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 2
    01 April 2025
      Research Articles
      Mengjun Hu, Jiali Wang, Zhenxing Zhou, Min Zhang, Xinchuang Xu, Lingxuan Wang, Mingxing Zhong, Jixun Chen, Xuehao Liu, Shenglei Fu
      2025, 18 (2): rtaf006.
      Abstract ( 33 )   PDF(pc) (2583KB) ( 38 )   Save
      The decomposition of deadwood is a crucial process for the accumulation and sequestration of soil organic carbon (SOC) in forest ecosystems. However, the response of SOC to different decay classes of deadwood and the underlying mechanisms remain poorly understood. Here, we investigated the dynamics of SOC, soil properties, extracellular enzyme activities, and phospholipid fatty acid biomarkers across five decay classes (ranging from 1 to 5) of Masson pine (Pinus massoniana Lamb.) downed deadwood in a subtropical–temperate ecotone forest in Central China. Our results revealed a nonlinear response pattern of SOC along the deadwood decomposition gradient, with the maximum value at the decay class 4. Soil available nitrogen content, bacterial biomass, fungal biomass, the ratio of fungal-to-bacterial biomass, cellulase, activity and ligninase activity all increased with the intensification of deadwood decay, while soil pH decreased. The increase in SOC content was associated with a direct positive effect of bacteria and both direct and indirect positive effects of fungi by cellulose activity, but ligninase activity showed no significant relationship with SOC content. These findings suggest that cellulose and microbial biomass are key determinants of soil C formation and sequestration during deadwood decomposition. This study highlights the importance of the nonlinear response of SOC to deadwood decay, providing valuable insights for predicting future carbon-climate feedbacks.
      Liancheng Zhang, Guli Jiapaer, Tao Yu, Hongwu Liang, Bojian Chen, Kaixiong Lin, Tongwei Ju, Philippe De Maeyer, Tim Van de Voorde
      2025, 18 (2): rtaf001.
      Abstract ( 26 )   PDF(pc) (2868KB) ( 22 )   Save
      Understanding the driving mechanisms of forest changes is of great significance for developing effective adaptation strategies to mitigate the impacts of climate change and human activities on ecosystems. This study used Theil–Sen median trend analysis, Mann–Kendall test, contribution rate decomposition, partial least squares, geodetector and residual analysis to explore the impact of climate change and human activities on the forest coverage area and NDVI of the Altai Mountains. Results show that changes in forest cover are driven by both forest management policies and climate change. Among them, forest management policy is the main factor. However, there are differences in the driving mechanisms in different altitude zones: in the alpine and subalpine zones, the promoting effects of natural death and climate change bring the forest coverage area toward a dynamic balance, while under the combined effects of human activities and climate change, the forest coverage area in the low mountain zones shows an expansion trend. For forest NDVI, the analysis results of the six scenarios show that the joint action of climate change and human activities promotes the growth of forest NDVI in the largest proportion (50.20%); the impact of climate change on forest NDVI is greater than that of human activities, and most of it is a promotion effect (30.28%). Forest degradation is mainly caused by human activities (19.39%), especially in the edge areas of the forest. Among climate factors, precipitation and snowmelt water are the main controlling factors for forest growth. Snowmelt water from March to April is an important water source before the growing season. This study provides the important scientific basis for forest management and strategic planning in the Altai Mountains.
      Qingling Sun, Jiang Zhu, Siyu Zhu, Baolin Li, Jie Zhu, Xiuzhi Chen, Wenping Yuan
      2025, 18 (2): rtaf009.
      Abstract ( 34 )   PDF(pc) (6009KB) ( 18 )   Save
      Phenological models are valuable tools for predicting vegetation phenology and investigating the relationships between vegetation dynamics and climate. However, compared to temperate and boreal ecosystems, phenological modeling in alpine regions has received limited attention. In this study, we developed a semi-mechanistic phenological model, the Alpine Growing Season Index (AGSI), which incorporates the differential impacts of daily maximum and minimum air temperatures, as well as the constraints of precipitation and photoperiod, to predict foliar phenology in alpine grasslands on the Qinghai–Tibetan Plateau (QTP). The AGSI model is driven by daily minimum temperature (Tmin), daily maximum temperature (Tmax), precipitation averaged over the previous month (PA), and daily photoperiod (Photo). Based on the AGSI model, we further assessed the impacts of Tmin, Tmax, PA, and Photo on modeling accuracy, and identified the predominant climatic controls over foliar phenology across the entire QTP. Results showed that the AGSI model had higher accuracy than other GSI models. The total root mean square error (RMSE) of predicted leaf onset and offset dates, when evaluated using ground observations, was 12.9 ± 5.7 days, representing a reduction of 10.9%–54.1% compared to other models. The inclusion of Tmax and PA in the AGSI model improved the total modeling accuracy of leaf onset and offset dates by 20.2%. Overall, PA and Tmin showed more critical and extensive constraints on foliar phenology in alpine grasslands. The limiting effect of Tmax was also considerable, particularly during July–November. This study provides a simple and effective tool for predicting foliar phenology in alpine grasslands and evaluating the climatic effects on vegetation phenological development in alpine regions.
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    The mechanisms of plant-associated microbes in regulating plant drought adaptation
    Chaoqun Chen, Juan Zhan, Wenzhi Du, Shulan Wu, Liu Li, Chunying Yin
    doi: 10.1093/jpe/rtaf047
    Abstract ( 6 )    PDF    Save
    Drought represents a paramount abiotic stressor constraining global agroforestry productivity. Plants have evolved multifaceted adaptive strategies involving active modulation of symbiotic microbial communities to mitigate drought stress. These plant-associated microbes enhance plant drought adaptation via five principal mechanisms: 1) EPS-mediated biofilm formation on plant surface enhances hydroregulation and edaphic structural stability; 2) Osmoprotectant biosynthesis (e.g., proline) maintains cellular osmotic equilibrium; 3) Synthesizing antioxidants to reduce damage from reactive oxygen species and oxidative stress; 4) Regulating plant phytohormone metabolism by secreting hormones (e.g., IAA) and 1-aminocyclopropane-1-carboxylic deaminase (ACCD); 5) Emitting signaling molecules (e.g., volatile organic compounds, hormones, and enzymes) to activate plant drought adaptation. Future researches should focus on the development of host-specific drought-adaptive microbial consortia while elucidating phyllosphere-rhizosphere microbiome crosstalk , ultimately harnessing translational microbiome engineering to evaluate their efficacy in multi-environment agricultural systems.
    Species and Elevation Differences in Climate Responses of Two Conifers at the Southern Edge of the Tengger Desert: Insights from Tree-ring Width and δ18O Analyses
    Qian Li, Liang Jiao, Yarong Qin, Xin Yuan, Ruhong Xue, Peng Zhang, Xuge Wang, Zhengdong Guo, Le Zhang
    doi: 10.1093/jpe/rtaf041
    Abstract ( 8 )    PDF    Save
    The physiological response mechanisms of trees to climate change are complex, particularly across varying elevations and among different tree species. In this study, we collected tree ring samples from two dominant conifer species (Picea crassifolia and Pinus tabuliformis) at three elevations at the edge of the Tengger Desert. We used tree-ring width (TRW) and tree ring oxygen isotopes (δ18OTR) to investigate how species and elevations affect their responses to climate change. Pearson's correlation analysis and relative importance analysis were used to study the specific response processes of the two conifers to climate. The results showed that the TRW was mainly controlled by SPEI during the growing season, which means that drought stress had the greatest effect on it. And δ18OTR mainly responded to summer relative humidity (RH). Both TRW and δ18OTR of Picea crassifolia showed higher sensitivity to climate change. This sensitivity is largely attributed to the rapid uptake of precipitation by its developed shallow-rooted root system, which allows it to retain the precipitation signal in both TRW and δ18OTR. However, Picea crassifolia may be more susceptible to drought stress and growth decline or even death in the context of a warming region. Our results are important for understanding the impacts of climate change on forest ecosystems using multiple indicators and developing corresponding ecological conservation measures.
    Shifts in plant reproductive phenology induced by multiple global change factors depend on phenological niche and pollination mode
    Xiaoyi Wang, Anne D. Bjorkman, Xin Li, Mengdi Luan, Mengqian Wang, Xuebin Yan, Ying Wang, Xianhui Zhou, Miaojun Ma, Hui Guo
    doi: 10.1093/jpe/rtaf048
    Abstract ( 9 )    PDF    Save
    Plant reproductive phenology is sensitive to climate change and has great implications for plant reproduction, community structure and ecosystem functions. Shifts in reproductive phenology under warmer temperatures have been widely studied, but how other global change factors, such as nitrogen enrichment and altered precipitation, interact with warming to influence phenology remains poorly understood. We conducted a field experiment in a Tibetan alpine meadow to examine the effects of warming, nitrogen addition, precipitation reduction and their interaction on plant reproductive phenology in 2017 and 2021. We found that warming interacted with precipitation reduction to affect reproductive phenology, independent of nitrogen addition. Specifically, warming led to an advance in flowering (3.5 days) and fruiting onset (3.8 days), but precipitation reduction offset this effect. Warming also extended the duration of flowering and reproduction, but only when interacting with precipitation reduction. Nitrogen addition delayed the onset of flowering (2.1 days) and fruiting (1.8 days). Moreover, the effects of warming depended on the phenological niche of each species as well as its pollination mode. Early-flowering species advanced more in flowering onset than late-flowering species. The duration of flowering and reproduction of wind-pollinated species was prolonged while that of insect-pollinated species was shortened by warming. Our study highlights the necessity of considering the interaction of multiple factors in predicting phenological responses under global change and suggests that plant life-history traits should be taken into account in future studies.
    Variation in niche effects on microbiota in two invasive plants
    Fanjiao Kong, Dingli Wang, Yu Shi, Liya Ma, Jianqing Ding
    doi: 10.1093/jpe/rtaf045
    Abstract ( 8 )    PDF    Save
    Terrestrial plants are colonized by various microorganisms in the rhizosphere, phyllosphere and endosphere. Variations of microorganisms between these niches could affect plant performance. While studies have indicated that microorganisms associated with invasive plants may facilitate their invasion success, niche effects on the composition, function and co-occurrence network of invasive plant microbiomes remain poorly understood. In this study, we investigated the bacterial and fungal communities in the rhizosphere soil, root and leaf endospheres of two invasive plants, Flaveria bidentis and Eclipta prostrata. F. bidentis is a recently introduced species (introduced in 2001), whereas E. prostrata has been invaded in China for over 1000 years. We found that microbial community of F. bidentis and E. prostrata harbored more specialists, fewer unique amplicon sequence variants (ASV), and lower diversity and network complexity in the leaf endosphere than that in the rhizosphere soil. Moreover, the bacterial and fungal communities in the rhizosphere soil, root and leaf endospheres of F. bidentis were more diverse, included more unique ASVs, and had a higher network complexity than those of E. prostrata. Predicted functional profiles revealed that there were more beneficial bacteria and fewer pathogenic fungi associated with F. bidentis than those with E. prostrata. These results demonstrate that there is a significant niche differentiation in the two invasive plant microbiotas, and this work may also indicate potential impact of residence time of invasive plants on plant-microbe interactions.
    Soil water availability alters plant‐soil feedback effects on invasive plant growth and foliar herbivory
    Lei Wang, Muhammad Hasnain, Zhanhui Tang, Kobayashi Makoto
    doi: 10.1093/jpe/rtaf044
    Abstract ( 15 )    PDF    Save
    Plant-soil feedback (PSF) effects of invasive plants are often regulated by abiotic factors, but whether soil water availability alters the impact of PSF on invasive plant growth and foliar herbivory remains unclear. We hypothesized that soil water content modifies PSF effects and then affects foliar herbivory. To test this, we established four soil water level treatments (soil surface elevated 0, 5, 10 or 15 cm above water) to examine their effects on PSF, growth traits, and herbivore resistance in the invasive weed Alternanthera philoxeroides. Results showed PSF was negative when soil surface was elevated 5 cm above water, but it was positive in other treatments. Soil condition, water treatment and their interactions significantly affected total biomass, leaf and branch numbers. As soil water content decreased, leaf nitrogen content increased, while the leaf C/N ratio decreased. Root nitrogen and C/N ratios were also affected by water treatment. Leaf mass per area and leaf area consumption rate were significantly affected by water content, with foliar herbivory being lowest when water content was at its minimum. Importantly, the effects of water availability on invasive plant performance and foliar herbivore resistance appeared to be stronger than those mediated by soil feedback. These findings suggest that soil water content, as a critical role, modifies the PSF effects on invasive plant performance, thereby indirectly affecting foliar herbivory.
  • 2025, Vol. 18 No.1
    2024, Vol. 17 No.6 No.5 No.4 No.3 No.2 No.1
    2023, Vol. 16 No.6 No.5 No.4 No.3 No.2 No.1
    2022, Vol. 15 No.6 No.5 No.4 No.3 No.2 No.1
    2021, Vol. 14 No.6 No.5 No.4 No.3 No.2 No.1
    2020, Vol. 13 No.6 No.5 No.4 No.3 No.2 No.1
    2019, Vol. 12 No.6 No.5 No.4 No.3 No.2 No.1
    2018, Vol. 11 No.6 No.5 No.4 No.3 No.2 No.1
    2017, Vol. 10 No.6 No.5 No.4 No.3 No.2 No.1
    2016, Vol. 9 No.6 No.5 No.4 No.3 No.2 No.1
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    2011, Vol. 4 No.4 No.3 No.1-2
    2010, Vol. 3 No.4 No.3 No.2 No.1
    2009, Vol. 2 No.4 No.3 No.2 No.1
    2008, Vol. 1 No.4 No.3 No.2 No.1
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