Response of distribution patterns of two closely related species in <i>Taxus</i> genus to climate change since last inter‐glacial

Wu, Xingtong; Wang, Minqiu; Li, Xinyu; Yan, Yadan; Dai, Minjun; Xie, Wanyu; Zhou, Xiaofen; Zhang, Donglin; Yi, Wen

doi:10.1002/ece3.9302

Cited by 8 publications

(8 citation statements)

References 131 publications

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“…Species distribution models (SDMs) are numerical tools used frequently to estimate current geographic distributions of species and to assess the effects of climate change on species distributions [14], as well as habitat suitability [15]. The Maximum Entropy (MaxEnt) model has been widely used in SDMs mainly due to its highly accurate and intuitive predictions [16,17], especially on predicting the impacts of climate change on the potential distribution of relict plants, such as Thuja sutchuenensis (Cupressaceae), Taiwania cryptomerioides (Cupressaceae) and Taxus wallichiana (Taxaceae) [18][19][20].…”

Section: Introductionmentioning

confidence: 99%

MaxEnt Modeling for Predicting Suitable Habitat for Endangered Tree Keteleeria davidiana (Pinaceae) in China

Zhang

Shen

Jiang

et al. 2023

Forests

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Understanding species response to climate change is essential for the conservation and utilization of species resources under rapid climate change in the future. In this study, the present and future suitable distribution range of Keteleeria davidiana, a tertiary relict gymnosperm, was predicted based on the maximum entropy model (MaxEnt). A total of 158 occurrence records were collected after removing the duplicated records. Six low-correlation climate variables were used to predict species distributions. The three key climate factors that affect the distribution of K. davidiana were temperature seasonality (34.96%), mean temperature of the coldest quarter (28.30%) and precipitation seasonality (13.58%). The most suitable zone of the temperature seasonality for K. davidiana was between 377.4 and 843.4. The highly suitable area was located in the mountainous regions of central and southeast China, which accounted for 13.39% of the whole study area. With climate warming in the future, the highly suitable distribution area of K. davidiana was estimated to decrease by 35% (SSP1-2.6 scenario) or 85% (SSP5-8.5 scenario). This study has provided a sufficient scientific basis for the future in situ and ex situ conservation of K. davidiana.

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Section: Introductionmentioning

confidence: 99%

MaxEnt Modeling for Predicting Suitable Habitat for Endangered Tree Keteleeria davidiana (Pinaceae) in China

Zhang

Shen

Jiang

et al. 2023

Forests

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“…Based on the output of the model, we used SDMtoolbox in ArcGIS v10.4 to analyze the centroid movement of F. suspensa over time under different GHG emission situation and plotted the trajectory of center-of-mass change ( Wu et al., 2022 ). When we take the MTSPS value (MTSPS = 0.3159) as the threshold, the current center of mass was situated in Xichuan County, Henan Province (111.314°E, 32.9972°N).…”

Section: Resultsmentioning

confidence: 99%

Current and future distribution of Forsythia suspensa in China under climate change adopting the MaxEnt model

Wang,

Lu,

Rohani

et al. 2024

Front. Plant Sci.

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This study evaluated the potential impact of climate change on the distribution of Forsythia suspensa, a valuable traditional Chinese medicinal plant, using the MaxEnt model integrated with Geographic Information System (GIS). By analyzing occurrence data from various databases and environmental variables including climate and soil factors, we forecasted the present and future (2050s and 2070s) habitat suitability of F. suspensa under different greenhouse gas emission scenarios (RCP8.5, RCP4.5, RCP2.6). Results indicated that the suitable habitats for F. suspensa were primarily located in North, East, Central, Northwest, and Southwest China, with a significant potential expansion of suitable habitats anticipated by the 2070s, particularly under the high emission scenario. The study identified precipitation and temperature as the primary environmental drivers impacting the distribution of F. suspensa. Furthermore, a northward shift in the centroid of suitable habitats under future climate scenarios suggested a potential migration response to global warming. This work provides crucial insights into the future conservation and cultivation strategies for F. suspensa amidst changing climatic conditions.

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“…At present, the models for the evaluation of suitable plant and animal habitats mainly include niche model (Xu et al, 2015;Grev et al, 2019;Wu et al, 2022;Zhang et al, 2022), mechanism model, and regression model. Among them, the niche model pays more attention to species occurrence sites and environmental variables.…”

Section: Main Environmental Factors Affecting the Distribution Of Gly...mentioning

confidence: 99%

Prediction of the potential distribution area of Glycyrrhiza inflata in China using a MaxEnt model

Du,

Xu,

Wang

et al. 2024

Front. Ecol. Evol.

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Glycyrrhiza inflata Batalin is an important medical plant of the genus Glycyrrhiza. It is one of the key protected plants in China, distributed in the desert areas of southern Xinjiang and Dunhuang of Gansu Province. It has a strong resistance to drought, heat, and salt stresses, and plays a pivotal role in sand fixtion in desert areas. In this study, based on 157 valid distribution records and eight environmental factors including climate factors and altitude, the potential distribution area of G. inflata in the last glacial maximum, middle Holocen, modern, and future (2050) times in China were predicted, using the optimized MaxEnt model and ArcGis 10.2 software. The results showed that the predicted distribution area was highly consistent with the current distribution range, and the area under the receiver operating characteristic (AUC) curve was 0.986, indicating that the prediction performance was excellent. The key climatic factors affecting the distribution were precipitation in December and the average annual precipitation. Meanwhile, the suitable area of G. inflata in modern times was 1,831,026 km2, mainly distributed in Turpan-Hami Basin, Tarim Basin, and Dunhuang of Gansu Province, with Lop Nur Town of Xinjiang as the distribution center. In 2050, the potential suitable area forG. inflata in China will be 1,808,090 km2, 250,970 km2 of which will be highly suitable, which is 150,600 km2 smaller than that in modern times, with a reduction rate of 60.0%. Therefore, there is a trend of great reduction in the suitable area of G. inflata. From the last glaciation maximum to the middle Holocene, the geographical distribution center shifted to the southwest margin of the Kumtag Desert, Xinjiang, then later continued to shift to the southwest. This study will provide a basis for understanding the origin and evolution of G. inflata, developing conservation strategies to minimize the impacts of environment change, and utilizing plant resource.

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Response of distribution patterns of two closely related species in Taxus genus to climate change since last inter‐glacial

Cited by 8 publications

References 131 publications

MaxEnt Modeling for Predicting Suitable Habitat for Endangered Tree Keteleeria davidiana (Pinaceae) in China

MaxEnt Modeling for Predicting Suitable Habitat for Endangered Tree Keteleeria davidiana (Pinaceae) in China

Current and future distribution of Forsythia suspensa in China under climate change adopting the MaxEnt model

Prediction of the potential distribution area of Glycyrrhiza inflata in China using a MaxEnt model

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