DCP
was used to establish that contaminant removed from the
aqueous phase was retained internal to L. minor. An
assay with Desulfitobacterium sp. strain Viet1 was used
to assess the readily bioavailable fraction of plant-sequestered
2,4-DCP and plant metabolites of 2,4-DCP. In plant-free
systems, strain Viet1 dechlorinated 2,4-DCP to stoichiometric
amounts of 4-chlorophenol (4-CP) as a stable and
quantifiable end product. Anaerobic microcosms containing
inactivated L. minor, which had accumulated 3.8 μmol of 2,4-DCP equivalents/g of plant material (fresh weight) during
a preceding aerobic exposure, were inoculated with strain
Viet1. After 118 d of incubation with strain Viet1, 43.5%
(±1.4%) of the contaminant was recovered as 4-CP, indicating
a large portion of plant-sequestered 2,4-DCP was
bioavailable for dechlorination by strain Viet1. In contrast,
4-CP formation was not observed in autoclaved microcosms,
and only 26.1% (±1.0%) of plant-sequestered 2,4-DCP was
recovered in the aqueous phase. These findings demonstrate
contaminant cycling between plants and microorganisms,
and emphasize that understanding the mechanisms and
pathways of contaminant sequestration by plants is critical
for predicting long-term contaminant fate.