Low-latitude zooplankton pigmentation plasticity in response to multiple threats

Lee, Marcus; Zhang, Huan; Sha, Yongcui; Hegg, Alexander; Ugge, Gustaf Ekelund; Vinterstare, Jerker; Škerlep, Martin; Pärssinen, Varpu; Herzog, Simon; Björnerås, Caroline; Gollnisch, Raphael; Johansson, Emma; Hu, Nan; Nilsson, P. Anders; Rengefors, Karin; Langerhans, R. Brian; Brönmark, Christer; Hansson, Lars

doi:10.1098/rsos.190321

Cited by 7 publications

(7 citation statements)

References 39 publications

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“…Additionally, young daphnids have been shown to respond more strongly than adults to UV-radiation [62][63][64], which has been reported for predator avoidance by DVM as well [44,61]. Despite this, zooplankton is able to increase pigmentation to protect itself against UV-radiation (see further below) [33,65,66]. Thus, the ultimate factor for DVM in response to both UV-radiation and light intensity is the increase in predation risk due to increased visibility to visually hunting predators.…”

Section: Behavioural Defencesmentioning

confidence: 90%

“…On the one hand, food and temperature are crucial for the growth and development of zooplankton. On the other hand, a response to light and UV-radiation may comprise a trade-off between protection against UV-radiation (e.g., by pigmentation) and the increase in vulnerability (due to increased visibility) to visually hunting predators [33,65,66]. Winder et al [60] proposed that temperature and food abundance modulate the depth selection in Daphnia, while predator kairomones and UV-radiation modulate the timing of the DVM (i.e., synchronizing with dusk and dawn), emphasizing the importance of considering these factors in experiments.…”

Section: Behavioural Defencesmentioning

confidence: 99%

“…Under favorable conditions, Daphnia typically reproduce asexually, rendering all offspring as clones of their mother, which is a great advantage for ecological and evolutionary experiments. Furthermore, some of its species have fully sequenced genomes [32,33]. Results obtained in laboratory studies on these organisms are crucial for reconstructing and understanding ecological processes in nature [34][35][36].…”

Section: Introductionmentioning

confidence: 99%

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Knowing the Enemy: Inducible Defences in Freshwater Zooplankton

et al. 2020

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Phenotypic plasticity in defensive traits is an appropriate mechanism to cope with the variable hazard of a frequently changing predator spectrum. In the animal kingdom these so-called inducible defences cover the entire taxonomic range from protozoans to vertebrates. The inducible defensive traits range from behaviour, morphology, and life-history adaptations to the activation of specific immune systems in vertebrates. Inducible defences in prey species play important roles in the dynamics and functioning of food webs. Freshwater zooplankton show the most prominent examples of inducible defences triggered by chemical cues, so-called kairomones, released by predatory invertebrates and fish. The objective of this review is to highlight recent progress in research on inducible defences in freshwater zooplankton concerning behaviour, morphology, and life-history, as well as difficulties of studies conducted in a multipredator set up. Furthermore, we outline costs associated with the defences and discuss difficulties as well as the progress made in characterizing defence-inducing cues. Finally, we aim to indicate further possible routes in this field of research and provide a comprehensive table of inducible defences with respect to both prey and predator species.

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Section: Behavioural Defencesmentioning

confidence: 90%

Section: Behavioural Defencesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Knowing the Enemy: Inducible Defences in Freshwater Zooplankton

et al. 2020

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“…In addition, copepods can accumulate photoprotective pigments, such as carotenoids, against UVR (Hansson and Hylander 2009a), although this comes at a cost as increased pigmentation makes copepods conspicuous, and thus, increases predation risk (Hylander et al 2009). A recent study demonstrated that copepods exhibited higher levels of pigmentation in fishless and low-predation Bahamian blue holes, but reduced their coloration significantly in blue holes with higher predation pressure (Lee et al 2019). Moreover, copepods may individually adjust their level of pigmentation, as well as other protective, nonpigment compounds such as mycosporine-like amino acids (Hylander 2020), to the prevailing risk from UVR and predation (Brüsin et al 2016;Hansson 2004).…”

Section: Discussionmentioning

confidence: 99%

Diel vertical migration of copepods and its environmental drivers in subtropical Bahamian blue holes

et al. 2020

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Diel vertical migration (DVM) is the most common behavioral phenomenon in zooplankton, and numerous studies have evaluated DVM under strong seasonality at higher latitudes. Yet, our understanding of the environmental drivers of DVM at low latitudes, where seasonal variation is less pronounced, remains limited. Therefore, we here examined patterns of vertical distribution in copepods in six subtropical Bahamian blue holes with different food web structure and tested the role of several key environmental variables potentially affecting this behavior. Day and night samplings showed that copepods generally performed DVM, characterized by downward migration to deeper depths during the day and upward migration to surface waters at night. Across all blue holes, the daytime vertical depth distribution of calanoid copepods correlated positively with both predation risk and depth of food resources (Chlorophyll a), but was less affected by ultraviolet radiation (UVR). A potential explanation is that since UVR is a continuous threat across seasons, zooplankton have established photoprotective pigmentation making them less vulnerable to this threat. The copepods also showed a size-structured depth segregation, where larger individuals were found at deeper depths during the day, which further strengthens the suggestion that predation is a major driver of DVM in these systems. Hence, in contrast to studies performed at higher latitudes, we show that despite the constant exposure to UVR, predator avoidance and food availability are the most pronounced drivers of copepod DVM at those low latitudes, suggesting that the main driver of DVM may vary among systems, but also systematically by latitude.

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“…As in most crustaceans, astaxanthin and canthaxanthin are the principal carotenoid types found in copepods (Czeczuga & Czerpak, 1966; de Carvalho & Caramujo, 2017; Fisher et al, 1964; Matsuno, 2001). Pigmented copepods are found in both marine and freshwater environments, particularly in polar and subpolar regions (Hylander et al, 2015), but also in subtropical systems (Lee et al, 2019). The red copepods from the North Atlantic ( Calanus spp.)…”

Section: Introductionmentioning

confidence: 99%

Copepods' true colors: astaxanthin pigmentation as an indicator of fitness

et al. 2023

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Pigmentation is often overlooked in zooplankton, since these organisms are mostly colorless to fit the translucid water medium. However, one of the dominant zooplankton taxa in aquatic ecosystems—copepods—often show a bright red‐orange or blue coloration owing to the accumulation of carotenoid pigments in some parts of their bodies. Even though there are many functional traits describing copepod's performance (e.g., size, feeding, and reproductive modes), it is surprising that the role of such a simple and visible trait as coloration has not been studied in a coherent manner yet. Here, by reviewing 95 studies, we demonstrate that carotenoid‐based pigmentation (mainly caused by astaxanthin molecules) is a widespread functional trait in freshwater and marine copepods. We propose a way to disentangle the complex and thus intriguing patterns of pigment expression along latitudinal and altitudinal gradients, addressing its relationship to diet quality and quantity, temperature, ultraviolet radiation stress, predation pressure, lipid metabolism, and reproduction. We show that large‐scale variations in pigmentation are difficult to tackle because of the fundamental plasticity of this trait at short time scales (i.e., hours, days), and the most recent information about carotenoid bioconversion are addressed (genes and enzyme identification, and influence of microbiota). From this literature review, we hypothesize that pigments play a “Swiss‐army knife” role for copepod's fitness, useful in various ecosystem conditions owing to the strong antioxidant power and the finely‐tuned metabolism of astaxanthin. With larger antioxidant capacities (survival), higher metabolisms (growth), and more offspring in better condition (reproduction), red morphs appear more successful than their uncolored siblings. Also, the potential camouflage strategies allowed by red and blue pigmentation are discussed. We finally formulate new directions and future research fields from molecular to ecosystem scales. Routine quantifications of copepod's pigmentation through trait‐based approaches could be useful (1) to obtain an accurate copepod fitness indicator and (2) to better estimate the transfer of antioxidant to higher trophic levels in ecosystems, including humans.

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Low-latitude zooplankton pigmentation plasticity in response to multiple threats

Cited by 7 publications

References 39 publications

Knowing the Enemy: Inducible Defences in Freshwater Zooplankton

Knowing the Enemy: Inducible Defences in Freshwater Zooplankton

Diel vertical migration of copepods and its environmental drivers in subtropical Bahamian blue holes

Copepods' true colors: astaxanthin pigmentation as an indicator of fitness

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