Description from NSF award abstract:
Prey selection, intake and, ultimately, the trophic impact of predators are determined by a succession of events that occur at the organismal level -- individual interactions among predators prey, and their environments. Furthermore, because the majority of predator-prey interactions occur in moving fluids, it is critical to observe and quantify predator-prey interactions within a hydrodynamic context. Successful predictions of trophic patterns in natural settings are limited by the ability to: 1) observe directly the effects of turbulence on feeding in pelagic organisms; 2) understand the mechanistic bases of animal-fluid interactions in turbulent environments; and 3) relate quantitative observations from still-water laboratory studies to nature. These limitations are pervasive in studies of trophic exchange within the larger scope of marine ecology.
Recent technological advances, and the combined expertise of the Co-PIs, enables meaningful studies of the influence of turbulence on feeding by the notoriously invasive lobate ctenophore, Mnemiopsis leidyi. Mnemiopsis is a delicate gelatinous predator which uses a laminar feeding current to entrain and capture prey. Using a remarkably effective feeding strategy, zooplankton standing stocks and overall zooplankton biodiversity are reduced, and standing stocks of phytoplankton are increased via a trophic cascade. Like many suspension feeders, however, the feeding current produced by Mnemiopsis may be vulnerable to hydrodynamic disruption by ambient flows. In fact, turbulent events may change the behavior, distribution and prey selection of lobate ctenophores such as Mnemiopsis. This species is an ideal model organism to determine the mechanisms by which turbulence affects trophic exchange patterns of ecologically influential planktonic suspension feeders.
Involving a combination of laboratory and in situ methods to quantify, at the organismal level, this study will determine effects of turbulent flows on the feeding mechanics and predator-prey interactions of Mnemiopsis. Understanding how these turbulent effects translate to the community level will be accomplished via in situ sampling techniques that relate natural turbulence levels to ingestion rates, prey selection and predatory impact of Mnemiopsis in the field. This approach extends beyond current laboratory and modeling studies, with the potential of establishing clear cause-and-effect relationships.
This research will: 1) directly quantify turbulent effects on in situ predator-prey interactions; 2) provide mechanistic understanding of key variables influencing the ecological impact of an important invasive marine species; and 3) develop a novel approach for studying small-scale physical-biological interactions both in the laboratory and in the field.
Knowing how turbulence affects feeding in lobate ctenophores is valuable at the scale of the organism, as well as ecologically. The approach developed here also may be applied to a variety of other turbulence-dominated situations (e.g., mixing at fronts, animal-marine snow interactions) or to other organisms (other plankton, benthic-water column exchanges). In all cases, the outcomes depend upon small-scale physical-biological processes.
Dataset | Latest Version Date | Current State |
---|---|---|
Wind data from June to October 2012; recorded near the MBL Dock, Woods Hole, MA, USA (Mnemiopsis feeding in turbulence project) | 2015-03-30 | Final no updates expected |
Acoustic Doppler Velocimeter (ADV) collected from the surface to the bottom at 30 cm intervals from the MBL dock in Woods Hole, MA, USA in 2012 (Mnemiopsis feeding in turbulence project) | 2015-03-27 | Final no updates expected |
Salinity and temperature data collected at the MBL dock in Woods Hole, MA, USA in 2012 (Mnemiopsis feeding in turbulence project) | 2015-03-27 | Final no updates expected |
Weather conditions recorded near the MBL Dock, Woods Hole, MA, USA on August 14, 2012 (Mnemiopsis feeding in turbulence project) | 2015-03-27 | Final no updates expected |
Lead Principal Investigator: John H. Costello
Providence College
Principal Investigator: Sean Colin
Roger Williams University (RWU)
Principal Investigator: John O. Dabiri
California Institute of Technology (Caltech)
Contact: John H. Costello
Providence College