Adaptive strategies of functional traits of Metasequoia glyptostroboides parent trees to changing habitats

doi:10.17520/biods.2019099

Abstract

Abstract:

Functional trait variability and phenotypic plasticity are the main mechanisms plants use to respond to heterogeneous habitats. These can determine how well a plant grows and where it is distributed. In the Xingdoushan National Nature Reserve, we assessed the response of the functional traits of a population of Metasequoia glyptostroboides parent trees to tree morphology, terrain factors and human disturbance. We found that the leaf area (LA), leaf dry weight (LDW) and specific leaf area (SLA) had large variation and great plasticity, while leaf dry matter content (LDMC) and twig dry matter content (TDMC) were more stable. Human disturbance and the four terrain factors together explained 5%-20% of variance for each functional trait, and crown size explained 38% and 76% of the variation in TDMC and LDMC, respectively. The five functional traits were mainly affected by altitude, slope aspect and human disturbance. The SLA responded slightly to environmental factors and disturbance pattern, while LA and LDW generally increased with strong disturbance. LDMC and TDMC were most sensitive to change in slope aspect. Taken together, the population of M. glyptostroboides parent trees demonstrated significant plasticity in response to the environment through its variability in functional traits. Because human disturbance had a great influence on the growth of these trees, artificial regeneration is recommended, and the impact of agriculture and human construction needs to be reduced.

Key words: Metasequoia glyptostroboides, functional trait, intraspecific variability, phenotypic plasticity, adaptive strategy

Jun Chen, Lan Yao, Xunru Ai, Jiang Zhu, Manling Wu, Xiao Huang, Siyi Chen, Jin Wang, Qiang Zhu. Adaptive strategies of functional traits of Metasequoia glyptostroboides parent trees to changing habitats[J]. Biodiv Sci, 2020, 28(3): 296-302.

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URL: https://www.biodiversity-science.net/EN/10.17520/biods.2019099

https://www.biodiversity-science.net/EN/Y2020/V28/I3/296

Figures/Tables 6

Table 1 Functional trait and its variance of Metasequoia glyptostroboides parent trees

性状 Trait	平均值 ± 标准差 Mean ± SD	最小值 Minimum	最大值 Maximum	中值 Median	偏度 Sewness	峰度 Kurtosis	变异系数 Coefficient of variation (%)
叶干重 Leaf dry weight (g)	0.229 ± 0.085	0.096	0.889	0.210	17,406.545	11.361	37.172
叶面积 Leaf area (cm²)	28.316 ± 5.813	5.419	61.215	28.903	6,389.909	2.264	20.389
比叶面积 Specific leaf area (cm²/g)	11.6 ± 3.735	1.915	32.454	11.322	4,838.621	0.983	32.121
叶干物质含量 Leaf dry matter content (g/g)	0.242 ± 0.045	0.129	0.430	0.237	4,740.165	0.902	18.358
枝干物质含量 Twig dry matter content (g/g)	0.415 ± 0.038	0.283	0.618	0.415	5,497.453	1.527	9.059

Fig. 1 Multiple factor analysis of functional traits, tree forms, and topographical factors. LA, Leaf area; SLA, Specific leaf area; LDW, Leaf dry weight; LDMC, Leaf dry matter content; TDMC, Twig dry matter content; DBH, Diameter at breast height; H, Height.

Fig. 2 Variance partitioning for function traits by different factors. LA, Leaf area; SLA, Specific leaf area; LDW, Leaf dry weight; LDMC, Leaf dry matter content; TDMC, Twig dry matter content.

Table 2 Grey relational grade analysis between functional traits and topographic factors

性状 Trait	海拔 Altitude	坡向 Aspect	坡度 Slope	坡位 Slope position
叶干重 Leaf dry weight	0.788	0.724	0.653	0.542
叶面积 Leaf area	0.719	0.620	0.632	0.499
比叶面积 Specific leaf area	0.875	0.774	0.762	0.601
叶干物质含量 Leaf dry matter content	0.786	0.616	0.606	0.506
枝干物质含量 Twig dry matter content	0.770	0.567	0.626	0.480

Fig. 3 Changes of functional trait values on the gradient of slope aspects. LA, Leaf area; SLA, Specific leaf area; LDW, Leaf dry weight; LDMC, Leaf dry matter content; TDMC, Twig dry matter content.

Fig. 4 Distribution of function trait values under human disturbances. LA, Leaf area; SLA, Specific leaf area; LDW, Leaf dry weight; LDMC, Leaf dry matter content.

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