The Zebra Mussel

Dreissena polymorpha, a European mussel, was first discovered in North America in Lake St. Clair in June 1988.  The first confirmed sighting in the western basin of Lake Erie was in July 1988, and by 1991, it was spreading rapidly throughout the Great Lakes basin and had reached the Hudson River, upper Mississippi River, and the Susquehanna drainage basins.  It will probably soon achieve a wide distribution in North American lakes and rivers and may be limited by soft water and temperatures in the extreme northern and southern areas.
    The zebra mussel arrived in the ballast water of transoceanic ships from Europe. Ballast transport and fouling can also be credited with the discontinuous spread of the mussel into major upper Great Lakes ports in 1990. The mussel often occurs in very large numbers, and can exert large and far-reaching impacts on freshwater ecosystems through biofouling and filter-feeding. In Lake St. Clair, as the mussels reached high densities, they were shown to detrimentally affect the native unionid clams in the lake and to improve water clarity in the Detroit River. In 1992, genetic surveys of Great Lakes zebra mussel populations have isolated a new introduced species of Dreissena. The earliest verified collections of this zebra mussel are from the Lake Ontario basin in 1991.

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    Zebra mussels get their name from the striped pattern of their shells. However, the pattern has been seen to vary greatly to where there are no stripes, only dark or light colored shells. Zebra mussels can grow to a maximum length of about 50 mm (5-10 mm in the first year) and live four to five years. They inhabit fresh water, usually at depths of two to seven meters. Even though zebra mussels are freshwater animals, they have recently been found living in brackish water with salinity levels of one to two parts per thousand. 

Zebra mussels travel using the tufts of hair like filaments called byssal threads.  They have as many as two hundred threads at one time and secrete approximately twelve per day.  These hair-like threads enable the animal to travel great distances and attach to many mobile objects.  The byssal threads firmly bond to objects holding these animals in place.  This is part of the reason that these invasion species can cause far-reaching destruction.  Another reason that zebra mussels can travel great distances is because they can survive out of water for about two weeks.  This enables them to be transported on boats or equipment from one body of water to another.  In the picture above, the zebra mussels have clogged a water pipe causing great damage to the system and requiring costly repairs (Lathlin, 2000).  In some water facilities, the zebra mussels have been known to reach layers about 1.5 meters thick.  A mature female is capable of producing up to one million eggs per season.  Once the eggs are released into the water, the male fertilizes them and within days, they turn into free-swimming larvae called veligers.  These veligers swim and travel on water current for about three to four weeks.  Only about one to three percent survives and attach to a substrate where they mature into adults.
 
    Zebra mussels are notorious for their biofouling capabilities by colonizing water supply pipes of hydroelectric and nuclear power plants, public water supply plants, and industrial facilities. They colonize pipes constricting flow, therefore reducing the intake in heat exchangers, condensers, fire fighting equipment, and air conditioning and cooling systems. Zebra mussel densities were as high as 700,000 m2 at one power plant in Michigan and the diameters of pipes have been reduced by two-thirds at water treatment facilities. Although there is little information on zebra mussels affecting irrigation, farms and golf courses could be likely candidates for infestations.

The animals were first found in Lake St. Clair in 1988.  Since the initial introduction of these species into North America, they have spread to about eighteen states in the USA and two provinces in Canada   The maps below illustrate the rapid spread of the zebra mussel in the United States:

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One theory of many environmental scientists discusses the biology and ecology of organisms that are the predators of zebra mussels.  The predators are primary birds and fish and they eat the zebra mussels.  Other types of animals that reduce the population of zebra mussels are leeches, crabs, crayfish, and small rodents.  Organisms that are capable of removing zebra mussels from their attached surface include sponges, amphipods, algae, bryozoans, hydrozoan coelenterates, and other bivalve species.  Large amounts of the competitive species in Europe are not present in North America.  There are no indications however that the competition is strong enough to eliminate the zebra mussel population.  Large areas may be affected by the competitors but is not likely to have a large cumulative effect .

Zebra mussels are capable of filtering the water of the planktonic organisms and this has caused a problem in the Great Lakes region.  A large amount of zebra mussels causes the amount of planktonic organisms to decrease rapidly. The planktonic organisms are vital to the maintenance of the aquatic food web.
 

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Source:  Unknown

Parts of this web page were developed by Lizzi Day, a GEO 333 student.

This material has been compiled for educational use only, and may not be reproduced without permission.  One copy may be printed for personal use.  Please contact Randall Schaetzl (soils@msu.edu) for more information or permissions.