2020
DOI: 10.1111/eff.12537
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An experimental study to evaluate predation threats on two native larval lampreys in the Columbia River Basin, USA

Abstract: Experimental predation studies were conducted to evaluate and compare the predation threats of 10 species of native and non‐native fishes on larvae of Pacific Lamprey, Entosphenus tridentatus, and Western Brook Lamprey, Lampetra richardsoni. The relative predatory threats were examined over four sets of binary factors, including the following: (a) short (2‐day) or long (7‐day) duration, (b) presence/absence of fine sediment, (c) live or dead larvae and (d) species of lampreys. Our short‐term results showed a p… Show more

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Cited by 16 publications
(16 citation statements)
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“…Our laboratory results suggest the observed changes in distribution and abundance at Leaburg Reservoir were at least partially due to mortality associated with dewatering. However, changes in distribution and abundance may also result from predation (Arakawa & Lampman, 2020; Beamish, 1980; Merrell, 1959), larval emergence and re‐burrowing elsewhere within the study area (i.e., individuals could re‐burrow in areas not yet dewatered), and escapement to watered habitat outside the study area (Liedtke et al, 2015). Regardless of larval fate, our research indicates dewatering can have substantial effects on abundance and spatial distribution of larval lampreys in freshwater habitats.…”
Section: Discussionmentioning
confidence: 99%
“…Our laboratory results suggest the observed changes in distribution and abundance at Leaburg Reservoir were at least partially due to mortality associated with dewatering. However, changes in distribution and abundance may also result from predation (Arakawa & Lampman, 2020; Beamish, 1980; Merrell, 1959), larval emergence and re‐burrowing elsewhere within the study area (i.e., individuals could re‐burrow in areas not yet dewatered), and escapement to watered habitat outside the study area (Liedtke et al, 2015). Regardless of larval fate, our research indicates dewatering can have substantial effects on abundance and spatial distribution of larval lampreys in freshwater habitats.…”
Section: Discussionmentioning
confidence: 99%
“…Each of the groups of predator fishes were tested separately and held with eight larvae per predator fish for either two or seven nights (short-and long-term studies). The short-term studies took place between December 5, 2016 and February 15, 2017 552 and the long-term studies took place between December 28, 2016 and February 20, 2017 (see Arakawa and Lampman 2020).…”
Section: Methodsmentioning
confidence: 99%
“…Hence, the true numbers of larval/juvenile lampreys contained in the stomach of predator fishes may be substantially underestimated due to their rapid degradation in the predators' stomach. Lampreys in the digestive system of predators are often fully digested and decomposed prior to stomach content analysis, making ID to genus or life stage (larval versus juvenile) extremely difficult (Schultz et al 2017;Arakawa and Lampman 2020).…”
mentioning
confidence: 99%
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“…After identifying PBH in the Umpqua River network, we assessed the potential overlap of PBH with water temperatures suitable for Smallmouth Bass Micropterus dolomieu , a nonnative predator. Lamprey larvae moving to find suitable burrowing habitat (Smith et al 2012) and lamprey transformers and juveniles migrating downstream may be consumed by Smallmouth Bass (Schultz et al 2017) and other nonnative warmwater species, such as Largemouth Bass M. salmoides (Arakawa and Lampman 2020), Bluegill Lepomis macrochirus , and Brown Bullhead Ameiurus nebulosus . Smallmouth Bass was introduced to the basin in 1964 (Simon and Markle 1999) and is now found throughout the Umpqua River basin and lower portions on most tributaries (Simon 2008).…”
Section: Figurementioning
confidence: 99%