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Although genetically modified crops have some big advantages over their regular counterparts, initially creating the modified plants can be quite challenging. Scientists have now developed a simpler approach, in which normal plants are altered with a spray that's applied to crops, Ben Coxworth reported for New Atlas.
Photo Insert: Majority of the said experiments were performed on thale cress plants (Arabidopsis thaliana).
Agricultural plants are typically genetically modified in order to boost their yield, require less water, or be more resistant to pests and diseases. Successfully implementing such modifications does take a considerable amount of time and money, however, plus many people are leery of consuming the harvested plants (or foods made with them.) A paper on the study was recently published in the journal ACS Nano.
Led by Masaki Odahara, a team at Japan's RIKEN Center for Sustainable Resource Science set out to develop an easier alternative that would deliver the same results.
More specifically, the scientists wanted to create bioactive molecules that could be sprayed onto crops, where they would enter the plants' cells and either suppress or trigger the activity of specific genes.
One of the first candidates the scientists looked to were chains of amino acids known as cell-penetrating peptides (CPPs). Previous studies had shown that such peptides are capable of delivering molecules into structures within plant cells, such as the chloroplasts which perform photosynthesis.
In order to see which peptides would work best, the researchers tagged multiple natural and synthetic CPPs with yellow fluorescence signals, then sprayed those CPPs onto the leaves of thale cress, soybeans and tomatoes.
When a confocal laser-scanning microscope was subsequently used to image the leaves, it was found that several of the peptides had been particularly successful at infiltrating their cells, causing them to fluoresce yellow.
Additional experiments showed that pieces of DNA called plasmids – which are frequently used to transfer foreign genes into organisms such as plants – could be carried into the plants' leaves after being attached to sprayed-on CPPs.
Other attached biomolecules caused the leaves to temporarily develop more pores, allowing a greater quantity of the spray to be taken in.
