Calcium-dependent protein kinase (CDPK) is an important mediator for Ca2 + signal recognition and transduction, playing a crucial role in plant stress response. Previous studies have shown that PcCDPK5 may be involved in the response of patchouli to p-hydroxybenzoic acid (p-HBA) stress. In this study, we further found that the subcellular localization of PcCDPK5 protein is in the cytoplasm, and its gene expression is closely related to continuous cropping (CC) and p-HBA stress. Under p-HBA stress, silencing the PcCDPK5 homologous gene in Nicotiana tabacum leads to decreased antioxidant enzyme activity and increased malondialdehyde (MDA) content, significantly accumulating reactive oxygen species (ROS) and affecting normal plant growth. On the contrary, overexpression of PcCDPK5 can effectively alleviate the damage caused by p-HBA stress to plant bodies. Through this research, the function of PcCDPK5 in response to p-HBA stress has been preliminarily analyzed, laying a theoretical foundation for alleviating CC obstacles in patchouli.

Soil salinity caused by NaCl is a major challenge to agricultural crops worldwide. For this, two WRKY transcription factors were evaluated for their role in salt stress tolerance in tomato plants ( Solanum lycopersicum; ; Sl ). SlWRKY36 and SlWRKY51 provided novel insight into the regulatory mechanism in tomato against salt stress via virus-induced gene silencing (VIGS). Salt stress significantly reduced chlorophyll-a, an abundant form of chlorophyll content to 6.0 and 5.1 mg/g and proline content to 0.06 mg/g and 0.09 mg/g respectively in SlWRKY36 and SlWRKY51 silenced tomato plants. This shows that salt stress affected proline content that act as osmoprotectant and damaged photosynthetic pigments in silenced SlWRKY36 and SlWRKY51 tomato plants. Similarly, the concentrations of Na+/ + / K+ + ratio also showed a significantly higher trend 14 days after salt stress with 5.5 mg/g and 8.9 mg/g concentration at 200 mM for SlWRKY36 and SlWRKY51 showing silencing promotes Na+/K+ +/K + ion ratio under salt stress. Also, salt stress responsive genes such as salt overly sensitive SOS1 and Na+/ +/ H+ + exchanger NHX1 displayed lower transcript level in silenced plants at 200 mM salt stress showing their negative regulation by SlWRKY36 and SlWRKY51 gene silencing. Collectively, these findings suggest for the first time the role of SlWRKY36 and SlWRKY51 as positive regulators of salt stress tolerance by managing ion homeostasis, proline content and photosynthetic machinery via transcriptional reprogramming. Overall, SlWRKY36 and SlWRKY51 were explored as potential candidates for engineering salt tolerance in tomato crop plants.