Abstract
Spawning Pacific salmon (Oncorhynchus spp.) contribute marine-derived nutrients to riparian ecosystems, potentially affecting characteristics of the associated soils and vegetation. We quantified these effects by comparing soil and vegetative characteristics upstream and downstream of natural migratory barriers on ten spawning streams in southwest Alaska. Mean δ15N values—indicative of salmon-borne nutrients—were significantly higher in the O horizon and surface mineral soils downstream of barriers (near spawning reaches) than in soils upstream of barriers (near non-spawning reaches). However, the mean total N concentration in surface mineral soil was lower downstream than upstream. Mean foliar δ15N values were higher downstream for three plant species (Picea glauca, Salix alaxensis and Arctagrostis latifolia) with contrasting physiognomies. Mean overstory stem density was 100% higher downstream, primarily due to a fivefold difference in the density of large-diameter willows (Salix spp.). Mean understory stem density was 47% lower downstream, also driven by a difference in willow density. Mean ground layer non-vascular and dwarf shrub species covers were 28% and 73% lower downstream, respectively. Of the ten soil and vegetative characteristics that differed upstream to downstream, two (O horizon and Picea glauca δ15N) were correlated with the density of spawning salmon. Collectively, the data suggest that salmon-borne nutrients alter riparian soils and vegetation, while factors unrelated to salmon are responsible for the ultimate expression of many community characteristics.
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Acknowledgements
We thank R. E. Bilby, J. M. Helfield, D. L. Peterson, D. Zabowski and three anonymous reviewers for comments on the manuscript; S. Bartz for field assistance; University of Washington Alaska Program for logistical support; Katmai and Lake Clark National Parks for site access, and P. Knuckles, J. Branson and A. Bradford for facilitating access; R. Russell and W. Lew for advice on site selection; and M. Barker and G. Davies for advice on plant identification. Financial support was provided by the Keeler Endowment, the National Science Foundation (DEB 98-06575) and the University of Washington School of Aquatic and Fishery Sciences.
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Bartz, K.K., Naiman, R.J. Effects of Salmon-Borne Nutrients on Riparian Soils and Vegetation in Southwest Alaska. Ecosystems 8, 529–545 (2005). https://doi.org/10.1007/s10021-005-0064-z
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DOI: https://doi.org/10.1007/s10021-005-0064-z