Interclonal proteomic responses to predator exposure in <i>Daphnia magna</i> may depend on predator composition of habitats

Otte, Kerstin; Schrank, Isabella; Fröhlich, Thomas; Arnold, Georg J.; Laforsch, Christian

doi:10.1111/mec.13287

Cited by 22 publications

(13 citation statements)

References 90 publications

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“…Despite a sensible explanation for this observation as being linked to an increase in translation, previous studies have shown increased transcription of ribosomal proteins without increased production of ribosomes (Sun, Li, & Wang, ; Wang et al., ). Proteomic data gathered on D. magna in response to predator cues show similar, but less extreme responses in ribosomal protein up‐regulation (Otte, Schrank, Frohlich, Arnold, & Laforsch, ). Furthermore, it is known that ribosomal proteins have functions outside of ribosome assembly and translation in response to stress (i.e., oncoprotein suppression, immune signalling and development; Zhou, Liao, Liao, Liao, & Lu, ).…”

Section: Discussionmentioning

confidence: 97%

Contrasting gene expression programs correspond with predator‐induced phenotypic plasticity within and across generations in Daphnia

et al. 2017

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Research has shown that a change in environmental conditions can alter the expression of traits during development (i.e., "within-generation phenotypic plasticity") as well as induce heritable phenotypic responses that persist for multiple generations (i.e., "transgenerational plasticity", TGP). It has long been assumed that shifts in gene expression are tightly linked to observed trait responses at the phenotypic level. Yet, the manner in which organisms couple within- and TGP at the molecular level is unclear. Here we tested the influence of fish predator chemical cues on patterns of gene expression within- and across generations using a clone of Daphnia ambigua that is known to exhibit strong TGP but weak within-generation plasticity. Daphnia were reared in the presence of predator cues in generation 1, and shifts in gene expression were tracked across two additional asexual experimental generations that lacked exposure to predator cues. Initial exposure to predator cues in generation 1 was linked to ~50 responsive genes, but such shifts were 3-4× larger in later generations. Differentially expressed genes included those involved in reproduction, exoskeleton structure and digestion; major shifts in expression of genes encoding ribosomal proteins were also identified. Furthermore, shifts within the first-generation and transgenerational shifts in gene expression were largely distinct in terms of the genes that were differentially expressed. Such results argue that the gene expression programmes involved in within- vs. transgeneration plasticity are fundamentally different. Our study provides new key insights into the plasticity of gene expression and how it relates to phenotypic plasticity in nature.

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Section: Discussionmentioning

confidence: 97%

Contrasting gene expression programs correspond with predator‐induced phenotypic plasticity within and across generations in Daphnia

et al. 2017

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“…For instance, many organisms express antipredator traits at the beginning of independent life, for example, as hatchlings, neonates, and seedlings (Osborn and Jaffe 1998;Laforsch and Tollrian 2004;Bosak et al 2013;Garla et al 2015). The expression of such traits can vary across genotypes prior to any exposure to cues from predators, and genotypes can differ with respect to the plasticity of those traits in response to cues from predators (Fischer et al 2014b;Sjoqvist et al 2014;Otte et al 2015;Christjani et al 2016). However, when animals are exposed to cues from predators, changes in antipredator behavior typically occur more rapidly than changes in morphological antipredator defenses (Van Buskirk 2002;Hossie and Murray 2012;Orizaola et al 2012).…”

Section: Discussionmentioning

confidence: 99%

Bayesian updating during development predicts genotypic differences in plasticity

et al. 2018

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Interactions between genotypes and environments are central to evolutionary genetics, but such interactions are typically described, rather than predicted from theory. Recent Bayesian models of development generate specific predictions about genotypic differences in developmental plasticity (changes in the value of a given trait as a result of a given experience) based on genotypic differences in the value of the trait that is expressed by naïve subjects. We used these models to make a priori predictions about the effects of an aversive olfactory conditioning regime on the response of Drosophila melanogaster larvae to the odor of ethyl acetate. As predicted, across 116 genotypes initial trait values were related to plasticity. Genotypes most strongly attracted to the odor of ethyl acetate when naïve reduced their attraction scores more as a result of the aversive training regime than those less attracted to the same odor when naïve. Thus, as predicted, the variance across genotypes in attraction scores was higher before than after the shared experience. These results support predictions generated by Bayesian models of development and indicate that such models can be successfully used to investigate how variation across genotypes in information derived from ancestors combines with personal experience to differentially affect developmental plasticity in response to specific types of experience.

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“…Since Daphnia need to shed their rigid carapace in order to grow, molting is directly related to changes in body size. Another analysis of D. magna exposed to Triops cancriformis kairomones revealed the role of proteins related to the cuticle, muscular system, energy metabolism and regulatory proteins that may be involved in morphological carapace defenses and changes in resource allocation (Otte et al 2014). In conclusion, a number of biological functions hypothesized to be involved in kairomone response could be confirmed, e.g., transcripts related to body remodeling and growth.…”

Section: Discussionmentioning

confidence: 79%

“…The 'structural constituent of cuticle' was enriched in D. pulex exposed to Chaoborus kairomones Rozenberg et al 2015) and related to remodeling of the cuticle. Furthermore, it was also enriched in the proteomic response of D. magna to Triops cancriformis (Otte et al 2015) and is thought to be related to changes in carapace morphology as well as the formation of ultrastructural defenses of the cuticle (Rabus et al 2013). Genes related to body remodeling and activation of cuticle proteins were enriched for D. magna exposed to vertebrate and invertebrate predator kairomones (Orsini et al 2018).…”

Section: Discussionmentioning

confidence: 99%

Insights into the genetic basis of predator-induced response inDaphnia galeata

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Nickel

Ehring

et al. 2018

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AbstractPhenotypic plastic responses allow organisms to rapidly adjust when facing environmental challenges - these responses comprise morphological, behavioral but also life-history changes. Alteration of life-history traits when exposed to predation risk have been reported often in the ecological and genomic model organism Daphnia. However, the molecular basis of this response is not well understood, especially in the context of fish predation. Here, we characterized the transcriptional profiles of two Daphnia galeata clonal lines with opposed life histories when exposed to fish kairomones. First, we conducted a differential gene expression, identifying a total of 125 candidate transcripts involved in the predator-induced response, uncovering substantial intra-specific variation. Second, we applied a gene co-expression network analysis to find clusters of tightly linked transcripts revealing the functional relations of transcripts underlying the predator-induced response. Our results showed that transcripts involved in remodeling of the cuticle, growth and digestion correlated with the response to environmental change in D. galeata. Furthermore, we used an orthology-based approach to gain functional information for transcripts lacking gene ontology (GO) information, as well as insights into the evolutionary conservation of transcripts. We could show that our candidate transcripts have orthologs in other Daphnia species but almost none in other arthropods. The unique combination of methods allowed us to identify candidate transcripts, their putative functions and evolutionary history associated with predator-induced responses in Daphnia. Our study opens up to the question as to whether the same molecular signature is associated fish kairomones-mediated life-history changes in other Daphnia species.

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Interclonal proteomic responses to predator exposure in Daphnia magna may depend on predator composition of habitats

Cited by 22 publications

References 90 publications

Contrasting gene expression programs correspond with predator‐induced phenotypic plasticity within and across generations in Daphnia

Contrasting gene expression programs correspond with predator‐induced phenotypic plasticity within and across generations in Daphnia

Bayesian updating during development predicts genotypic differences in plasticity

Insights into the genetic basis of predator-induced response inDaphnia galeata

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