The rich club,as a community of highly interconnected nodes,serves as the topological center of the network.However,the similarities and differences in how the rich club supports functional integration and segregation...The rich club,as a community of highly interconnected nodes,serves as the topological center of the network.However,the similarities and differences in how the rich club supports functional integration and segregation in the brain across different species remain unknown.In this study,we first detected and validated the rich club in the structural networks of mouse,monkey,and human brains using neuronal tracing or diffusion magnetic resonance imaging data.Further,we assessed the role of rich clubs in functional integration,segregation,and balance using quantitative metrics.Our results indicate that the presence of a rich club facilitates whole-brain functional integration in all three species,with the functional networks of higher species exhibiting greater integration.These findings are expected to help to understand the relationship between brain structure and function from the perspective of brain evolution.展开更多
Background:A number of hypotheses and theories,such as the Janzen-Connell hypothesis,have been proposed to explain the natural maintenance of biodiversity in tropical and temperate forest ecosystems.However,to date th...Background:A number of hypotheses and theories,such as the Janzen-Connell hypothesis,have been proposed to explain the natural maintenance of biodiversity in tropical and temperate forest ecosystems.However,to date the details of the processes behind this natural maintenance are still unclear.Recently two new nearest-neighbour characteristics were proposed and in this paper we demonstrate how they can contribute to a better understanding of the ontogenesis of global forest structure from localised neighbourhoods.Methods:We applied the new species and size segregation functions together with appropriate test procedures to four example woodland data sets from China at Daqingshan,Jiaohe,Jiulongshan and Xiaolongshan forest regions.In addition we quantified the morphology of the new characteristics and modelled a neighbourhood allometric coefficient linking the two functions.Results:The results revealed quite different species segregation patterns with both conspecific and heterospecific attraction.We found these to be generally matched by equivalent size segregation patterns of attraction of similar and different sizes.It was straightforward to model the size segregation function from the knowledge of the species segregation function by estimating a neighbourhood allometric coefficient.Conclusions:The new characteristics have helped to quantify the extent and rate of decline of neighbourhood interactions in terms of spatial species and size diversity.Through the allometric neighbourhood coefficient the analysis highlighted once more how closely related species and size segregation are,thus supporting the minglingsize hypothesis.Using both a traditional and a restricted random-labelling test has provided a valuable tool for understanding the exact nature of species-mingling and size-inequality relationships.展开更多
基金supported by STI2030-Major Projects(2021ZD0200200)the National Natural Science Foundation of China(62327805 and 82151307)+1 种基金the Equipment Development Project of the Chinese Academy of Sciences(YJKYYQ20190040)the Science and Technology Innovation Program of Hunan Province(2024RC4028).
文摘The rich club,as a community of highly interconnected nodes,serves as the topological center of the network.However,the similarities and differences in how the rich club supports functional integration and segregation in the brain across different species remain unknown.In this study,we first detected and validated the rich club in the structural networks of mouse,monkey,and human brains using neuronal tracing or diffusion magnetic resonance imaging data.Further,we assessed the role of rich clubs in functional integration,segregation,and balance using quantitative metrics.Our results indicate that the presence of a rich club facilitates whole-brain functional integration in all three species,with the functional networks of higher species exhibiting greater integration.These findings are expected to help to understand the relationship between brain structure and function from the perspective of brain evolution.
基金partly supported by the Guangxi Innovation Driven Development Project(No.AA17204087-8)funded by the National Natural Science Foundation of China(project No.31670640)。
文摘Background:A number of hypotheses and theories,such as the Janzen-Connell hypothesis,have been proposed to explain the natural maintenance of biodiversity in tropical and temperate forest ecosystems.However,to date the details of the processes behind this natural maintenance are still unclear.Recently two new nearest-neighbour characteristics were proposed and in this paper we demonstrate how they can contribute to a better understanding of the ontogenesis of global forest structure from localised neighbourhoods.Methods:We applied the new species and size segregation functions together with appropriate test procedures to four example woodland data sets from China at Daqingshan,Jiaohe,Jiulongshan and Xiaolongshan forest regions.In addition we quantified the morphology of the new characteristics and modelled a neighbourhood allometric coefficient linking the two functions.Results:The results revealed quite different species segregation patterns with both conspecific and heterospecific attraction.We found these to be generally matched by equivalent size segregation patterns of attraction of similar and different sizes.It was straightforward to model the size segregation function from the knowledge of the species segregation function by estimating a neighbourhood allometric coefficient.Conclusions:The new characteristics have helped to quantify the extent and rate of decline of neighbourhood interactions in terms of spatial species and size diversity.Through the allometric neighbourhood coefficient the analysis highlighted once more how closely related species and size segregation are,thus supporting the minglingsize hypothesis.Using both a traditional and a restricted random-labelling test has provided a valuable tool for understanding the exact nature of species-mingling and size-inequality relationships.
