Evaluating Sorghum bicolor resistance to Solidago canadensis invasion under different nitrogen scenarios

Ecosystem exposure to a biological invasion such as plant invasion could contribute to the extinction of native species and loss of productivity and ecosystem balance. ( ) is a highly invasive species that has formed monocultures in China, Europe, Asia, Australia, and New Zealand. It was designated...

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Published in:Frontiers in plant science 2024-10, Vol.15, p.1468816
Main Authors: Anas, Muhammad, Khan, Irfan Ullah, Alomrani, Sarah Owdah, Nawaz, Mohsin, Huang, Zhi-Yun, Alshehri, Mohammed Ali, Al-Ghanim, Khalid A, Qi, Shan-Shan, Li, Jian, Dai, Zhi-Cong, Ali, Shafaqat, Du, Dao-Lin
Format: Article
Language:English
Subjects:
ecosystem
invasion
nitrogen
Plant Science
S. bicolor
S. canadensis
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Summary:Ecosystem exposure to a biological invasion such as plant invasion could contribute to the extinction of native species and loss of productivity and ecosystem balance. ( ) is a highly invasive species that has formed monocultures in China, Europe, Asia, Australia, and New Zealand. It was designated as a notorious invasive species by the Chinese government. It has adversely affected the agroecosystem's ability to germinate various plant seeds, including wheat, lettuce, and pepper, which could lead to food insecurity. This study was conducted to control the invasive species by utilizing a competitive species, ( ) as a cover plant. exudes allelochemicals such as sorgoleone from its roots which suppress the photosystem II activity of nearby plants. The synthesis of sorgoleone depends on a supply of nitrogen. The present study involved the cultivation of alongside the invasive species , with three different invasion levels (high, medium, and low) and three different nitrogen forms (ammonical, nitrate, and combined ammonical and nitrate nitrogen) applied as a modified Hogland solution. expressed higher performance over the invasive species under ammonical and combined nitrogen forms under low and medium invasion levels. Furthermore, even at greater levels of invasion, was not suppressed by . However, the plant height and dry biomass of were significantly high across both nitrogen forms. Leaf area, CO uptake, and photosystem II activity of were unable to sustain its growth under the low invasion condition. The plant biomass of was suppressed by up to 80% and the relative dominance index of was 5.22 over . There was a strong correlation between CO uptake, leaf area, and plant biomass. Principal component analysis showed that the first four components had a total variance of 96.89%, with principal component 1 (PC1) having the highest eigenvalue at 18.65. These promising findings suggested that , whose high intensity might be employed to control the invasion process for environmental safety, might be able to recover the barren ground that had invaded.
ISSN:1664-462X
1664-462X
DOI:10.3389/fpls.2024.1468816