A metabolic approach to dormancy in pelagic copepods helps explaining inter- and intra-specific variability in life-history strategies

Maps, Frédéric; Record, Nicholas R.; Pershing, Andrew J.

doi:10.1093/plankt/fbt100

Cited by 56 publications

(61 citation statements)

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“…Merging Coltrane 1.0 with a light-and size-based predation scheme similar to Varpe et al (2015) or Ohman and Romagnan (2015) would allow one to better test the balance of bottom-up and top-down controls on calanoid biogeography. Second, our experience constructing the Bering Sea and Disko Bay cases suggests that the greatest uncertainty in the model bioenergetics is actually not the physiology itselfempirical reviews like Saiz and Calbet (2007), Maps et al (2014), Kiørboe and Hirst (2014), and have constrained the key rates moderately well-but rather the problem of translating a prey field into a rate of ingestion. Within each of our model testbeds, the prey time series P remains subject to uncertainty in relative grazing rates on ice algae, large and small pelagic phytoplankton, and microzooplankton, despite a wealth of local observations and a history of work on this problem in Calanus specifically (Olson et al, 2006;Campbell et al, 2009, in press).…”

Section: Uncertainties and Unresolved Processesmentioning

confidence: 99%

Copepod Life Strategy and Population Viability in Response to Prey Timing and Temperature: Testing a New Model across Latitude, Time, and the Size Spectrum

et al. 2016

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A new model ("Coltrane": Copepod Life-history Traits and Adaptation to Novel Environments) describes environmental controls on copepod populations via (1) phenology and life history and (2) temperature and energy budgets in a unified framework. The model tracks a cohort of copepods spawned on a given date using a set of coupled equations for structural and reserve biomass, developmental stage, and survivorship, similar to many other individual-based models. It then analyzes a family of cases varying spawning date over the year to produce population-level results, and families of cases varying one or more traits to produce community-level results. In an idealized globalscale testbed, the model correctly predicts life strategies in large Calanus spp. ranging from multiple generations per year to multiple years per generation. In a Bering Sea testbed, the model replicates the dramatic variability in the abundance of Calanus glacialis/marshallae observed between warm and cold years of the 2000s, and indicates that prey phenology linked to sea ice is a more important driver than temperature per se. In a Disko Bay, West Greenland testbed, the model predicts the viability of a spectrum of large-copepod strategies from income breeders with a adult size ∼100 µgC reproducing once per year through capital breeders with an adult size >1000 µgC with a multiple-year life cycle. This spectrum corresponds closely to the observed life histories and physiology of local populations of Calanus finmarchicus, C. glacialis, and Calanus hyperboreus. Together, these complementary initial experiments demonstrate that many patterns in copepod community composition and productivity can be predicted from only a few key constraints on the individual energy budget: the total energy available in a given environment per year; the energy and time required to build an adult body; the metabolic and predation penalties for taking too long to reproduce; and the size and temperature dependence of the vital rates involved.

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Section: Uncertainties and Unresolved Processesmentioning

confidence: 99%

Copepod Life Strategy and Population Viability in Response to Prey Timing and Temperature: Testing a New Model across Latitude, Time, and the Size Spectrum

et al. 2016

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“…Recently, Maps et al (2014) summarised published metabolic rates for Calanus species. In total, five papers have reported respiration rates for C. finmarchicus (Hirche, 1983;Marshall and Orr, 1958;Saumweber and Durbin, 2006;Ingvarsdóttir et al, 1999;Ikeda et al, 2001).…”

Section: Metabolism and Excretionmentioning

confidence: 99%

“…finmarchicus and C. helgolandicus should be very similar. In addition, Maps et al (2014) concluded that there was an almost identical inter-species pattern in allometric scaling of metabolism with body size across Calanus species. However, apparent interspecies differences in response of ingestion to temperature suggests that the energetics of each species differ, which may result in different metabolic rates.…”

Section: Metabolism and Excretionmentioning

confidence: 99%

“…Metabolic costs are understood to have approximately three quarter power scaling with body weight in general (Gillooly et al, 2001) and the review by Maps et al (2014) indicates that this holds for Calanus. Metabolism also increases with temperature, and this relationship follows a Q 10 relationship, i.e.…”

Section: Growth and Development Modelmentioning

confidence: 99%

“…each increase in temperature of 10°C will result in respiration rates increasing by a factor of Q 10 . Therefore we use the equation Q 10 T=10 kw 0:75 to represent metabolic costs (units: lg C h À1 ), where T is temperature (°C) and with Q 10 and k being parameterised within reasonable bounds derived from the literature review contained in Maps et al (2014). Minimum and maximum published Q 10 are 2.3 (Marshall and Orr, 1958) and 3.4 (Hirche, 1983) respectively.…”

Section: Growth and Development Modelmentioning

confidence: 99%

See 2 more Smart Citations

On the surprising lack of differences between two congeneric calanoid copepod species, Calanus finmarchicus and C. helgolandicus

Wilson

Speirs

Heath

2015

Progress in Oceanography

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The important calanoid copepod species Calanus finmarchicus and C. helgolandicus have distinct geographic ranges which are changing under the influence of climate change. Understanding the mechanisms underlying their distributions is becoming increasingly important as a result of the possible ecological impacts of these range shifts. Here we review inter-species differences in key life cycle traits that influence each species’ geographic distribution, in particular development and growth, fecundity, feeding behaviour, vertical migration and overwintering behaviour. The distinct temperature niche of each species leads to an a priori assumption that the response of life cycle traits to temperature is a key determinant of their contrasting geographic distributions. A new development model was created to reconcile published experimental development times for each species. Model output indicates that at temperatures below approximately 12-13 ˚C, C. finmarchicus is the faster developing species, but above these temperatures C. helgolandicus develops more quickly. Conventionally Calanus development time is assumed to decrease monotonically with temperature; however our model indicates that the response of development time to temperature is instead U-shaped. Differences in life cycle aspects such as seasonality and vertical structuring are interpreted in light of this development model. Body size and lipid accumulation abilities could be significant influences on each species’ geographic distribution; however evidence is consistent with inter-species differences not existing for these traits. Published evidence shows that inter-species differences in egg production may exist, but do not follow a clear pattern. Diapause is an important and well studied life cycle adaptation of C. finmarchicus, but has received little attention in C. helgolandicus. We synthesised knowledge of diapause and suggest the hypothesis that C. helgolandicus is restricted to continental shelf regions as a result of an inability to diapause for significant periods. This synthesised view of each species’ respective life cycle traits is that response of growth and development to temperature is the only known difference between each species, which indicates a promising direction for the extension of population models of C. finmarchicus to C. helgolandicus

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Early ice retreat and ocean warming may induce copepod biogeographic boundary shifts in the Arctic Ocean

Feng

Campbell

et al. 2016

JGR Oceans

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Early ice retreat and ocean warming are changing various facets of the Arctic marine ecosystem, including the biogeographic distribution of marine organisms. Here an endemic copepod species, Calanus glacialis, was used as a model organism, to understand how and why Arctic marine environmental changes may induce biogeographic boundary shifts. A copepod individual‐based model was coupled to an ice‐ocean‐ecosystem model to simulate temperature‐ and food‐dependent copepod life history development. Numerical experiments were conducted for two contrasting years: a relatively cold and normal sea ice year (2001) and a well‐known warm year with early ice retreat (2007). Model results agreed with commonly known biogeographic distributions of C. glacialis, which is a shelf/slope species and cannot colonize the vast majority of the central Arctic basins. Individuals along the northern boundaries of this species' distribution were most susceptible to reproduction timing and early food availability (released sea ice algae). In the Beaufort, Chukchi, East Siberian, and Laptev Seas where severe ocean warming and loss of sea ice occurred in summer 2007, relatively early ice retreat, elevated ocean temperature (about 1–2°C higher than 2001), increased phytoplankton food, and prolonged growth season created favorable conditions for C. glacialis development and caused a remarkable poleward expansion of its distribution. From a pan‐Arctic perspective, despite the great heterogeneity in the temperature and food regimes, common biogeographic zones were identified from model simulations, thus allowing a better characterization of habitats and prediction of potential future biogeographic boundary shifts.

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A metabolic approach to dormancy in pelagic copepods helps explaining inter- and intra-specific variability in life-history strategies

Cited by 56 publications

References 50 publications

Copepod Life Strategy and Population Viability in Response to Prey Timing and Temperature: Testing a New Model across Latitude, Time, and the Size Spectrum

Copepod Life Strategy and Population Viability in Response to Prey Timing and Temperature: Testing a New Model across Latitude, Time, and the Size Spectrum

On the surprising lack of differences between two congeneric calanoid copepod species, Calanus finmarchicus and C. helgolandicus

Early ice retreat and ocean warming may induce copepod biogeographic boundary shifts in the Arctic Ocean

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