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Succession of a broad-leaved Korean pine mixed forest: Functional plant trait composition
Journal Pre-proof Succession of a broad-leaved Korean pine mixed forest: Functional plant trait composition Hede Gong, Fenggui Yao, Jie Gao PII:
S2351-9894(20)30001-9
DOI:
https://doi.org/10.1016/j.gecco.2020.e00950
Reference:
GECCO 950
To appear in:
Global Ecology and Conservation
Received Date: 1 January 2020 Revised Date:
31 January 2020
Accepted Date: 31 January 2020
Please cite this article as: Gong, H., Yao, F., Gao, J., Succession of a broad-leaved Korean pine mixed forest: Functional plant trait composition, Global Ecology and Conservation (2020), doi: https:// doi.org/10.1016/j.gecco.2020.e00950. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2020 Published by Elsevier B.V.
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Succession of a broad-leaved Korean pine mixed forest: functional
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plant trait composition Hede Gong1, Fenggui Yao1, Jie Gao2
3 4
1
School of Geography and Ecotourism, Southwest Forestry University, Kunming, Yunnan, China
5
2
Beijing Key Laboratory for Forest Resources and Ecosystem Processes,
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university, Beijing 100083, China;
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Corresponding authors: Gao Jie
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E-mail:[email protected].
Beijing
forestry
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Abstracts: A longstanding goal of ecology and conservation biology is to understand the climatic
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and biological controls of forest succession. However, the patterns and mechanisms that guide
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forest succession, especially within broad-leaved forests, remain unclear. We collected leaf traits
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and abiotic data across a 200-year chronosequence within a broad-leaved Korean pine forest in
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northeastern China. We focused on five key leaf traits related to resource acquisition and
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competition by quantifying the community-weighted trait distributions for specific leaf area (SLA),
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leaf dry matter concentration (LDMC), leaf nitrogen content (Nmass (g/kg)), leaf phosphorus
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content (Pmass (g/kg)) and the ratio of nitrogen content to phosphorus content (Nmass / Pmass). We
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also studied how these traits respond to changing environmental variables (climatic, soil and
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topographical) during succession. Redundancy analysis was used to examine the importance of the
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environmental variables in shaping the successional variation in plant traits. Our results revealed
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the following. Older forests differed significantly from younger forests in species composition and
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trait distribution. For example, SLA, leaf N and P content and the N/P ratio tended to increase and
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then decrease throughout the community during forest succession (p < 0.01). LDMC was also
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reduced over the course of succession. Mean annual temperature (MAT) and mean annual
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precipitation (MAP) correlated significantly with the succession of SLA and LDMC. However,
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temperature and rainfall were not significantly related to the temporal pattern of leaf nutrient (N
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and P) contents. The successional variation in leaf nutrients was instead mainly affected by soil
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and terrain factors (slope). Climatic factors independently accounted for 21.5% of the latitudinal
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difference in leaf function, which was slightly higher than soil factors (13.2%) and topographical
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factors (8.7%).
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Keywords: Functional traits; Forest succession; Climate change; Soil; Topographical factors
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1. Introduction
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The broad-leaved Korean pine mixed forest (BKF) is a typical variety of forest vegetation in
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northeast China. Compared with other forests of the world at the same latitude, it is famous for its
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unique species and rich species diversity (Hao et al., 2007). However, BKF biomes have been
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rarely studied, so there is no clear understanding of the mechanisms that drive forest succession
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here. This makes it more difficult to correctly predict their successional trajectories so as to assist
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communities and ecosystems in recovering from major disturbances (Prach & Walker 2011;
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Buzzard et al., 2016). Studying the species composition alone is not enough (Zhou et al. 2014;
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Norden et al. 2015; Buzzard et al., 2016), but studying the composition of functional groups may
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offer a stronger basis on which to build these predictions (Fukami et al. 2005, McGill et al. 2006).
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Buzzard (2016) observed that increased community productivity during forest succession is
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mainly reflected in some key functional traits of plants. Such key plant traits may ramify, so as to
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influence the structure and dynamics of the community and the functioning of the ecosystem. For
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example, in the early stage of succession, plants have a relatively higher growth rate and resource
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acquisition ability, which is manifested as high specific leaf area (SLA) (Muscarella et al., 2016).
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SLA reflects the ability of light interception and self-protection of leaves under strong light.
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However, Reich (2014) pointed out that SLA is actually at its largest in the later stage of
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succession. N / P is an important index of plant growth rate. The lower N / P ratio reflects the
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higher plant growth rate (Gao et al., 2019). The changes in resource availability that occur during
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succession are expected to select for traits associated with different physiological and life-history
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strategies at different stages. For example, increased niche differentiation among various species is
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understood to lead to over-dispersion of traits in later stages of succession (Enquist et al., 2015;
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Buzzard et al., 2016). In contrast however, many studies have found that increased competition
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can lead to a convergence of trait composition in the absence of disturbance late in succession
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(Bell 2001). Community-wide functional traits can reflect the traits of the community as a whole,
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and can solve the wrong estimation of traits caused by species differences (Gong et al., 2019).
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Leaf traits were affected by climate, soil and topography (Wright et al., 2005). However, the
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specific effects of environmental factors on plant functional traits are still unclear. To assess the
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various potential drivers of BKF assembly during succession, we measured environmental factors
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(climatic, soil and topographical), taxonomic composition and functional trait distributions in
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eight BKF communities within a broad-leaved Korean pine mixed forest that differed in stand age.
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Our analyses allowed us to uniquely: (i) characterize how community-wide functional traits
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change during BKF succession; (ii) assess how different potential drivers of functional trait
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dispersion change during BKF succession and (iii) quantify the relative contribution of climatic,
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soil and topographical factors to the variation in leaf traits throughout succession.
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2 Materials and Methods
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2.1 Study Sites
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We sampled forests across a chronosequence in Changbai mountain range, where BKF is the
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typical top community of ecological succession. Changbai mountain range is warm and rainy in
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the summer, and cold and dry in the winter. Using a ‘space-for-time’ substitution, we sampled
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forests with 10,20,30,40,50,70,130 and 200 years. Among them, the forests of 10-year, 20-year,
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30-year, 40-year are secondary birch forests, 50-year and 70-year are secondary broad-leaved
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forests, 130-year is coniferous forests and 200-year is broad-leaved Korean pine forests. Species
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composition of forests with different ages were listed in Table S1.
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We randomly selected four (20 m × 20 m) plots in each forest of different ages as our research
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objects. Thirty-two plots (20 m × 20 m) with eight different stages of succession were selected as
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our study objects. We measured the DBH (diameter at breast height) and height of all living trees
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that were at least 1 cm in DBH. All trees in the plot were identified, with their scientific names
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confirmed using herbarium specimens housed in different regions of China. Each of the 36 forest
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plots was divided into 16 subplots (5m × 5m). We recorded the species, number, height and
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coverage of shrubs in each subplot. We also selected small samples (1m × 1m) from the four
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corners of each subplot to investigate herbaceous species. Species of different life forms in
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different forest ages are listed in Table S1.
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2.2
Environmental variables
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Two climatic variables related to vegetative and successional gradients were quantified and
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obtained for the longitude, latitude and altitude of each plot from the WorldClim database (Fick,
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S.E. & R.J. Hijmans, 2017). The two factors were mean annual temperature (MAT) and mean
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annual precipitation (MAP). Two soil variables related to vegetative and successional gradients
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were also quantified, soil N content (g / kg) and soil P content (g / kg). We dug three soil sections
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at two corners and the center of the sample plot, and took soil according to the depth of 0-20cm
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soil layer. At the same time, we took about 500g soil samples and put them into sample bags to
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determine the content of nitrogen and phosphorus in the soil. Remove the gravel and plant roots
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from the soil sample in the ring knife, and dry them in the oven to constant weight. The total
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nitrogen content of soil was detected by Kjeldahl nitrogen analyzer, and the total P content of soil
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was detected by sodium bicarbonate extraction method. The average values of soil total nitrogen
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and total phosphorus were selected for each succession stage (Powers et al. 2009). The only
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topographical variable studied was slope of every plot. We took the average value of all
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environmental factor data as the overall environmental factor characteristics of a succession stage.
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The change of environmental factors with forest age were shown in Figure S1.
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2.3
Leaf traits
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More than 10 mature and well-developed individuals (tree,shrub and herb) were selected for
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each plant species in each plot, and the leaves without pests and diseases were collected. For trees,
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we selected the leaves on the outer branches of the crown. For trees and shrubs, we first cut the
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branches and then cut the leaves with scissors. For herbs, we cut the leaves directly. We put the
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leaves between two pieces of wet filter paper, put them into self sealing bags, took them back to
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the laboratory, and then put them into the refrigerator fresh-keeping layer for storage. Specific leaf
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area (SLA), leaf nitrogen content (Nmass (g / kg)), leaf phosphorus content (Pmass (g / kg)), Nmass /
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Pmass and leaf dry matter content (LDMC) were selected as key plant traits. We put the leaves in
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the dark environment of 5
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with filter paper, and then weigh them on the electronic balance (saturated fresh weight). We put
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the blade into 80 ℃ oven and dry it for 24 hours, then take it out and weigh it (dry weight).
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LDMC = dry weight of leaves (mg) / saturated fresh weight of leaves (g). We used a scanner to
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scan the leaf area, and then calculate the leaf area. SLA = area of blade (cm2) / dry weight of blade
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(g). For conifer species, we regard each bunch of needles as a cylinder, and calculate the specific
for 12h, then quickly absorb the water on the surface of the leaves
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leaf area by using half of the total surface area. The results of the specific leaf area of broadleaf
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plants and other flat plants calculated by this method are consistent with those of single leaf. For
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broadleaf species, we use a scanner to scan and calculate the specific leaf area. Kjeldahl method
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was used for the determination of total nitrogen in leaves, and Mo sb colorimetry was used for the
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determination of total phosphorus in leaves (Huang et al., 2019). The community leaf functional
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traits (CWM) is the value of leaf traits measured at the species level. Tree、shrub and herb are
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weighted average based on important values to get the average value of each trait at the
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community level. Importance value of tree= (relative density + relative dominance + relative
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frequency) / 300. Importance value of shrub = (relative density + relative coverage + relative
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frequency) / 300. Importance value of herb = (relative height + relative coverage + relative
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frequency) / 300.
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CWM = ∑ pi * traiti
n
i =1
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CWM represents the community trait of species i, pi represents important value of species i and
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traiti represents the mean trait valye of species i.
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2.4 Data analysis
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We logarithmically transformed all the soil and climatic factor data to give it a more normal
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distribution (Gong et al., 2019). A generalized linear mixed model was used to examine the
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relationships between leaf traits, forest age and climatic, soil and topographical variables. R2 was
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used to evaluate the explanatory power of the regression models. To estimate the relative
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importance of climate and soil factors for each functional trait, we used boosted regression trees
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(BRTs), which is a machine learning-based approach to regression (Gong et al., 2019). The
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advantage of using BRTs is that the relationship between predicted (leaf traits) and predictor
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variables (climatic, soil and topographical variables) is independent, and BRTs can also deal with
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nonlinear relationships and with multicollinearity between predictors. The relative influence is
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scaled so it adds up to 100% in each model.
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Redundancy analysis (RDA) was used to analyze the relationship between trait variation and
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climatic and soil variables. In our analysis, variance partitioning led to four individual fractions:
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(i) unique climate; (ii) unique soil; (iii) unique topography as well as shared variation due to
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redundant explained variation for (iiii) climate, soil and topography; These analyses were
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performed using the vegan package in R (Gong et al., 2019).
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3 Results
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We observed wide variation in leaf traits during succession. Across all life-forms, as stand age
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increased, SLA, leaf N and P content increased significantly at first, and then they declined (P <
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0.05). Stand age alone explained more than 82% of the variation in most leaf traits throughout
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succession (SLA, leaf N and P content) across all life forms (Fig.1). For LDMC and leaf N/P
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though, successional trends in trees were opposite those in shrubs and herbs.
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The successional variation in leaf traits that we observed appears to be driven largely by variation
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in climate (Fig.2; Fig.3). As temperature increased, SLA also increased significantly across all
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life-forms (p <0.05). LDMC and N/P trends also correlated similarly with temperature and
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rainfall.
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The role of soil factors and topography cannot be ignore when explaining the successional
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variation in leaf traits. SLA responded to soil N and P content differently (Fig.4; Fig.5). As soil P
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content increased, leaf N content and N/P decreased significantly. Slope had a significantly greater
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effect on N than P content in leaves (Fig.6).
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Among all environmental factors, Soil N content and MAP best explained leaf P content and SLA
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in all three life forms. Soil P content also explained the successional variation in LDMC, leaf N
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and N/P well across all life forms (Fig.7). RDA analysis revealed that climatic variables accounted
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for the largest proportion of variation in leaf traits, explaining 27.1 % of variation. Independently,
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climatic factors contributed 21.5% of the latitudinal difference in leaf function, which was slightly
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higher than soil factors (13.2%) and topographical factors (8.7%) (Fig.8).
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4 Discussion
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We observed that successional variation in leaf functional traits underlies a coordinated
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trade-off between resource acquisition. Leaf traits determine where on a growth vs. survival
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trade-off a species is located, given a set of environmental conditions (Buzzard et al., 2016). Reich
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(2014) believed that successional variation in leaf traits reflects a fundamental trade-off between
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competitive aptitude and the ability to avoid mortality under stressful conditions. The goal of our
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study was to determine the drivers of BKF succession by focusing on traits associated with
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resource acquisition and competitive ecological and life-history strategies.
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Most of the leaf traits showed significant change characteristics with the succession stage.
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With the succession stage, the SLA, N content, P content and N / P of leaves showed a significant
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trend of increasing first and then decreasing (P < 0.05). The results of this study are consistent
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with those of Buzzard (2016). In the early and middle stages of succession, the canopy density is
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low and the light transmittance is high. Therefore, the light resources are sufficient and the SLA is
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very small. With the progress of succession, the transmittance of forest decreased, and the SLA of
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plants began to increase. When the middle and later stage of succession was reached, due to the
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existence of "self thinning" phenomenon of forest, the transmittance of forest increased to a
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certain extent, and then the SLA decreased (Kraft et al., 2009; Díaz et al., 2010). Generally
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speaking, low SLA is accompanied by high LDMC. Although LDMC in this study is higher in the
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early stage of succession, this trend is not significant with the progression of succession. With the
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development of succession stage, N / P increased first and then decreased, which reflected the
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change from N limitation in the early stage of succession to P limitation in the middle and late
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stage of succession (Gao et al., 2019). N / P measurement is an important index of plant growth
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rate. The lower N / P ratio reflects the higher plant growth rate (Wang et al., 2016). Therefore,
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with the development of succession, the growth rate of the whole community showed a significant
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upward trend and then a significant downward trend. These leaf traits are all associated with
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longer-lived leaves, lower photosynthetic rates and slower growth rates (Wright et al. 2005).
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Together, the observed trait shifts appeared to be primarily determined by a concomitant shift in
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resource availability, e.g. water availability.
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Because we used the commonly methods in ecology-‘space-for-time’, in addition to the
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differences in forest age, there are also some differences(climate, soil and topography) in these
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forests. We found that climatic and soil variables were important factors affecting change in leaf
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functional traits during forest succession by changing the species composition and community
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structure under different environmental conditions. According to the theory of community
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construction, species composition in the community varies along the environmental gradient
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according to the differences among species in their adaptability to the external environment
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(Cornwell et al., 2009; Andersen et al., 2012). Under the suitable temperature range, with the
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increase of temperature, the photosynthetic capacity of plants increases, and the plants have higher
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SLA (Wright et al., 2010) and the aging of leaves increases, the photosynthetic capacity of plants
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decreases, and the accumulation of organic matter decreases. Therefore, LDMC decreases
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significantly with the increase of temperature (Niinemets 2001).
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On the whole, the ability of soil factors in shaping the change pattern of plant functional
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characters is lower than that of climate factors. We were surprised to find that there was no
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significant correlation between leaf nutrients and soil nutrients. There is no direct relationship
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between leaf nutrients and soil nutrients (Furtado et al., 2009). Nutrients absorbed by plants from
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the soil enter the roots, leaves and branches of plants. The survival strategies of different plant
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species are different, so the distribution strategies of nutrients obtained from the soil are different,
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which explains that the correlation between soil nutrients and leaf nutrients is not significant with
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the succession (Gao et al., 2019). Slope can affect the growth of plants by affecting the light,
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water and heat conditions. In the degree of soil water absorption, the larger the slope, the easier
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the water loss, the worse the soil water and nutrient conservation capacity, the more unfavorable
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to plant growth (Buzzard et al., 2016). Therefore, SLA will decrease with the increase of slope.
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Although climatic, soil and topographical factors barely explained temporal patterns of leaf
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traits, they did have direct and indirect effects on the spatial distribution of leaf traits in a different
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way. On one hand, environmental factors can directly affect the morphological construction of
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plant leaves, as well as the carbon distribution related to metabolic activities (Moles et al., 2014).
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On the other hand, climatic conditions naturally shape the large-scale geographical pattern of
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vegetation types (Han et al., 2011) and also regulate the availability of soil resources (Buzzard et
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al., 2016).
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Acknowledgements
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This work was supported by the Key Project of National Key Research and Development Plans
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(Grant No. 2017YFC0504004). We would like to thank Elizabeth Tokarz at Yale University for
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her assistance with English language and grammatical editing.
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Figures
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296 297
Fig.1. Community-weighted mean (CWM) for functional traits: specific leaf area (SLA), leaf dry
298
matter concentration (LDMC), leaf nitrogen content (Nmass (g/kg)), leaf phosphorus content
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(Pmass (g/kg)) and the ratio of nitrogen content to phosphorus content (N/P) as a function of stand
300
age. A solid regression line indicates statistical significance for the best fit regression model (as
301
determined by the lowest AIC score).
302 303
Fig.2. Relationship between community-weighted mean (CWM) for functional traits: specific leaf
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area (SLA), leaf dry matter concentration (LDMC), leaf nitrogen content (Nmass (g/kg)), leaf
305
phosphorus content (Pmass (g/kg)) and the ratio of nitrogen content to phosphorus content (N/P)
306
and annual average temperature (MAT). A solid regression line indicates statistical significance
307
for the best fit regression model (as determined by the lowest AIC score).
308 309
Fig.3. Relationship between community-weighted mean (CWM) for functional traits: specific leaf
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area (SLA), leaf dry matter concentration (LDMC), leaf nitrogen content (Nmass (g/kg)), leaf
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phosphorus content (Pmass (g/kg)) and the ratio of nitrogen content to phosphorus content (N/P)
312
and annual average precipitation (MAP). A solid regression line indicates statistical significance
313
for the best fit regression model (as determined by the lowest AIC score).
314 315
Fig.4. Relationship between community-weighted mean (CWM) for functional traits: specific leaf
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area (SLA), leaf dry matter concentration (LDMC), leaf nitrogen content (Nmass (g/kg)), leaf
317
phosphorus content (Pmass (g/kg)) and the ratio of nitrogen content to phosphorus content (N/P)
318
and soil N content. A solid regression line indicates statistical significance for the best fit
319
regression model (as determined by the lowest AIC score).
320 321
Fig.5. Relationship between community-weighted mean (CWM) for functional traits: specific leaf
322
area (SLA), leaf dry matter concentration (LDMC), leaf nitrogen content (Nmass (g/kg)), leaf
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phosphorus content (Pmass (g/kg)) and the ratio of nitrogen content to phosphorus content (N/P)
324
and soil P content. A solid regression line indicates statistical significance for the best fit
325
regression model (as determined by the lowest AIC score).
326 327
Fig.6. Relationship between community-weighted mean (CWM) for functional traits: specific leaf
328
area (SLA), leaf dry matter concentration (LDMC), leaf nitrogen content (Nmass (g/kg)), leaf
329
phosphorus content (Pmass (g/kg)) and the ratio of nitrogen content to phosphorus content (N/P)
330
and slope of samples. A solid regression line indicates statistical significance for the best fit
331
regression model (as determined by the lowest AIC score).
332
333 334
Fig.7. Effects of climate (MAT and MAP), soil (Soil N and P) and topographical (Slope) factors on
335
each functional trait (specific leaf area (SLA), leaf dry matter concentration (LDMC), leaf nitrogen
336
content (Nmass (g/kg)), leaf phosphorus content (Pmass (g/kg)) and the ratio of nitrogen content to
337
phosphorus content (N/P)) by BRTs analysis.
338
339 340
Fig.8. Results of variation partitioning for life traits in terms of the fractions of variation explained.
341
A: Climate factors B: Topographical factors C: Soil factors. The variation in leaf traits is
342
explained by the three groups of explanatory variables (A, B, C), and unexplained is the
343
undetermined variation. a, b and c are the unique effects of climate, topographical and soil factors.
344
d, e, f and g are fractions indicating their joint effects.
345 346
Table S1
347 348
Table S1 The dominant species composition of different life forms in different succession stages. Stand Age Life forms Tree layer 10a
Dominant Species Betula platyphylla Suk
Shrub layer Syringa oblata Lindl + Ribes komarovii A.Pojark Herb layer Cardamine leucantha + Enemion raddeanum Tree layer
20a
Betula platyphylla Suk + Populus davidiana
Shrub layer Syringa oblata Lindl. + Philadelphus incanus Koehne + Ribes komarovii A.Pojark Herb layer Athyrium filix-femina + Cardamine leucantha+ Enemion raddeanum Tree layer
30a
Shrub layer
Betula platyphylla Suk + Salix matsuda +Populus davidiana Syringa oblata Lindl. + Philadelphus incanus Koehne + Acer barbinerve + Ribes komarovii A.Pojark + Euonymus alatus
Herb layer Athyrium filix-femina + Cardamine leucantha + Enemion raddeanum + Ephedra equisetina Tree layer 40a
Betula platyphylla Suk + Populus davidiana + Acer mono Maxim
Shrub layer Acer barbinerve + Ribes komarovii A.Pojark + Euonymus alatus + Lonicera Japonica Herb layer Athyrium filix-femina + Lonicera caerules Tree layer
50a
Quercus mongolica + Phellodendron amurense + Tilia amurensis
Shrub layer Acer barbinerve + Euonymus alatus + Lonicera Japonica+ Corylus mandshurica Herb layer Athyrium filix-femina + Meehania fargesii + Farges Meehania + Lonicera caerules Tree layer
70a
Quercus mongolica + Phellodendron amurense + Acer mono Maxim + Fraxinus mandshurica + Tilia amurensis
Shrub layer A.pseudo-sieboldiarum + Acer barbinerve + Euonymus alatus + Lonicera Japonica + Corylus mandshurica Herb layer Meehania fargesii + Lonicera caerules Tree layer
130a
Abies nephrolepis + Pinus koraiensis + Picea jezoensis + Phellodendron amurense
Shrub layer Acer triflorum + Actinidia kolomikta + Ribes komarovii A.Pojark + Acer barbinerve Herb layer Flosseu Radix Impatientis nolitangeris + Lonicera caerules + Ephedra equisetina Tree layer
200a Shrub layer
Pinus koraiensis + Quercus mongolica + Tilia amurensis + Fraxinus mandshurica Corylus mandshurica + Ribes komarovii A.Pojark + Deutzia scabra Thunb + Philadelphus incanus + Syringa oblata Lindl. + Acer barbinerve
Herb layer Flosseu Radix Impatientis nolitangeris + Meehania fargesii + Athyrium filix-femina + Cardamine leucantha
349
Fig S1
350 351
Fig S1 The change pattern of environmental factors with succession. MAT represents mean annual temperature,
352
MAP represents annual average rainfall. Solid line represents fitting curve, R2 represents goodness of fit, and P
353
represents significance; the optimal model is selected according to the minimum AIC value standard.
354 355 356 357 358 359 360
Conflict of interest statement We declare that we have no financial and personal relationships with other people or organizations that can inappropriately influence our work.
S2351-9894(20)30001-9
DOI:
https://doi.org/10.1016/j.gecco.2020.e00950
Reference:
GECCO 950
To appear in:
Global Ecology and Conservation
Received Date: 1 January 2020 Revised Date:
31 January 2020
Accepted Date: 31 January 2020
Please cite this article as: Gong, H., Yao, F., Gao, J., Succession of a broad-leaved Korean pine mixed forest: Functional plant trait composition, Global Ecology and Conservation (2020), doi: https:// doi.org/10.1016/j.gecco.2020.e00950. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2020 Published by Elsevier B.V.
1
Succession of a broad-leaved Korean pine mixed forest: functional
2
plant trait composition Hede Gong1, Fenggui Yao1, Jie Gao2
3 4
1
School of Geography and Ecotourism, Southwest Forestry University, Kunming, Yunnan, China
5
2
Beijing Key Laboratory for Forest Resources and Ecosystem Processes,
6
university, Beijing 100083, China;
7
Corresponding authors: Gao Jie
8
E-mail:[email protected].
Beijing
forestry
9 10
Abstracts: A longstanding goal of ecology and conservation biology is to understand the climatic
11
and biological controls of forest succession. However, the patterns and mechanisms that guide
12
forest succession, especially within broad-leaved forests, remain unclear. We collected leaf traits
13
and abiotic data across a 200-year chronosequence within a broad-leaved Korean pine forest in
14
northeastern China. We focused on five key leaf traits related to resource acquisition and
15
competition by quantifying the community-weighted trait distributions for specific leaf area (SLA),
16
leaf dry matter concentration (LDMC), leaf nitrogen content (Nmass (g/kg)), leaf phosphorus
17
content (Pmass (g/kg)) and the ratio of nitrogen content to phosphorus content (Nmass / Pmass). We
18
also studied how these traits respond to changing environmental variables (climatic, soil and
19
topographical) during succession. Redundancy analysis was used to examine the importance of the
20
environmental variables in shaping the successional variation in plant traits. Our results revealed
21
the following. Older forests differed significantly from younger forests in species composition and
22
trait distribution. For example, SLA, leaf N and P content and the N/P ratio tended to increase and
23
then decrease throughout the community during forest succession (p < 0.01). LDMC was also
24
reduced over the course of succession. Mean annual temperature (MAT) and mean annual
25
precipitation (MAP) correlated significantly with the succession of SLA and LDMC. However,
26
temperature and rainfall were not significantly related to the temporal pattern of leaf nutrient (N
27
and P) contents. The successional variation in leaf nutrients was instead mainly affected by soil
28
and terrain factors (slope). Climatic factors independently accounted for 21.5% of the latitudinal
29
difference in leaf function, which was slightly higher than soil factors (13.2%) and topographical
30
factors (8.7%).
31
Keywords: Functional traits; Forest succession; Climate change; Soil; Topographical factors
32
1. Introduction
33
The broad-leaved Korean pine mixed forest (BKF) is a typical variety of forest vegetation in
34
northeast China. Compared with other forests of the world at the same latitude, it is famous for its
35
unique species and rich species diversity (Hao et al., 2007). However, BKF biomes have been
36
rarely studied, so there is no clear understanding of the mechanisms that drive forest succession
37
here. This makes it more difficult to correctly predict their successional trajectories so as to assist
38
communities and ecosystems in recovering from major disturbances (Prach & Walker 2011;
39
Buzzard et al., 2016). Studying the species composition alone is not enough (Zhou et al. 2014;
40
Norden et al. 2015; Buzzard et al., 2016), but studying the composition of functional groups may
41
offer a stronger basis on which to build these predictions (Fukami et al. 2005, McGill et al. 2006).
42
Buzzard (2016) observed that increased community productivity during forest succession is
43
mainly reflected in some key functional traits of plants. Such key plant traits may ramify, so as to
44
influence the structure and dynamics of the community and the functioning of the ecosystem. For
45
example, in the early stage of succession, plants have a relatively higher growth rate and resource
46
acquisition ability, which is manifested as high specific leaf area (SLA) (Muscarella et al., 2016).
47
SLA reflects the ability of light interception and self-protection of leaves under strong light.
48
However, Reich (2014) pointed out that SLA is actually at its largest in the later stage of
49
succession. N / P is an important index of plant growth rate. The lower N / P ratio reflects the
50
higher plant growth rate (Gao et al., 2019). The changes in resource availability that occur during
51
succession are expected to select for traits associated with different physiological and life-history
52
strategies at different stages. For example, increased niche differentiation among various species is
53
understood to lead to over-dispersion of traits in later stages of succession (Enquist et al., 2015;
54
Buzzard et al., 2016). In contrast however, many studies have found that increased competition
55
can lead to a convergence of trait composition in the absence of disturbance late in succession
56
(Bell 2001). Community-wide functional traits can reflect the traits of the community as a whole,
57
and can solve the wrong estimation of traits caused by species differences (Gong et al., 2019).
58
Leaf traits were affected by climate, soil and topography (Wright et al., 2005). However, the
59
specific effects of environmental factors on plant functional traits are still unclear. To assess the
60
various potential drivers of BKF assembly during succession, we measured environmental factors
61
(climatic, soil and topographical), taxonomic composition and functional trait distributions in
62
eight BKF communities within a broad-leaved Korean pine mixed forest that differed in stand age.
63
Our analyses allowed us to uniquely: (i) characterize how community-wide functional traits
64
change during BKF succession; (ii) assess how different potential drivers of functional trait
65
dispersion change during BKF succession and (iii) quantify the relative contribution of climatic,
66
soil and topographical factors to the variation in leaf traits throughout succession.
67
2 Materials and Methods
68
2.1 Study Sites
69
We sampled forests across a chronosequence in Changbai mountain range, where BKF is the
70
typical top community of ecological succession. Changbai mountain range is warm and rainy in
71
the summer, and cold and dry in the winter. Using a ‘space-for-time’ substitution, we sampled
72
forests with 10,20,30,40,50,70,130 and 200 years. Among them, the forests of 10-year, 20-year,
73
30-year, 40-year are secondary birch forests, 50-year and 70-year are secondary broad-leaved
74
forests, 130-year is coniferous forests and 200-year is broad-leaved Korean pine forests. Species
75
composition of forests with different ages were listed in Table S1.
76
We randomly selected four (20 m × 20 m) plots in each forest of different ages as our research
77
objects. Thirty-two plots (20 m × 20 m) with eight different stages of succession were selected as
78
our study objects. We measured the DBH (diameter at breast height) and height of all living trees
79
that were at least 1 cm in DBH. All trees in the plot were identified, with their scientific names
80
confirmed using herbarium specimens housed in different regions of China. Each of the 36 forest
81
plots was divided into 16 subplots (5m × 5m). We recorded the species, number, height and
82
coverage of shrubs in each subplot. We also selected small samples (1m × 1m) from the four
83
corners of each subplot to investigate herbaceous species. Species of different life forms in
84
different forest ages are listed in Table S1.
85
2.2
Environmental variables
86
Two climatic variables related to vegetative and successional gradients were quantified and
87
obtained for the longitude, latitude and altitude of each plot from the WorldClim database (Fick,
88
S.E. & R.J. Hijmans, 2017). The two factors were mean annual temperature (MAT) and mean
89
annual precipitation (MAP). Two soil variables related to vegetative and successional gradients
90
were also quantified, soil N content (g / kg) and soil P content (g / kg). We dug three soil sections
91
at two corners and the center of the sample plot, and took soil according to the depth of 0-20cm
92
soil layer. At the same time, we took about 500g soil samples and put them into sample bags to
93
determine the content of nitrogen and phosphorus in the soil. Remove the gravel and plant roots
94
from the soil sample in the ring knife, and dry them in the oven to constant weight. The total
95
nitrogen content of soil was detected by Kjeldahl nitrogen analyzer, and the total P content of soil
96
was detected by sodium bicarbonate extraction method. The average values of soil total nitrogen
97
and total phosphorus were selected for each succession stage (Powers et al. 2009). The only
98
topographical variable studied was slope of every plot. We took the average value of all
99
environmental factor data as the overall environmental factor characteristics of a succession stage.
100
The change of environmental factors with forest age were shown in Figure S1.
101
2.3
Leaf traits
102
More than 10 mature and well-developed individuals (tree,shrub and herb) were selected for
103
each plant species in each plot, and the leaves without pests and diseases were collected. For trees,
104
we selected the leaves on the outer branches of the crown. For trees and shrubs, we first cut the
105
branches and then cut the leaves with scissors. For herbs, we cut the leaves directly. We put the
106
leaves between two pieces of wet filter paper, put them into self sealing bags, took them back to
107
the laboratory, and then put them into the refrigerator fresh-keeping layer for storage. Specific leaf
108
area (SLA), leaf nitrogen content (Nmass (g / kg)), leaf phosphorus content (Pmass (g / kg)), Nmass /
109
Pmass and leaf dry matter content (LDMC) were selected as key plant traits. We put the leaves in
110
the dark environment of 5
111
with filter paper, and then weigh them on the electronic balance (saturated fresh weight). We put
112
the blade into 80 ℃ oven and dry it for 24 hours, then take it out and weigh it (dry weight).
113
LDMC = dry weight of leaves (mg) / saturated fresh weight of leaves (g). We used a scanner to
114
scan the leaf area, and then calculate the leaf area. SLA = area of blade (cm2) / dry weight of blade
115
(g). For conifer species, we regard each bunch of needles as a cylinder, and calculate the specific
for 12h, then quickly absorb the water on the surface of the leaves
116
leaf area by using half of the total surface area. The results of the specific leaf area of broadleaf
117
plants and other flat plants calculated by this method are consistent with those of single leaf. For
118
broadleaf species, we use a scanner to scan and calculate the specific leaf area. Kjeldahl method
119
was used for the determination of total nitrogen in leaves, and Mo sb colorimetry was used for the
120
determination of total phosphorus in leaves (Huang et al., 2019). The community leaf functional
121
traits (CWM) is the value of leaf traits measured at the species level. Tree、shrub and herb are
122
weighted average based on important values to get the average value of each trait at the
123
community level. Importance value of tree= (relative density + relative dominance + relative
124
frequency) / 300. Importance value of shrub = (relative density + relative coverage + relative
125
frequency) / 300. Importance value of herb = (relative height + relative coverage + relative
126
frequency) / 300.
127
CWM = ∑ pi * traiti
n
i =1
128
CWM represents the community trait of species i, pi represents important value of species i and
129
traiti represents the mean trait valye of species i.
130
2.4 Data analysis
131
We logarithmically transformed all the soil and climatic factor data to give it a more normal
132
distribution (Gong et al., 2019). A generalized linear mixed model was used to examine the
133
relationships between leaf traits, forest age and climatic, soil and topographical variables. R2 was
134
used to evaluate the explanatory power of the regression models. To estimate the relative
135
importance of climate and soil factors for each functional trait, we used boosted regression trees
136
(BRTs), which is a machine learning-based approach to regression (Gong et al., 2019). The
137
advantage of using BRTs is that the relationship between predicted (leaf traits) and predictor
138
variables (climatic, soil and topographical variables) is independent, and BRTs can also deal with
139
nonlinear relationships and with multicollinearity between predictors. The relative influence is
140
scaled so it adds up to 100% in each model.
141
Redundancy analysis (RDA) was used to analyze the relationship between trait variation and
142
climatic and soil variables. In our analysis, variance partitioning led to four individual fractions:
143
(i) unique climate; (ii) unique soil; (iii) unique topography as well as shared variation due to
144
redundant explained variation for (iiii) climate, soil and topography; These analyses were
145
performed using the vegan package in R (Gong et al., 2019).
146
3 Results
147
We observed wide variation in leaf traits during succession. Across all life-forms, as stand age
148
increased, SLA, leaf N and P content increased significantly at first, and then they declined (P <
149
0.05). Stand age alone explained more than 82% of the variation in most leaf traits throughout
150
succession (SLA, leaf N and P content) across all life forms (Fig.1). For LDMC and leaf N/P
151
though, successional trends in trees were opposite those in shrubs and herbs.
152
The successional variation in leaf traits that we observed appears to be driven largely by variation
153
in climate (Fig.2; Fig.3). As temperature increased, SLA also increased significantly across all
154
life-forms (p <0.05). LDMC and N/P trends also correlated similarly with temperature and
155
rainfall.
156
The role of soil factors and topography cannot be ignore when explaining the successional
157
variation in leaf traits. SLA responded to soil N and P content differently (Fig.4; Fig.5). As soil P
158
content increased, leaf N content and N/P decreased significantly. Slope had a significantly greater
159
effect on N than P content in leaves (Fig.6).
160
Among all environmental factors, Soil N content and MAP best explained leaf P content and SLA
161
in all three life forms. Soil P content also explained the successional variation in LDMC, leaf N
162
and N/P well across all life forms (Fig.7). RDA analysis revealed that climatic variables accounted
163
for the largest proportion of variation in leaf traits, explaining 27.1 % of variation. Independently,
164
climatic factors contributed 21.5% of the latitudinal difference in leaf function, which was slightly
165
higher than soil factors (13.2%) and topographical factors (8.7%) (Fig.8).
166
4 Discussion
167
We observed that successional variation in leaf functional traits underlies a coordinated
168
trade-off between resource acquisition. Leaf traits determine where on a growth vs. survival
169
trade-off a species is located, given a set of environmental conditions (Buzzard et al., 2016). Reich
170
(2014) believed that successional variation in leaf traits reflects a fundamental trade-off between
171
competitive aptitude and the ability to avoid mortality under stressful conditions. The goal of our
172
study was to determine the drivers of BKF succession by focusing on traits associated with
173
resource acquisition and competitive ecological and life-history strategies.
174
Most of the leaf traits showed significant change characteristics with the succession stage.
175
With the succession stage, the SLA, N content, P content and N / P of leaves showed a significant
176
trend of increasing first and then decreasing (P < 0.05). The results of this study are consistent
177
with those of Buzzard (2016). In the early and middle stages of succession, the canopy density is
178
low and the light transmittance is high. Therefore, the light resources are sufficient and the SLA is
179
very small. With the progress of succession, the transmittance of forest decreased, and the SLA of
180
plants began to increase. When the middle and later stage of succession was reached, due to the
181
existence of "self thinning" phenomenon of forest, the transmittance of forest increased to a
182
certain extent, and then the SLA decreased (Kraft et al., 2009; Díaz et al., 2010). Generally
183
speaking, low SLA is accompanied by high LDMC. Although LDMC in this study is higher in the
184
early stage of succession, this trend is not significant with the progression of succession. With the
185
development of succession stage, N / P increased first and then decreased, which reflected the
186
change from N limitation in the early stage of succession to P limitation in the middle and late
187
stage of succession (Gao et al., 2019). N / P measurement is an important index of plant growth
188
rate. The lower N / P ratio reflects the higher plant growth rate (Wang et al., 2016). Therefore,
189
with the development of succession, the growth rate of the whole community showed a significant
190
upward trend and then a significant downward trend. These leaf traits are all associated with
191
longer-lived leaves, lower photosynthetic rates and slower growth rates (Wright et al. 2005).
192
Together, the observed trait shifts appeared to be primarily determined by a concomitant shift in
193
resource availability, e.g. water availability.
194
Because we used the commonly methods in ecology-‘space-for-time’, in addition to the
195
differences in forest age, there are also some differences(climate, soil and topography) in these
196
forests. We found that climatic and soil variables were important factors affecting change in leaf
197
functional traits during forest succession by changing the species composition and community
198
structure under different environmental conditions. According to the theory of community
199
construction, species composition in the community varies along the environmental gradient
200
according to the differences among species in their adaptability to the external environment
201
(Cornwell et al., 2009; Andersen et al., 2012). Under the suitable temperature range, with the
202
increase of temperature, the photosynthetic capacity of plants increases, and the plants have higher
203
SLA (Wright et al., 2010) and the aging of leaves increases, the photosynthetic capacity of plants
204
decreases, and the accumulation of organic matter decreases. Therefore, LDMC decreases
205
significantly with the increase of temperature (Niinemets 2001).
206
On the whole, the ability of soil factors in shaping the change pattern of plant functional
207
characters is lower than that of climate factors. We were surprised to find that there was no
208
significant correlation between leaf nutrients and soil nutrients. There is no direct relationship
209
between leaf nutrients and soil nutrients (Furtado et al., 2009). Nutrients absorbed by plants from
210
the soil enter the roots, leaves and branches of plants. The survival strategies of different plant
211
species are different, so the distribution strategies of nutrients obtained from the soil are different,
212
which explains that the correlation between soil nutrients and leaf nutrients is not significant with
213
the succession (Gao et al., 2019). Slope can affect the growth of plants by affecting the light,
214
water and heat conditions. In the degree of soil water absorption, the larger the slope, the easier
215
the water loss, the worse the soil water and nutrient conservation capacity, the more unfavorable
216
to plant growth (Buzzard et al., 2016). Therefore, SLA will decrease with the increase of slope.
217
Although climatic, soil and topographical factors barely explained temporal patterns of leaf
218
traits, they did have direct and indirect effects on the spatial distribution of leaf traits in a different
219
way. On one hand, environmental factors can directly affect the morphological construction of
220
plant leaves, as well as the carbon distribution related to metabolic activities (Moles et al., 2014).
221
On the other hand, climatic conditions naturally shape the large-scale geographical pattern of
222
vegetation types (Han et al., 2011) and also regulate the availability of soil resources (Buzzard et
223
al., 2016).
224
Acknowledgements
225
This work was supported by the Key Project of National Key Research and Development Plans
226
(Grant No. 2017YFC0504004). We would like to thank Elizabeth Tokarz at Yale University for
227
her assistance with English language and grammatical editing.
228
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Figures
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Fig.1. Community-weighted mean (CWM) for functional traits: specific leaf area (SLA), leaf dry
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matter concentration (LDMC), leaf nitrogen content (Nmass (g/kg)), leaf phosphorus content
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(Pmass (g/kg)) and the ratio of nitrogen content to phosphorus content (N/P) as a function of stand
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age. A solid regression line indicates statistical significance for the best fit regression model (as
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determined by the lowest AIC score).
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Fig.2. Relationship between community-weighted mean (CWM) for functional traits: specific leaf
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area (SLA), leaf dry matter concentration (LDMC), leaf nitrogen content (Nmass (g/kg)), leaf
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phosphorus content (Pmass (g/kg)) and the ratio of nitrogen content to phosphorus content (N/P)
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and annual average temperature (MAT). A solid regression line indicates statistical significance
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for the best fit regression model (as determined by the lowest AIC score).
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Fig.3. Relationship between community-weighted mean (CWM) for functional traits: specific leaf
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area (SLA), leaf dry matter concentration (LDMC), leaf nitrogen content (Nmass (g/kg)), leaf
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phosphorus content (Pmass (g/kg)) and the ratio of nitrogen content to phosphorus content (N/P)
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and annual average precipitation (MAP). A solid regression line indicates statistical significance
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for the best fit regression model (as determined by the lowest AIC score).
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Fig.4. Relationship between community-weighted mean (CWM) for functional traits: specific leaf
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area (SLA), leaf dry matter concentration (LDMC), leaf nitrogen content (Nmass (g/kg)), leaf
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phosphorus content (Pmass (g/kg)) and the ratio of nitrogen content to phosphorus content (N/P)
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and soil N content. A solid regression line indicates statistical significance for the best fit
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regression model (as determined by the lowest AIC score).
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Fig.5. Relationship between community-weighted mean (CWM) for functional traits: specific leaf
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area (SLA), leaf dry matter concentration (LDMC), leaf nitrogen content (Nmass (g/kg)), leaf
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phosphorus content (Pmass (g/kg)) and the ratio of nitrogen content to phosphorus content (N/P)
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and soil P content. A solid regression line indicates statistical significance for the best fit
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regression model (as determined by the lowest AIC score).
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Fig.6. Relationship between community-weighted mean (CWM) for functional traits: specific leaf
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area (SLA), leaf dry matter concentration (LDMC), leaf nitrogen content (Nmass (g/kg)), leaf
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phosphorus content (Pmass (g/kg)) and the ratio of nitrogen content to phosphorus content (N/P)
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and slope of samples. A solid regression line indicates statistical significance for the best fit
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regression model (as determined by the lowest AIC score).
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Fig.7. Effects of climate (MAT and MAP), soil (Soil N and P) and topographical (Slope) factors on
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each functional trait (specific leaf area (SLA), leaf dry matter concentration (LDMC), leaf nitrogen
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content (Nmass (g/kg)), leaf phosphorus content (Pmass (g/kg)) and the ratio of nitrogen content to
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phosphorus content (N/P)) by BRTs analysis.
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Fig.8. Results of variation partitioning for life traits in terms of the fractions of variation explained.
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A: Climate factors B: Topographical factors C: Soil factors. The variation in leaf traits is
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explained by the three groups of explanatory variables (A, B, C), and unexplained is the
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undetermined variation. a, b and c are the unique effects of climate, topographical and soil factors.
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d, e, f and g are fractions indicating their joint effects.
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Table S1
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Table S1 The dominant species composition of different life forms in different succession stages. Stand Age Life forms Tree layer 10a
Dominant Species Betula platyphylla Suk
Shrub layer Syringa oblata Lindl + Ribes komarovii A.Pojark Herb layer Cardamine leucantha + Enemion raddeanum Tree layer
20a
Betula platyphylla Suk + Populus davidiana
Shrub layer Syringa oblata Lindl. + Philadelphus incanus Koehne + Ribes komarovii A.Pojark Herb layer Athyrium filix-femina + Cardamine leucantha+ Enemion raddeanum Tree layer
30a
Shrub layer
Betula platyphylla Suk + Salix matsuda +Populus davidiana Syringa oblata Lindl. + Philadelphus incanus Koehne + Acer barbinerve + Ribes komarovii A.Pojark + Euonymus alatus
Herb layer Athyrium filix-femina + Cardamine leucantha + Enemion raddeanum + Ephedra equisetina Tree layer 40a
Betula platyphylla Suk + Populus davidiana + Acer mono Maxim
Shrub layer Acer barbinerve + Ribes komarovii A.Pojark + Euonymus alatus + Lonicera Japonica Herb layer Athyrium filix-femina + Lonicera caerules Tree layer
50a
Quercus mongolica + Phellodendron amurense + Tilia amurensis
Shrub layer Acer barbinerve + Euonymus alatus + Lonicera Japonica+ Corylus mandshurica Herb layer Athyrium filix-femina + Meehania fargesii + Farges Meehania + Lonicera caerules Tree layer
70a
Quercus mongolica + Phellodendron amurense + Acer mono Maxim + Fraxinus mandshurica + Tilia amurensis
Shrub layer A.pseudo-sieboldiarum + Acer barbinerve + Euonymus alatus + Lonicera Japonica + Corylus mandshurica Herb layer Meehania fargesii + Lonicera caerules Tree layer
130a
Abies nephrolepis + Pinus koraiensis + Picea jezoensis + Phellodendron amurense
Shrub layer Acer triflorum + Actinidia kolomikta + Ribes komarovii A.Pojark + Acer barbinerve Herb layer Flosseu Radix Impatientis nolitangeris + Lonicera caerules + Ephedra equisetina Tree layer
200a Shrub layer
Pinus koraiensis + Quercus mongolica + Tilia amurensis + Fraxinus mandshurica Corylus mandshurica + Ribes komarovii A.Pojark + Deutzia scabra Thunb + Philadelphus incanus + Syringa oblata Lindl. + Acer barbinerve
Herb layer Flosseu Radix Impatientis nolitangeris + Meehania fargesii + Athyrium filix-femina + Cardamine leucantha
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Fig S1
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Fig S1 The change pattern of environmental factors with succession. MAT represents mean annual temperature,
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MAP represents annual average rainfall. Solid line represents fitting curve, R2 represents goodness of fit, and P
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represents significance; the optimal model is selected according to the minimum AIC value standard.
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Conflict of interest statement We declare that we have no financial and personal relationships with other people or organizations that can inappropriately influence our work.