Biotic colonization of subtropical East Asian caves through time

Caves are home to unique and fragile biotas with high levels of endemism. However, little is known about how the biotic colonization of caves has developed over time, especially in caves from middle and low latitudes. Subtropical East Asia holds the world’s largest karst landform with numerous ancie...

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Published inProceedings of the National Academy of Sciences - PNAS Vol. 119; no. 34; pp. 1 - 6
Main Authors Li, Xiao-Qian, Xiang, Xiao-Guo, Jabbour, Florian, Hagen, Oskar, del C. Ortiz, Rosa, Soltis, Pamela S., Soltis, Douglas E., Wang, Wei
Format Journal Article
LanguageEnglish
Published United States National Academy of Sciences 23.08.2022
Subjects
Animals
Asia, Eastern
Biodiversity
Biodiversity and Ecology
Biodiversity hot spots
Biological Sciences
Biota
Caves
Climate change
Colonization
Endemism
Environmental Sciences
Evolution
Forests
Karst
Landforms
Latitude
Miocene
Neogene
Oligocene
Phylogeny
Underground caverns
Vegetation
Asia, Eastern
East Asian monsoon
troglobites
multiple taxa
Miocene
climate change
Climate change
Multiple taxa
Troglobites
Online AccessGet full text
ISSN0027-8424
1091-6490
1091-6490
DOI10.1073/pnas.2207199119

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Abstract Caves are home to unique and fragile biotas with high levels of endemism. However, little is known about how the biotic colonization of caves has developed over time, especially in caves from middle and low latitudes. Subtropical East Asia holds the world’s largest karst landform with numerous ancient caves, which harbor a high diversity of cave-dwelling organisms and are regarded as a biodiversity hotspot. Here, we assess the temporal dynamics of biotic colonization of subtropical East Asian caves through a multi-taxon analysis with representatives of green plants, animals, and fungi. We then investigate the consequences of paleonviromental changes on the colonization dynamics of these caves in combination with reconstructions of vegetation, temperature, and precipitation. We discover that 88% of cave colonization events occurred after the Oligocene-Miocene boundary, and organisms from the surrounding forest were a major source for subtropical East Asian cave biodiversity. Biotic colonization of subtropical East Asian caves during the Neogene was subject to periods of acceleration and decrease, in conjunction with large-scale, seasonal climatic changes and evolution of local forests. This study highlights the long-term evolutionary interaction between surface and cave biotas; our climate-vegetation-relict model proposed for the subtropical East Asian cave biota may help explain the evolutionary origins of other mid-latitude subterranean biotas.
AbstractList Caves are home to unique and fragile biotas with high levels of endemism. However, little is known about how the biotic colonization of caves has developed over time, especially in caves from middle and low latitudes. Subtropical East Asia holds the world's largest karst landform with numerous ancient caves, which harbor a high diversity of cave-dwelling organisms and are regarded as a biodiversity hotspot. Here, we assess the temporal dynamics of biotic colonization of subtropical East Asian caves through a multi-taxon analysis with representatives of green plants, animals, and fungi. We then investigate the consequences of paleonviromental changes on the colonization dynamics of these caves in combination with reconstructions of vegetation, temperature, and precipitation. We discover that 88% of cave colonization events occurred after the Oligocene-Miocene boundary, and organisms from the surrounding forest were a major source for subtropical East Asian cave biodiversity. Biotic colonization of subtropical East Asian caves during the Neogene was subject to periods of acceleration and decrease, in conjunction with large-scale, seasonal climatic changes and evolution of local forests. This study highlights the long-term evolutionary interaction between surface and cave biotas; our climate-vegetation-relict model proposed for the subtropical East Asian cave biota may help explain the evolutionary origins of other mid-latitude subterranean biotas.Caves are home to unique and fragile biotas with high levels of endemism. However, little is known about how the biotic colonization of caves has developed over time, especially in caves from middle and low latitudes. Subtropical East Asia holds the world's largest karst landform with numerous ancient caves, which harbor a high diversity of cave-dwelling organisms and are regarded as a biodiversity hotspot. Here, we assess the temporal dynamics of biotic colonization of subtropical East Asian caves through a multi-taxon analysis with representatives of green plants, animals, and fungi. We then investigate the consequences of paleonviromental changes on the colonization dynamics of these caves in combination with reconstructions of vegetation, temperature, and precipitation. We discover that 88% of cave colonization events occurred after the Oligocene-Miocene boundary, and organisms from the surrounding forest were a major source for subtropical East Asian cave biodiversity. Biotic colonization of subtropical East Asian caves during the Neogene was subject to periods of acceleration and decrease, in conjunction with large-scale, seasonal climatic changes and evolution of local forests. This study highlights the long-term evolutionary interaction between surface and cave biotas; our climate-vegetation-relict model proposed for the subtropical East Asian cave biota may help explain the evolutionary origins of other mid-latitude subterranean biotas.
Subtropical East Asian caves are characterized by high levels of biodiversity and endemism but most do not fall within protected areas. Here, we investigate the timing and mode of cave colonization through a multi-taxon meta-analysis combined with investigation of paleoenvironmental dynamics. We show that most cave colonization events occurred after the Oligocene-Miocene boundary. Importantly, we document that biotic colonization of subtropical East Asian caves was not a random process, but was subject to periods of acceleration and decrease, in association with the climate and vegetational changes and the establishment of seasonal climate in subtropical East Asia. Our results provide insights into how subterranean biodiversity in subtropical East Asia has been shaped over time and also have implications for biodiversity conservation. Caves are home to unique and fragile biotas with high levels of endemism. However, little is known about how the biotic colonization of caves has developed over time, especially in caves from middle and low latitudes. Subtropical East Asia holds the world's largest karst landform with numerous ancient caves, which harbor a high diversity of cave-dwelling organisms and are regarded as a biodiversity hotspot. Here, we assess the temporal dynamics of biotic colonization of subtropical East Asian caves through a multi-taxon analysis with representatives of green plants, animals, and fungi. We then investigate the consequences of paleonviromental changes on the colonization dynamics of these caves in combination with reconstructions of vegetation, temperature, and precipitation. We discover that 88% of cave colonization events occurred after the Oligocene-Miocene boundary, and organisms from the surrounding forest were a major source for subtropical East Asian cave biodiversity. Biotic colonization of subtropical East Asian caves during the Neogene was subject to periods of acceleration and decrease, in conjunction with large-scale, seasonal climatic changes and evolution of local forests. This study highlights the long-term evolutionary interaction between surface and cave biotas; our climate-vegetation-relict model proposed for the subtropical East Asian cave biota may help explain the evolutionary origins of other mid-latitude subterranean biotas.
Caves are home to unique and fragile biotas with high levels of endemism. However, little is known about how the biotic colonization of caves has developed over time, especially in caves from middle and low latitudes. Subtropical East Asia holds the world’s largest karst landform with numerous ancient caves, which harbor a high diversity of cave-dwelling organisms and are regarded as a biodiversity hotspot. Here, we assess the temporal dynamics of biotic colonization of subtropical East Asian caves through a multi-taxon analysis with representatives of green plants, animals, and fungi. We then investigate the consequences of paleonviromental changes on the colonization dynamics of these caves in combination with reconstructions of vegetation, temperature, and precipitation. We discover that 88% of cave colonization events occurred after the Oligocene-Miocene boundary, and organisms from the surrounding forest were a major source for subtropical East Asian cave biodiversity. Biotic colonization of subtropical East Asian caves during the Neogene was subject to periods of acceleration and decrease, in conjunction with large-scale, seasonal climatic changes and evolution of local forests. This study highlights the long-term evolutionary interaction between surface and cave biotas; our climate-vegetation-relict model proposed for the subtropical East Asian cave biota may help explain the evolutionary origins of other mid-latitude subterranean biotas.
Caves are home to unique and fragile biotas with high levels of endemism. However, little is known about how the biotic colonization of caves has developed over time, espe- cially in caves from middle and low latitudes. Subtropical East Asia holds the world’s largest karst landform with numerous ancient caves, which harbor a high diversity of cave-dwelling organisms and are regarded as a biodiversity hotspot. Here, we assess the temporal dynamics of biotic colonization of subtropical East Asian caves through a multi-taxon analysis with representatives of green plants, animals, and fungi. We then investigate the consequences of paleonviromental changes on the colonization dynamics of these caves in combination with reconstructions of vegetation, temperature, and precipitation. We discover that 88% of cave colonization events occurred after the Oligocene-Miocene boundary, and organisms from the surrounding forest were a major source for subtropical East Asian cave biodiversity. Biotic colonization of subtropical East Asian caves during the Neogene was subject to periods of acceleration and decrease, in conjunction with large-scale, seasonal climatic changes and evolution of local forests. This study highlights the long-term evolutionary interaction between surface and cave biotas; our climate-vegetation-relict model proposed for the subtropical East Asian cave biota may help explain the evolutionary origins of other mid-latitude subterranean biotas.
Author del C. Ortiz, Rosa
Jabbour, Florian
Wang, Wei
Hagen, Oskar
Soltis, Pamela S.
Soltis, Douglas E.
Li, Xiao-Qian
Xiang, Xiao-Guo
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Issue 34
Keywords East Asian monsoon
troglobites
multiple taxa
Miocene
climate change
Climate change
Multiple taxa
Troglobites
Language English
License Distributed under a Creative Commons Attribution 4.0 International License: http://creativecommons.org/licenses/by/4.0
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Edited by Zhonghe Zhou, Chinese Academy of Sciences, Beijing, China; received April 27, 2022; accepted July 12, 2022
Author contributions: W.W. designed research; X.-Q.L., X.-G.X., F.J., O.H., R.C.O., P.S.S., D.E.S., and W.W. performed research; X.-Q.L., X.-G.X., O.H., and W.W. analyzed data; and X.-Q.L., F.J., R.C.O., P.S.S., D.E.S., and W.W. wrote the paper.
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Snippet Caves are home to unique and fragile biotas with high levels of endemism. However, little is known about how the biotic colonization of caves has developed...
Subtropical East Asian caves are characterized by high levels of biodiversity and endemism but most do not fall within protected areas. Here, we investigate...
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SubjectTerms Animals
Asia, Eastern
Biodiversity
Biodiversity and Ecology
Biodiversity hot spots
Biological Sciences
Biota
Caves
Climate change
Colonization
Endemism
Environmental Sciences
Evolution
Forests
Karst
Landforms
Latitude
Miocene
Neogene
Oligocene
Phylogeny
Underground caverns
Vegetation
Title Biotic colonization of subtropical East Asian caves through time
URI https://www.jstor.org/stable/27171547
https://www.ncbi.nlm.nih.gov/pubmed/35969742
https://www.proquest.com/docview/2708391822
https://www.proquest.com/docview/2702976647
https://hal.science/hal-03751940
https://pubmed.ncbi.nlm.nih.gov/PMC9407641
Volume 119
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