南极两种具有不同脱水能力的苔藓——钩叶泥炭藓和高山金发藓的可溶性碳水化合物含量变化
Soluble carbohydrate content variation in Sanionia uncinata and Polytrichastrum alpinum, two Antarctic mosses with contrasting desiccation capacities.
作者信息
Zúñiga-González Paz, Zúñiga Gustavo E, Pizarro Marisol, Casanova-Katny Angélica
机构信息
Laboratorio de Micología y Micorrizas, Facultad de Ciencias Naturales y Oceanográficas and Laboratorio de Investigación en Agentes Antibacterianos, Facultad de Ciencias Biológicas, Universidad de Concepción, Barrio Universitario s/n, Concepción, Chile.
Departamento de Biología, Facultad de Química y Biología, Universidad de Santiago, Alameda, 3363, Santiago, Chile.
出版信息
Biol Res. 2016 Jan 28;49:6. doi: 10.1186/s40659-015-0058-z.
BACKGROUND
Cryptogamic vegetation dominates the ice-free areas along the Antarctic Peninsula. The two mosses Sanionia uncinata and Polytrichastrum alpinum inhabit soils with contrasting water availability. Sanionia uncinata grows in soil with continuous water supply, while P. alpinum grows in sandy, non-flooded soils. Desiccation and rehydration experiments were carried out to test for differences in the rate of water loss and uptake, with non-structural carbohydrates analysed to test their role in these processes.
RESULTS
Individual plants of S. uncinata lost water 60 % faster than P. alpinum; however, clumps of S. uncinata took longer to dry than those of P. alpinum (11 vs. 5 h, respectively). In contrast, rehydration took less than 10 min for both mosses. Total non-structural carbohydrate content was higher in P. alpinum than in S. uncinata, but sugar levels changed more in P. alpinum during desiccation and rehydration (60-50 %) when compared to S. uncinata. We report the presence of galactinol (a precursor of the raffinose family) for the first time in P. alpinum. Galactinol was present at higher amounts than all other non-structural sugars.
CONCLUSIONS
Individual plants of S. uncinata were not able to retain water for long periods but by growing and forming carpets, this species can retain water the longest. In contrast individual P. alpinum plants required more time to lose water than S. uncinata, but as moss cushions they suffered desiccation faster than the later. On the other hand, both species rehydrated very quickly. We found that when both mosses lost 50 % of their water, carbohydrates content remained stable and the plants did not accumulate non-structural carbohydrates during the desiccation prosses as usually occurs in vascular plants. The raffinose family oligosaccarides decreased during desiccation, and increased during rehydration, suggesting they function as osmoprotectors.
背景
隐花植物植被在南极半岛的无冰区域占主导地位。两种苔藓,即钩状真藓(Sanionia uncinata)和高山金发藓(Polytrichastrum alpinum)生长在水分可利用性不同的土壤中。钩状真藓生长在有持续水源供应的土壤中,而高山金发藓生长在沙质、无积水的土壤中。进行了脱水和复水实验,以测试水分丧失和吸收速率的差异,并分析非结构性碳水化合物以测试它们在这些过程中的作用。
结果
钩状真藓的单株失水速度比高山金发藓快60%;然而,钩状真藓的丛生体干燥所需时间比高山金发藓长(分别为11小时和5小时)。相比之下,两种苔藓的复水时间均不到10分钟。高山金发藓的总非结构性碳水化合物含量高于钩状真藓,但在脱水和复水过程中,高山金发藓的糖分水平变化(60%-50%)比钩状真藓更大。我们首次在高山金发藓中报道了棉子糖醇(棉子糖家族的前体)的存在。棉子糖醇的含量高于所有其他非结构性糖类。
结论
钩状真藓的单株无法长时间保持水分,但通过生长并形成草皮,该物种能够最长时间地保持水分。相比之下,高山金发藓的单株植物比钩状真藓需要更多时间来失水,但作为苔藓垫,它们比钩状真藓更快地遭受干燥。另一方面,两种物种复水都非常迅速。我们发现,当两种苔藓都失去50%的水分时,碳水化合物含量保持稳定,并且植物在脱水过程中不会像维管植物通常那样积累非结构性碳水化合物。棉子糖家族的寡糖在脱水过程中减少,在复水过程中增加,表明它们起到渗透保护剂的作用。
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