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引用次数: 0
摘要
植物糖基转移酶(UGTs)在植物生长和新陈代谢中发挥着关键作用。在这里,我们研究了从早期藻类到被子植物的 28 个完全测序物种中 UGTs 的进化情况。我们的研究结果表明,茶叶(Camellia sinensis)中 G 组和 H 组的 UGTs 分别出现了明显的扩张和收缩。全基因组复制和串联复制事件共同推动了UGTs的大规模扩增,自然选择和人工选择的相互作用导致了中华茶树种群G群内部明显的功能分化。在G群的簇II中,UGT基因编码的酶在底物(如脱落酸)选择上的差异导致了其功能的多样化,这些基因分别通过不同的正负调控模式影响对低温和干旱等非生物胁迫的耐受性。G 组第 III 群组中的 UGTs 对香气底物的偏好各不相同,从而形成了多种多样的中茶香气谱。所有簇 III 基因都对低温胁迫有反应,而人工选择形成的簇 III-1 内的 UGTs 对干旱无反应。这表明,茶树的人工选择以提高品质和耐寒性为主要目标。
Evolution and functional divergence of glycosyltransferase genes shaped the quality and cold tolerance of tea plants.
Plant glycosyltransferases (UGTs) play a key role in plant growth and metabolism. Here, we examined the evolutionary landscape among UGTs in 28 fully sequenced species from early algae to angiosperms. Our findings revealed a distinctive expansion and contraction of UGTs in the G and H groups in tea (Camellia sinensis), respectively. Whole-genome duplication and tandem duplication events jointly drove the massive expansion of UGTs, and the interplay of natural and artificial selection has resulted in marked functional divergence within the G group of the sinensis-type tea population. In Cluster II of group G, differences in substrate selection (e.g., Abscisic Acid) of the enzymes encoded by UGT genes led to their functional diversification, and these genes influence tolerance to abiotic stresses such as low temperature and drought via different modes of positive and negative regulation, respectively. UGTs in Cluster III of the G group have diverse aroma substrate preferences, which contributes a diverse aroma spectrum of the sinensis-type tea population. All Cluster III genes respond to low-temperature stress, whereas UGTs within Cluster III-1, shaped by artificial selection, are unresponsive to drought. This suggests that artificial selection of tea plants focused on improving quality and cold tolerance as primary targets.
期刊介绍:
Title: Plant Cell
Publisher:
Published monthly by the American Society of Plant Biologists (ASPB)
Produced by Sheridan Journal Services, Waterbury, VT
History and Impact:
Established in 1989
Within three years of publication, ranked first in impact among journals in plant sciences
Maintains high standard of excellence
Scope:
Publishes novel research of special significance in plant biology
Focus areas include cellular biology, molecular biology, biochemistry, genetics, development, and evolution
Primary criteria: articles provide new insight of broad interest to plant biologists and are suitable for a wide audience
Tenets:
Publish the most exciting, cutting-edge research in plant cellular and molecular biology
Provide rapid turnaround time for reviewing and publishing research papers
Ensure highest quality reproduction of data
Feature interactive format for commentaries, opinion pieces, and exchange of information in review articles, meeting reports, and insightful overviews.
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