Toward a more comprehensive theory of zooplankton diel vertical migration: Integrating ultraviolet radiation and water transparency into the biotic paradigm

Williamson, Craig E.; Fischer, Janet M.; Bollens, Stephen M.; Overholt, Erin P.; Breckenridge, Joanne K.

doi:10.4319/lo.2011.56.5.1603

Cited by 186 publications

(219 citation statements)

References 241 publications

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“…Hence, it is highly probable that it is beneficial for the snails to be plastic in mantle pigmentation and that this plasticity may be adaptive. While photoprotective pigmentation can counteract the negative effects of UVR [6,7], it can also be used as camouflage [9,10]. An inducible morphological defence can increase a prey's chance of escaping an attack [19]; in this case, pigmentation linked to camouflage may decrease predation rate by reducing encounter rates with predators [10].…”

Section: Discussionmentioning

confidence: 99%

“…High levels of UVR have severe consequences for organisms, including effects on growth, behaviour and DNA damage [3,4]. However, the ability to induce photoprotective pigmentation can counteract the negative effects of UVR [5][6][7]. Risk of predation is another environmental threat that may affect the level of pigmentation individuals express.…”

Section: Introductionmentioning

confidence: 99%

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Camouflaged or tanned: plasticity in freshwater snail pigmentation

Ahlgren

Hansson

et al. 2013

Biol. Lett.

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By having phenotypically plastic traits, many organisms optimize their fitness in response to fluctuating threats. Freshwater snails with translucent shells, e.g. snails from the Radix genus, differ considerably in their mantle pigmentation patterns, with snails from the same water body ranging from being completely dark pigmented to having only a few dark patterns. These pigmentation differences have previously been suggested to be genetically fixed, but we propose that this polymorphism is owing to phenotypic plasticity in response to a fluctuating environment. Hence, we here aimed to assess whether common stressors, including ultraviolet radiation (UVR) and predation, induce a plastic response in mantle pigmentation patterns of Radix balthica. We show, in contrast to previous studies, that snails are plastic in their expression of mantle pigmentation in response to changes in UVR and predator threats, i.e. differences among populations are not genetically fixed. When exposed to cues from visually hunting fish, R. balthica increased the proportion of their dark pigmentation, suggesting a crypsis strategy. Snails increased their pigmentation even further in response to UVR, but this also led to a reduction in pattern complexity. Furthermore, when exposed to UVR and fish simultaneously, snails responded in the same way as in the UVR treatment, suggesting a trade-off between photoprotection and crypsis.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Camouflaged or tanned: plasticity in freshwater snail pigmentation

Ahlgren

Hansson

et al. 2013

Biol. Lett.

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“…DOC acts as a natural aquatic 'sunscreen' that strongly regulates exposure of aquatic organisms to UVR. Together, variation in depth and DOC govern attenuation of UVR in the water column [19,20]. Hence, hosts and parasites in different ponds experience dramatically different UVR exposures.…”

Section: Introductionmentioning

confidence: 99%

Joint effects of habitat, zooplankton, host stage structure and diversity on amphibian chytrid

Hite

Bosch

Fernández-Beaskoetxea

et al. 2016

Proc. R. Soc. B.

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Why does the severity of parasite infection differ dramatically across habitats? This question remains challenging to answer because multiple correlated pathways drive disease. Here, we examined habitat-disease links through direct effects on parasites and indirect effects on parasite predators (zooplankton), host diversity and key life stages of hosts. We used a case study of amphibian hosts and the chytrid fungus, Batrachochytrium dendrobatidis, in a set of permanent and ephemeral alpine ponds. A field experiment showed that ultraviolet radiation (UVR) killed the free-living infectious stage of the parasite. Yet, permanent ponds with more UVR exposure had higher infection prevalence. Two habitat-related indirect effects worked together to counteract parasite losses from UVR: (i) UVR reduced the density of parasite predators and (ii) permanent sites fostered multi-season host larvae that fuelled parasite production. Host diversity was unlinked to hydroperiod or UVR but counteracted parasite gains; sites with higher diversity of host species had lower prevalence of infection. Thus, while habitat structure explained considerable variation in infection prevalence through two indirect pathways, it could not account for everything. This study demonstrates the importance of creating mechanistic, food web-based links between multiple habitat dimensions and disease.

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“…These gradients can be rather persistent during stratification and, therefore, lead to relatively constant vertical aggregations of plankton. Diurnally changing effects, such as light-dependent predation by fish (Zaret and Suffern, 1976;Gliwicz, 1986) or harmful ultraviolet radiation (UVR) (Rhode et al, 2001;Williamson et al, 2011), however, can drive systematic diel changes in zooplankton vertical distribution (i.e., diel vertical migration).…”

Section: Introductionmentioning

confidence: 99%

Vertical distribution of zooplankton in a shallow peatland pond: the limiting role of dissolved oxygen

Vad

Horváth

Kiss

et al. 2013

Ann. Limnol. - Int. J. Lim.

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-We investigated the diel vertical distribution patterns of microcrustacean zooplankton (Cladocera, Copepoda) in a shallow pond (max. depth: 70 cm) of the Ö reg-turja´n peatland (Ó csa, Central Hungary) during three 24-h periods in July (19-20th), August (17-18th) and September (11-12th) 2011. Environmental variables showed remarkable vertical stratification. Oxygen concentration was close to zero in the entire water column from night until sunrise, while the lower strata (from 20 cm below the surface) were close to anoxic during all three diel cycles. It proved to be the main determinant of the vertical distribution of microcrustaceans. Accordingly, the highest proportion of individuals was present in the surface layer.Chlorophyll-a concentration and phytoplankton biomass were inversely distributed compared to zooplankton. Microcrustaceans (mainly Daphnia curvirostris) migrated to the middle layer only in August, which could be explained by a trade-off between food resources, dissolved oxygen (DO) and competition with littoral zooplankters. The diurnal density patterns of microcrustaceans suggested horizontal migration into the aquatic macrophytes during night, which could be a strategy to avoid Chaoborus predation. Our results show that strong vertical gradients of abiotic and biotic factors occur even in such shallow waterbodies. Among them, DO can maintain constant vertical aggregation of zooplankters by limiting their occurrence to the surface layers.

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Toward a more comprehensive theory of zooplankton diel vertical migration: Integrating ultraviolet radiation and water transparency into the biotic paradigm

Cited by 186 publications

References 241 publications

Camouflaged or tanned: plasticity in freshwater snail pigmentation

Camouflaged or tanned: plasticity in freshwater snail pigmentation

Joint effects of habitat, zooplankton, host stage structure and diversity on amphibian chytrid

Vertical distribution of zooplankton in a shallow peatland pond: the limiting role of dissolved oxygen

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