Etoposide induces novel heritable phenotypes. Credit: PLOS Genetics (2025). DOI: 10.1371/journal.pgen.1011977

Crops increasingly need to thrive in a broader range of conditions, including drought, salinity, and heat. Traditional plant breeding can select for desirable traits, but is limited by the genetic variation that already exists in plants. In many crops, domestication and long-term selection have narrowed genetic diversity, constraining efforts to develop new varieties.

To work around these limits, researchers have developed ways to introduce helpful traits, such as drought or salt tolerance, into plants through mutation breeding. This deliberately introduces random genetic changes into plants. Then researchers screen the genetically altered plants to see which have acquired useful traits.

One widely used approach relies on radiation to generate structural variants—large-scale DNA changes that can affect multiple genes at once. However, irradiation introduces logistical and regulatory hurdles that restrict who can use it and which crops can be studied.

New chemical method for genetic changes

In a paper published in PLOS Genetics, Whitehead Institute Member Mary Gehring and colleagues offer a new method for generating large-scale genetic changes without irradiation.

Lead author Lindsey Bechen, the Gehring lab manager; Gehring; former postdoc P.R.V. Satyaki (now a faculty member at the University of Toronto), and their colleagues developed the approach by exposing germinating seeds to etoposide, a chemotherapy drug, during early growth.

The drug interferes with an enzyme that helps manage DNA structure during cell division. When cells attempt to repair the resulting breaks in their DNA, errors in the repair process can produce large-scale rearrangements in the genome. Seeds collected from treated plants carry these changes in a heritable form.

The process relies on standard laboratory tools: seeds are germinated on growth medium containing the drug, then transferred to soil to complete their life cycle.

"I was surprised at how efficient it was," says Gehring, who is also a professor of biology at MIT and an HHMI Investigator. "The diversity of new traits that you could see just by looking at the plants in the first generation was extensive."

Results in Arabidopsis and pigeon pea

The researchers demonstrated the method in Arabidopsis thaliana, a model plant widely used in genetic studies. Roughly two-thirds of treated plant lines showed visible differences, including changes in leaf shape, plant size, pigmentation, and fertility. Genetic analyses linked these traits to deletions, duplications, and rearrangements of DNA segments.

In several cases, the team linked specific plant traits to individual genetic changes. A dwarf plant with thick stems and unusual leaves carried a large change that disrupted a gene involved in leaf development. Another plant, marked by green-and-white mottled leaves, carried a deletion in the gene IMMUTANS—the same gene identified in radiation-induced mutants described more than 60 years ago.

Beyond Arabidopsis, Gehring’s lab is applying the technique to pigeon pea, a drought-tolerant legume and an important source of dietary protein in parts of Asia and Africa. Pigeon pea is an underutilized crop with the potential to become a staple crop—if its lack of genetic diversity, caused by a historical cultivation bottleneck, can be overcome.

Often referred to as orphan crops, species like pigeon pea receive limited research attention and often lack the genetic variation needed for breeding improved varieties.

"All of the traits that we might want to see in pigeon pea are not present in the existing population," says Gehring. "The idea is to do a large-scale mutation experiment to increase genetic diversity."

The team, which includes Gehring lab postdoc Sonia Boor, is now screening treated pigeon pea lines for salt tolerance, a trait that shapes where crops can be grown and how they perform in saline soils. Although pigeon pea takes longer to grow than Arabidopsis, the researchers have reached the second generation and identified several lines that show promising responses under saline conditions.

Advantages over gene editing and future plans

The researchers’ chemical approach may also be beneficial for crops that are difficult to modify using gene-editing tools such as CRISPR. Although CRISPR enables precise genetic changes, it often relies on genetic transformation, a technically challenging step for many plant species.

"A lot of species that one works with, either in agriculture or horticulture, are not amenable to genetic transformation," says Gehring.

The new method complements existing genetic tools rather than replacing them. By providing a more accessible alternative to irradiation, chemical mutation could expand the availability of large-scale genetic changes and novel plant varieties.

Looking ahead, Gehring’s lab plans to develop comprehensive collections of Arabidopsis mutants carrying well-characterized structural variants.

Such resources could help researchers better understand how large-scale changes in genome structure influence plant development and performance, informing future efforts to study and enhance crops.

More information: Lindsey L. Bechen et al, A simple method to efficiently generate structural variation in plants, PLOS Genetics (2025). DOI: 10.1371/journal.pgen.1011977

Citation: New chemical method makes it easier to select desirable traits in crops (2026, January 9) retrieved 9 January 2026 from https://phys.org/news/2026-01-chemical-method-easier-desirable-traits.html

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