Low temperature effects on ubiquinone content, respiration rates and lipid peroxidation levels of etiolated seedlings of two differentially chilling-sensitive species

Ubiquinone functions primarily in the electron transport chain of the mitochondria of plants and animals. Secondary roles in plant tissue, such as antioxidant activity, have also been proposed. The effect of low temperature exposure on etiolated seedling embryonic axes of two differentially chilling-sensitive species, mung bean ( Vigna radiata L.) (chilling-sensitive) and pea ( Pisum sativum L. cv. Lincoln) (chilling-tolerant) with respect to respiration rate, lipid peroxidation and ubiquinone content was examined. Whole seedlings (embryonic axis and cotyledon) of both species were exposed to control temperatures (20°C) (6 days) or an acclimatory low temperature treatment of 10°C (3 days) followed by exposure at 5°C (3 days). Measurements were initiated 3 days after seedlings had reached 50% germination (D0). Prior to measurements the cotyledons were removed and only the embryonic axis was used in these experiments. Ubiquinol (UQH₂), ubiquinone (UQ) and total ubiquinone (UQ_tot) content decreased in mung bean in response to the temperature treatment and UQH₂ and UQ_tot remained stable in the more chilling-tolerant pea. The reduction of the total Q-pool was approximately 85–92%, suggesting a high degree of saturation of the respiration pathways. Respiration declined and the RQ ratio increased in both species in response to low temperature. Cytochrome c oxidase (COX) (EC 1.9.3.1) activity was higher in pea than in mung bean but decreased during low temperature exposure in both species. Considering that levels of MDA (lipid peroxidation) did not increase in either species in response to chilling, decreased levels of UQH₂ and UQ observed in chilling-sensitive mung bean may indicate that these compounds were damaged prior to other membrane lipids during low temperature treatment and rendered undetectable.