Heat shock‐induced enhanced susceptibility of barley to Bipolaris sorokiniana is associated with elevated ROS production and plant defence‐related gene expression

Abstract

Abstract Heat stress alters plant defence responses to pathogens. Short‐term heat shock promotes infections by biotrophic pathogens. However, little is known about how heat shock affects infection by hemibiotrophic pathogens like Bipolaris sorokiniana (teleomorph: Cochliobolus sativus). We assessed the effect of heat shock in B. sorokiniana‐susceptible barley (Hordeum vulgare cv. Ingrid) by monitoring leaf spot symptoms, B. sorokiniana biomass, ROS and plant defence‐related gene expression following pre‐exposure to heat shock. For heat shock, barley plants were kept at 49 °C for 20 s. B. sorokiniana biomass was assessed by qPCR, ROS levels determined by histochemical staining, while gene expression was assayed by RT‐qPCR. Heat shock suppressed defence responses of barley to B. sorokiniana, resulting in more severe necrotic symptoms and increased fungal biomass, as compared to untreated plants. Heat shock‐induced increased susceptibility was accompanied by significant increases in ROS (superoxide, H2O2). Transient expression of plant defence‐related antioxidant genes and a barley programmed cell death inhibitor (HvBI‐1) were induced in response to heat shock. However, heat shock followed by B. sorokiniana infection caused further transient increases in expression of HvSOD and HvBI‐1 correlated with enhanced susceptibility. Expression of the HvPR‐1b gene encoding pathogenesis‐related protein‐1b increased several fold 24 h after B. sorokiniana infection, however, heat shock further increased transcript levels along with enhanced susceptibility. Heat shock induces enhanced susceptibility of barley to B. sorokiniana, associated with elevated ROS levels and expression of plant defence‐related genes encoding antioxidants, a cell death inhibitor, and PR‐1b. Our results may contribute to elucidating the influence of heat shock on barley defence responses to hemibiotrophic pathogens.