Plant detectives seek sources of invasive trees

August 12, 2002

Like modern day Sherlock Holmeses, plant biologists at Washington University in St. Louis have donned their deerstalkers to get to the bottom of some botanical mysteries.

Barbara A. Schaal, Ph.D., Washington University professor of biology and her graduate students use DNA sequences to reveal information on historical events. Schaal has traced the origins of cassava using molecular techniques, and now is using systematics and phylogeography to document the role of hybridization and introgression in the evolution of Phlox species and to trace the Eurasian source of invasive Tamarix species in the United States.

The Tamarix species, commonly called saltcedar, are environmental threats that have invaded the arid southwest and are contributing to the drying up of creeks and streams in that water-threatened area. Over a million acres are now infested with saltcedar monocultures along streams and riverbeds. The salt cedars' long taproots suck up salty ground water and drop salt-crusted leaves on the soil surface. This makes it almost impossible for native plants to take root. The loss of native plants also decreases the insect and bird biodiversity.

Schaal's graduate student, John Gaskin, has used DNA sequences to identify which species are here and to document hybridization. Their DNA analyses also help them pinpoint where the plants may have originated in Eurasia. Earlier USDA studies show that an Arizona saltcedar will not be eaten by certain Asian insects known to like saltcedars; these insects, instead, prefer plants that grow in Texas or New Mexico. So, there are different kinds of the plants in different areas.

So far Schaal and Gaskin have found that the most common invasive here is a hybrid of two species that do not grow in the same areas of Asia, and thus is a novel plant genotype. These results will help USDA biological control researchers determine which insects to import in the future to help control the invasion, but caution that any novel hybrid plants may prove to be unpalatable to species-specific insects, since they did not evolve with them.

Schall and Gaskin published their results in the Proceedings of the National Academy of Sciences (PNAS), the week of Aug. 12-16, 2002.

Tamarix is the second most evasive plant in the United States. Purple loosestrife (Lythrum salicaria) is number one and a big problem in northern areas. Invasive plants are second only to habitat loss in contributing to loss of biodiversity.

PNAS WRITE-UP

Hybrid Plants Run Rampant

Previously undetected hybrids are a major component of a non-native plant invasion that has taken over more than 600,000 hectares of U.S. wetlands and riparian areas, report the authors of article #4032. Eurasian Tamarix, commonly known as saltcedar or tamarisk, was first introduced to the United States in the 1800s for the purposes of shade and erosion control. Since then, according to a genetic analysis performed by authors John Gaskin and Barbara Schaal, two of the introduced species of Tamarix have interbred to create a hybrid that may be resistant to biological control agents currently under development. In their native environments, the two species rarely overlap--T. ramosissima was found almost exclusively west of central China, while T. chinensis was found primarily to the east--but in the U.S., the two species have been placed in close proximity to each other and given ample opportunity to hybridize. By analyzing genetic variations among more than 250 plants gathered in the U.S. and Eurasia, the authors found that overall diversity is higher in Eurasia, but the proportion of novel hybrids is higher in the U.S. In fact, the most common plant in the U.S. invasion is a hybrid of T. ramosissima and T. chinensis. The authors also found that a small region within the Republic of Georgia and Azerbaijan contains all of the genetic variation of T. ramosissima common to both the U.S. and Eurasia, a discovery that could aid in the development of effective

biological controls. The authors note that Tamarix continues to spread across the U.S. at a rate of about 18,000 hectares per year, displacing other species and altering the hydrology of watercourses in fragile, arid environments.

"Hybrid Tamarix widespread in U.S. invasion and undetected in native Asian range," by John F. Gaskin and Barbara A. Schaal
-end-
Links: For more information on Tamarix or the current biological control project, see http://www.invasivespecies.gov/profiles/saltcedar.shtml and http://groups.ucanr.org/saltcedar/

Missouri Exotic Invasive Plant Page: http://www.mobotgradstudents.org/~mobot/MOEPPC/MOEIPP1.html

Gaskin Web site: http://www.mobotgradstudents.org/~mobot/Gaskin/johnpage.html

Schaal Web site: http://artsci.wustl.edu/~jfgaskin/schaal.html

Washington University in St. Louis

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