Abstract

Larval aquatic insects are used to assess water quality, but less attention is paid to their adult, terrestrial life stage, which is an important food resource for declining aerial insectivorous birds. We used open-access water-quality, aquatic-invertebrate, and bird-survey data to study how impaired water quality can emanate from streams and lakes through changes in aquatic insect communities across the contiguous United States. Emergent insect relative abundance was highest across the West, in northern New England, and the Carolinas in streams, and highest near the Great Lakes, parts of the Southwest, and northern New England for lakes. Emergent insects declined with sedimentation, roads, and elevated ammonium concentrations in streams, but not lakes. The odds that a given taxon would be non-emergent increased by up to 2.0× as a function of pollution tolerance, underscoring the sensitivity of emergent aquatic insects to water-quality impairment. However, relationships between bird populations and emergent insects were generally weak for both streams and lakes. For streams, we observed the strongest positive relationships for a mixture of upland and riparian aerial insectivorous birds such as Western Wood-Pewee, Olive-sided Flycatcher, and Acadian Flycatcher and the strongest negative association for Purple Martin. Different avian insectivores responded to emergent insect abundances in lakes (e.g., Barn Swallow, Chimney Swift, Eastern Wood-Pewee, Common Nighthawk). In both streams and lakes, we observed stronger, but opposing, relationships between several aerial insectivores and the relative abundance of sensitive insect orders (E)phemeroptera, (P)lecoptera, and (T)richoptera (positive), and pollution tolerant individuals (negative). Overall, our findings indicate that emergent insects are negatively correlated with pollution tolerance, suggesting a large-scale loss of this nutritional subsidy to terrestrial environments from impaired aquatic ecosystems. While some bird populations tracked scarcities of emergent aquatic insects, especially EPT taxa, responses varied among species, suggesting that unique habitat and foraging behaviors likely complicated these relationships. Strengthening spatial and temporal concordance between emergent-insect and bird-survey data will improve our ability to interpret species-level responses over time. Thus, our analysis highlights the need for developing conservation and biomonitoring strategies that consider the cross-ecosystem effects of water quality declines for threatened insectivorous avifauna and other terrestrial wildlife.

Highlights

  • The health of aquatic ecosystems is strongly influenced by their surrounding landscape—a foundational idea for our current understanding of streams and lakes that is often applied to the conservation and management of these ecosystems in the United States (e.g., Hynes, 1975; Wohl, 2017; Sullivan et al, 2019)

  • We found a similar pattern for invertebrates sampled from lakes, where the odds of a given taxa exhibiting non-emergence increased by 2.01× per unit increase in pollution tolerance value

  • We show at the scale of the contiguous US, the impacts of land use and water quality were related to reduced relative abundances of emergent insects

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Summary

Introduction

The health of aquatic ecosystems is strongly influenced by their surrounding landscape—a foundational idea for our current understanding of streams and lakes that is often applied to the conservation and management of these ecosystems in the United States (e.g., Hynes, 1975; Wohl, 2017; Sullivan et al, 2019). Recent biological assessments of wadeable streams and lakes conducted by the US Environmental Protection Agency (EPA; National Aquatic Resource Surveys) suggest that 46% of streams surveyed were in “poor” condition (US EPA, 2016), and 57% of lakes surveyed were considered “moderately” to “most” disturbed (US EPA, 2017). These condition assessments were based on well established, multimetric indices of benthic macroinvertebrates living within the stream or in the littoral (near-shore) zone of lakes; such indices are widely recognized for their utility as integrative measures of detrimental human activities that affect the health of receiving waters in the landto-water direction. The reciprocal, water-to-land effects of poor water quality on adjacent terrestrial (riparian) habitats has only recently begun to gain traction as an important conservation paradigm that recognizes how aquatic-to-terrestrial ecological linkages are critical for the functioning of both aquatic and adjacent riparian systems (Walters et al, 2008; Kraus et al, 2014; Sullivan and Manning, 2019)

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