6种温带树木的冻害疲劳及其与冻融栓塞和木质部解剖结构的关系

doi:10.11707/j.1001-7488.LYKX20240234

摘要/Abstract

摘要：

目的: 探究不同温带树木的冻害疲劳及其与冻融栓塞和木质部解剖结构的关系，提高对冬季植物水力学的认知，为温带和北方地区造林工作中选择适宜树种提供新的理论依据。方法: 以６种温带常见树种（元宝枫、I-101×84K杨、鹅掌楸、旱柳、白桦、法国梧桐）为试验材料，于冬季1月采集枝条，通过改进型的Cavitron冷冻离心机进行冻融处理，构建自然栓塞脆弱曲线（NVC）和冻害疲劳脆弱曲线（FFVC），计算２条脆弱曲线的栓塞面积（EA），评估冻害疲劳程度（DFF）。使用低压液流计测定自然导水率损失（NPLC），即冻融栓塞程度。测定木质部导管直径（D）、导管密度（V_D）、导管占比（F）、导管连接度（F_C）、木质部密度（WD）等解剖结构特征。结果: 经历冻融处理后，６种树种对木质部栓塞的抗性下降，发生冻害疲劳现象。与自然栓塞脆弱曲线的典型S形相比，各树种的冻害疲劳脆弱曲线均呈双S形。与NVC的栓塞面积相比，元宝枫FFVC的栓塞面积轻微减小，无显著差异；其他5种树种FFVC的栓塞面积显著下降。冻害疲劳程度表现出明显的物种差异，从大到小为I-101×84K杨>旱柳>法国梧桐>鹅掌楸>白桦>元宝枫。各树种的冻融栓塞程度与木质部解剖结构特征也存在显著差异。冻害疲劳程度与冻融栓塞程度显著正相关，仅与木质部解剖结构特征中的导管直径显著正相关。冻融栓塞程度与导管直径显著正相关。结论: 6种树种的冻害疲劳存在明显的种间差异。元宝枫对冻害疲劳具有很强的抗性，其疲劳程度最小，为“弹性树种”，其他５种树种对冻害疲劳具有较高的脆弱性，为“脆弱树种”。导管直径越大的树种，冻融栓塞程度越高，冻害疲劳程度越高。导管直径是决定树木冻融栓塞程度和冻害疲劳的关键结构特征。木质部导管窄小的树木对于冻融引起的栓塞和冻害疲劳具有较强的抵抗力，这将有利于其在温带和北方地区寒冷环境下的生存和分布。

关键词: 冻融栓塞, 冻害疲劳, 导管直径, 栓塞面积

Abstract:

Objective: This study aims to explore frost fatigue and its relationships with freeze-thaw-induced embolism and xylem anatomical structure in different trees from temperate zones, which can improve knowledge of winter plant hydraulics and provide new theoretical basis for the selection of suitable tree species for afforestation in temperate and boreal regions. Method: Six common temperate trees [Acer truncatum, I-101 (Populus alba) × 84K (P. alba× P. glandulosa), Liriodendron chinense, Salix matsudana, Betula platyphylla, and Platanus orientalis] were used as study materials and their branches were collected in January of winter. A modified Cavitron freezing centrifuge was utilized for freeze-thaw treatments and constructed native vulnerability curves (NVCs) and frost fatigue vulnerability curves (FFVCs). The embolic areas (EAs) of these two vulnerability curves per species were calculated to assess the degree of frost fatigue (DFF). For each of species, the native percentage loss of hydraulic conductivity (NPLC), i.e., the degree of freeze-thaw-induced embolism, was determined by a low-pressure flow meter (LPFM) and xylem anatomical structure traits were measured, such as vessel diameter (D), vessel density (V_D), vessel lumen fraction (F), intervessel contact fraction (F_C), and wood density (WD). Result: After undergoing freeze-thaw treatment, the resistance of xylem embolism decreased for all tree species and frost fatigue occurred. For all tree species, the frost fatigue vulnerability curves were double S-shaped compared to the S-shape of the native vulnerability curves. Compared with the embolism area of NVC, the embolism area of FFVC of A. truncatum was slightly reduced with no significant difference, while the embolism areas of FFVCs of the other five tree species were significantly reduced. The degree of frost fatigue showed pronounced interspecific differences and ranked as I-101 (P. alba)×84K (P. alba×P. glandulosa) > S. matsudana > P. orientalis > L. chinense > B. platyphylla > A. truncatum. There were significant differences in the degree of freeze-thaw-induced embolism and xylem anatomical structure traits among different tree species. The degree of frost fatigue was significantly positively correlated with the degree of embolism induced by freeze-thaw, and only with vessel diameter in the xylem anatomical structure traits. The degree of freeze-thaw-induced embolism was also significantly positively correlated with vessel diameter. Conclusion: There are obvious differences in frost fatigue among the six tree species. A. truncatum has strong resistance to frost fatigue with the lowest degree of frost fatigue and is “resilient species”. The other five species have high vulnerability to frost fatigue and are “weakened species”. Tree species with wider vessel have higher degrees of freeze-thaw-induced embolism and frost fatigue. Vessel diameter thus is the key structural trait that determines the degree of freeze-thaw-induced embolism and frost fatigue of trees. Tree species with narrow conduits in the xylem are more resistant to freeze-thaw-induced embolism and frost fatigue, which would favor their survival and distribution in cold environments in temperate and boreal regions.

Key words: freeze-thaw-induced embolism, frost fatigue, vessel diameter, embolism area

中图分类号:

S718.43

马博龙,张钧堯,吕倾子,李泽义,陈邑烜,郭佳璇,蔡靖. 6种温带树木的冻害疲劳及其与冻融栓塞和木质部解剖结构的关系[J]. 林业科学, 2025, 61(1): 95-103.

Bolong Ma,Junyao Zhang,Qingzi Lü,Zeyi Li,Yixuan Chen,Jiaxuan Guo,Jing Cai. Frost Fatigue and Its Relationships with Freeze-Thaw-Induced Embolism and Xylem Anatomical Structure in Six Temperate Trees[J]. Scientia Silvae Sinicae, 2025, 61(1): 95-103.

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树种Tree species	压力值 Tension value	NVC	FFVC
元宝枫 A. truncatum	P₁₂ /MPa	?3.79 ± 0.06	?2.45 ± 0.72
	P₅₀ /MPa	?4.65 ± 0.04	?4.26 ± 0.45
	P₈₈ /MPa	?5.32 ± 0.06	?5.48 ± 0.20
I-101×84K杨 I-101 (Populus alba) × 84K (P. alba×P. glandulosa)	P₁₂ /MPa	?1.52 ± 0.06	?0.87 ± 0.11	**
	P₅₀ /MPa	?2.08 ± 0.03	?1.43 ± 0.04	***
	P₈₈ /MPa	?2.56 ± 0.04	?1.94 ± 0.04	***
鹅掌楸 L. chinense	P₁₂ /MPa	?1.59 ± 0.05	?0.62 ± 0.09	**
	P₅₀ /MPa	?1.89 ± 0.04	?1.73 ± 0.07	*
	P₈₈ /MPa	?2.13 ± 0.04	?1.94 ± 0.09
旱柳 S. matsudana	P₁₂ /MPa	?1.48 ± 0.02	?0.63 ± 0.07	***
	P₅₀ /MPa	?1.81 ± 0.02	?1.37 ± 0.02	***
	P₈₈ /MPa	?2.07 ± 0.04	?1.61 ± 0.01	***
白桦 B. platyphylla	P₁₂ /MPa	?1.68 ± 0.03	?1.53 ± 0.07
	P₅₀ /MPa	?1.91 ± 0.01	?1.79 ± 0.02	**
	P₈₈ /MPa	?2.07 ± 0.01	?1.90 ± 0.02	**
法国梧桐 P. orientalis	P₁₂ /MPa	?1.38 ± 0.07	?0.67 ± 0.10	**
	P₅₀ /MPa	?1.70 ± 0.06	?1.45 ± 0.06	*
	P₈₈ /MPa	?1.96 ± 0.06	?1.70 ± 0.04	*

指标 Index	元宝枫 A. truncatum	I-101×84K杨 I-101(Populus alba) × 84K (P. alba×P. glandulosa)	鹅掌楸 L. chinense	旱柳 S. matsudana	白桦 B. platyphylla	法国梧桐 P. orientalis
NPLC (%)	10.77 ± 2.69d	44.50 ± 9.14ab	13.85 ± 1.02cd	63.84 ± 8.93a	21.94 ± 4.17cd	32.64 ± 7.03bc
DFF (%)	2.04 ± 3.57e	31.17 ± 3.11a	12.65 ± 2.87cd	26.46 ± 2.43ab	6.25 ± 0.90de	18.42 ± 3.00bc
D /μm	21.45 ± 0.67c	29.35 ± 1.54b	26.69 ± 0.24b	34.76 ± 0.61a	22.85 ± 0.78c	29.09 ± 0.59b
V_D /mm^?2	198.13 ± 12.83d	165.30 ± 15.27d	390.78 ± 12.57a	170.20 ± 19.24d	322.37 ± 20.64b	266.41 ± 18.68c
F (%)	0.076 ± 0.006d	0.116 ± 0.003c	0.233 ± 0.013a	0.177 ± 0.017b	0.139 ± 0.007c	0.189 ± 0.011b
F_C	0.063 ± 0.003c	0.037 ± 0.007d	0.093 ± 0.012ab	0.047 ± 0.007cd	0.107 ± 0.009a	0.070 ± 0.006bc
WD/ (g·cm^?3)	0.574 ± 0.014a	0.335 ± 0.012e	0.375 ± 0.007d	0.362 ± 0.013de	0.458 ± 0.012c	0.514 ± 0.012b