Proteomic Study to Understand Promotive Effects of Plant-Derived Smoke on Soybean (Glycine maxL.) Root Growth Under Flooding Stress

Plant-derived smoke plays a key role in plant growth. Proteomic technique was used for underlying mechanisms of plant-derived smoke on the growth of soybean (Glycine maxL.) under flooding stress. The length and weight of soybean root increased with 2000 parts per million plant-derived smoke under flooding stress within 4 days. Altered proteins by plant-derived smoke treatment under flooding stress were mainly related to protein metabolism, stress, and redox. Furthermore, proteins related to mitochondrial electron transport chain decreased by flooding stress; however, they increased by addition of plant-derived smoke under flooding stress. Based on the results of proteomic analysis, confirmation experiments were performed. ATPase abundance and ATP content increased with the treatment of plant-derived smoke under flooding stress. Furthermore, the ascorbate/glutathione cycle was activated with the treatment of plant-derived smoke under flooding stress. These results suggest that plant-derived smoke improves the root growth of soybean with energy production and reactive oxygen scavenging even if it is under flooding stress, which might positively regulate soybean tolerance towards flooding stress.

Automated summary

Plant-derived smoke enhances root growth of soybean under flooding stress by increasing energy production and reactive oxygen scavenging, potentially improving soybean tolerance towards flooding stress.