ERD14 regulation by the HY5‐ or HY5‐MED2 module mediates the cold signal transduction of asparagus bean

SUMMARY Cold stress affects the growth, development, and yield of asparagus bean ( Vigna unguiculata subsp. sesquipedalis ). Mediator (MED) complex subunits regulate the cold tolerance of asparagus bean, but the underlying regulatory mechanisms remain unclear. Here, VunMED2 positively responds to cold stress of asparagus beans. Under cold acclimation and freezing treatment, the survival rate, ROS scavenging activity, and expression levels of VunMED2 were increased in VunMED2 transgenic plants. Natural variation in the promoter of VunMED2 in two different cold‐tolerant asparagus beans was observed. Under cold stress, the expression of the GUS reporter gene was higher in cold‐tolerant plants than in cold‐sensitive plants, and the expression of the GUS reporter gene was tissue‐specific. VunHY5 positively influenced the expression of VunMED2 by binding to the E‐box motif, and the transcriptional activation of the promoter was stronger in the cold‐tolerant variety than in cold‐sensitive plants. VunHY5 overexpression improved plant freezing resistance by increasing the antioxidant capacity and expression of dehydrin genes. VunHY5 and VunMED2 play a synergistic role in binding to the G‐box/ABRE motif and transcriptionally activating the expression of VunERD14 . VunERD14 complemented the med2 mutant, which could positively respond to plant freezing resistance by reducing membrane lipid peroxidation and improving the antioxidant capacity. Therefore, the VunHY5‐VunERD14 module and the VunHY5‐VunMED2‐VunERD14 positive cascade effect are involved in the cold signal transduction in asparagus bean. Our findings have implications for the breeding of asparagus bean varieties with improved cold tolerance.