The root of herbaceous peony (<i>Paeonia lactiflora</i> Pall.) is fleshy, and different varieties have different tolerance to waterlogging stress. In order to explore its response and recovery characterist...The root of herbaceous peony (<i>Paeonia lactiflora</i> Pall.) is fleshy, and different varieties have different tolerance to waterlogging stress. In order to explore its response and recovery characteristics to waterlogging stress, six varieties of herbaceous peony with strong, medium and weak waterlogging tolerance and high ornamental value were selected as experimental materials. After the vegetative growth of each variety was completed, the field simulated waterlogging stress experiment was carried out by the semi-flooded (the water surface is half the height of the flowerpot) pot method. Changes in photosynthetic p<span>arameters, chlorophyll fluorescence parameters, relative water content (R</span>WC), relative conductivity (REC), chlorophyll content, lutein cycle, and leaf microstructure were analyzed during recovery from waterlogging stress and stress relief. The results showed that the time of reaching the most significant difference between CK and tested varieties was different. From the beginning of <span>stress to 60% of the leaves with symptoms, the varieties with strong and m</span>oderate waterlogging tolerance experienced longer time;the proportion of palisade tissue in leaves was larger;the maximum photochemical quantum yield (Fv/Fm) was reduced less;it could increase xanthophyll cycle and heat dissi<span>pation (NPQ) to consume excess light energy, and maintain a higher net ph</span>otosynthetic rate (Pn) for normal growth of plants in a short period of time. The REC in leaves of varieties with weak waterlogging tolerance increased more, and the damage of cell membrane was more serious. After the stress was removed, all indexes recovered to different degrees. Based on our comprehensive analysis, the comprehensive waterlogging resistance of the experimental materials followed the pattern: “Lihong” > “Yangfeichuyu” > “Taohuafeixue” > “Dafugui” > “Qihualushuang” > “Hongxiuqiu”. It is suggested <span>that the variety “Lihong” and “Yangfeichuyu”, with strong comprehensive wa</span>terlogging tolerance, can be selected for propagation and cultivation in areas prone to waterlogging. In the later stage, it is still necessary to further expand the number and scale of varieties, combined with the in-depth study of wa<span>terlogging-resistance genes, so as to provide a theoretical reference for the cu</span>ltivation and production of new waterlogging-resistant varieties.展开更多
文摘The root of herbaceous peony (<i>Paeonia lactiflora</i> Pall.) is fleshy, and different varieties have different tolerance to waterlogging stress. In order to explore its response and recovery characteristics to waterlogging stress, six varieties of herbaceous peony with strong, medium and weak waterlogging tolerance and high ornamental value were selected as experimental materials. After the vegetative growth of each variety was completed, the field simulated waterlogging stress experiment was carried out by the semi-flooded (the water surface is half the height of the flowerpot) pot method. Changes in photosynthetic p<span>arameters, chlorophyll fluorescence parameters, relative water content (R</span>WC), relative conductivity (REC), chlorophyll content, lutein cycle, and leaf microstructure were analyzed during recovery from waterlogging stress and stress relief. The results showed that the time of reaching the most significant difference between CK and tested varieties was different. From the beginning of <span>stress to 60% of the leaves with symptoms, the varieties with strong and m</span>oderate waterlogging tolerance experienced longer time;the proportion of palisade tissue in leaves was larger;the maximum photochemical quantum yield (Fv/Fm) was reduced less;it could increase xanthophyll cycle and heat dissi<span>pation (NPQ) to consume excess light energy, and maintain a higher net ph</span>otosynthetic rate (Pn) for normal growth of plants in a short period of time. The REC in leaves of varieties with weak waterlogging tolerance increased more, and the damage of cell membrane was more serious. After the stress was removed, all indexes recovered to different degrees. Based on our comprehensive analysis, the comprehensive waterlogging resistance of the experimental materials followed the pattern: “Lihong” > “Yangfeichuyu” > “Taohuafeixue” > “Dafugui” > “Qihualushuang” > “Hongxiuqiu”. It is suggested <span>that the variety “Lihong” and “Yangfeichuyu”, with strong comprehensive wa</span>terlogging tolerance, can be selected for propagation and cultivation in areas prone to waterlogging. In the later stage, it is still necessary to further expand the number and scale of varieties, combined with the in-depth study of wa<span>terlogging-resistance genes, so as to provide a theoretical reference for the cu</span>ltivation and production of new waterlogging-resistant varieties.
