IF: 3.0
5-year IF: 2.5
Editors-in-Chief
Yuanhe Yang
Bernhard Schmid
CN 10-1172/Q
ISSN 1752-9921(print)
ISSN 1752-993X(online)
  • Volume 18,Issue 1
    01 February 2025
      Research Articles
      Ming-Liu Yang, Jin-Chun Liu, Meng-Ke Gao, Yu-Rong Sun, Zhi-Qiang Zhang
      2025, 18 (1): rtae098.
      Abstract ( 95 )   PDF(pc) (1291KB) ( 80 )   Save
      The mating systems and floral traits often among relatives of hermaphroditic plants can exhibit considerable diversity. This diversity can be influenced by the evolution of selfing and associated floral traits as a form of reproductive assurance (RA) when pollen limitation (PL) results from insufficient pollinator availability. To explore whether the degree of PL primarily drives differences in mating systems and floral traits, we conducted a comprehensive study involving two closely related species, Halenia elliptica and Halenia grandiflora, in three sympatric sites. We investigated floral characteristics, pollinator visitation, PL, autonomous selfing ability, RA and mating system in studied populations. Our findings show that H. elliptica produces smaller flowers and less nectar production than H. grandiflora, making it less attractive to pollinators. Compared with H. grandiflora, H. elliptica experienced more severe outcross pollen limitation (OPL), but compensates with a higher capacity for autonomous selfing, ensuring seed production under natural conditions. Moreover, significant differences in mating systems were detected between them, with H. elliptica exhibiting a higher selfing rate than H. grandiflora across all studied sympatric populations. These differences are also reflected in variations in herkogamy and dichogamy. Our study suggested that the degree of OPL impacts the divergence in mating systems and floral traits between sympatric closely related species, offering valuable insights into the evolution of plant mating systems and floral traits.
      Bingqian Su, Wenlong Xu, Zhuoxia Su, Zhouping Shangguan
      2025, 18 (1): rtae104.
      Abstract ( 114 )   PDF(pc) (4008KB) ( 119 )   Save
      The decline in tree growth has become a global issue. It is critically important to explore the factors affecting tree growth under the background of global climate change to understand tree growth models. A database was established based on Robinia pseudoacacia growth and its driving factors on China’s Loess Plateau. Linear regression and three machine learning methods, including support vector machine, random forest (RF) and gradient boosting machine were used to develop R. pseudoacacia growth models considering forest age, density, climate factors and topographic factors. The root mean square deviation method was adopted to quantitatively assess the relationship between tree growth and soil properties. The average tree height of R. pseudoacacia on the Loess Plateau was 8.8 ± 0.1 m, the average diameter at breast height (DBH) was 10.4 ± 0.1 cm and the average crown diameter was 3.2 ± 0.1 m. The RF model was a fast and effective machine learning method for predicting R. pseudoacacia growth, which showed the best simulation capability and could account for 67% of tree height variability and 55% of DBH variability. Model importance indicated that forest age and stand density were the main factors predicting R. pseudoacacia growth, followed by climate factors. The trade-off between R. pseudoacacia growth and soil properties revealed that soil texture and soil pH were the primary determinants of R. pseudoacacia growth in this region. Our synthesis provides a good framework for sustainable forest management in vulnerable ecological areas under future climate change.
      Baoyu Sun, Jiaye Ping, Ming Jiang, Jianyang Xia, Fanyu Xia, Guangxuan Han, Liming Yan
      2025, 18 (1): rtae107.
      Abstract ( 65 )   PDF(pc) (3198KB) ( 50 )   Save
      The intricate interplay among plant productivity and soil factors is a pivotal driver for sustaining the carbon sequestration capacity of coastal wetlands. Yet, it remains uncertain whether climate warming will reshape the cause-and-effect interactions between coastal plant productivity and soil factors. In this study, we combined a manipulative warming experiment with a convergent cross-mapping technique to quantify the causal relationships, which can be either unidirectional or bidirectional, between plants (gross primary productivity, GPP) and soil environment (e.g. soil temperature, moisture and salinity). Our findings revealed that warming amplified the interaction between GPP and soil salinity in the coastal wetland ecosystem. While soil temperature primarily drove this causal relationship in control plots, a more complex interaction emerged in warming plots: soil salinity not only directly influenced GPP but also indirectly affected it by altering soil temperature and moisture. Overall, warming increased the number of causal pathways linking GPP with soil environmental factors, such as the effect of soil salinity on GPP and the impacts of GPP on soil moisture. These findings provide experimental evidence of intensified plant–soil causality in coastal wetlands under climate warming.
      Jiatai Tian, Yawei Dong, Jianqiang Qian, Jin Tao, Dongmei Li, Zhiming Xin, Zhiming Zhang, Jinlei Zhu
      2025, 18 (1): rtae088.
      Abstract ( 77 )   PDF(pc) (1807KB) ( 36 )   Save
      Trade-offs have long been recognized as a crucial ecological strategy for plant species in response to environmental stresses and disturbances. However, it remains unclear whether trade-offs exist among different structures (or functions) of clonal plants in response to aeolian activities in sandy environments. We examined the growth (reproductive vs. vegetative), reproduction (sexual vs. asexual), and bud bank (tiller buds and rhizome buds, representing vertical and horizontal growth potential) characteristics of two dominant rhizomatous grasses (Psammochloa villosa and Phragmites australis) in the arid sand dunes of northwestern China. Our results showed that these two rhizomatous clonal species exhibited significant trade-offs in their adaptation strategies in response to changes in sand burial depth. Specifically, as sand burial depth increased, the clonal species tended to reduce their reproductive growth, sexual reproductive capacity, and horizontal growth potential, as evidenced by reductions in reproductive ramet number and proportion, panicles number, biomass, and their proportions, as well as rhizome bud number, biomass, and their proportions. Conversely, they increased vegetative growth, reproduction, and vertical growth potential, as evidenced by enhancements in vegetative ramet number and proportion, belowground bud number, biomass, and their proportions, and in tiller bud number, biomass, and their proportions. Our study underscores the importance of trade-offs in the adaptation strategies of rhizomatous clonal species in sandy environments where drought stress and aeolian disturbance coexist. Those trade-offs could ensure the population persistence and stability of pioneering psammophytes in sand dunes, which should be considered during sand-fixing and vegetation restoration efforts in arid sand dunes.
      Liang Mao, Jie Liu, Xiang Xiang, Feifei Tian, Linkai Yang, Xueqin Wan, Hanbo Yang, Fang He, Gang Chen, Lianghua Chen
      2025, 18 (1): rtae099.
      Abstract ( 32 )   PDF(pc) (4379KB) ( 22 )   Save
      The ecologically fragile arid valleys in western China have low afforestation survival rates, and the lack of adaptable superior variety is key to restricting forestry production and ecological restoration in this region. The native poplar trees are important germplasm resources in this region, with a wide range of taxa, rich genetic variations, and great potential for breeding and utilization. Six clones of native poplars were used in a field trial to investigate variations in survival, growth and adaptation to arid-warm and arid-hot valleys. In the arid-hot valley, clone Y1-2 exhibited the highest survival rate and growth condition, surpassing other clones, while clones B7-4 and P3-6 demonstrated superior survival and growth performance in the arid-warm valley. Clone B7-4 displayed the highest soluble sugar content in leaves across both habitats. Superoxide dismutase and ascorbate peroxidase activities, along with malondialdehyde content in leaves, were higher in the arid-hot valley for all clones compared with the arid-warm valley. Long-term water use efficiency, as indicated by δ13C in leaves, was significantly higher for all clones in the arid-hot valley, particularly for H1-6, T3-2 and P3-6. Increases in upper epidermis thickness were observed in clones E1, B7-4 and P3-6, while Y1-2 exhibited a higher palisade parenchyma thickness (PT) in the arid-hot valley compared with the arid-warm valley. Vein densities were higher in leaves of clones E-1, B7-4, Y1-2 and P3-6 in both valleys compared with other clones, with B7-4 showing a significant increase in mean vein width in the arid-hot valley. In conclusion, the superior growth performance of clone B7-4 in the arid-warm valley may be attributed to its stronger osmotic adjustment and higher capacity to maintain water transportation through venation. The exceptional performance of clone Y1-2 in the arid-hot valley may be associated with its compact arrangement of PT, as well as its stronger capacity for hydraulic transport and antioxidant resistance in leaves.
      Xianglong Jin, Yanjing Lou, Peng Zhang, Haoran Tang, Qiyao Zhang, Pete Smith
      2025, 18 (1): rtae113.
      Abstract ( 25 )   PDF(pc) (1361KB) ( 12 )   Save
      Accurate estimation of vegetation biomass is a critical component for estimating terrestrial ecosystem carbon stocks. However, research on biomass estimation for herbaceous marshes remains limited. In this study, we collected 270 paired above-ground biomass (AGB) and trait data from reed marshes in Northeast China to estimate AGB, and 70 paired AGB and below-ground biomass (BGB) data from global literature to estimate BGB. The results showed that classifying reed marshes into saltwater and freshwater marshes greatly improved the model fit (R2 values of classified vs. overall models: >0.50 vs. >0.31 for AGB estimation and >0.50 vs. >0.10 for BGB estimation, respectively). A power-law allometric model using plant height as the sole predictor was optimal for AGB estimation, and the inclusion of plant density did not markedly enhance prediction accuracy. The power function also effectively described the relationship between AGB and BGB, with scaling exponents of 1.13 and 0.60 for saltwater and freshwater marshes, respectively. Our results indicate that saltwater and freshwater marsh classification is necessary for accurate wetland vegetation carbon estimation. These findings provide valuable insights into the prediction of carbon dynamics in wetland ecosystem and supports a better understanding of wetland carbon sequestration.
      Xian Wu, David C. Deane, Hua Xing, Jiarong Yang, Junfang Chen, Xiaolin Liu, Shu Dong, Fangliang He, Yu Liu
      2025, 18 (1): rtae105.
      Abstract ( 41 )   PDF(pc) (4309KB) ( 25 )   Save
      The significance of microbes for ecosystem functioning is well known; however, within a single system, the relative contributions of keystone and rare taxa to soil microbial functions are less well quantified, as are their shared or unique responses to abiotic conditions. Furthermore, their associations with tree community composition in natural forest ecosystems are not well understood. In this study, a total of 1287 soil samples were collected from a 20-ha subtropical forest plot and analyzed using high-throughput sequencing. Based on co-occurrence network analyses, we conducted a comparison of the associations between keystone and rare taxa with the structure, functions and stability of soil microbial communities. Additionally, we examined their associations with tree community composition. Results showed that keystone taxa made a significantly greater contribution than rare taxa in all comparisons of microbial functions and stability. Keystone taxa had direct effects on microbial community structure and also mediated indirect effects of abiotic conditions. Neither effect was evident for rare taxa. The importance of keystone taxa also extended to aboveground composition, where tree community composition was more closely associated with keystone taxa than with rare taxa. While it may still be premature to establish causality, our study represents one of the initial attempts to compare the relative importance of keystone and rare microbial taxa in forest soils. These findings offer the potential to improve natural forest ecosystem functioning and tree diversity through the manipulation of a small number of keystone soil microbial taxa, as has been demonstrated in agroecosystems.
      Xuanping Qin, Wei Liang, Minghu Liu, Zhiming Xin, Zhigang Wang, Quanlai Zhou, Liang Tian, Lu Zong, Jinlei Zhu, Zhimin Liu
      2025, 18 (1): rtae106.
      Abstract ( 22 )   PDF(pc) (1522KB) ( 9 )   Save
      Plant crown can affect the seed dispersal process. Clarifying the influence of plant crown type on seed dispersal kernel is important for predicting species distribution. However, the effects of different plant crown types on seed dispersal have rarely been tested. To address this, we conducted wind tunnel experiments to investigate the average seed dispersal distance, range, kurtosis and skewness of 29 species with varying diaspore traits (e.g., appendage type, mass, projected area, shape index, wing loading and terminal velocity) under 3 wind speeds (2, 4 and 6 m s−1). We examined seeds passing through different crown types, classified based on crown size, branch density, and the presence or absence of leaves. We fitted functions to the seed dispersal distance and found that the Gaussian function provided the best fit. Our results showed that plant crown type had significant effects on dispersal kurtosis and skewness but not on the average dispersal distance or range under low wind speed conditions. Specifically, crown width and branch density influenced dispersal kurtosis, while the presence of leaves affected both kurtosis and skewness. Increasing wind speed reduced the influence of plant crowns on dispersal kurtosis and skewness. Although plant crowns did not significantly affect average seed dispersal distance, they altered the shape of the seed dispersal kernel. Consequently, while the dispersal range of seeds through different crowns remained relatively invariant, the density of dispersal varied significantly. These findings provide valuable insights into plant metapopulation dynamics and highlight the importance of considering crown architecture in seed dispersal studies.
      Ming-Wei Li, Jing Zhang, Zhao-Fei Wu, Yong-Shuo Fu
      2025, 18 (1): rtae108.
      Abstract ( 15 )   PDF(pc) (3219KB) ( 6 )   Save
      Climate change has significantly altered the carbon and water cycles of terrestrial ecosystems. Climate change and the extended vegetation growing season enhanced ecosystem gross primary production (GPP). However, the relative contributions of climate drivers and vegetation phenology to GPP remain unclear. Based on satellite-derived vegetation phenology and GPP datasets from 1982 to 2018, we investigated the spatiotemporal patterns of GPP and its drivers in the Jinsha River watershed. We found that the growing season GPP significantly increased from 1982 to 2018, which was primarily attributed to changes in the growing season length (GSL) and temperature. The effect of GSL on GPP was the highest (r = 0.34), with its effect being larger than that of temperature, precipitation and radiation in 41% of the watershed. Importantly, the area where GPP was predominantly influenced by GSL increased by 12% in grid cells during the period of 2001–2018 compared with 1982–2000, indicating that GSL was playing an increasingly important role in driving GPP. Our findings highlight the dynamic responses of GPP to climate change and the associated phenological variations, which are crucial for improving the understanding of the terrestrial carbon balance.
      Fandong Meng, Yanzi Yan, Lili Li, Lirong Zhang, Bixi Guo, Zhiyong Yang, Tsechoe Dorji
      2025, 18 (1): rtae114.
      Abstract ( 15 )   PDF(pc) (1482KB) ( 7 )   Save
      The spatial pattern of phenology reflects long-term plant adaptation to local environments, yet the drivers of these patterns remain poorly understood. Using satellite data from 2001 to 2018, this study employed the normalized difference vegetation index for vegetation structural greenness and solar-induced chlorophyll fluorescence for vegetation functional photosynthesis to analyze spring phenology on the Qinghai-Tibetan Plateau (hereafter, QTP). A machine learning method, Boosted Regression Trees (BRT), was applied to evaluate the contributions of 19 abiotic and biotic factors to the spring phenology. The results showed that both the spring leaf phenology (SOSNDVI) and photosynthesis phenology (SOSCISF) exhibited a delayed trend decreasing from east to west across the QTP. BRT analysis demonstrated shortwave radiation or/and elevation as key drivers, with higher radiation or elevation associated with more delayed spring phenology spatially, likely due to the constraints of extreme radiation and elevations on spring phenology. Furthermore, we also noted that plants were acclimated to strong radiation to some extent with increasing elevation, namely declined negative effect of radiation/elevation on spring phenology. This acclimation likely enhances plant fitness in the harsh environments of the QTP. Our study provides novel insights into plant phenology on the QTP and highlights the importance of integrating spatial and temporal analysis to improve the localization of phenology models.
      Yuan-Yuan Cui, Liu Bai, Dong-Jie Hou, Zhong-Wu Wang, Jing Wang, Zhi-Qiang Qu, Yun-Bo Wang, Guo-Dong Han, Zhi-Guo Li, Hai-Yan Ren, Hai-Ming Wang
      2025, 18 (1): rtae112.
      Abstract ( 47 )   PDF(pc) (2295KB) ( 15 )   Save
      Precipitation significantly influences the composition and structure of grassland ecosystems, particularly in arid desert steppes. Stipa breviflora, as a keystone species, plays a crucial role in maintaining the stability of the desert steppe. However, the response of S. breviflora’s succession strategy to changes in precipitation within the community remains uncertain. Since 2016, this research was conducted in a desert steppe in Inner Mongolia, China, involving control precipitation (PCK), and increases of 50% (P50) and 100% (P100) in natural precipitation. We measured biomass, height and canopy cover, calculated the importance value (IV) by species, and assessed the photosynthetic parameters and leaf elemental content of S. breviflora in 2021 and 2022. Results showed that the increase of precipitation significantly reduced the IV of S. breviflora. The net photosynthetic rate, transpiration rate, stomatal conductance, aboveground biomass carbon content and aboveground biomass nitrogen of S. breviflora leaves grew considerably in experimental plots receiving more precipitation, while δ13C value of leaves decreased significantly. Linear regression analysis and structural equation model showed that although the increase of precipitation improved the adaptability of S. breviflora functional traits and increased its IV, a higher transpiration rate significantly contributed to the decrease in its IV. Consequently, our research reveals the succession strategy of S. breviflora and provides a theoretical basis for studying the response mechanisms of desert steppe plant communities to climate change.
      Siqi Wu, Yanyu Jiang, Ling Ai, Fuzhong Wu, Qiuxia Wu, Xinying Zhang, Jingjing Zhu, Xiangyin Ni
      2025, 18 (1): rtaf002.
      Abstract ( 25 )   PDF(pc) (1794KB) ( 13 )   Save
      Atmospheric carbon dioxide (CO2) concentrations have been increasing dramatically due to human activities and land use changes, and the CO2 fertilization effect significantly increases global net primary productivity. However, whether the decomposition of surplus litter input on the soil surface is facilitated by elevated CO2 (eCO2) across a broad range of terrestrial ecosystems is not fully understood. We compiled 227, 85 and 131 paired observations (with and without eCO2) for litter mass loss, carbon (C) and nitrogen (N) release, respectively, during litter decomposition to assess the fate of decomposing litter and C and N release under eCO2 across terrestrial ecosystems. Litter mass loss was decreased by 4.5%, and C and N release were significantly reduced by 6.7% and 3.4%, respectively, under eCO2. This eCO2 effect on litter mass loss was greater in forests (decreased by 7.2%) than in croplands and grasslands. In forests, eCO2 had a greater effect on the decomposition rate of broadleaved than coniferous litter, and root litter was more sensitive than leaf and stem litter. Changes in litter lignin concentration and edaphic factors under eCO2 contributed to these differences in litter decomposition. Greater decreases in litter mass loss and C and N release were found after longer time (6–12 months) than short-term (less than 6 months) CO2 enrichment. A possible consequence is that more litter accumulates on the soil surface without being decomposed due to eCO2 in terrestrial ecosystems over longer time periods, resulting in a negative loop in biogeochemical cycles with increasing atmospheric CO2 concentration.
      Min Liu, Man-Juan Huang, Finn Kjellberg, Yan Chen, Jian Zhang, Rui Zhao, Yuan-Yuan Ding, Yang Yang, Jun-Yin Deng, Kai Jiang, Yuan-Yuan Li, Xin Tong, Tong Luo, Rong Wang, Xiao-Yong Chen
      2025, 18 (1): rtaf007.
      Abstract ( 20 )   PDF(pc) (3866KB) ( 10 )   Save
      Closely related and co-distributed species usually share a common phylogeographic history, but it remains unclear whether ecologically interacting species can respond synchronously to historical climate changes. Here, we focused on a fig–pollinator mutualism comprising Ficus pumila var. pumila and its obligate pollinators (morphospecies Wiebesia pumilae), and collected samples across most of their distribution ranges. We employed cytoplasmic DNA sequences and nuclear microsatellite loci to reveal the species composition within the pollinators and to test whether the two mutualists exhibited similar postglacial phylogeographic patterns. We identified three cryptic pollinator species, with two dominant cryptic species exhibiting parapatric distributions in the northern and southern parts of the plant’s range, respectively. Similar current spatial genetic structures were detected in the two dominant cryptic pollinator species and the host plant, with both showing eastern and western genetic clusters. Moreover, evidence for postglacial expansion was found for all three species, and their potential refugia during the Last Glacial Maximum were located in the eastern and western parts of their distribution ranges. These results suggest synchronous responses to historical climate changes. Our study demonstrates congruent phylogeographic patterns between obligate mutualists and highlights the role of biogeographic factors in shaping the current biodiversity across trophic levels.
      Bo Guan, Rong Hu, Mengdi Wu, Qiutang Wu, Jisong Yang, Xuehong Wang, Weimin Song, Guangxuan Han
      2025, 18 (1): rtae115.
      Abstract ( 19 )   PDF(pc) (2419KB) ( 10 )   Save
      To explore the adaptive strategies of the clonal plant Phragmites australis in heterogeneous salt habitats, we conducted a pot control experiment with severing, salt heterogeneity and competition treatment using dominant plants from the Yellow River Delta, including P. australis and Suaeda salsa. This study assessed the effects of salt heterogeneity, clonal integration and interspecific competition on the morphological and physiological traits of P. australis. The results showed that clonal integration significantly promoted root system growth and underground biomass accumulation of P. australis. Competition significantly reduced plant height, tiller number, leaf number, leaf length and internode length, inhibiting above- and underground biomass accumulation. Under the heterogeneous salt treatment, clonal integration significantly promoted only the rhizome biomass of P. australis. The S. salsa competition treatment significantly lowered the chlorophyll contents, net photosynthetic rate, stomatal conductance and transpiration rate of P. australis. Nevertheless, leaf length and width were maintained, potentially to minimize photoinhibition. Competition significantly reduced K+ contents in P. australis fine roots and rhizomes and Na+ contents in fine roots. The Na+ content of fine roots was significantly affected by competition, salt heterogeneity, severing treatment and the interaction between competition and severing treatment. In conclusion, competition significantly inhibited the growth, photosynthesis and ion content accumulation of P. australis. Meanwhile, clonal integration promoted root growth, especially under heterogeneous salt conditions. Hence, this research provided a significant and deeper understanding of the ecological adaptive responses of clonal plants in coastal heterogeneous habitats.
      Baoyi Peng, Mengcheng Ye, Jingyao Li, Hao Zhang, Leyao Xu, Yuan Jia, Yipeng Wang, Bin Huang, Fangzhou Liu, Peixuan Liu, Jiamin Lin, Fenghuang Wu, Jianrong Xia, Peng Jin
      2025, 18 (1): rtae116.
      Abstract ( 17 )   PDF(pc) (3497KB) ( 5 )   Save
      Understanding how phytoplankton adapt to elevated CO2 and/or warming through long-term genotypic changes is critical for predicting future phytoplankton distribution and community structure. In this study, we conducted a 4.5-year experimental evolution with the model marine diatom Phaeodactylum tricornutum Bohlin under four environmental conditions: ambient (control), elevated CO2, warming and combined elevated CO2 + warming. Following this long-term adaptation, we exposed the populations to a broad CO2 gradient in a short-term (7-day) experiment to assess their multi-trait responses. Our results demonstrate that P. tricornutum Bohlin populations adapted to different environmental regimes exhibit significant multi-trait variation across CO2 gradients. Notably, the variability driven by long-term adaptation exceeded that induced by short-term CO2 changes. Furthermore, both long-term adaptation and short-term CO2 exposure altered trait co-variations, highlighting the complex interplay between environmental history and immediate conditions. This study emphasizes the importance of assessing long-term genetic changes in marine phytoplankton under global change, as short-term experiments alone may underestimate their adaptive potential and the broader implications for marine ecosystems under future climate scenarios.
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    Soil nutrients drive the spatial variability of wetland productivity along degradation gradients through plant functional traits
    Junxiang Ding, Mingli Zhang, Xiaowen Zeng, Ming Dou, Wenjing Ge, Yingshu Cao, Qingbin Mi, Jihua Wang, Fengmin Lu, Liang Zhao, Deliang Kong, Huajun Yin, Lin Wang, Guangsheng Zhou
    doi: 10.1093/jpe/rtaf028
    Abstract ( 17 )    PDF    Save
    The stability mechanisms of ecosystem functions have been a hot topic in ecology. However, in wetland ecosystems, the mechanisms by which biotic and abiotic factors interact to affect ecosystem stability in changing environments remain largely unclear. This study investigated the key factors and underlying mechanisms that regulate the spatial variability of wetland productivity by measuring community productivity, multiple components of biodiversity (i.e., species diversity, community functional composition and diversity), and environmental factors along a well-characterized gradient of wetland degradation in the lower reaches of the Yellow River. The results showed that the spatial variability of productivity in wetlands increased with intensified degradation. The spatial variability of wetland productivity was not related to species richness, but was mainly affected by changes in community functional composition and diversity. Furthermore, degradation-induced changes in soil nutrients drove the spatial variability of productivity to increase with shifts in functional composition towards more conservative traits (i.e., higher leaf dry matter content and root tissue density), and to decrease with higher functional trait diversity. These findings reveal the driving mechanism of spatial variability in wetland productivity under degradation, and suggest that reduced nutrient availability, by altering plant resource strategies, can affect the spatial reliability of key ecosystem functions in wetlands.
    Responses of fine root dynamics to nitrogen application in global temperate forests and grasslands: inconsistencies between biomass and turnover
    Yixiao Tao, Xiaofeng Fu, Xia Xu, Qinghong Geng, Chonghua Xu, Chenghui Ju, Qian Li, Wenfang Liu, Xiaochou Chen
    doi: 10.1093/jpe/rtaf027
    Abstract ( 15 )    PDF    Save
    Fine root dynamics are crucial for terrestrial ecosystem productivity and nutrient cycling. However, the effects of nitrogen (N) deposition on fine root dynamics in temperate ecosystems remain poorly understood. In this study, we used a meta-analysis to explore the general patterns and key drivers of fine root biomass and turnover in temperate forests and grasslands in response to N application. We found that N application significantly reduced fine root biomass compared to the control group (no N application), with notable differences across N forms. However, the impact of N application on fine root biomass remained consistent across ecosystem types, soil depths and root diameters. In terms of fine root turnover rate, N application had no significant overall effect, and the response did not vary across N forms, ecosystem types, soil depths or root diameters. However, significant differences were observed across methods for estimating fine root turnover rate. Multiple regression analysis showed that mean annual temperature (MAT) and experimental factors (including duration and N application rates) were the primary determinants of fine root biomass response to N application. In contrast, fine root turnover was not significantly influenced by any of the factors analyzed. Overall, our findings highlight the negative impact of N application on fine root biomass and the neutral effect on fine root turnover, and also suggest that find root dynamics are closely associated with experimental factors, including experiment duration and N application rate. This study provides an important advancement in understanding the feedback between root dynamics and global change, offering insights for developing management strategies to address belowground ecological processes under global change scenarios.
    Rest-grazing in Spring affects the soil microbial community mainly by altering plant diversity
    Min Zhang, Jun Wen, Xiaoli Wang, Cancan Zhao, Yuan Ma, Yushou Ma, Shixiong Li
    doi: 10.1093/jpe/rtae110
    Abstract ( 18 )    PDF    Save
    Soil microorganisms play a very important role in the alpine grassland ecosystem of the Qinghai-Tibetan Plateau as indicators of environmental change; scientific and reasonable rest-grazing can effectively curb the degradation of grassland, but the response of soil microbial communities to rest-grazing and the intrinsic driving factors are uncertain. Therefore, in this study, two types of winter-spring pastures, steppe meadow (StM) and swamp meadow (SwM), were selected for rest-grazing and grazing treatments in spring, and indicators such as vegetation community characteristics, soil properties and microbial community changes were measured to investigate the response of soil microbial communities to rest-grazing and its mechanisms. The results showed that rest-grazing in spring could significantly increase above-ground biomass and soil organic carbon in alpine grassland. In steppe meadow, Total PLFAs, Actinomycetes, Bacteria, Gram-positive bacterial and Gram-negative bacterial were lower than the control in StM1, higher than the control in StM2. Total PLFAs, Arbuscular mycorrhizal fungi, Actinomycetes, Bacteria, Fungi, Gram-positive bacterial, Gram-negative bacterial and ratio of Gram-positive bacterial to Gram-negative bacterial were higher than control in SwM. The stress indices of the two grassland types were lower than the control after rest-grazing. Fungi tended to increase with above-ground biomass when grassland type was not taken into account (P<0.05), Total PLFAs showed an increasing trend with above-ground biomass (P>0.05). The combination of soil physicochemical properties and vegetation community characteristics influences changes in soil microbial community structure (40.87%). Simpson, vegetation coverage, soil total phosphorus and soil bulk density significantly influenced the soil microbial community, with species diversity (Simpson) being the most significant contributor (60%) to the soil microbial community. In summary, rest-grazing in spring can beneficially affect the soil microbial community by improving the characteristics of alpine grassland vegetation communities and restoring soil properties, which in turn can beneficially affect the soil microbial community.
    Canopy properties predominately explain above-ground biomass stock in temperate forests
    Pengcheng Jiang, Han He, Zikun Mao, Yanjun Su, Mengxu Zhang, Meihui Zhu, Zhichao Xu, Jin Yin, Hongyi Jiang, Shuai Fang, Xugao Wang
    doi: 10.1093/jpe/rtaf026
    Abstract ( 24 )    PDF    Save
    Canopy properties (e.g., canopy structure and spectral variables) strongly influence forest above-ground biomass (AGB). However, the importance of these canopy properties in driving AGB in natural forests, especially relative to other drivers such as plant species diversity and environmental conditions, remains poorly understood. We assessed the relative importance of canopy properties (structure and spectral variables) and plant species diversity (multidimensional diversity metrics and trait composition) in regulating AGB along environmental gradients (topography and soil nutrients) in a temperate forest in Northeast China, using UAV-based LiDAR and hyperspectral data. We found that the explanatory power of environmental conditions, plant species diversity, canopy spectral properties and canopy structure on temperate old-growth forests AGB was 3.8%, 8.0%, 4.1% and 13.3%, respectively. AGB increased with increasing canopy height and structural complexity. Canopy spectral diversity was a better predictor of AGB than traditional diversity metrics in old-growth forests. Canopy spectral composition also played an important role in explaining AGB in the secondary forests. In addition, plant phylogeny, functional diversity and the community-weighted mean (CWM) of acquisitive traits had significant direct positive effects on AGB. Finally, topography and soil nutrient content indirectly influenced AGB through canopy properties and plant species diversity. Our study highlights the key role of canopy properties in influencing AGB. For future monitoring, regular monitoring with spectral and LiDAR data should be emphasized to provide real-time insights for forest management.
    Contrasting trait variations and trait correlation networks across heteromorphic leaves of Populus euphratica
    Hong-Yu Yang, Ze-qi Zhang, Jia Ding, Lei Li, Yi-Yun Tang, Jin-Chao Feng, Sha Shi
    doi: 10.1093/jpe/rtaf025
    Abstract ( 13 )    PDF    Save
    Traits and their correlation networks can reflect plant adaptive strategies. However, variations in traits and trait correlation networks across heteromorphic leaves within species remain largely unexplored. In this study, we systematically quantified a diverse array of leaf traits—spanning morphology, anatomy, physiology and biochemistry—among the striped, lanceolate, ovate, and broadly ovate leaves of Populus euphratica, aiming to elucidate the adaptive differences across these various leaf types. We found that the four heteromorphic leaves showed significant differences in leaf traits. From striped leaves to broadly ovate leaves, leaf size, leaf thickness, water use efficiency and catalase content significantly increased, while specific leaf area showed the opposite pattern. Principal component analysis and cluster analysis revealed distinct aggregation and clear demarcation of the four leaf types, indicating substantial variations in trait compositions and their distinct ecological adaptations. Plant trait networks varied significantly across the four leaf types, with the broadly ovate leaves exhibiting a fragmented network structure that enhances their modularity. This suggests strong resilience to disturbances and is consistent with the characteristic foliage on mature trees. Regardless of leaf type, nitrogen and phosphorus consistently emerged as hub traits within plant trait networks, underscoring their fundamental role in driving physiological processes and influencing phenotypic expression. This study meticulously delineates the variations in both individual leaf traits and trait correlation networks across the heteromorphic leaves of P. euphratica, significantly deepening our understanding of plant adaptive strategies.
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    2021, Vol. 14 No.6 No.5 No.4 No.3 No.2 No.1
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