posted on 2024-08-22, 15:12authored byNoor Hamdan, Carmen Villaruel, Matthew N. Newmeyer, Veronica Wallace, John R. Spear, James F. Ranville, Carsten Prasse
Water-based recreational activities
can impact freshwater
systems,
but the resulting anthropogenic alterations to the chemical and microbial
composition of natural streams remain poorly understood. Utilizing
state-of-the-art analytical approaches, including liquid chromatography-high-resolution
mass spectrometry (LC-HRMS), inductively coupled plasma mass spectrometry
(ICP-MS), and 16S rRNA gene sequencing, we investigated changes in
stream chemistry and microbiology resulting from recreational activities
in Clear Creek (Golden, Colorado). Spatial and temporal sampling was
conducted for 3 days over a summer holiday weekend when a large influx
of recreational float tubing activity occurred. Nontarget LC-HRMS
analysis demonstrated substantial differences in the organic fingerprint
on days and locations with high recreational use compared to that
of low use. Similarly, increases in the total suspended solids were
correlated with suspended particulate metal concentrations (Al, Cu,
Ti, Pb, and Zn). Element ratios suggest recreation-induced resuspension
of streambed sediments as the metal source rather than other anthropogenic
inputs (e.g., Ti/Zn-containing sunscreens). Gene sequencing revealed
significant shifts in the stream microbial community, supporting an
input of human-associated enteric microbiota during high recreation
periods. However, the overall results indicate that recreational activities
have a short-lived effect on the stream. In this work, we established
a first-of-its-kind holistic assessment of the impact of anthropogenic
activity on a natural stream by simultaneously considering changes
in the organic, inorganic, and microbial fingerprints.