Glomalin: soil's superglue.
Abstract: Sara E. Wright, an Agricultural Research Service soil scientist, has discovered a certain fungal protein that may be used as a primary soil glue. The protein was named 'glomalin' for Glomales which is a scientific name for the group of common root-dwelling fungi that secrete the protein through the hairlike filaments called hyphae. Glomalin coats soil particles which hold them together in a stable structure. Higher glomalin content explains why eastern soils have stronger structural stability than the western soils.
Subject: Soil permeability (Methods)
Soil fungi (Usage)
Author: Comis, Don
Pub Date: 10/01/1997
Publication: Name: Agricultural Research Publisher: U.S. Government Printing Office Audience: Academic; General Format: Magazine/Journal Subject: Agricultural industry; Biotechnology industry; Business Copyright: COPYRIGHT 1997 U.S. Government Printing Office ISSN: 0002-161X
Issue: Date: Oct, 1997 Source Volume: v45 Source Issue: n10
Accession Number: 20095597
Full Text: Agricultural Research Service soil scientist Sara E. Wright has discovered a unique fungal protein that may be the primary glue that holds soils together.

She named the gooey protein "glomalin" for Glomales, the scientific name for the group of common rootdwelling fungi that secrete the protein through hairlike filaments called hyphae. The fungal hyphae are found worldwide on the roots of many plants. Glomalin sloughs off of the hyphae and finds its way into soil.

"It coats soil particles and may be what holds them together in the stable structures we call aggregates," says Wright. "Farmers and gardeners know them as the small grains of soil that sift through their hands and suggest to them that the soil has good structure."

Wright knew she had something unique when it took up to 90 minutes in a heat-sterilizing autoclave to free glomalin from the hyphae. "That's unheard of in the soil sciences, although an hour or more of autoclaving has been used to free proteins from some yeasts. With that level of persistence, we knew glomalin must stay in the soil, too."

So Wright began searching soils. She started with a dozen eastern soils and found that with the measuring technique she used, glomalin was as high as 2 percent of the total weight of a soil aggregate. When she moved on to test soils from the West and Midwest, she found levels were dramatically lower, although still abundant. She has also found glomalin in soil samples sent from several cooperators throughout the world.

"It may be that the higher glomalin levels explain why eastern soils have stronger structural stability than western soils," says Wright. "Knowing about glomalin gives us a reason to alter farming practices to raise or maintain glomalin levels. For example, tillage tends to lower glomalin levels. We found that soil from no-till corn plots had more glomalin and higher aggregate stability than soil from tilled plots."

Sara E. Wright is at the USDA-ARS Soil Microbial Systems Laboratory, Bldg. 001, 10300 Baltimore Ave., Beltsville, MD 20705-2350; phone (301) 504-8156, fax (301) 504-8370, e-mail swright@asrr.arsusda.gov
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