The invasive strain of Phragmites australis, or common reed, believed to have originated in Eurasia, exudes from its roots an acid so toxic that the substance literally disintegrates the structural protein in the roots of neighboring plants, thus toppling the competition.
“Phragmites is taking over the marsh world,” said UD plant biologist Harsh Bais. “It's a horticultural disaster.”
In Delaware alone, the tall, tasseled grass has overtaken tens of thousands of acres of wetlands, decreasing biodiversity, reducing the food and habitat available to wildlife, and altering wetland hydrology, transforming marshes once dissected by tidal creeks and open pools into much drier systems with dense monocultures of the plant.
Bais, who led the project, is an assistant professor of plant and soil sciences in UD's College of Agriculture and Natural Resources and holds an appointment at the Delaware Biotechnology Institute. His collaborators included postdoctoral researcher Thimmaraju Rudrappa, undergraduate student Justin Bonstall, and marine botanists John Gallagher and Denise Seliskar, who co-direct the Halophyte Biotechnology Center in UD's College of Marine and Earth Studies.
The results of the research are reported in the latest issue of the
Journal of Chemical Ecology.
Bais is an expert on allelopathy, in which one plant produces a chemical to inhibit the growth of another plant. He refers to these plants with the capability to wage chemical warfare as “natural killers.”
Walnut trees, pine trees, ferns and sunflowers are among the plants that release harmful chemicals to prevent other plants from growing too close to them.
However, Phragmites uses this strategy not so much to keep other plants away, but to aggressively conquer them and invade new territory.
“We've seen this capability in a number of invasive plants that have come from Eurasia, such as garlic mustard,” Bais said. “The roots exude a toxin that kills native plants.”
In laboratory analyses at the Delaware Biotechnology Institute, Rudrappa and Bais used activated charcoal, the material in aquarium filters, to sequester secretions from both invasive and native Phragmites plants. The charcoal attracts and traps organic chemicals.
The scientists identified the toxin produced by Phragmites as 3,4,5-trihydroxybenzoic acid. Also known as gallic acid, it is used for tanning leather, to formulating astringents.
“It's nasty stuff,” Bais said. “If you get some of it on your skin, you definitely know it.”
The toxin works, Bais said, by targeting tubulin, the structural protein that helps plant roots to maintain their cellular integrity and grow straight in the soil. Within 10 minutes of exposure to the toxin in the lab, the tubulin of a marsh plant under siege starts to disintegrate. Within 20 minutes, the structural material is completely gone.
“When the roots collapse from the acid, the plant loses its integrity and dies,” Bais noted. “It's like having a building with no foundation--it's on its way to self-destruction.”
The native Phragmites also secretes the toxin, but the exotic strain releases much higher concentrations, which could be a key to its dominance, Bais said.
Today in Delaware, stands of native Phragmites are few and far between. Bais credits Gallagher and Seliskar, who have conducted extensive research on the plant, for growing sterile cultures of the native and exotic strains for his lab tests.
“This research reveals another weapon in the arsenal that Phragmites uses to overtake marshland,” Seliskar said.
“Screening large numbers of marsh plants to identify those that are naturally resistant to invasive Phragmites may be one avenue for preserving the native strain, as well as controlling the invasive's spread,” Bais noted.
With the current discovery in hand, Bais said he hopes to pursue further research to pinpoint exactly how the invasive Phragmites has become such a “super weed.” Such information could help scientists and environmental managers gain a foothold in halting Phragmites' rapid advance across the United States.
“We now know this plant secretes a toxin underground, but could it have a partner in crime"” Bais asks. “Could there be some kind of microbe, a deleterious pathogen, that is associated with this plant" And does this plant use changing environmental systems to its advantage" We just don't know the answers yet, but we'd like to find out.”
Source: University of Delaware
Related stories:
New gene that helps plants beat the heat
Michigan State University plant scientists have discovered another piece of the genetic puzzle that controls how plants respond to high temperatures. That may allow plant breeders to create new varieties of crops that flourish in warmer, drier climates.
Venus flytraps caught in shrinking natural habitat
(AP) -- Laura Gadd pauses at the edge of a pristine savanna, delicately lifting her feet to avoid trampling any venus flytraps hidden underfoot.
AP Investigation: Ike environmental toll apparent
(AP) -- Hurricane Ike's winds and massive waves destroyed oil platforms, tossed storage tanks and punctured pipelines. The environmental damage only now is becoming apparent: At least a half million gallons of crude oil spilled into the Gulf of Mexico and the marshes, bayous and bays of Louisiana and Texas, according to an analysis of federal data by The Associated Press.
Which grass is greener to power the bioenergy era?
(PhysOrg.com) -- Talk about a field of dreams. Cornell bioenergy plant experts are learning which field grasses are the best candidates for "dedicated energy" crops in the Northeast, considering the region's climate and soil conditions.
Reproducing early and often is the key to rapid evolution in plants
Yale researchers have harnessed the power of 21st century computing to confirm an idea first proposed in 1916 — that plants with rapid reproductive cycles evolve faster. Their findings appear in the October 3rd edition of
Science.
Biochemists devise method for bypassing aluminum toxicity effects in plants
(PhysOrg.com) -- Aluminum toxicity, a global agricultural problem, halts root growth in plants, severely limiting agricultural productivity for more than half of the world's arable land.
Sharp Launches Mass Production of 2nd-Generation Thin-Film Solar Cells
Sharp Corporation has completed installation of a new 2nd-generation thin-film solar cell production line at its Katsuragi Plant (Katsuragi City, Nara Prefecture) using large-size glass substrates measuring 1,000 x 1,400 mm, equivalent to 2.7 times the area of conventional substrates (560 x 925 mm), and will begin volume production this October.
The search for 'green' gold in the Amazon rain forest
(PhysOrg.com) -- In a hunt for plants in the Amazon rain forest that have potential to be used for sustainable light-weight construction beams, electronic cases or other high-performance materials, Cornell fiber science professors Anil Netravali and Juan Hinestroza are forging new collaborations with researchers in Brazil.
