摘要
采用盆栽种植,以玉米品种郑单958为试验材料,设置对照(CK)、轻度(LS)、中度(MS)和重度(SS)水分胁迫(土壤含水量分别为田间持水量的75%-85%、65%-75%、55%-65%、45%-55%)4个水分梯度,从气孔开度的调控、花环结构的变化、叶片维管束水分运输等方面研究了玉米对土壤水分胁迫的应激反应.结果表明:随着水分胁迫程度的不断加剧,气孔保卫和副卫细胞中过氧化氢(H2O2)的积累量逐渐增多,应用荧光染色定位也发现H2O2荧光强度逐渐增强,而气孔开度和气孔导度均逐渐减小.同时,花环的正常结构被破坏,花环细胞排列凌乱且体积逐渐变小,维管束鞘细胞变得不规则;大维管束断面面积、木质部面积以及韧皮部细胞数均减少,总的叶片和上、下表皮的厚度逐渐变薄.此外,花环细胞和维管束鞘细胞中叶绿体数目减少,且在中度胁迫下花环细胞中叶绿体的分布发生了变化,由紧贴细胞质膜内侧环靠细胞壁分布向偏细胞中心扩散.发现玉米气孔关闭可能是由保卫细胞和副卫细胞中的H2O2共同调节,副卫细胞中的H2O2对保卫细胞主导的气孔关闭具有协同作用.总之,在水分胁迫下,玉米通过改变叶片花环结构和厚度、叶绿体的分布,减小木质部和韧皮部面积等降低叶片表面水势,促进气孔关闭,减少体内水分散失,以减轻干旱胁迫对其伤害。
Seedlings of the popular maize cultivar“Zhengdan-958” growing in pots individually were exposed to suitable soil water conditions as control, light water shortage, moderate water shortage, and severe water shortage, corresponding to soil water contents between 75%-85% , 65%- 75% , 55%-65%, and 45% -55% of field water capacity, respectively. Responses of stomatal aperture, Kranz anatomy, and vascular bundle structure to different water contents of maize leaves were investigated. Results showed that under increased water shortages, the levels of H2O2 in both guard cells and subsidiary cells were enhanced, also the fluorescence intensity of H2O2 labeled with fluorescent dye increased, while stomatal aperture and conductance decreased gradually. Moreover, Kranz cells were messily arranged and the cell size became smaller and smaller, and the structure of bundle sheath cells went irregular; and the sectional area of the big bundle and xylem, the cell number of phloem, and the thickness of whole leaf and of upper and lower epidermis reduced. In addition, the number of chloroplasts in mesophyll cells and vascular bundle sheath cells decreased, particularly under the moderate water deficit, chloroplasts in Kranz cells which located in the inside of cytoplasmic membrane and cling on the cell wall spread to the direction of cell center. It demon- strated that stomatal closing of maize could be together, and H2O2 in subsidiary cells maybe creased soil water shortages, drought-induced regulated by H2O2 in guard cells and subsidiary cells played a cooperative role. In conclusion, under in- H2O2 accumulations in both guard cells and subsidiary cells of maize leaves participated in the regulation of stomatal closing. And, the size of Kranz cells and bundle sheath cells, the cell number of phloem, and the area of the xylem and phloem reduced, thereby, reducing water shortage-induced damage.
出处
《应用生态学报》
CAS
CSCD
北大核心
2014年第10期2944-2950,共7页
Chinese Journal of Applied Ecology
基金
国家高技术研究发展计划项目(2011AA100504)资助