Year 11 | 14 November 2019 | firstname.lastname@example.org
Reasearchers observed that E. coli cells are capable of migrating into the roots of spinach plant
A technique developed by U.S. Department of Agriculture (USDA) scientists for tracking pathogens has helped confirm that Escherichia coli is not likely to contaminate the internal vascular structure of field-grown leafy greens and thus increase the incidence of foodborne illness.
Agricultural Research Service (ARS) microbiologist Manan Sharma wanted to find out if plant roots could draw in E. coli pathogens from the soil when taking in nutrients and water. He and colleagues modified several types of E. coli—including some highly pathogenic strains that cause foodborne illness—by adding a gene for fluorescence. This allowed them to track the pathogen's journey from the field to the produce.
ARS is USDA's chief intramural scientific research agency, and this work supports the USDA priority of ensuring food safety.
The team, which is located at the ARS Environmental Microbial and Food Safety Laboratory in Beltsville, Md., confirmed that the pathogenic E. coli could survive in the soil for up to 28 days. They also observed that the fluorescent E. coli cells were capable of migrating into the roots of spinach plants.
The researchers also examined baby spinach plants over the course of 28 days after germination to see if any of the E. coli strains were taken up past the roots and into the plant's interior structures. For this part of the study, they grew baby spinach in pasteurized soil and hydroponic media.
At day 28, there was no evidence that the E. coli had become "internalized" in leaves or shoots of baby spinach plants grown in the pasteurized soil. E. coli could be detected in hydroponically-grown spinach samples, but its survival in shoot tissue was sporadic 28 days after the plants had germinated.
These findings strongly suggest that although E. coli can survive in soils, it's highly unlikely that foodborne illness would result from the bacterium becoming "internalized" through roots in leafy produce.
by R. T.
04 april 2011, Technical Area > Science News