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Waterbird Distribution and Foraging Patterns on the Great Lakes with Respect to Avian Botulism Active

By Upper Midwest Environmental Sciences Center May 19, 2017

The Upper Midwest Environmental Sciences Center (UMESC) in La Crosse, Wisconsin is studying the distribution and foraging patterns of sentinel fish-eating waterbirds through aerial surveys, and by tracking migration movements coupled with foraging depth profiles of common loons equipped with archival geo-locator tags and satellite transmitters. The results of this work are expected to elucidate where piscivorous waterbirds are likely to be exposed to forage fish carrying type-E botulinum toxin, which in turn will inform site-specific efforts to assess the degree to which physical and ecological factors contribute to the occurrence of botulinum toxin in aquatic food webs.

Periodic outbreaks of type-E botulism have resulted in die-offs of fish and fish-eating birds in the Great Lakes since at least the 1960s, but outbreaks have become more common and widespread since 1999.  Extensive bird mortality has caused great public concern, yet the actual site of toxin exposure among birds remains unclear. The physical and ecological factors that lead to botulism outbreaks are poorly understood, but invasive species, such as dreissenid mussels and round gobies, may serve to mobilize toxin from lake-bed sediments to fish-eating water birds and other aquatic species. Central to this question are feeding patterns and exposure routes of sentinel waterbird species, such as common loons (Gavia immer), historically at risk to botulism die-offs. This study is part of a larger USGS effort to investigate the dynamics of botulinum toxin production and food web distribution of the toxin.

Geolocator Tag on Loon, Gavia immer
Sources/Usage: Public Domain.
Geolocator tags, attached to common loons via leg bands, record daily location, temperature, and water-pressure data that will log the foraging depths of these diving birds.​​​​​​​Geolocator Tag on Loon, Gavia immer(Credit: Kevin Kenow, USGS UMESC. Public domain.)

 

Loon with geolocator
Sources/Usage: Public Domain.
The common loon is a species that is susceptible to avian botulism during migration stop-over on the Great Lakes.Loon with geolocator, Porcupine Bay (Credit: Luke Fara, USGS UMESC. Public domain.)
Dive profile
Sources/Usage: Public Domain.
Dive profile, interpreted from geolocator tag pressure data, depicting timing and depths of individual dives of common loon on November 4, 2009 during a migration stop-over on Lake Michigan.(Public domain.)

 

 

concentrations of common loons (warmer colors indicate higher densities)
Sources/Usage: Public Domain.
The abundance and distribution of waterbirds are determined during aerial surveys of Lake Michigan.  This graphic depicts concentrations of common loons (warmer colors indicate higher densities) in survey areas that were estimated from individual common loon observations (dot size is related to number of loons observed).(Public domain.)

Below are publications associated with this project.

Distribution and foraging patterns of common loons on Lake Michigan with implications for exposure to type E avian botulism

Common loons (Gavia immer) staging on the Great Lakes during fall migration are at risk to episodic outbreaks of type E botulism. Information on distribution, foraging patterns, and exposure routes of loons are needed for understanding the physical and ecological factors that contribute to avian botulism outbreaks. Aerial surveys were conducted to document the spatiotemporal distribution of common
Authors
Kevin P. Kenow, Steven C. Houdek, Luke J. Fara, Brian R. Gray, Brian R. Lubinski, Darryl J. Heard, Michael W. Meyer, Timothy J. Fox, Robert Kratt
By
Ecosystems Mission Area, Upper Midwest Environmental Sciences Center

Identifying the origin of waterbird carcasses in Lake Michigan using a neural network source tracking model

Avian botulism type E is responsible for extensive waterbird mortality on the Great Lakes, yet the actual site of toxin exposure remains unclear. Beached carcasses are often used to describe the spatial aspects of botulism mortality outbreaks, but lack specificity of offshore toxin source locations. We detail methodology for developing a neural network model used for predicting waterbird carcass m
Authors
Kevin P. Kenow, Zhongfu Ge, Luke J. Fara, Steven C. Houdek, Brian R. Lubinski
By
Ecosystems Mission Area, Upper Midwest Environmental Sciences Center
  • Overview

    The Upper Midwest Environmental Sciences Center (UMESC) in La Crosse, Wisconsin is studying the distribution and foraging patterns of sentinel fish-eating waterbirds through aerial surveys, and by tracking migration movements coupled with foraging depth profiles of common loons equipped with archival geo-locator tags and satellite transmitters. The results of this work are expected to elucidate where piscivorous waterbirds are likely to be exposed to forage fish carrying type-E botulinum toxin, which in turn will inform site-specific efforts to assess the degree to which physical and ecological factors contribute to the occurrence of botulinum toxin in aquatic food webs.

    Periodic outbreaks of type-E botulism have resulted in die-offs of fish and fish-eating birds in the Great Lakes since at least the 1960s, but outbreaks have become more common and widespread since 1999.  Extensive bird mortality has caused great public concern, yet the actual site of toxin exposure among birds remains unclear. The physical and ecological factors that lead to botulism outbreaks are poorly understood, but invasive species, such as dreissenid mussels and round gobies, may serve to mobilize toxin from lake-bed sediments to fish-eating water birds and other aquatic species. Central to this question are feeding patterns and exposure routes of sentinel waterbird species, such as common loons (Gavia immer), historically at risk to botulism die-offs. This study is part of a larger USGS effort to investigate the dynamics of botulinum toxin production and food web distribution of the toxin.

    Geolocator Tag on Loon, Gavia immer
    Sources/Usage: Public Domain.
    Geolocator tags, attached to common loons via leg bands, record daily location, temperature, and water-pressure data that will log the foraging depths of these diving birds.​​​​​​​Geolocator Tag on Loon, Gavia immer(Credit: Kevin Kenow, USGS UMESC. Public domain.)

     

    Loon with geolocator
    Sources/Usage: Public Domain.
    The common loon is a species that is susceptible to avian botulism during migration stop-over on the Great Lakes.Loon with geolocator, Porcupine Bay (Credit: Luke Fara, USGS UMESC. Public domain.)
    Dive profile
    Sources/Usage: Public Domain.
    Dive profile, interpreted from geolocator tag pressure data, depicting timing and depths of individual dives of common loon on November 4, 2009 during a migration stop-over on Lake Michigan.(Public domain.)

     

     

    concentrations of common loons (warmer colors indicate higher densities)
    Sources/Usage: Public Domain.
    The abundance and distribution of waterbirds are determined during aerial surveys of Lake Michigan.  This graphic depicts concentrations of common loons (warmer colors indicate higher densities) in survey areas that were estimated from individual common loon observations (dot size is related to number of loons observed).(Public domain.)
  • Publications

    Below are publications associated with this project.

    Distribution and foraging patterns of common loons on Lake Michigan with implications for exposure to type E avian botulism

    Common loons (Gavia immer) staging on the Great Lakes during fall migration are at risk to episodic outbreaks of type E botulism. Information on distribution, foraging patterns, and exposure routes of loons are needed for understanding the physical and ecological factors that contribute to avian botulism outbreaks. Aerial surveys were conducted to document the spatiotemporal distribution of common
    Authors
    Kevin P. Kenow, Steven C. Houdek, Luke J. Fara, Brian R. Gray, Brian R. Lubinski, Darryl J. Heard, Michael W. Meyer, Timothy J. Fox, Robert Kratt
    By
    Ecosystems Mission Area, Upper Midwest Environmental Sciences Center

    Identifying the origin of waterbird carcasses in Lake Michigan using a neural network source tracking model

    Avian botulism type E is responsible for extensive waterbird mortality on the Great Lakes, yet the actual site of toxin exposure remains unclear. Beached carcasses are often used to describe the spatial aspects of botulism mortality outbreaks, but lack specificity of offshore toxin source locations. We detail methodology for developing a neural network model used for predicting waterbird carcass m
    Authors
    Kevin P. Kenow, Zhongfu Ge, Luke J. Fara, Steven C. Houdek, Brian R. Lubinski
    By
    Ecosystems Mission Area, Upper Midwest Environmental Sciences Center