Degradation and adsorption of synthetic DNA water tracers in environmental matrices

Liping Pang; Laura Heiligenthal; Aruni Premaratne; Kyrin R Hanning; Phillip Abraham; Richard Sutton; John Hadfield; Craig Billington

doi:10.1016/j.scitotenv.2022.157146

Degradation and adsorption of synthetic DNA water tracers in environmental matrices

Sci Total Environ. 2022 Oct 20:844:157146. doi: 10.1016/j.scitotenv.2022.157146. Epub 2022 Jul 4.

Authors

Liping Pang¹, Laura Heiligenthal², Aruni Premaratne², Kyrin R Hanning³, Phillip Abraham², Richard Sutton², John Hadfield⁴, Craig Billington²

Affiliations

¹ Institute of Environmental Science and Research, PO Box 29181, Christchurch 8540, New Zealand. Electronic address: liping.pang@esr.cri.nz.
² Institute of Environmental Science and Research, PO Box 29181, Christchurch 8540, New Zealand.
³ Institute of Environmental Science and Research, PO Box 29181, Christchurch 8540, New Zealand; School of Biological Sciences, University of Canterbury, Private Bag 4800, Christchurch 8140, New Zealand.
⁴ Waikato Regional Council, Private Bag 3038, Hamilton 3240, New Zealand.

PMID: 35798098
DOI: 10.1016/j.scitotenv.2022.157146

Abstract

Synthetic DNA tracers are gaining interest as tools for tracking contamination pathways and hydraulic connections in surface water and groundwater systems. However, few quantitative data exist that describe DNA tracer degradation and adsorption in environmental matrices. We undertook laboratory experiments to quantify the degradation of multiple double-stranded DNA tracers in stream water, groundwater, and domestic and dairy-shed effluent, and adsorption to stream sediments, soils, coastal sand aquifer media and alluvial sandy gravel aquifer media. Faster DNA tracer degradation seemed to be associated with high bacterial concentrations in the liquid phase. Overall, the degradation of the 352 base pair (bp) DNA tracers in the aqueous phase was significantly (P = 0.018) slower than that of the 302 bp DNA tracers. Although the tracers' internal amplicon lengths were similar, the longer non-amplified flanking regions of the 352 bp tracers may better protect them from environmental degradation. Thermodynamic analysis suggests that longer flanking regions contribute to greater tracer stability. This finding may explain our previous field observations that 352 bp tracer mass reductions were often lower than 302 bp tracer mass reductions. The 2 sets of DNA tracers did not differ significantly regarding their adsorption to stream sediment-stream water or aquifer media-groundwater mixtures (P > 0.067), but the 352 bp tracers showed significantly less adsorption to soil-effluent mixtures than the 302 bp tracers (P = 0.005). The DNA tracers' adsorption to soil-effluent mixtures was comparatively less than their adsorption to the aquifer media-groundwater and stream sediment-stream water mixtures, suggesting that DNA tracers may compete with like-charged organic matter for adsorption sites. These findings provide insights into the fate of DNA tracers in the environment. The DNA tracers' degradation rate constants determined in this study for a range of environmental conditions could assist the design of future field investigations.

Keywords: Adsorption; DNA tracer; Degradation; Fresh water; Porous media.

MeSH terms

Adsorption
DNA
Environmental Monitoring
Groundwater*
Soil
Water / analysis
Water Pollutants, Chemical* / analysis

Substances

Soil
Water Pollutants, Chemical
Water
DNA