Energy–water and seasonal variations in climate underlie the spatial distribution patterns of gymnosperm species richness in China

Pandey, Bipin; Khatiwada, Janak Raj; Zhang, Lin; Pan, Kaiwen; Dakhil, Mohammed A.; Xiong, Qinli; Yadav, Ram Kailash P.; Siwakoti, Mohan; Tariq, Akash; Olatunji, Olusanya Abiodun; Justine, Meta Francis; Wu, Xiaogang; Sun, Xiaoming; Liao, Ziyan; Tadesse, Zebene

doi:10.1002/ece3.6639

Cited by 19 publications

(55 citation statements)

References 88 publications

(226 reference statements)

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“…In general, the large geographic area could support more species and vice versa (Rosenzweig, 1995;Körner, 2003). Therefore, to explain the species richness patterns in plants, several hypotheses have been proposed, which concern the primary productivity (Bhattarai and Vetaas, 2003;Vetaas et al, 2019), temperature (Hawkins et al, 2003;Vetaas et al, 2019), availability of water (rainfall/precipitation) (Currie and Paquin, 1987;Hawkins et al, 2003;Kluge et al, 2017), potential evapotranspiration (Bhattarai et al, 2004;Vetaas and Ferrer-Castán, 2008;Geng et al, 2019), and seasonality (Gao and Liu, 2018;Pandey et al, 2020a).…”

Section: Introductionmentioning

confidence: 99%

“…On the other hand, climatic seasonality increases the level of tolerance in plant species and favors the wide spread of organisms. There are studies that support the use of temperature seasonality (TS) and precipitation seasonality (PS) in explaining the richness pattern of plant species, including gymnosperms (Gao and Liu, 2018;Pandey et al, 2020a). Finally, net primary productivity (NPP) is directly linked to biochemical oxidation processes (Rahbek et al, 2007;Vetaas et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

“…China is one of the biodiversity hotspots of plant species on the earth, which can be proven by the presence of more than 25,000 species of flowering and non-flowering plants, including gymnosperms (Wu and Raven, 1999). There are 248 taxa of gymnosperms distributed in the ecoregions of China (Wu and Raven, 1999;Fang et al, 2011;Tang, 2015;You et al, 2017;Pandey et al, 2020a), where more than 80% are threatened, and around 50% are endemic species (Ying et al, 2004;Pandey et al, 2020a), demonstrating the hotspot of gymnosperm diversity. In this study, more attention was given to threatened and endemic gymnosperms because of their conservation priorities and geographical limitation, respectively (Vetaas and Grytnes, 2002;Ying et al, 2004;Kubota et al, 2015;Paudel et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

“…On the other hand, endemic species are geographic range specific and are given more attention; however, little is known about the elevational pattern of endemic gymnosperms' distribution (Kubota et al, 2015). Moreover, southwest China and Taiwan are abundant in the diversity of gymnosperms (Pandey et al, 2020a). These regions are characterized by the presence of the mountain with an elevation range of more than 4,000 m. On the other hand, extreme and harsh climatic conditions in the North, Tibetan plateau, and Inner-Mongolian regions might be the limiting factor for the distribution of gymnosperms (Pandey et al, 2020a).…”

Section: Introductionmentioning

confidence: 99%

“…Moreover, southwest China and Taiwan are abundant in the diversity of gymnosperms (Pandey et al, 2020a). These regions are characterized by the presence of the mountain with an elevation range of more than 4,000 m. On the other hand, extreme and harsh climatic conditions in the North, Tibetan plateau, and Inner-Mongolian regions might be the limiting factor for the distribution of gymnosperms (Pandey et al, 2020a). Therefore, the ecoregions of China are suitable for the study on the EDG of gymnosperm species.…”

Section: Introductionmentioning

confidence: 99%

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Contrasting Gymnosperm Diversity Across an Elevation Gradient in the Ecoregion of China: The Role of Temperature and Productivity

et al. 2021

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The species richness–climate relationship is a significant concept in determining the richness patterns and predicting the cause of its distribution. The distribution range of species and climatic variables along elevation have been used in evaluating the elevational diversity gradients (EDG). However, the species richness of gymnosperms along elevation and its driving factors in large geographic areas are still unknown. Here, we aimed at evaluating the EDG of gymnosperms in the ecoregions of China. We divided the geographical region of China into 34 ecoregions and determine the richness pattern of gymnosperm taxa along elevation gradients. We demonstrated the richness patterns of the 237-gymnosperm (219 threatened, 112 endemic, 189 trees, and 48 shrubs) taxa, roughly distributed between 0 and 5,300 m (above sea level) in China. As possible determinants of richness patterns, annual mean temperature (TEMP), annual precipitation (PPT), potential evapotranspiration (PET), net primary productivity (SNPP), aridity index (AI), temperature seasonality (TS), and precipitation seasonality (PS) are the major predictor variables driving the EDG in plants. We used the species interpolation method to determine the species richness at each elevation band. To evaluate the richness pattern of gymnosperms in an ecoregion, generalized additive modeling and structural equation modeling were performed. The ecoregions in the southern part of China are rich in gymnosperm species, where three distinct richness patterns—(i) hump-shaped, (ii) monotonic increase, and (iii) monotonic decline—were noticed in China. All climatic variables have a significant effect on the richness pattern of gymnosperms; however, TEMP, SNPP, TS, and PS explained the highest deviance in diversity-rich ecoregions of China. Our results suggests that the highest number of gymnosperms species was found in the southwestern and Taiwan regions of China distributed at the 1,600- and 2,800-m elevation bands. These regions could be under severe stress in the near future due to expected changes in precipitation pattern and increase of temperature due to climate change. Thus, our study provided evidence of the species–climate relationship that can support the understanding of future conservation planning of gymnosperms.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Contrasting Gymnosperm Diversity Across an Elevation Gradient in the Ecoregion of China: The Role of Temperature and Productivity

et al. 2021

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Distribution patterns and drivers of nonendemic and endemic glires species in China

Meng

Zhou

2023

Ecology and Evolution

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Spatial patterns and determinants of species richness in complex geographical regions are important subjects of current biogeography and biodiversity conservation research. Glires are small herbivorous mammal species with limited migratory ability that may serve as an indicator of biodiversity and ecosystems. Herein, we aimed to evaluate how multiple ecological hypotheses could explain the species richness patterns of glires in China. Initially, we constructed a mapping grid cell operating units of 80 × 80 km 2 which covered China's land mass and mapped the distribution ranges of the 237 glires species that had recorded. The glires taxa were separated into three response variables based on their distribution: (a) all species, (b) nonendemic species, and (c) endemic species. The species richness patterns of the response variables were evaluated using four predictor sets: (a) hydrothermal characteristics, (b) climatic seasonality, (c) habitat heterogeneity, and (d) human factors. We performed regression tree analysis, multiple linear regression analysis, and variation partitioning analyses to determine the effects of predictors on spatial species patterns. The results showed that the distribution pattern of species richness was the highest in the Hengduan Mountains and surrounding areas in southwest China. However, only a few endemic species adapted to high‐latitude environments. It was found that there are differences about the determinants between nonendemic and endemic species. Habitat heterogeneity was the most influential determinant for the distribution patterns of nonendemic species richness. Climatic seasonality was the best predictor to determine the richness distribution pattern of endemic species, whereas this was least affected by human factors. Furthermore, it should be noted that hydrothermal characteristics were not strong predictors of richness patterns for all or nonendemic species, which may be due to the fact that there are also more species in some areas with less precipitation or energy. Therefore, glires are likely to persist in areas with characteristics of high habitat heterogeneity and stable climate.

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Gymnosperms of Nepal: Diversity, Distribution, Economic Importance, and Future Perspectives

Pandey,

Timilsina

2024

Flora and Vegetation of Nepal

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Energy–water and seasonal variations in climate underlie the spatial distribution patterns of gymnosperm species richness in China

Cited by 19 publications

References 88 publications

Contrasting Gymnosperm Diversity Across an Elevation Gradient in the Ecoregion of China: The Role of Temperature and Productivity

Contrasting Gymnosperm Diversity Across an Elevation Gradient in the Ecoregion of China: The Role of Temperature and Productivity

Distribution patterns and drivers of nonendemic and endemic glires species in China

Gymnosperms of Nepal: Diversity, Distribution, Economic Importance, and Future Perspectives

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