News Release

Nature mimics industry

Natural organohalogen compounds deserve more respect

Peer-Reviewed Publication

Dartmouth College



Gordon Gribble (photo by Amanda Weatherman)

Full size image available here.

Human made chemical compounds called organohalogens get loads of attention as they are best known for their often harmful effect on the environment – substances like the CFCs (the ozone-damaging chemicals), dioxin (found in the herbicide Agent Orange), PCBs (industrial fluids) and several pesticides. Their naturally occurring cousins, however, don't get the recognition they deserve, according to Dartmouth Chemistry Professor Gordon Gribble. Gribble has taken it upon himself to help scientists and the public understand that there are more than 4,000 naturally occurring organohalogens, and many are similar or even identical to their synthetic counterparts.

"Humans have been manufacturing organohalogen compounds like bleach, pesticides, pharmaceuticals, and other industrial chemicals for decades," says Gribble, who wrote about these compounds in the July-August issue of American Scientist, the magazine of the scientific research society Sigma Xi. "I think researchers forget to look to nature for remarkable examples of similar and often identical halogenated organic chemicals. These amazing compounds are a vital part of life, and they serve natural purposes as hormones, pheromones, repellents and natural pesticides."



The yellow star thistle is one of the few terrestrial plants that produces organochlorine compounds. (Photo courtesy of US Department of Agriculture)

Full size image available here.

Organohalogen compounds all contain one of the halogen elements chlorine, bromine, iodine or fluorine. Gribble keeps a record of newly discovered natural organohalogens. Because of improved underwater exploration and research capabilities, most new ones, he says, are being found in the ocean's marine life. The cone snail, for instance, which lives in tropical marine environments, produces a bromine-based venom that is extremely toxic to people, but allows the snail to effectively immobilize and kill its prey. Gribble explains that the cone snail's particular organobromine peptide is in human clinical trials for the treatment of pain.

"Sponges and tunicates are great examples of using chemicals for survival," says Gribble. "Being anchored to the reef, they can't swim and they don't have protective shells or teeth, so they biosynthesize chemicals for defense, many of which contain halogen due to the ocean's high salt content." Sponges and other marine organisms produce a variety of bromine-based organohalogens, which repel predatory fish and prevent bacterial overgrowth, he says. These compounds are being studied to someday prevent barnacle growth on the underside of ships. Several other marine organohalogens have promising medicinal value, including treatment for cancer, bacterial infection and HIV.



The females of 14 species of tick, like this deer tick, produce an organohalogen sex pheromone. (Photo courtesy of US Department of Agriculture)

Full size image available here.

Plants also make organohalogens. Broccoli and other related plants like cabbage, turnips and rapeseed (used to make canola oil) create a bromine-based organohalogen, methyl bromide, which is the same industrial chemical that has been used as a pesticide and fumigant, and which also has an ozone-depleting effect. According to Gribble's paper, rapeseed fields alone account for about 6,600 tons of this organobromine compound each year, or about 15 percent of the total from human activities. Peas, beans, lentils and other legumes make an organochlorine chemical as a growth hormone. The yellow star thistle, a hardy invasive species in many western states, produces a chlorine chemical that is currently being studied for its cancer-fighting characteristics. Other plant species make a highly toxic fluorine compound that is poisonous to livestock.

The organohalogen produced by many ticks, however, has a more alluring effect. The female of 14 tick species emits a chlorine-containing chemical that is a sex pheromone to attract suitors. After termites munch on wood, they produce chloroform, the same chemical produced when chlorine disinfects drinking water. People, too, make oganohalogens. Gribble's paper describes the process of how human white blood cells, in response to invasion by bacteria and fungi, create bleach and chlorine gas, an important germ-killing component of our immune system. Gribble is in the process of updating his book featuring examples of all known naturally occurring organohalogens. He searches scientific literature for references to new cases of plants, animals, insects and even bacteria producing organohalogens. He catalogues the references and keeps track of them all. Gribble emphasizes that many of these natural organohalogens have potent anticancer and antibacterial activity, and one organochlorine, vancomycin, is the life-saving drug for treating penicillin-resistant bacterial infections in hospital patients.

"The first edition in 1996 had about 2,400 compounds," he says. "The new edition will have more than 4,000. As chemists continue to explore terrestrial and marine organisms for new medicinal agents, a fraction of these natural chemicals will invariably contain chlorine or bromine, elements that have been a normal component of all life since the birth of our planet."

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