Head blight, which is caused by mycotoxin-producing fungi of the genus Fusarium, is an economically important crop disease. We assessed the potential of host-induced gene silencing targeting the fungal cytochrome P450 lanosterol C-14α-demethylase (CYP51) genes, which are essential for ergosterol biosynthesis, to restrict fungal infection. In axenic cultures of Fusarium graminearum, in vitro feeding of CYP3RNA, a 791-nt double-stranded (ds)RNA complementary to CYP51A, CYP51B, and CYP51C, resulted in growth inhibition [half-maximum growth inhibition (IC 50 ) = 1.2 nM] as well as altered fungal morphology, similar to that observed after treatment with the azole fungicide tebuconazole, for which the CYP51 enzyme is a target. Expression of the same dsRNA in Arabidopsis and barley rendered susceptible plants highly resistant to fungal infection. Microscopic analysis revealed that mycelium formation on CYP3RNA-expressing leaves was restricted to the inoculation sites, and that inoculated barley caryopses were virtually free of fungal hyphae. This inhibition of fungal growth correlated with in planta production of siRNAs corresponding to the targeted CYP51 sequences, as well as highly efficient silencing of the fungal CYP51 genes. The high efficiency of fungal inhibition suggests that host-induced gene-silencing targeting of the CYP51 genes is an alternative to chemical treatments for the control of devastating fungal diseases.T he diseases Fusarium head blight (FHB) and root rot, caused by pathogenic ascomycete fungi of the genus Fusarium, such as Fusarium graminearum (Fg), are devastating diseases of cereal crops (1). Fusarium represents one of the most important cereal killers worldwide, exerting great economic and agronomic impact on global grain production and the grain industry. In addition to considerable yield losses, food quality is detrimentally affected by grain contamination with mycotoxins, which are produced by the fungi during plant infection (2-4). These contaminants represent a serious threat to human and animal health (5).Plant protection and toxin reduction strategies are presently mediated by chemical treatments, resistance breeding strategies, biological control, and genetic engineering. The latter relies on the use of antifungal transgenes, such as chitinase, defensins, polygalacturonase, and the use of mycotoxin detoxifying enzymes (6). However, the use of antifungal traits has not provided convincing practical solutions in terms of efficiency and reliability under agronomical practice.Currently, the application of systemic fungicides, such as sterol demethylation inhibitors (DMIs), is essential for controlling Fusarium diseases and thereby reaching the attainable production level of modern high-yield cultivars. DMI fungicides, such as tebuconazole, triadimefon, and prochloraz, act as ergosterol biosynthesis inhibitors because of cytochrome P450 lanosterol C-14α-demethylase (CYP51) binding, which subsequently disturbs fungal membrane integrity (7). Because of a shortage of alternative chemicals, D...
