卡罗莱纳天竺葵(牻牛儿苗科)发育种子中物理休眠的获得和珠孔——水孔复合体的个体发生。
Acquisition of physical dormancy and ontogeny of the micropyle--water-gap complex in developing seeds of Geranium carolinianum (Geraniaceae).
机构信息
Department of Biology, University of Kentucky, Lexington, KY 40546, USA.
出版信息
Ann Bot. 2011 Jul;108(1):51-64. doi: 10.1093/aob/mcr103. Epub 2011 May 5.
BACKGROUND AND AIMS
The 'hinged valve gap' has been previously identified as the initial site of water entry (i.e. water gap) in physically dormant (PY) seeds of Geranium carolinianum (Geraniaceae). However, neither the ontogeny of the hinged valve gap nor acquisition of PY by seeds of Geraniaceae has been studied previously. The aims of the present study were to investigate the physiological events related to acquisition of PY and the ontogeny of the hinged valve gap and seed coat of G. carolinianum.
METHODS
Seeds of G. carolinianum were studied from the ovule stage until dispersal. The developmental stages of acquisition of germinability, physiological maturity and PY were determined by seed measurement, germination and imbibition experiments using intact seeds and isolated embryos of both fresh and slow-dried seeds. Ontogeny of the seed coat and water gap was studied using light microscopy.
KEY RESULTS
Developing seeds achieved germinability, physiological maturity and PY on days 9, 14 and 20 after pollination (DAP), respectively. The critical moisture content of seeds on acquisition of PY was 11 %. Slow-drying caused the stage of acquisition of PY to shift from 20 to 13 DAP. Greater extent of cell division and differentiation at the micropyle, water gap and chalaza than at the rest of the seed coat resulted in particular anatomical features. Palisade and subpalisade cells of varying forms developed in these sites. A clear demarcation between the water gap and micropyle is not evident due to their close proximity.
CONCLUSIONS
Acquisition of PY in seeds of G. carolinianum occurs after physiological maturity and is triggered by maturation drying. The micropyle and water gap cannot be considered as two separate entities, and thus it is more appropriate to consider them together as a 'micropyle--water-gap complex'.
背景与目的
先前已经确定,在 physically dormant(PY)的Geranium carolinianum(Geraniaceae)种子中,“铰接阀隙”是水进入的初始部位(即水隙)。然而,之前尚未研究过铰接阀隙的个体发生以及Geraniaceae 种子获得 PY 的情况。本研究的目的是研究与获得 PY 相关的生理事件以及 G. carolinianum 的铰接阀隙和种皮的个体发生。
方法
从胚珠阶段开始对 G. carolinianum 的种子进行研究,直到分散。通过使用完整种子和新鲜种子以及缓慢干燥种子的分离胚进行种子测量、发芽和吸胀实验,确定可发芽性、生理成熟度和 PY 的获得的发育阶段。使用光学显微镜研究种皮和水隙的个体发生。
主要结果
发育中的种子分别在授粉后 9、14 和 20 天(DAP)达到可发芽性、生理成熟度和 PY。获得 PY 的种子临界水分含量为 11%。缓慢干燥导致获得 PY 的阶段从 20 天转移到 13 天 DAP。与种皮的其余部分相比,珠孔、水隙和合点处的细胞分裂和分化程度更大,导致了特定的解剖特征。在这些部位形成了不同形式的栅栏组织和副栅栏组织细胞。由于它们彼此靠近,因此水隙和珠孔之间没有明显的分界线。
结论
G. carolinianum 种子中 PY 的获得发生在生理成熟之后,是由成熟干燥引发的。珠孔和水隙不能被视为两个独立的实体,因此将它们一起视为“珠孔-水隙复合体”更为合适。
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