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纳帕海湖滨带优势植物杉叶藻(Hippuris vulgaris)茎解剖结构对模拟增温的响应

管东旭1,2,冯春慧1,2,田昆1,2,王志保1,2,张依南1,2,孙梅1,2*   

  1. (1西南林业大学湿地学院, 昆明 650224;2国家高原湿地研究中心, 昆明 650224)
  • 出版日期:2019-06-10 发布日期:2019-06-10

Responses of stem anatomical structure of a lakeside dominant plant Hippuris vulgaristo simulated warming in Napahai wetland.

GUAN Dong-xu1,2, FENG Chun-hui1,2, TIAN Kun1,2, WANG Zhi-bao1,2, ZHANG Yi-nan1,2, SUN Mei1,2*   

  1. (1College of Wetland, Southwest Forestry University, Kunming 650224, China; 2National Plateau Wetlands Research Center, Southwest Forestry University, Kunming 650224, China).
  • Online:2019-06-10 Published:2019-06-10

摘要: 温度是影响植物茎解剖结构的重要环境因子,但过去对温度如何影响植物茎解剖结构的研究较少涉及湿地植物。基于IPCC对未来大气增温的预测,本研究以滇西北典型高原湿地——纳帕海流域为研究区域,采用开顶式生长室(OTCs)模拟大气增温,研究了湖滨带优势植物杉叶藻(Hippuris vulgaris)茎解剖结构对大气增温的响应。结果显示,增温显著增加了地上茎的表皮细胞厚度及角质层厚度,且地上茎的薄壁细胞大小及表皮细胞大小也呈增大趋势,所有地上茎性状均表现出随温度升高逐步增大的趋势。同时,增温对地下茎角质层厚度也存在显著影响,所有地下茎性状均表现出随温度升高先减小后增大的趋势。在众多温度变量中,年平均温度和日间平均温度对杉叶藻地上茎解剖性状的影响最为显著,且上述两温度变量与地上茎解剖性状均为正相关;年最高温和年平均温度对杉叶藻地下茎解剖性状的影响最为显著,且上述两温度变量与地下茎解剖性状均为负相关。本研究结果表明,气候变暖显著影响杉叶藻的茎解剖结构,体现了杉叶藻对增温的有效适应,进而揭示了高原湿地植物形态结构对气候变暖的响应规律及其生理生态适应策略。

关键词: 光合作用, 物质生产, 移栽密度, 超级稻, 臭氧

Abstract: Temperature is an important environmental factor affecting stem anatomical structure. It is less well understood how it affects the structure of wetland plants. In this study, we used opentop growth chambers (OTCs) to simulate climate warming, based on the prediction of future atmospheric warming by IPCC, to study the response of stem anatomical structure of the lakeside dominant species Hippuris vulgaris to the simulated warming in a typical plateau wetland in Northwestern Yunnan (Napahai basin). The results showed that warming significantly increased epidermal cell thickness and cuticle thickness of aboveground stem. The size of parenchyma cells and epidermal cells of the aboveground stem showed increasing trends. All the aboveground stem traits showed increasing trends with increasing temperature. Warming had a significant effect on cuticle thickness of belowground stem. All the belowground stem traits showed trends of decreasing first and then increasing with the increasing temperature. Among temperature variables, the annual mean temperature and daily mean temperature were the most significant factors positively affecting aboveground stem anatomical structure of H. vulgaris. The maximum temperature and annual mean temperature had most significantly negative impacts on the belowground stem anatomical structure of H. vulgaris. Our results suggest that warming significantly affects stem anatomical structure of H. vulgaris, reflecting its effective adaptation to warming, and thus reveal the response patterns and ecophysiological adaptive strategies of plant structure in plateau wetland to climate warming.

Key words: super rice, ozone, photosynthesis, dry matter production, planting density.