**ABSTRACT NOT FOR CITATION WITHOUT AUTHOR PERMISSION. The title, authors, and abstract for this completion report are provided below.  For a copy of the full completion report, please contact the author via e-mail at njohnson@usgs.gov or via phone at (989)734-4768 x 128. Questions? Contact the GLFC via email at frp@glfc.org or via telephone at 734-662-3209.**

 

DETERMINE THE CONTRIBUTION OF TRANSFORMERS FROM LENTIC AREAS TO SEA LAMPREY POPULATIONS IN LAKES HURON AND MICHIGAN

 

Nicholas S. Johnson 1, William D. Swink1,2, Travis Brenden3, and Matt Lipps4

 

1USGS Hammond Bay Biological Station, 11188 Ray Road, Millersburg, MI 49759

 

2Retired

 

3Michigan State University, Department of Fisheries and Wildlife, Room 13 Natural Resources Building, East Lansing, MI 48824

 

4U. S. Fish and Wildlife Service, Ludington Biological Station, 229 S. Jebavy

Drive, Ludington, MI 49431

 

July 2016

 

ABSTRACT:

 

Although population demographics of larval lampreys in streams have been studied extensively, demographics in lentic areas near stream mouths have not.  Here, we estimated survival and rates of metamorphosis for larval sea lamprey (Petromyzon marinus) populations residing in the Great Lakes near river mouths (herein termed lentic areas).  Tagged larvae were stocked and a Bayesian multi-state tag-recovery model was used to investigate population parameters associated with tag recovery, including survival and metamorphosis probabilities.  Compared to previous studies of larvae in streams, larval growth in lentic areas was substantially slower (Brody growth coefficient = 0.00132), survival was slightly greater (annual survival = 63%), and the length at which 50% of the larvae would be expected to metamorphose was substantially shorter (126 mm).  Stochastic simulations were used to estimate the production of parasitic stage (juvenile) sea lamprey from a hypothetical population of larvae in a lentic environment.  Production of juvenile sea lamprey was substantial because, even though larval growth in these environments was slow relative to stream environments, survival was high and length at metamorphosis was less.  However, estimated production of juvenile sea lamprey was less for the lentic environment than for similar simulations for river environments where larvae grew faster.  In circumstances where the cost to kill a larva with lampricide was equal and control funds are limited, sea lamprey control effort may be best directed toward larvae in streams with fast-growing larvae, because stream-produced larvae will most likely contribute to juvenile sea lamprey populations and teleost fish losses.