Long-Term Effect of Photoperiod, Temperature and Feeding Regimes on the Respiration Rates of Antarctic Krill (&amp;lt;i&amp;gt;Euphausia superba&amp;lt;/i&amp;gt;)

Brown, Matthew T.; Kawaguchi, So; Candy, Steven G.; Yoshida, Teruaki; Virtue, Patti; Nicol, Steve

doi:10.4236/ojms.2013.32a005

Cited by 14 publications

(22 citation statements)

References 64 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The presence of food alone is not sufficient to trigger feeding activity (Atkinson et al 2002;Teschke et al 2007). Recent research indicated that endogenous (inherent) mechanisms exist to synchronise the seasonal and circadian rhythmicity of metabolic and physiological output (Teschke et al 2007(Teschke et al , 2008(Teschke et al , 2011Mazzotta et al 2010), triggered by light (Seear et al 2009;Teschke et al 2011;Brown et al 2013). On the other hand, it was clearly shown in short-term starvation experiments that food availability does play a role: even after only 18 days without food, krill switched to a mode that reduced energy consumption and initiated consumption of body lipids (Atkinson et al 2002;Auerswald et al 2009).…”

Section: Original Papermentioning

confidence: 99%

Physiological response of adult Antarctic krill, Euphausia superba, to long-term starvation

et al. 2015

Self Cite

View full text Add to dashboard Cite

Adult Euphausia superba survive winter without or with little feeding. It is not exactly known whether the scarcity of food or an internal clock, set by the natural Antarctic light regime, are responsible for non-feeding. Our research questions were therefore the following: (1) How will physiological and biochemical conditions of krill change during long-term starvation at constant light regime? (2) If and how do enzyme activities change during such starvation? (3) What is the influence of food availability versus that of light regime? To answer these questions, adult krill were starved under laboratory conditions for 12 weeks with constant light regime (12:12; dark/light) and the impact on physiological functions was studied. Initial experimental condition of krill resembled the condition of late spring krill in the field with fully active metabolism and low lipid reserves. Metabolic activity and activities of enzymes catabolising lipids decreased after the onset of starvation and remained low throughout, whereas lipid reserves declined and lipid composition changed. Mass and size of krill decreased while the inter-moult period increased. Depletion of storage-and structural metabolites occurred in the order of depot lipids and glycogen reserves after onset of starvation until proteins were almost exclusively used after 6-7 weeks of starvation. Results confirmed various proposed overwintering mechanisms such as metabolic slowdown, slow growth or shrinkage and use of lipid reserves. However, these changes were set in motion by food shortage only, i.e. without the trigger of a changing light regime.

show abstract

Section: Original Papermentioning

confidence: 99%

Physiological response of adult Antarctic krill, Euphausia superba, to long-term starvation

et al. 2015

Self Cite

View full text Add to dashboard Cite

show abstract

“…from regions across the whole Antarctic Ocean. This pattern shows evidence for a general metabolic strategy in E. superba, which has been investigated from the molecular (Seear et al, 2009;Teschke et al, 2011) to the organism level Teschke et al, 2007;Gaten et al, 2008;Pape et al, 2008;Brown et al, 2013). Although, the signaling cascade that links the photoperiod cue to the target response still remains unknown, the photoperiodic cycle clearly seems to act as a major Zeitgeber for the seasonal cycle of RR, suggesting that krill has evolved an endogenous time keeping system that perceives seasonal variations in photoperiod (Meyer, 2011).…”

Section: Seasonal Respiration Models For Single Euphausiid Speciesmentioning

confidence: 91%

“…Thus, the seasonal cycle of RR in krill could be linked to an endogenous timing system, synchronized with the seasonal course of photoperiod in the environment. In a long-term experimental study lasting several years, Brown et al (2013) maintained E. superba first under simulated natural photoperiod, before they exposed part of the group to complete darkness and variable food availability and temperature over several months. These experiments showed that E. superba maintained similar RR patterns under constant darkness as under a simulated natural light regime.…”

Section: Seasonal Respiration Models For Single Euphausiid Speciesmentioning

confidence: 99%

Euphausiid respiration model revamped: Latitudinal and seasonal shaping effects on krill respiration rates

Tremblay¹,

Werner²,

Huenerlage³

et al. 2014

Ecological Modelling

View full text Add to dashboard Cite

a b s t r a c tEuphausiids constitute a major biomass component in shelf ecosystems and play a fundamental role in the rapid vertical transport of carbon from the ocean surface to the deeper layers during their daily vertical migration (DVM). DVM depth and migration patterns depend on oceanographic conditions with respect to temperature, light and oxygen availability at depth, factors that are highly dependent on season in most marine regions. Here we introduce a global krill respiration ANN (artificial neural network) model including the effect of latitude (LAT), the day of the year (DoY), and the number of daylight hours (DLh), in addition to the basal variables that determine ectothermal oxygen consumption (temperature, body mass and depth). The newly implemented parameters link space and time in terms of season and photoperiod to krill respiration. The ANN model showed a better fit (r 2 = 0.780) when DLh and LAT were included, indicating a decrease in respiration with increasing LAT and decreasing DLh. We therefore propose DLh as a potential variable to consider when building physiological models for both hemispheres. For single Euphausiid species investigated in a large range of DLh and DoY, we also tested the standard respiration rate for seasonality with Multiple Linear Regression (MLR) and General Additive model (GAM). GAM successfully integrated DLh (r 2 = 0.563) and DoY (r 2 = 0.572) effects on respiration rates of the Antarctic krill, Euphausia superba, yielding the minimum metabolic activity in mid-June and the maximum at the end of December. We could not detect DLh or DoY effects in the North Pacific krill Euphausia pacifica, and our findings for the North Atlantic krill Meganyctiphanes norvegica remained inconclusive because of insufficient seasonal data coverage. We strongly encourage comparative respiration measurements of worldwide Euphausiid key species at different seasons to improve accuracy in ecosystem modeling.

show abstract

“…Current experimental procedures typically necessitate krill being sacrificed to determine any effect of environmental change on krill anatomy (e.g. Brown et al, 2013).…”

Section: Optical Coherence Tomography (Oct) Is a Non--invasive High-mentioning

confidence: 99%

“…Observing any environmentally induced physiological effect typically requires the sacrifice of individual animals precluding repeated measures type analysis and requiring large control and treatment group sizes (e.g. Brown et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

Internal physiology of live krill revealed using new aquaria techniques and mixed optical microscopy and optical coherence tomography (OCT) imaging techniques

Cox

Kawaguchi

King

et al. 2015

Marine and Freshwater Behaviour and Physiology

Self Cite

View full text Add to dashboard Cite

The accurate observation of physiological changes on in vivo samples of important animal species such as Euphasia superba (Antarctic krill) is an important goal in helping to understand how environmental changes can affect animal development. Using a custom made 'krill trap', live un--anaesthetized krill were confined for seven hours, during which three hours of optical imaging were obtained and no subsequent ill effects observed. The trap enabled two imaging methods to be employed: Optical Coherence Tomography (OCT) and microscopy. OCT enabled internal structure and tissues to be imaged to a depth of approximately 2 mm and resolution of approximately 12 μm. Microscopy was used to observe heart rate. During our experiments, we imaged a range of internal structures in live animals including the heart and gastric areas. The trap design enables a new generation of mixed modality imaging of these animals in vivo.These techniques will enable detailed studies of the internal physiology of live krill to be undertaken under a wide range of environmental conditions and have the potential to highlight important variations in behaviour and animal development.

show abstract

Long-Term Effect of Photoperiod, Temperature and Feeding Regimes on the Respiration Rates of Antarctic Krill (<i>Euphausia superba</i>)

Cited by 14 publications

References 64 publications

Physiological response of adult Antarctic krill, Euphausia superba, to long-term starvation

Physiological response of adult Antarctic krill, Euphausia superba, to long-term starvation

Euphausiid respiration model revamped: Latitudinal and seasonal shaping effects on krill respiration rates

Internal physiology of live krill revealed using new aquaria techniques and mixed optical microscopy and optical coherence tomography (OCT) imaging techniques

Contact Info

Product

Resources

About