Your search keyword '"Yueyao Feng"' showing total 2 results

1. Inter- and intra-specific phenotypic variation of ecological stoichiometric traits in a mixed-oak secondary forest in China

Author

Huanchao Zhang, Biyao Zhou, Jiading Yang, Yanming Fang, Yueyao Feng, Rong Hu, and Xuan Li

Subjects

0106 biological sciences, Ecology, Phosphorus, education, Diameter at breast height, chemistry.chemical_element, Forestry, 04 agricultural and veterinary sciences, Biology, 01 natural sciences, Nutrient, chemistry, Ecological stoichiometry, 040103 agronomy & agriculture, 0401 agriculture, forestry, and fisheries, Secondary forest, Ecosystem, Adaptation, Carbon, 010606 plant biology & botany

Abstract

Ecological stoichiometry provides a framework for the balance and flow of elements between organisms and ecosystems. Elemental phenotypes have an important influence on the environmental adaptation and ecological evolution of plants. There have been few reports on inter- and intra-specific phenotypic variations of ecological stoichiometric traits for congeneric species in a mixed forest although such variations are well- documented at the species level at global, regional and local scales. In this study, total carbon (TC), nitrogen (TN), phosphorus (TP) and potassium (TK) were measured in leaves and the elemental phenotypes were statistically analyzed in four species of oaks—Quercus fabri, Q. serrata var. glandulifera, Q. acutissima and Q. variabilis—in a mixed-oak secondary forest in Yushan, Jiangsu, China. The average element concentrations in the four oak species were not relatively higher than previously reported for oaks from world and Chinese flora. Ecological stoichiometry traits were correlated with tree height and diameter at breast height, indicating that phosphorous and potassium were positively correlated with tree size, while carbon was negatively correlated, especially the relationship between oak growth and total carbon or total phosphorus was obvious, and the study concluded that this was because plant growth depended on phosphorus storage and had opposite effects on leaf carbon accumulation. Based on tree plasticity index and the coefficient of variation, there was medium variation in element concentrations. The plasticity index of total carbon levels was the lowest, and that of potassium the highest. Principal component analysis and cluster analysis showed that the intra-specific variation among the four oak species was higher than inter-specific variation. From the perspective of nutrient supply and ecological adaptation, this study creates a foundation for the management of secondary oak forest stands.

Published

2021

2. A Meta-Analysis Indicates Positive Correlation between Genetic Diversity and Species Diversity

Author

Ningjie Wang, Yueyao Feng, Lei Xie, Hui Ding, Yuan Yang, Lu Wang, Ting Lv, Shuifei Chen, Yanming Fang, and Yao Li

Subjects

Genetic diversity, General Immunology and Microbiology, community genetic, SGDC, QH301-705.5, Biodiversity, community dissimilarity, Species diversity, Sampling (statistics), Biology, Article, General Biochemistry, Genetics and Molecular Biology, Correlation, meta-analysis, Statistics, Ecosystem, genetic differentiation, Biology (General), General Agricultural and Biological Sciences, human activities, Diversity (business), Global biodiversity, biodiversity

Abstract

Simple Summary Understanding species and genetic correlations (SGDCs) is essential to establish community composition. In this study, 295 observations from 39 studies explored the SGDCs and the underlying drivers through conducting a global meta-analysis. A positive correlation was found, suggesting that parallel processes (environmental heterogeneity, area, and connectivity etc.) have effects on two diversities. As current biodiversity hotspots have mainly been identified based on high species diversity and high endemism of taxon, the understanding of SGDC will substantially help us to determine whether and how genetic diversity can be used in identifying biodiversity hotspots, as well as in developing conservation practices and policies for biodiversity. Abstract Species diversity (SD) and genetic diversity (GD) are the two basic levels of biodiversity. In general, according to the consensus view, the parallel effects of environmental heterogeneity, area, and connectivity on two levels, can drive a positive correlation between GD and SD. Conversely, a negative correlation or no correlation would be expected if these effects are not parallel. Our understanding of the relationships between SD and GD among different ecosystems, sampling methods, species, and under climate change remains incomplete. In the present study, we conducted a hierarchical meta-analysis based on 295 observations from 39 studies and found a positive correlation between genetic diversity and species diversity (95% confidence interval, 7.6–22.64%). However, significant relationships were not found in some ecosystems when we conducted species–genetic diversity correlation analysis based on a single ecosystem. Moreover, the magnitudes of the correlations generally decreased with the number of sampling units and the annual average the temperature of sampling units. Our results highlight the positive correlation between GD and SD, thereby indicating that protecting SD involves protecting GD in conservation practice. Furthermore, our results also suggest that global increases in temperature during the 21st century will have significant impacts on global biodiversity.

Published

2021