Integrative transcriptome analysis reveals distinct and common stress-responsive regulatory networks driving drought and heat responses in sorghum

Drought and heat are key abiotic stresses that severely affect crop production. Sorghum ( Sorghum bicolor L. Moench ), a drought-resilient cereal, serves as a model for studying abiotic stress responses in cereals. To elucidate the molecular responses to individual drought and heat stress, we conducted a transcriptome analysis of sorghum seedlings subjected to individual drought and heat treatment for 1h and 6h. Our analysis revealed distinct as well as overlapping patterns of gene expression between the two stresses at two time points, with a larger transcriptional shift observed at 6h of drought and heat treatment. We identified 410 and 4,136 differentially expressed genes (DEGs) in response to 1 and 6 h of drought treatments, respectively, whereas 1,807 and 2,776 DEGs were identified under 1 and 6 h of heat treatments. Among all four stress conditions, 32 common DEGs were identified. Genes encoding ion transporters were enriched among DEGs common in both 1h stress treatments. Genes involved in ribosome biogenesis were enriched among the common DEGs in both 6 h stress treatments. Specifically, drought-regulated genes were involved in ribosome biogenesis, whereas heat-induced genes were involved in protein folding and histone modifications. Enrichment of ribosome biogenesis in different sets of DEGs suggests that maintaining a balance between growth and survival by regulating protein synthesis may play a role in defining early stress response in sorghum. 6h of drought resulted in strong upregulation of abscisic acid and jasmonate-associated genes. Genes encoding bZIP, MYB, and HSF transcription factors displayed both stress-specific and common temporal regulation, suggesting vital regulatory roles of these transcription factors in mediating responses to drought and heat treatments. Extensive downregulation of genes encoding core histone proteins, in response to both 6h of drought and heat stress, was detected, indicating possible roles of chromatin structure and accessibility in mediating early responses to drought and heat treatments in sorghum.