Genetically Engineered (GE) seeds were commercially introduced for major field crops in 1996, with adoption rates increasing rapidly in the years that followed. Currently, more than 90 percent of U.S. corn, upland cotton, and soybeans are produced using GE varieties. GE crops are broadly classified in this data product as herbicide-tolerant (HT), insect-resistant (Bt) or stacked varieties (which are a combination of both HT and Bt traits). Although other GE traits have been developed (such as virus and fungus resistance, drought resistance, and enhanced protein, oil, or vitamin content), HT and Bt traits are the most commonly used traits in U.S. crop production. Most GE acres are planted to three major field crops: corn, cotton, and soybeans—while HT seeds are also widely used in alfalfa, canola, and sugar beet production.
Herbicide-tolerant (HT) crops, which tolerate potent herbicides (such as glyphosate, glufosinate, and dicamba), provide farmers with a broad variety of options for effective weed control. Based on USDA survey data, the percent of domestic soybean acres planted with HT seeds rose from 17 percent in 1997 to 68 percent in 2001, before plateauing at 94 percent in 2014. In 2024, soybean HT acreage reached its highest adoption at 96 percent and remains at 96 percent in 2025. HT cotton acreage expanded from approximately 10 percent in 1997 to 56 percent in 2001 and exceeded 90 percent of upland cotton acres in 2017. In 2025, 93 percent of upland cotton acres were GE herbicide tolerant. Adoption rates for HT corn grew relatively slowly immediately following the commercialization of GE seeds with adoption rates increasing after the turn of the century. Currently, approximately 92 percent of domestic corn acres are produced with HT seeds.
Insect-resistant crops, which generally contain genes from the soil bacterium Bt (Bacillus thuringiensis) and produce insecticidal proteins, have been available for corn and cotton since 1996. Insect resistant traits have recently expanded beyond Bt (such as RNA interference (RNAi)), but the data presented here only include insect resistant traits from Bt. Domestic Bt corn acreage grew from approximately 8 percent in 1997 to 19 percent in 2000, before climbing to 87 percent in 2025. Bt cotton acreage also expanded, from 15 percent of U.S. cotton acreage in 1997 to 37 percent in 2001. Currently, 91 percent of U.S. cotton acres are planted with genetically engineered, insect-resistant seeds.
Increases in adoption rates for Bt corn may be due to the commercial introduction of new varieties that are resistant to the corn rootworm and the corn earworm (prior to 2003, Bt corn varieties only targeted the European corn borer). Adoption rates for Bt corn may fluctuate over time, depending on the severity of European corn borer and corn rootworm infestations. Similarly, adoption rates for Bt cotton may depend on the severity of tobacco budworm, bollworm, and pink bollworm infestations.
The figures below illustrate increases in adoption rates for stacked varieties, which have both (in some cases, multiple) HT and Bt traits. Adoption of stacked varieties has increased in recent years. Approximately 87 percent of cotton acres and 84 percent of corn acres were planted with stacked seeds in 2025.
