Date: 20.2.2013
In our ongoing quest for alternative energy sources, researchers are looking more to plants that grow in the wild for use in biofuels, plants such as switchgrass. However, attempts to "domesticate" wild-growing plants have a downside, as it could make the plants more susceptible to any number of plant viruses.
In a presentation at this year's meeting of the American Association for the Advancement of Science, Michigan State University plant biologist Carolyn Malmstrom said that when we start combining the qualities of different types of plants into one, there can be unanticipated results. "Most wild plants are perennials, while most of our agriculture crops are annuals," Malmstrom said. "Sometimes when you mix the properties of the two, unexpected things can happen."
In the domestication of wild plants for bioenergy, long-lived plants are being selected for fast growth like annuals. "Now you have a plant that could be a long-term reservoir, but it also happens to be faster growing and can serve as an amplifier for viruses. This all-in-one combination could increase virus pressure in crop areas unless mitigated."
Malmstrom said that plant virus ecology and the study of viral interactions between wild-growing plants and agricultural crops is an expanding field. In the last 15 years, disease ecology has really come to the fore as a basic science. Most of what is known about plant viruses comes from studies of crops. To understand the complete ecology of viruses, researchers are now studying these tiny organisms in nature, too.
Gate2Biotech - Biotechnology Portal - All Czech Biotechnology information in one place.
ISSN 1802-2685
This website is maintained by: CREOS CZ
© 2006 - 2024 South Bohemian Agency for Support to Innovative Enterprising (JAIP)
Interesting biotechnology content:
Animal Biotechnology - Animals, animal biotech
Biotechnology Books no. 14 - 14th page of aour database of biotechnology books
AI-designed DNA switches flip genes on and off, allowing precise activation or repression
Precision engineering enables design of virus-like particles that can deliver genetic material into cells