Regulation of gene expression is associated with tolerance of the Arctic copepod <i>Calanus glacialis</i> to <scp>CO</scp><sub>2</sub>‐acidified sea water

Bailey, Allison; Wit, Pierre De; Thor, Peter; Browman, Howard I.; Bjelland, Reidun M.; Shema, Steven; Fields, David M.; Runge, Jeffrey A.; Thompson, Cameron; Hop, Haakon

doi:10.1002/ece3.3063

Cited by 43 publications

(37 citation statements)

References 115 publications

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“…Notable were those related to the response and detection of stress, and actin organization and regulation. Actin regulation is linked to cytoskeleton maintenance and has been identified as responsive to low pH stress in copepods (39). In addition, we found strong allelic differences between lines in regulators of expression (Table S1), suggesting that trans-acting regulators may have been under selection and responsible for the adaptive changes in gene expression.…”

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confidence: 77%

Loss and recovery of transcriptional plasticity after long-term adaptation to global change conditions in a marine copepod

Brennan

deMayo

Dam

et al. 2020

Preprint

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Global conditions are changing at unprecedented rates (1), challenging species resilience (2). Populations can respond to these changes through genetic adaptation and physiological plasticity (3, 4), and it is well accepted that these processes interact (5). However, the relative role plasticity and adaptation play in promoting resilience to global change and the potential impacts of rapid adaptation on plasticity during this process are not well understood (3, 5–10). Here, using experimental evolution and reciprocal transplantation of the marine coastal copepod, Acartia tonsa, we show rapid adaptation to global change conditions carries costs, notably a loss of physiological plasticity. Twenty generations of selection resulted in rapid, highly parallel adaptation to greenhouse conditions. However, this adaptation reduced plasticity and fitness, particularly when returned to ambient conditions and under food limitation. Due to the loss of plasticity, greenhouse adapted lines could no longer tolerate ambient conditions and compensated by additional adaptive evolution, a process that eroded nucleotide diversity in genes containing adaptive genetic variation for global change conditions. These results show that adaptation can negatively affect plasticity, limiting resilience to new stressors and previously benign environments. Our findings challenge the common assertion that the presence of adaptive genetic potential or physiological plasticity alone will enable population resilience under global change conditions.Significance statementUnderstanding how species will respond to changing environmental conditions is an essential step in mitigating the potential negative consequences of human induced global change conditions. Typically, it is assumed that a species with sufficient plasticity or adaptive potential will be resilient in the face of these changes. Here, we experimentally evolve a copepod to simulated future acidic and warm conditions. We show that rapid adaptation reduced phenotypic plasticity and eroded the adaptive genetic variation necessary to tolerate additional environmental stress. These findings demonstrate that the presence of plasticity or adaptive potential do not necessarily indicate a resilient population, illustrating the importance of considering the interaction between these factors when predicting species tolerance to global change.

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confidence: 77%

Loss and recovery of transcriptional plasticity after long-term adaptation to global change conditions in a marine copepod

Brennan

deMayo

Dam

et al. 2020

Preprint

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“…These studies emphasize that a core response of marine metazoans to decreases in pH involves a reallocation and/or changes in production of ATP, often as a trade-off in maintaining ion homeostasis, calcification and control of internal pH levels. Modulation of ATP-producing enzymes has also been reported in non-calcifying marine organisms in response to low pH, including Arctic copepods [66] and within brains of coral reef fish [89]. Another commonly reported gene expression signature that predicts metabolic depression is changes in genes involved in mitochondrial and oxidative metabolism.…”

Section: Observation 1: Organisms Alter Metabolic Processes Under Expmentioning

confidence: 93%

“…Organisms employ different mechanisms of metabolic responses based on length of exposure to stressors. Upregulation of genes involved in lipid metabolism is observed in many studies of long-term pCO 2 stress response in a variety of taxa: reef-building corals [21,23,25,32], pteropods [62,63], and Arctic copepods [66]. Concurrently, there are studies reporting increased lipid content in corals after exposure to increased pCO 2 [111,112].…”

Section: Observation 1: Organisms Alter Metabolic Processes Under Expmentioning

confidence: 93%

“…While studies have investigated metabolic rates and ATP production in response to pH [98], gene expression has become another tool to assess the potential for metabolic depression, especially to elucidate mechanisms of this response (Table 2). Gene expression studies reporting metabolic depression in marine metazoans include adult blue mussels [45], adult pearl oysters [50,51], purple sea urchin larvae [81,82], temperate brittle stars [72], clams [41], Arctic copepods [66], developing Medaka fish [93], marine polychaetes [37] and reef-building corals [21,[24][25][26]. Despite being commonly observed across gene expression studies in response to low pH, the means by which metabolic depression is characterized through gene expression data varies by study and taxon.…”

Section: Observation 1: Organisms Alter Metabolic Processes Under Expmentioning

confidence: 99%

“…Studies of transcriptomic responses to high pCO 2 /low pH exposure in shell-forming zooplankton show dramatic modulation of energetic processes. Both Arctic copepods and Antarctic pteropods show massive downregulation of much of the transcriptome after low pH exposure (1700 μatm and 902 μatm, respectively) [62,66]. Decreased expression of mitochondrion and oxidative metabolism genes are also observed under high pCO 2 (720 μatm) in Mediterranean pteropods, including suppressed expression of the entire protein synthesis machinery [60].…”

Section: Observation 1: Organisms Alter Metabolic Processes Under Expmentioning

confidence: 99%

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Ocean acidification promotes broad transcriptomic responses in marine metazoans: a literature survey

2020

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For nearly a decade, the metazoan-focused research community has explored the impacts of ocean acidification (OA) on marine animals, noting that changes in ocean chemistry can impact calcification, metabolism, acid-base regulation, stress response and behavior in organisms that hold high ecological and economic value. Because OA interacts with several key physiological processes in marine organisms, transcriptomics has become a widely-used method to characterize whole organism responses on a molecular level as well as inform mechanisms that explain changes in phenotypes observed in response to OA. In the past decade, there has been a notable rise in studies that examine transcriptomic responses to OA in marine metazoans, and here we attempt to summarize key findings across these studies. We find that organisms vary dramatically in their transcriptomic responses to pH although common patterns are often observed, including shifts in acid-base ion regulation, metabolic processes, calcification and stress response mechanisms. We also see a rise in transcriptomic studies examining organismal response to OA in a multi-stressor context, often reporting synergistic effects of OA and temperature. In addition, there is an increase in studies that use transcriptomics to examine the evolutionary potential of organisms to adapt to OA conditions in the future through population and transgenerational experiments. Overall, the literature reveals complex organismal responses to OA, in which some organisms will face more dramatic consequences than others. This will have wide-reaching impacts on ocean communities and ecosystems as a whole.

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Gene expression and epigenetic responses of the marine Cladoceran, Evadne nordmanni, and the copepod, Acartia clausi, to elevated CO₂

Aluru

Fields

Shema

et al. 2021

Ecology and Evolution

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The release of anthropogenic carbon emissions into the earth's atmosphere has resulted in changes in oceanic temperature and pH that have an impact on marine organisms and ecosystems (IPCC, 2021).IPCC scenarios project that pCO 2 will continue to climb resulting in an average sea surface temperature increase of 0.6°C-2.0°C and a pH drop of 0.06-0.32 units by the end of the century (IPCC, 2013).The rapid changes in these concurrent stressors is causing concern that some marine organisms may be unable to adapt and that this will reduce the resilience of marine ecosystems in which complex food webs maintain stability (Gledhill et al., 2015).

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Regulation of gene expression is associated with tolerance of the Arctic copepod Calanus glacialis to CO₂‐acidified sea water

Cited by 43 publications

References 115 publications

Loss and recovery of transcriptional plasticity after long-term adaptation to global change conditions in a marine copepod

Loss and recovery of transcriptional plasticity after long-term adaptation to global change conditions in a marine copepod

Ocean acidification promotes broad transcriptomic responses in marine metazoans: a literature survey

Gene expression and epigenetic responses of the marine Cladoceran, Evadne nordmanni, and the copepod, Acartia clausi, to elevated CO₂

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Regulation of gene expression is associated with tolerance of the Arctic copepod Calanus glacialis to CO2‐acidified sea water

Cited by 43 publications

References 115 publications

Loss and recovery of transcriptional plasticity after long-term adaptation to global change conditions in a marine copepod

Loss and recovery of transcriptional plasticity after long-term adaptation to global change conditions in a marine copepod

Ocean acidification promotes broad transcriptomic responses in marine metazoans: a literature survey

Gene expression and epigenetic responses of the marine Cladoceran, Evadne nordmanni, and the copepod, Acartia clausi, to elevated CO2

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Product

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Regulation of gene expression is associated with tolerance of the Arctic copepod Calanus glacialis to CO₂‐acidified sea water

Gene expression and epigenetic responses of the marine Cladoceran, Evadne nordmanni, and the copepod, Acartia clausi, to elevated CO₂