A deep chlorophyll maximum nourishes benthic filter feeders in the coastal zone of a large clear lake

Malkin, Sairah Y.; Silsbe, Greg M.; Smith, Ralph E. H.; Howell, E. Todd

doi:10.4319/lo.2012.57.3.0735

Cited by 23 publications

(15 citation statements)

References 44 publications

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“…Consequently, faster growth may be explained by stronger effects of the fall bloom, consistent with our biophysical model results suggesting that most food in the profundal habitats is available to mussels during only brief mixing periods (Fig. a,b; see below), or by the contact of the deep chlorophyll layer with the lake bottom, which can promote mussel growth (Malkin et al ). In either case, these conditions do not appear to be representative of other profundal habitats below 50 m depths.…”

Section: Resultssupporting

confidence: 88%

“…In littoral habitats, mussels grew nearly twice as fast as in most profundal habitats, an effect which our study likely underestimated by omitting the effects of food depletion within a near‐bottom boundary layer because all cages in 2015 were suspended about 0.7 m above the bottom. Suspension of cages in the water column above the benthic layer resulted in elevated growth compared to animals on the bottom, where food resources are depleted due to mussel filtration, a result found for both fresh and marine mussels (Wildish and Kristmanson ; Fréchette and Bourget ; Peterson and Beal ; Yu and Culver ; Karatayev et al ; Malkin et al ). In the Great Lakes specifically, seston‐depleted benthic boundary layers extending 1–2 m above dreissenid mussel beds have been reported previously (Ackerman et al ; Liao et al ); these layers were maintained by mussel consumption of particles and a downward turbulent flux of particles into the benthic boundary layer from waters above.…”

Section: Discussionmentioning

confidence: 96%

“…Food resources are likely depleted within the benthic boundary layer due to mussel filtration. Such features are known to limit growth in both freshwater and marine mussels (Fréchette and Bourget ; Peterson and Beal ; Yu and Culver ; Karatayev et al ), including in the Great Lakes (Malkin et al ). To resolve any boundary layer effects on growth and recruitment, we also placed cages directly on the bottom (i.e., on the cinder block anchor) and 0.7 m above the bottom.…”

Section: Methodsmentioning

confidence: 99%

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Food depletion regulates the demography of invasive dreissenid mussels in a stratified lake

Karatayev

Burlakova

et al. 2018

Limnology & Oceanography

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Lake stratification produces sharp gradients in temperature and pelagic resources which have cascading effects on the traits of aquatic populations, including invasive species and their ecosystem impacts. We study the consequences of such common environmental gradients on the demography of quagga mussels, one of the world's most aggressive invasive species. Coupling a series of in situ experiments with a biophysical model of the pelagic community, we quantify mussel growth and recruitment in littoral vs. profundal benthic habitats of eastern Lake Erie. We found that both severe food depletion and cold temperatures in the hypolimnion during summer stratification cause mussels to grow twice as slowly and currently inhibit recruitment in profundal compared to littoral habitats. Together with the high biomass and large mean mussel size found in long-term monitoring surveys in the profundal habitats, our results imply that mussels successfully colonizing profundal habitats have relatively long lifespans with low growth rates, and therefore lower productivity, compared to mussels in shallow areas. Consequently, the bulk of dreissenid biomass in Lake Erie and other Great Lakes found in the vast but resource-poor profundal habitats may have very limited impacts on epilimnetic communities compared to mussels in littoral areas. By contrast, mussels in profundal habitats strongly reduce food availability to hypolimnetic communities throughout the year. Thus, our results explain how the ecosystem impacts of sessile freshwater invaders are likely to vary among habitats and lakes depending on the relative size of profundal populations and the extent of stratification.The physiological activities of individuals both determine and reflect how species interact with and impact their ecosystem. For example, high rates of reproduction, growth, and mortality within a species correspond to a strong per capita energetic role in the ecosystem. Differences in environmental conditions or community composition across habitats can therefore produce variation in both the demographic rates of a species and its ecological role (J onasson 2004;Benton et al. 2006). This variation can be especially pronounced in widespread species with strong capacity for phenotypic plasticity, such as invasive species (Davidson et al. 2011). Consequently, ignoring demographic variation among habitats by focusing detailed population studies on specific habitats can produce a strong, unrecognized bias in the estimated ecological role of a species. The importance of this bias is especially acute for invaders rapidly expanding their distribution range, as the impacts of such species in novel ecosystems can be simultaneously strong and poorly resolved.Thermal stratification is one particularly common source of habitat heterogeneity in aquatic ecosystems. In lakes with strong stratification during productive summer seasons, species are distributed along environmental gradients from the warm, well-mixed littoral zone, where the surface mixedlayer intersects th...

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Section: Resultssupporting

confidence: 88%

Section: Discussionmentioning

confidence: 96%

Section: Methodsmentioning

confidence: 99%

See 1 more Smart Citation

Food depletion regulates the demography of invasive dreissenid mussels in a stratified lake

Karatayev

Burlakova

et al. 2018

Limnology & Oceanography

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“…Predicted feeding rates were commonly half or less of those expected in the absence of the hydrodynamic limitation that results in creation of the near-bottom depletion zone (Boegman et al 2008a), and mussel growth is likely affected as well. In Lake Ontario, mussels suspended 2 m off bottom, outside the near-bottom zone of depleted Chl-a, grew faster than those living on the bottom (Malkin et al 2012), with bottom-dwelling mussels actually losing weight over the latter half of the summer. In Lake Simcoe, such hydrodynamic limitation (causing near-bottom depletion) could occur at a range of depths but seems especially likely for mussels in the 7.5-15 m depth interval, where high dreissenid biomass is commonly found and thermal stratification decreases turbulent mixing and thus facilitates near-bottom depletion.…”

Section: Discussionmentioning

confidence: 99%

“…In Lake Ontario, the DCM seems to be important in permitting growth of mussels at intermediate depths (10-15 m) in early summer, whereas mussels at such depths achieve either no or even negative growth in late summer when the DCM has deepened and dissipated (Malkin et al 2012). Additional study of DCM biomass and productivity as well as mussel feeding and growth in Lake Simcoe would be warranted to better understand how mussels succeed in maintaining population biomass in the face of hydrodynamic limitation, which is likely to be persistent when seasonal stratification is present.…”

Section: Discussionmentioning

confidence: 99%

Impacts of hydrodynamics and benthic communities on phytoplankton distributions in a large, dreissenid-colonized lake (Lake Simcoe, Ontario, Canada)

Schwalb

Bouffard

Ozersky

et al. 2013

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We quantified the vertical and horizontal variation of chlorophyll a (Chl-a) to test how benthic filter feeders (dreissenid mussels), rooted macrophytes, and hydrodynamics influence phytoplankton distributions in a large lake (Lake Simcoe, Canada). Water column Chl-a did not differ significantly among sites of different depth, distance offshore, or rooted macrophyte biomass, but among the nearshore sites (7.5-10 m deep) it was higher where mussel biomass was greater. This counterintuitive result may be explained by wind-driven horizontal circulation during our specific study periods together with the patchy distribution of the mussels in the lake. Information on mixing depths, vertical eddy diffusivity, and mussel biomass was used to predict when and where the grazing pressure of mussels would likely deplete near-bottom phytoplankton. Chl-a depletion was frequently predicted at sites with moderate or high mussel biomass and sufficient thermal stratification to impede vertical mixing but never at sites without thermal stratification. Observations were consistent with predictions in most cases. The results suggested that mussels at depths of 7.5-15 m (a depth range of generally high mussel biomass in the lake) may frequently suffer food limitation due to near-bottom depletion during the early and middle stratified season. A deep Chl-a maximum was documented and may be important for mussel nutrition at such times.

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Movements of the thermocline lead to high variability in benthic mixing in the nearshore of a large lake

Chowdhury

Wells

Howell

2016

Water Resources Research

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The thermocline of Lake Ontario is in constant motion, and as it washes back and forth along the sloping lakebed there is a striking asymmetry in near‐bed stratification and benthic turbulence between its rise and fall. Detailed field observations of the stratification and water currents from the summers of 2012 and 2013 showed that the thermocline motions had large amplitudes (as high as 15 m) and a dominant period between 16 and 17.5 h, corresponding to a near‐inertial internal Poincaré wave. During the falling phase, the warmer down‐slope flow was strongly stratified with near‐bed water temperature gradients of 1°C m−1. In contrast during the rising phase of colder up‐slope flow, there was an unstable stratification in near‐bed water and large temperature overturns due to the differential advection of stratified waters, i.e., the shear‐driven convective mechanism. Using a Thorpe‐scale analysis of overturns, the inferred turbulent diffusivity during the up‐slope flow was Kz =5 × 10−4 m2 s−1. In striking contrast during the down‐slope flow, the strong stratification had lower turbulent diffusivities of Kz =10−6 m2 s−1. The near bottom region of Lake Ontario within the thermocline swash‐zone has intense biological activity and the highest concentrations of invasive dreissenid mussels. We discuss the potential biological implications of the striking variability in benthic mixing and near‐bed stratification for nutrient cycling in the Lake Ontario nearshore.

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A deep chlorophyll maximum nourishes benthic filter feeders in the coastal zone of a large clear lake

Cited by 23 publications

References 44 publications

Food depletion regulates the demography of invasive dreissenid mussels in a stratified lake

Food depletion regulates the demography of invasive dreissenid mussels in a stratified lake

Impacts of hydrodynamics and benthic communities on phytoplankton distributions in a large, dreissenid-colonized lake (Lake Simcoe, Ontario, Canada)

Movements of the thermocline lead to high variability in benthic mixing in the nearshore of a large lake

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