中国3个主要梨砧木资源木质部导管分子结构及分布比较

doi:10.3724/SP.J.1259.2015.00227

植物学报 ›› 2015, Vol. 50 ›› Issue (2): 227-233.DOI: 10.3724/SP.J.1259.2015.00227

中国3个主要梨砧木资源木质部导管分子结构及分布比较

董星光, 曹玉芬^*(), 王昆, 田路明, 张莹, 齐丹

中国农业科学院果树研究所, 农业部园艺作物种质资源利用重点实验室, 兴城 125100

收稿日期:2014-03-20 接受日期:2014-08-25 出版日期:2015-03-01 发布日期:2015-04-10
通讯作者: 曹玉芬
作者简介:
? 共同第一作者
基金资助:
公益性行业(农业)科研专项(No.201003021)和国家自然科学基金(No.31272128)

Comparison of the Characters and Distribution of Vessel Elements in Xylem Among Three Main Pear Rootstocks in China

Xingguang Dong, Yufen Cao^*, Kun Wang, Luming Tian, Ying Zhang, Dan Qi

Research Institute of Pomology, Chinese Academy of Agricultural Sciences, Ministry of Agriculture, Key Laboratory of Horticultural Crops Germplasm Resources Utilization, Xingcheng 125100, China

Received:2014-03-20 Accepted:2014-08-25 Online:2015-03-01 Published:2015-04-10
Contact: Cao Yufen
About author:
? These authors contributed equally to this paper

摘要/Abstract

摘要： 采用组织离析法、石蜡切片法和显微照相技术, 观测了山梨(Pyrus ussuriensis)、杜梨(P. betuleafolia)和豆梨(P. calleryana)3种我国最主要梨属砧木茎干部位导管分子结构及分布。结果表明, 3种梨砧木导管分子结构在侧壁次生增厚和木质化的方式、纹孔式、主要穿孔板类型, 以及端壁倾斜、尾有无、尾长短分布趋势基本一致, 但山梨、杜梨复穿孔板比例、两端端壁倾斜比例高于豆梨。豆梨导管分子直径显著高于山梨和杜梨; 山梨和杜梨导管频率显著高于豆梨。木质部比导率测定结果显示, 豆梨显著高于山梨和杜梨, 山梨与杜梨间无显著差异。因此, 不同生境下的梨属植物木质部导管分子形态及分布与其生态适应性之间有较强的相关性, 表现为南方温暖潮湿环境起源的梨砧木导管较短, 直径较宽, 直接影响木质部导水率, 从而适于水分高效输导; 北方寒冷干旱环境起源的梨砧木导管较长, 直径较小, 导水能力低, 但木质部导管分布密度高, 利于水分安全输导。

Abstract: The characteristics and distribution of vessel elements in xylem of three main pear rootstocks (Pyrus ussuriensis, P. betuleafolia, P. calleryana) in China were examined by tissue isolation, paraffin sectioning and biometric statistics. The pattern of secondary wall thickening and lignification, pitting pattern, main types of perforation plates and proportion of tail, end walls, and tail length of vessel elements did not differ among the species. However, the proportion of vessel elements with multiperforate perforation and two tapered end walls and vessel frequency were higher in P. ussuriensis and in P. betuleafolia than P. calleryana. The diameter of vessel elements and specific conductivity were higher in P. calleryana than in P. ussuriensis and P. betuleafolia. Morphological structure and ecological adaptability are correlated in Pyrus varieties in different habitats. The vessel elements of pear rootstock species from south China are shorter in length and broader in diameter, which appears to directly affect hydraulic conductance capacity and therefore may be suitable for conducting water with high efficiency. The vessel elements of pear rootstock species from north China are longer in length and smaller in diameter with higher vessel frequency, which may help for conducting water safely.

董星光, 曹玉芬, 王昆, 田路明, 张莹, 齐丹. 中国3个主要梨砧木资源木质部导管分子结构及分布比较. 植物学报, 2015, 50(2): 227-233.

Xingguang Dong, Yufen Cao, Kun Wang, Luming Tian, Ying Zhang, Dan Qi. Comparison of the Characters and Distribution of Vessel Elements in Xylem Among Three Main Pear Rootstocks in China. Chinese Bulletin of Botany, 2015, 50(2): 227-233.

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链接本文: https://www.chinbullbotany.com/CN/10.3724/SP.J.1259.2015.00227

https://www.chinbullbotany.com/CN/Y2015/V50/I2/227

图/表 6

图1 3种梨砧木导管分子形态比较 (A) 具尾数目; (B) 尾长度; (C) 端壁形状

Figure 1 The morphological comparison of vessel element in the xylem of three pear rootstocks (A) Number of tail; (B) Length of tail; (C) Shape of end walls

图2 梨砧木导管分子形态 (A), (D), (K) 两端倾斜且具尾; (B) 一端水平, 一端倾斜, 无尾; (C), (H), (L) 两端水平且具尾; (E), (G) 两端倾斜, 一端具尾; (F) 一端水平, 一端倾斜且具尾; (I), (M) 两端倾斜无尾; (J) 一端水平, 一端倾斜, 一端具尾; (N) 具有双穿孔板

Figure 2 Vessel element shape in three pear rootstocks (A), (D), (K) Both end tapered, and tails at both end; (B) One end flat, the other tapered and no tail; (C), (H), (L) Both end flat, and tail at one end; (E), (G) Both end tapered, and tail at one end; (F) One end flat, the other tapered, and tail at both end; (I), (M) Both ends tapered, and no tail; (J) One end flat, the other tapered and tail at one end; (N) With double perforation plates

表1 3个砧木导管分子长度、直径、孔隙度及导管频率的比较

Table 1 Comparison of the length, diameter, porosity and frequency of vessel element in three pear rootstocks

Variety	The length of vessel element (μm)	The diameter of vessel element (μm)	The ratio of length to diameter	Xylem porosity (%)	Vessel frequency (Number∙mm^-2)
Pyrus ussuriensis	304.51 a	35.69 b	8.92 a	21.46 a	440.75 a
P. betuleafolia	286.08 a	33.29 c	8.99 a	20.99 a	405.88 ab
P. calleryana	253.32 b	39.51 a	6.66 b	23.41 a	345.85 b

图3 3种梨砧木导管分子长度(A)和直径(B)分布频率

Figure 3 Frequency of length (A) and diameter (B) of vessel element in three pear stock stems

图4 3种梨砧木木质部横切面 (A) 山梨; (B) 杜梨; (C) 豆梨

Figure 4 The cross section of xylem of three pear rootstocks (A) Pyrus ussuriensis; (B) P. betuleafolia; (C) P. calleryana

图5 3种梨砧木次生木质部比导率

Figure 5 Specific conductivity of xylem of three pear rootstocks

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中国3个主要梨砧木资源木质部导管分子结构及分布比较

Comparison of the Characters and Distribution of Vessel Elements in Xylem Among Three Main Pear Rootstocks in China

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