News Release

Controlling insect pests by targeting genes acquired from other species

Researchers show RNAi silencing of horizontally transferred genes (HTGs) in insect pests reduces their survival without harming beneficial insect species.

Peer-Reviewed Publication

Boyce Thompson Institute

HonglinFeng

image: The Boyce Thompson Intitute’s Honglin Feng brushes some green peach aphids off of a tobacco plant. view more 

Credit: Boyce Thompson Institute

ITHACA, NY - Killing crop-damaging insects by targeting genes essential to their survival is a promising approach to pest control. Because essential genes are often conserved across multiple insect species, the challenge is finding targets whose silencing kills the pests but not beneficial insects.

Led by Georg Jander, a professor at the Boyce Thompson Institute (BTI), a team of researchers have demonstrated that horizontally transferred genes (HTGs) – genes transmitted from one species to another – found in insect genomes are valid targets for selectively killing green peach aphids (Myzus persicae), whiteflies (Bemisia tabaci) and potentially other insects that cause major damage to food crops worldwide.

The results were published in Plant Biotechnology Journal in December.

“The genes we identified and targeted in aphids and whiteflies originated in bacteria, fungi, viruses and plants,” said Jander, who is also an adjunct professor in the School of Integrative Plant Science (SIPS) at Cornell University.

“Because horizontally transferred genes are not easily or rapidly incorporated into the genome of their new host species, we assumed they were present in aphids and whiteflies because they had given the insects an evolutionary advantage and were now essential to their survival. We therefore reasoned that silencing the HTGs would have a deleterious effect on the insects,” Jander added.

Previously, in a 2016 study, a team led by BTI professor Zhangjun Fei identified 142 genes that were likely HTGs in a subspecies of whitefly. For the new study – on which Fei is also a co-author – the researchers sequenced the genome of a strain of green peach aphid and identified 30 likely HTGs, most of which were also present in other species of aphids but not in whiteflies. Fei also is a co-author on the current study.

“Besides being essential genes, horizontally transferred genes are good targets for insect pest control because they are species-specific: an HTG found in one species is typically not found in any other species,” said Honglin Feng, a postdoctoral scientist in the Jander lab and first author on the study. “The aphids and whiteflies in our study have completely different sets of HTGs, and we showed that silencing aphid HTGs did not affect two species of ladybugs that feed on the aphids.”

To silence HTGs in aphids and whiteflies, the researchers used a method called RNA interference, or RNAi. The researchers used a virus to deliver the RNAi molecule into the plants that the insects fed on: a strain of the wild tobacco species Nicotiana benthamiana previously developed by the Jander lab.

In aphids, they silenced 11 different HTGs of bacterial, fungal, viral or plant origin; in most cases, silencing the HTG decreased aphid survival. When larvae of seven-spotted ladybugs (Coccinella septempunctata) and adult mealybug ladybirds (Cryptolaemus montrouzieri) were allowed to feed on the aphids from the treated plants, the RNAi molecules were transmitted to the ladybugs but caused no adverse effects because their genomes lacked the targeted genes.

In whiteflies, silencing five different HTGs also had adverse effects on survival, demonstrating the potential for expanding this method of pest control to insects beyond aphids.

However, while silencing the individual HTGs caused measurable reductions in insect survival, the size of those impacts was not large, Feng said. “The reductions were 40% or less in most cases, and often around 20%.”

For this reason, Feng wants to “stack” targets by silencing multiple HTGs in the insect pest simultaneously, to see if the combination treatment could have a greater killing power than silencing the individual HTGs.

“Stacking HTGs is likely to have an additive effect on survival over individual HTGs, especially if the targeted genes are on different biological pathways or have different biological functions,” Jander said.

About Boyce Thompson Institute:

Opened in 1924, Boyce Thompson Institute is a premier life sciences research institution located in Ithaca, New York. BTI scientists conduct investigations into fundamental plant and life sciences research with the goals of increasing food security, improving environmental sustainability in agriculture, and making basic discoveries that will enhance human health. Throughout this work, BTI is committed to inspiring and educating students and to providing advanced training for the next generation of scientists. BTI is an independent nonprofit research institute that is also affiliated with Cornell University. For more information, please visit BTIscience.org.

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