Zhang Honglin, Zhu Zhitao, Di Yining, Luo Jixun, Su Xianyue, Shen Yong, Liu Qing, Liu Tao, Xu Xiaoyu
College of Agronomy and Biotechnology, Key Laboratory for Crop Production and Smart Agriculture of Yunnan Province, Yunnan Agricultural University, Kunming, 650201, China.
Department of Laboratory Animal Science, Fudan University, Shanghai, 200433, China.
BMC Plant Biol. 2024 Dec 28;24(1):1269. doi: 10.1186/s12870-024-05999-1.
Yellow nutsedge (Cyperus esculentus, known as 'YouShaDou' in China, YSD) and purple nutsedge (Cyperus rotundus, known as 'XiangFuZi' in China, XFZ), closely related Cyperaceae species, exhibit significant differences in triacylglycerol (TAG) accumulation within their tubers, a key factor in carbon flux repartitioning that highly impact the total lipid, carbohydrate and protein metabolisms. Previous studies have attempted to elucidate the carbon anabolic discrepancies between these two species, however, a lack of comprehensive genome-wide annotation has hindered a detailed understanding of the underlying molecular mechanisms.
This study utilizes transcriptomic analyses, supported by a comprehensive YSD reference genome, and metabolomic profiling to uncover the mechanisms underlying the major carbon perturbations between the developing tubers of YSD and XFZ germplasms harvested in Yunnan province, China, where the plant biodiveristy is renowned worldwide and may contain more genetic variations relative to their counterparts in other places. Our findings indicate distinct expression patterns of key regulatory genes involved in TAG biosynthesis and lipid droplet formation, including transcriptional factors and structural genes such as ABI3 transcriptional factor, rate-limiting enzymes GPAT3/6/9 and DGAT2/3, and oleosin and caleosin homologs. Furthermore, our omics data suggest that these differences in gene expression are not the sole contributors to the diverse tuber compositions. Instead, complex interactions among highly regulated catalytic reactions, governing carbohydrate, protein, and species-specific metabolite metabolisms, such as starch and sucrose metabolic pathways, flavonoid and amino acids biosynthetic pathways, collectively contribute to the pronounced carbon anabolic differentiation primarily evident in TAG accumulation, as well as the starch properties in mature tubers.
This study offers new metabolic insights into the high-value underground non-photosynthetic tissues of Cyperaceae species, which harbors not only high biomass productivity but also abundant nutrients as favorable food or industrial sources in the modern agriculture. The detailed omics analyses aim to deepen our understanding of the Cyperaceae species, which may potentially broaden their application values and facilitate the molecular breeding of better varieties to ameliorate the food safety problem.
黄莎草(Cyperus esculentus,在中国被称为“油莎豆”,YSD)和紫莎草(Cyperus rotundus,在中国被称为“香附子”,XFZ)是莎草科的近缘物种,它们块茎中的三酰甘油(TAG)积累存在显著差异,这是碳通量重新分配的一个关键因素,对总脂质、碳水化合物和蛋白质代谢有重大影响。以往的研究试图阐明这两个物种之间的碳合成差异,然而,缺乏全面的全基因组注释阻碍了对潜在分子机制的详细理解。
本研究利用转录组分析,并辅以全面的YSD参考基因组和代谢组分析,以揭示中国云南省收获的YSD和XFZ种质发育块茎之间主要碳扰动的潜在机制,云南省植物生物多样性世界闻名,相对于其他地方的同类植物可能含有更多的遗传变异。我们的研究结果表明,参与TAG生物合成和脂滴形成的关键调控基因具有不同的表达模式,包括转录因子和结构基因,如ABI3转录因子、限速酶GPAT3/6/9和DGAT2/3,以及油质蛋白和钙结合蛋白同源物。此外,我们的组学数据表明,基因表达的这些差异并非块茎成分多样化的唯一原因。相反,高度调控的催化反应之间的复杂相互作用,控制着碳水化合物、蛋白质和物种特异性代谢物的代谢,如淀粉和蔗糖代谢途径、类黄酮和氨基酸生物合成途径,共同导致了主要在TAG积累以及成熟块茎淀粉特性中明显的显著碳合成分化。
本研究为莎草科物种高价值的地下非光合组织提供了新的代谢见解,这些组织不仅具有高生物量生产力,而且在现代农业中作为良好的食物或工业来源含有丰富的营养成分。详细的组学分析旨在加深我们对莎草科物种的理解,这可能会拓宽它们的应用价值,并促进优良品种的分子育种,以改善食品安全问题。
