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- Wang, Yi-Qiang, et al.
(författare)
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Analysis of expressed sequence tags from Ginkgo mature foliage in China
- 2010
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Ingår i: TREE GENET GENOMES. - : Springer Science and Business Media LLC. - 1614-2942 .- 1614-2950. ; 6:3, s. 357-365
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Tidskriftsartikel (refereegranskat)abstract
- Ginkgo biloba L. is a tree native to China, which has large importance within medicine and horticulture. The extracts from Ginkgo mature leaves with rich flavonoids and terpenoids are commonly used for a variety of folk remedies. We constructed a cDNA library derived from mature leaves of Ginkgo, which consisted of 8.12 x 10(5) clones with the insert length of 500-2,000 bp. We performed an analysis of expressed sequence tags (ESTs) and obtained partial sequences from 2,039 clones, which represented 1,437 unigenes consisting of 249 contigs and 1,188 singletons. The 2,039 ESTs were submitted to GenBank (dbEST) at NCBI and were assigned GenBank accession numbers from GE647881 to GE649919. The 1,235 cDNA clones out of 2,039 (60.1%) were assigned putative functions, and the remaining 804 clones were not similar to any known gene sequences in the databases. The five largest categories of Ginkgo clones were: "energy" (19.4%), "disease/defense" (16%), "metabolism" (11.3%), "unclassified proteins" (12.5%), and "secondary metabolism" (9%). The highly expressed transcripts in the cDNA library were some genes related to photosynthesis, disease/defense, and flavonoid biosynthesis, including ribulose-bisphosphate carboxylase small-chain gene, pathogenesis-related protein gene, light-harvesting chlorophyll a/b binding protein of photosystem gene, catalase gene, and phenylcoumaran benzylic ether reductase gene et al. Many genes with ESTs similar to photosynthesis, secondary metabolism, and stress-response genes were characterized. The analysis of ESTs indicates that it is a useful approach for isolating Ginkgo genes homologous to known genes. Our results provide new information about mature leaf-specific transcripts of Ginkgo.
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| 2. |
- Yang, Danni, et al.
(författare)
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Drip irrigation improves spring wheat water productivity by reducing leaf area while increasing yield
- 2023
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Ingår i: European Journal of Agronomy. - : Elsevier BV. - 1161-0301. ; 143
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Tidskriftsartikel (refereegranskat)abstract
- To mitigate the climate change-induced water shortage and realize the sustainable development of agriculture, drip irrigation, a more efficient water-saving irrigation method, has been intensively implemented in most arid agricultural regions in the world. However, compared to traditional border irrigation, how drip irrigation affects the biophysical conditions in the cropland and how crops physiologically respond to changes in biophysical conditions in terms of water, heat and carbon exchange remain largely unknown. In view of the above situation, to reveal the mechanism of drip irrigation in improving spring wheat water productivity, paired field experiments based on drip irrigation and border irrigation were conducted to extensively monitor water and heat fluxes at a typical spring wheat field (Triticum aestivum L.) in Northwest China during 2017–2020. The results showed that drip irrigation improved yield by 10.3 % and crop water productivity (i.e., yield-to-evapotranspiration-ratio) by 15.6 %, but reduced LAI by 16.9 % in contrast with border irrigation. Under drip irrigation, the lateral development of spring wheat roots was promoted by higher soil temperature combined with frequent dry-wet alternation in the shallow soil layer (0–20 cm), which was the basis for efficient absorption of water and fertilizer, as well as efficient formation of photosynthate. Meanwhile, drip irrigation increased net radiation and decreased latent heat flux by inhibiting leaf growth, thereby increased sensible heat, causing a higher soil temperature (+1.10 ℃) and canopy temperature (+1.11 ℃). Further analysis proved that soil temperature was the key factor affecting yield formation. Based on the above conditions, the decrease in leaf distribution coefficient (−0.030) led to the decrease in evapotranspiration (−5.7 %) and the increase in ear distribution coefficient (+0.029). Therefore, drip irrigation emphasized the role of soil moisture in the soil-plant-atmosphere continuum, enhanced crop activity by increasing field temperature, especially soil temperature, and finally improved yield and water productivity via carbon reallocation. The study revealed the mechanism of drip irrigation for improving spring wheat yield, and would contribute to improving Earth system models in representing agricultural cropland ecosystems with drip irrigation and predicting the subsequent biophysical and biogeochemical feedbacks to climate change.
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