BP's Gulf leak boosts interests in oil-eating microbes

Fred TaskerMcClatchy-Tribune News Service

One scientist compares them to the yellow chompers in the Pac-Man video game —

hungry, single-minded little microbes fueled by the same fertilizer that farmers use on

soybeans, gobbling hydrocarbons from the oily waters, marshes and shores of the Gulf of

Mexico.

Can the naturally occurring microbes help clean up the oil spill?

Yes, experts say. At least in part, with some risk.

Officials are taking note. Florida Gov. Charlie Crist on Thursday visited a Sarasota company

that sells microbes that eat oil. BP says it's open to using them. And the federal

government this week is contacting its pre-approved list of more than a dozen companies

to see how quickly they can ramp up production.

Scientists call the process bioremediation.

"You take natural oil-eating microbes in the water and give them fertilizer to make

them multiply and degrade the oil faster. Oil is a natural product. It's inherently

biodegradable,'' said Terry Hazen, microbial ecologist in the Earth Sciences Division of

the Lawrence Berkeley National Lab in California.

Oil-eating microbes are some of the smallest living things on earth, but they can

have a powerful impact. They occur naturally in water and, when they come in contact

with oil, they eat it, producing the byproducts carbon dioxide and water. When

fertilized with nitrogen and phosphorous, they grow in size and multiply and their

appetites become prodigious.

Still, scientists caution that bioremediation is only a partial solution. It's best

used on sandy beaches and in salt marshes after the thickest oil has been removed by

bulldozer and shovel. It's never been tried before in deep water or open ocean.

And it runs some risk of damaging the very waters it's meant to rescue. Some

scientists say it may be better at times to let nature take its course.

Jay Grimes, a microbiologist at the University of Southern Mississippi, is a fan of

the process: "It could help a lot. It was used in the Alaska oil spill [from the Exxon

Valdez in 1989]. It worked very well on the rocky shores.''

Bioremediation can't do the whole job, said Chris Reddy, marine chemist at Woods Hole

Oceanographic Institution in Massachusetts.

"The idea that microbes can come in and clean house from A to Z is not likely,'' he

said. "What they can do — on their own time — is eat some compounds and play an

important role in the cleanup.''

BP says it's looking into bioremediation. "Potentially we could do it, but we would

need approval from the EPA,'' spokesman Tristan Vanhegan said Wednesday. "Typically

it's not done until the oil has stopped flowing.''

The federal government is working on possible bioremediation efforts. The EPA has

created a National Contingency Plan Product Schedule listing more than 20 biological

agents approved for use in encouraging microbes to attack oil spills. And the USDA's

Natural Resources Conservation Service is contacting the companies that make them to see

how quickly they can ramp up production.

And there's yet another oil-eating product, called Munox, made by Osprey Biotechnics

of Sarasota, that has interest from Florida officials. Munox isolates natural microbes

from nature, ferments them and adds proprietary ingredients to turn them into a

concentrated liquid form to spray on oil spills.

But there's a danger. Add too much fertilizer and you can create blooms of algae that

use up all the oxygen in the surrounding water, creating "dead zones.'' There's already

a 6,000-square-mile dead zone in the Gulf off the mouth of the Mississippi River,

created years ago by the same fertilizers washing down from upriver farms.

"It's pretty big and pretty scary,'' said Jim Spain, professor of environmental

engineering at Georgia Tech.

As much as 20 million gallons of oil a year naturally seeps into the Gulf through

tiny fissures in the seabed. Over time, microbes have evolved that eat the oil in the

water — enough so that all the seeping oil doesn't create a sheen.

The microbes are neither plant nor animal. They're bacteria, with names like

Alcanivorax borkumensis.

But the huge BP spill has overwhelmed existing microbes. To grow enough in size and

number to cope with the spill, they need nitrogen, phosphorous and iron.

"They're like Pac-Men — their mouths are only so big,'' said Reddy. "Their ability

to eat oil is closely coupled to their number.''

Fueled by fertilizer, the microbes can multiply and eat the oil. That's the upside.

The possible downsides are less well-understood.

"There hasn't been a full-scale addition of fertilizer in the open ocean to clean up

a spill,'' said Spain. "There's never been an experiment as big as this. We have to be

very careful.''

Scientists differ over the success of past bioremediations.

In Alaska after the 1989 Exxon Valdez spill, clean-up crews spread nitrogen and

phosphorus in liquid sprays and slow-release pellets on hundreds of miles of oil-coated

rocks in Prince William Sound to quicken the action of natural microbes in eating the

oil, says Ronald Atlas, a microbiologist at the University of Louisville who took part

in the cleanup.

Atlas says, and a 1991 EPA after-action report confirms, that the fertilizer

increased the degradation of the oil three- to five-fold, with no damage to the

environment.

"The beaches became visually cleaner,'' the report said.

Hazen, who studied the project, has a different conclusion. He says the

bioremediation of the sound with phosphorous and nitrogen wrought severe long-term

damage to its ecology.

"We took a low-nutrition environment and added lots of fertilizer. The phosphorous

created nuisance algae.''

Bioremediation in the Gulf of Mexico must be thoroughly studied and done carefully,

the experts agree.

"There may be reason to use it where the oil is not degrading fast enough,'' Hazen

said. "In other cases, the best thing may be to do nothing.''

Scientists differ on whether fertilizing natural microbes can help degrade deep oil

plumes as far as 3,300 feet beneath the surface of the Gulf. Georgia Tech's Spain said

he fears fertilizing microbes at great depths might use up the tiny amounts of oxygen

that exist there, creating even more oxygen-depleted dead zones.

Last week, Hazen and his team set out in boats to examine the plumes, taking 200

water samples in the Gulf. They found microbes already in existence and noted it might

not be necessary to add fertilizer.

But nearer shore, on sandy beaches and in salt marshes, microbes might have a bigger

role, Hazen said.

"The best thing you can do is to use sorbentsû and skimmers to get as much as you

can. Then look seriously to decide if you need to do anything else,'' he said.

Grimes, the Mississippi biologist, believes microbes can help in salt marshes, where

oil mixes with water and grass and can't be cleaned by bulldozers or shovels.

"The first year there's not much you can do do reverse damage to marine animals or

plants in marshes. But if you can speed biodegradation, you can hope the ecosystem will

start to rebuild within four or five years,'' he said.

He added that it's important not to let wave action wash fertilizer into the water

where it could create algae blooms.

Another potential problem is that when microbes eat oil, a byproduct is carbon

dioxide — a greenhouse gas. In an area as large as the Gulf, could it be enough to hurt

the ozone layer?

"We don't have that answer,'' Grimes said.

Despite its shortcomings, bioremediation of oil spills has influential supporters.

Albert Venosa, an environmental expert at the EPA's National Risk Management Research

Laboratory who studied the issue told a U.S. House subcommittee June 9: "Bioremediation

can be very effective on sandy marine shorelines, wetlands and salt marshes. But it is

much slower [than mechanical means] — weeks to months or more — and is not usually

considered a first response.''


Fred Tasker
Miami Herald