Abstract
Genes involved in disease resistance are crucial for plant immune systems, yet their transcriptional regulatory mechanisms remain poorly understood. SRC4, a key member of the soybean mosaic virus resistance cluster (SRC), encodes a Ca(2+)-binding EF-hand domain and possesses antiviral activity, but its expression regulation is unclear. Here, we systematically analyzed 4085 soybean (Glycine max) transcriptome datasets and conducted SMV inoculation experiments to characterize SRC4 expression patterns. Cis-acting element analysis identified 12 regulatory elements in the SRC4 promoter, including salicylic acid (SA)-responsive elements. Furthermore, a Pro(SRC4)::GUS reporter vector was constructed and functional analysis was performed in tobacco (Nicotiana benthamiana) and transgenic Arabidopsis thaliana. SRC4 exhibited significantly higher basal expression than typical resistance genes (R genes) and was induced by SMV infection, SA treatment, and Ca(2+) supplementation, with peak expression at 2-5 h post-treatment (hpi). In transgenic tobacco overexpressing NahG, neither SMV nor Ca(2+) could induce Pro(SRC4)::GUS expression, demonstrating that SRC4 transcriptional regulation is mediated through SA signaling pathways. SRC4 showed predominant expression in roots and leaves and responded to temperature stress. Transgenic plants overexpressing SRC4 exhibited enhanced tolerance to both 12 °C and 37 °C temperature stress. This study elucidates the molecular mechanisms underlying SRC4 transcriptional regulation through Ca(2+) and SA signaling pathways, revealing its dual role in both biotic and abiotic stress responses, especially in temperature stress.