期刊
MOLECULES
卷 26, 期 22, 页码 -出版社
MDPI
DOI: 10.3390/molecules26226957
关键词
Psammosilene tunicoides; oxalic acid; H+-ATPase; programmed cell death
资金
- Dalian's Science and Technology Innovation Fund grant [2020JJ27SN107]
- Science and Technology Program of Fujian Province [2019N5008]
- Guangxi Distinguished Experts Fellowship
Psammosilene tunicoides is a rare and endangered perennial medicinal plant species, and research indicates that oxalic acid is an effective substance inducing cell death by affecting intracellular pH values and H+-ATPase activity to enhance plant cell resistance against stress.
Psammosilene tunicoides is a unique perennial medicinal plant species native to the Southwestern regions of China. Its wild population is rare and endangered due to over-excessive collection and extended growth (4-5 years). This research shows that H+-ATPase activity was a key factor for oxalate-inducing programmed cell death (PCD) of P. tunicoides suspension cells. Oxalic acid (OA) is an effective abiotic elicitor that enhances a plant cell's resistance to environmental stress. However, the role of OA in this process remains to be mechanistically unveiled. The present study evaluated the role of OA-induced cell death using an inverted fluorescence microscope after staining with Evans blue, FDA, PI, and Rd123. OA-stimulated changes in K+ and Ca2+ trans-membrane flows using a patch-clamp method, together with OA modulation of H+-ATPase activity, were further examined. OA treatment increased cell death rate in a dosage-and duration-dependent manner. OA significantly decreased the mitochondria activity and damaged its electron transport chain. The OA treatment also decreased intracellular pH, while the FC increased the pH value. Simultaneously, NH4Cl caused intracellular acidification. The OA treatment independently resulted in 90% and the FC led to 25% cell death rates. Consistently, the combined treatments caused a 31% cell death rate. Furthermore, treatment with EGTA caused a similar change in intracellular pH value to the La3+ and OA application. Combined results suggest that OA-caused cell death could be attributed to intracellular acidification and the involvement of OA in the influx of extracellular Ca2+, thereby leading to membrane depolarization. Here we explore the resistance mechanism of P. tunicoides cells against various stresses endowed by OA treatment.
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