Effects of interdecadal climate variability on marine trophic interactions: rhinoceros auklets and their fish prey

Hedd, April; Bertram, Douglas F.; Ryder, John L.; Jones, Ian L.

doi:10.3354/meps309263

Cited by 58 publications

(61 citation statements)

References 50 publications

(63 reference statements)

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“…However, the effects of extreme climatic events are far from being understood; some cases remain unexplained and results of studies are contradictory (Croxall et al 2002, Forcada & Trathan 2009, Bailey & van de Pol 2016. Breeding performance in particular may be affected directly by sea surface temperature (SST) by changing the distribution and/or abundance of important prey species (Frederiksen et al 2007), or indirectly via effects on prey recruitment (Hedd et al 2006). Furthermore, unfavourable climate conditions may induce seabirds to skip breeding (Jenouvrier et al 2005a, Olivier et al 2005, Cubaynes et al 2011 or affect nest-site conditions (Chambers et al 2011, Moreno & Møller 2011, Soldatini et al 2014).…”

Section: Seabirds and Environmental Variabilitymentioning

confidence: 99%

Forecasting ocean warming impacts on seabird demography: a case study on the European storm petrel

Soldatini

Albores‐Barajas

Massa

et al. 2016

Mar. Ecol. Prog. Ser.

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Bottom-up climatic forcing has been shown to be influential for a variety of marine taxa, but evidence on seabird populations is scarce. Seasonal variation in environmental conditions can have an indirect effect on subsequent reproduction, which, given the longevity and single-brooding of seabirds, may affect population dynamics. Our study focuses on linking the effect of oceanographic conditions (from 1991 to 2013) to the fecundity and consequently population growth rate of the Mediterranean subspecies of the European storm petrel Hydrobates pelagicus melitensis. In this study, we examined 23 yr of > 5400 capture-mark−recaptures (CMR) and modelled the probability of skipping reproduction as a function of oceanographic variables using CMR models. We demonstrate that a decrease in sea surface temperature in the pre-breeding period negatively influences skipping propensity, and therefore hypothesize that this behaviour would have significant influence on population abundance over time. For this reason, we analysed population growth as a function of skipping probability as affected by oceanographic conditions. We used stochastic demographic models to forecast the fate of the population, and evaluated contrasted environmental condition scenarios. As a result, we found that a decrease in frequency of cold winter events would probably reduce skipping propensity, with a positive effect on the population as a whole.

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Section: Seabirds and Environmental Variabilitymentioning

confidence: 99%

Forecasting ocean warming impacts on seabird demography: a case study on the European storm petrel

Soldatini

Albores‐Barajas

Massa

et al. 2016

Mar. Ecol. Prog. Ser.

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“…Cooler conditions and decreased water column stability associated with coastal upwelling indicate greater vertical mixing and nutrient availability to primary producers in the California Current (Chavez and Messié 2009;Demarcq 2009). Increases in nutrient availability cause bottom-up increases in phytoplankton and zooplankton abundances and subsequent increases in forage fish consumption (Peterson and Schwing 2003;Harris et al 2009;Boyce et al 2010;Keister et al 2011), condition (Astthorsson and Gislason 1998;Robards et al 2002;Takahashi et al 2012), and abundance (Hedd et al 2006;Thayer et al 2008;Sydeman et al 2013). Furthermore, cooler conditions can prompt favorable shifts in prey composition (Hedd et al 2006;Mackas et al 2007;Thayer et al 2008;Keister et al 2011;Gladics et al 2015).…”

Section: Black Rockfish In the California Currentmentioning

confidence: 99%

“…Increases in nutrient availability cause bottom-up increases in phytoplankton and zooplankton abundances and subsequent increases in forage fish consumption (Peterson and Schwing 2003;Harris et al 2009;Boyce et al 2010;Keister et al 2011), condition (Astthorsson and Gislason 1998;Robards et al 2002;Takahashi et al 2012), and abundance (Hedd et al 2006;Thayer et al 2008;Sydeman et al 2013). Furthermore, cooler conditions can prompt favorable shifts in prey composition (Hedd et al 2006;Mackas et al 2007;Thayer et al 2008;Keister et al 2011;Gladics et al 2015). For example, during cool conditions, Pacific Sand Lances and Northern Anchovy Engraulis mordax dominate seabird diets, with commensurate increases in seabird breeding success, whereas in warm years, rockfishes and Pacific Herring are more common in seabird diets and breeding success is lower (Hedd et al 2006;Thayer et al 2008;Gladics et al 2015).…”

Section: Black Rockfish In the California Currentmentioning

confidence: 99%

“…Furthermore, cooler conditions can prompt favorable shifts in prey composition (Hedd et al 2006;Mackas et al 2007;Thayer et al 2008;Keister et al 2011;Gladics et al 2015). For example, during cool conditions, Pacific Sand Lances and Northern Anchovy Engraulis mordax dominate seabird diets, with commensurate increases in seabird breeding success, whereas in warm years, rockfishes and Pacific Herring are more common in seabird diets and breeding success is lower (Hedd et al 2006;Thayer et al 2008;Gladics et al 2015). Because Black Rockfish also consume these same forage fish species (Moulton 1977;Love 2011), the increased availability of Pacific Sand Lances and Northern Anchovy may confer similar benefits to the condition and growth of Black Rockfish.…”

Section: Black Rockfish In the California Currentmentioning

confidence: 99%

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Influence of Basin‐ and Local‐Scale Environmental Conditions on Nearshore Production in the Northeast Pacific Ocean

et al. 2016

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Nearshore marine habitats are productive and vulnerable owing to their connections to pelagic and terrestrial landscapes. To understand how ocean basin‐ and local‐scale conditions may influence nearshore species, we developed an annual index of nearshore production (spanning the period 1972–2010) from growth increments recorded in otoliths of representative pelagic‐feeding (Black Rockfish Sebastes melanops) and benthic‐feeding (Kelp Greenling Hexagrammos decagrammus) nearshore‐resident fishes at nine sites in the California Current and Alaska Coastal Current systems. We explored the influence of basin‐ and local‐scale conditions across all seasons at lags of up to 2 years to represent changes in prey quantity (1‐ or 2‐year time lags) and quality (within‐year relationships). Relationships linking fish growth to basin‐scale (Pacific Decadal Oscillation, North Pacific Gyre Oscillation, and multivariate El Niño–Southern Oscillation index) and local‐scale (sea surface temperature, sea surface height anomalies, upwelling index, photosynthetically active radiation, and freshwater discharge) environmental conditions varied by species and current system. Growth of Black Rockfish increased with cool basin‐scale conditions in the California Current and warm local‐scale conditions in the Alaska Coastal Current, consistent with existing hypotheses linking climate to pelagic production on continental shelves in the respective regions. Relationships for Kelp Greenlings in the California Current were complex, with faster growth related to within‐year warm conditions and lagged‐year cool conditions. These opposing, lag‐dependent relationships may reflect differences in conditions that promote quantity versus quality of benthic invertebrate prey in the California Current. Thus, we hypothesize that benthic production is maximized by alternating cool and warm years, as benthic invertebrate recruitment is food limited during warm years while growth is temperature limited by cool years in the California Current. On the other hand, Kelp Greenlings grew faster during and subsequent to warm conditions at basin and local scales in the Alaska Coastal Current. Received November 3, 2015; accepted May 5, 2016

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“…The abundance and timing of forage fish populations in the coastal region play a significant role in a number of ecosystem interactions, including the timing and success of seabird breeding performance (Anderson et al 1982, Safina & Burger 1988, Hedd et al 2006, Anderson et al 2007, and the ecology of sea lions (Sinclair & Zeppelin 2002, Womble et al 2005, Weise et al 2006, Womble & Sigler 2006, killer whales (Similä et al 1996), and minke whales (Macleod et al 2004). The timing of forage fish presence is also hypothesized to be an important factor in determining juvenile salmon marine survival by providing alternative prey for large piscivorous fish, marine mammals, and seabirds (Pearcy 1992).…”

Section: Introductionmentioning

confidence: 99%

Timing of forage fish seasonal appearance in the Columbia River plume and link to ocean conditions

Kaltenberg¹,

Emmett²,

Benoit‐Bird³

2010

Mar. Ecol. Prog. Ser.

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This study described the phenology and patterns of variability of forage fish and mesozooplankton populations near the Columbia River plume. Our objective was to identify the timing of the seasonal appearance of forage fish and to characterize the temporal patterns of abundance in relation to ocean conditions including zooplankton availability. Observations were collected at 2 stations in 2008 and 2009 using 200 kHz bio-acoustic moorings, and with bi-weekly net sampling surveys conducted at nearby stations to measure total fish density and relative species composition. Acoustic time series results revealed that the seasonal timing of acoustic schools, representing the forage fishes northern anchovy Engraulis mordax, whitebait smelt Allosmerus elongatus, and Pacific sardine Sardinops sagax, occurred abruptly, with specific dates of appearance identified at each station in mid-May in both years. Both 2008 and 2009 represented very similar years for the timing and strength of wind-driven coastal upwelling. The timing of forage fish appearances in these years was linked with ocean temperature and salinity data collected at a nearby oceanographic buoy but was poorly correlated with mesozooplankton abundance, which was highly variable and fluctuating over a period of hours to days. Fluctuations in zooplankton and forage fish populations drive many trophic interactions, including juvenile salmon, seabirds, and large predators (e.g. adult salmon) that rely on the timing and abundances of these populations and have significant implications for ecosystem based management.

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Effects of interdecadal climate variability on marine trophic interactions: rhinoceros auklets and their fish prey

Cited by 58 publications

References 50 publications

Forecasting ocean warming impacts on seabird demography: a case study on the European storm petrel

Forecasting ocean warming impacts on seabird demography: a case study on the European storm petrel

Influence of Basin‐ and Local‐Scale Environmental Conditions on Nearshore Production in the Northeast Pacific Ocean

Timing of forage fish seasonal appearance in the Columbia River plume and link to ocean conditions

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