New 'biofactories' produce rare healing substances in the endangered Devil's claw plant

Deep in Africa’s Kalahari Desert lies the “Devil’s claw,” a plant that may hold the key to effective treatments for arthritis, tendonitis and other illnesses that affect millions each year. Unfortunately, years of drought have pushed the Devil’s claw toward extinction, so scientists are scrambling to devise new ways to produce the valuable medicinal chemicals of the Devil’s claw and other rare plants.

One group of scientists reported a major advance toward that goal here today at the 238th National Meeting of the (ACS). They described the first successful method of producing the in Devil’s claw — ingredients that have made the Devil’s claw a sensation in in Europe. Their technique may eventually lead to the development of “biofactories” that could produce huge quantities of extracts quickly and at little cost.

Milen I. Georgiev, Ph.D., who delivered the report, pointed out that for thousands of years, in Southern Africa have used the Devil’s claw as a remedy for a huge number of ailments, including fever, diarrhea and blood diseases. Today, there are dozens of medicinal and around the world that are based on chemicals derived from the Devil’s claw.

In particular, studies suggest that two chemicals — the so-called iridoid glycosides harpagoside and harpagide — may have in the treatment of degenerative , osteoarthritis, tendonitis, and other conditions, Georgiev said.

“In Germany, 57 based on Devil’s claw, marketed by 46 different companies, have cumulative sales volumes alone worth more than $40 million.” Georgiev noted. In the United States, Devil’s claw extracts are in phase II clinical trials for the treatment of arthritis. Other promising uses are not far behind. But while the demand for these is increasing, the supply of natural Devil’s claw is dwindling.

“The Devil’s Claw faces significant problems with its natural renewal, especially low rainfall,” Georgiev notes. “These problems are driving efforts to find alternative ways to produce high value compounds from the plant, independent of geographical and climatic factors,” he says.

Currently, more than 25 percent of all prescribed medicines used in industrialized countries are derived either directly or indirectly from plants, many of which are rare and sometimes endangered. “Hairy root,” an infectious plant disease caused by the soil bacteria Agrobacterium rhizogenes, is at the core of a promising new technique that could one day lead to “biofactories” that produce medicines derived from rare plants in huge quantities at a low cost. Georgiev notes that hairy roots are a big improvement over traditional, greenhouse-based plant culturing.

“The transformed root cultures possess fast growth rates, genetic and biochemical stability and the capacity for synthesis of plant metabolites. It should be also mentioned that the amount of active metabolites in naturally grown plants in greenhouses significantly vary seasonally,” notes Georgiev. Hairy root biofactories, on the other hand, could produce consistently high levels of plant metabolites year round.

Georgiev and his team are the first to induce hairy root cultures of Devil’s claw. They took the roots of the Devil’s claw and infected them with the A. rhizogenes soil bacteria — a natural genetic engineer — to create a system of hairy roots to produce the plant’s key medicinal chemicals. Their studies demonstrated stable growth and high production of both iridoid glycosides harpagoside and harpagide. Previous studies were only capable of producing one of these two compounds.

Georgiev notes that there is a long way to go before hairy root biofactories become commercialized, but he hopes to make the technology ready for use within a few years.

“Our target aim is to develop such technology, so we are paying attention not only to fundamental scientific tasks, but also to those related to some of the technological problems associated with hairy root biofactories,” Georgiev said. “It is the desire of each scientist is to see the fruits of his work. In the current case, we hope to be able to develop cost-effective laboratory technology for production of these pharmaceutically-important metabolites within the next five years.”

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