Saved in:
| Main Authors: | , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , |
|---|---|
| Format: | Artículo científico |
| Language: | en |
| Published: |
Nature communications
2025
|
| Subjects: | |
| Online Access: | https://pubmed.ncbi.nlm.nih.gov/41413313/ |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| _version_ | 1868266111361875969 |
|---|---|
| author | Brienen, Roel J W Locosselli, Giuliano Maselli Krottenthaler, Stefan Gloor, Emanuel Wrigley, Robyn Voelker, Steven L Altman, Jan Altmanova, Nela Anderegg, Leander D L Baliva, Michele Barua, Deepak Bazant, Vaclav Black, Bryan M Brown, Peter Ceccantini, Gregorio DeRose, R Justin Villanueva Diaz, Jose Di Filippo, Alfredo Dolezal, Jiri Duchesne, Louis Earle, Christopher Fibich, Pavel Griesbauer, Hardy Helama, Samuli Klesse, Stefan Korznikov, Kirill Lindenmayer, David Liu, Shuhui Lopez, Lidio Mencuccini, Maurizio Nagel, Thomas A Pavlin, Jakob Pederson, Neil Piovesan, Gianluca Restaino, Christina Reich, Peter B Sauchyn, David Schöngart, Jochen Shaw, John D Smith, Dan Sunny, Ron Svoboda, Miroslav Villalba, Ricardo Wood, Lisa J Zhang, Chunyu |
| author_facet | Brienen, Roel J W Locosselli, Giuliano Maselli Krottenthaler, Stefan Gloor, Emanuel Wrigley, Robyn Voelker, Steven L Altman, Jan Altmanova, Nela Anderegg, Leander D L Baliva, Michele Barua, Deepak Bazant, Vaclav Black, Bryan M Brown, Peter Ceccantini, Gregorio DeRose, R Justin Villanueva Diaz, Jose Di Filippo, Alfredo Dolezal, Jiri Duchesne, Louis Earle, Christopher Fibich, Pavel Griesbauer, Hardy Helama, Samuli Klesse, Stefan Korznikov, Kirill Lindenmayer, David Liu, Shuhui Lopez, Lidio Mencuccini, Maurizio Nagel, Thomas A Pavlin, Jakob Pederson, Neil Piovesan, Gianluca Restaino, Christina Reich, Peter B Sauchyn, David Schöngart, Jochen Shaw, John D Smith, Dan Sunny, Ron Svoboda, Miroslav Villalba, Ricardo Wood, Lisa J Zhang, Chunyu Brienen, Roel J W Locosselli, Giuliano Maselli Krottenthaler, Stefan Gloor, Emanuel Wrigley, Robyn Voelker, Steven L Altman, Jan Altmanova, Nela Anderegg, Leander D L Baliva, Michele Barua, Deepak Bazant, Vaclav Black, Bryan M Brown, Peter Ceccantini, Gregorio DeRose, R Justin Villanueva Diaz, Jose Di Filippo, Alfredo Dolezal, Jiri Duchesne, Louis Earle, Christopher Fibich, Pavel Griesbauer, Hardy Helama, Samuli Klesse, Stefan Korznikov, Kirill Lindenmayer, David Liu, Shuhui Lopez, Lidio Mencuccini, Maurizio Nagel, Thomas A Pavlin, Jakob Pederson, Neil Piovesan, Gianluca Restaino, Christina Reich, Peter B Sauchyn, David Schöngart, Jochen Shaw, John D Smith, Dan Sunny, Ron Svoboda, Miroslav Villalba, Ricardo Wood, Lisa J Zhang, Chunyu |
| collection | PubMed - marine biology |
| contents | Contrasting pathways to tree longevity in gymnosperms and angiosperms. Brienen, Roel J W Locosselli, Giuliano Maselli Krottenthaler, Stefan Gloor, Emanuel Wrigley, Robyn Voelker, Steven L Altman, Jan Altmanova, Nela Anderegg, Leander D L Baliva, Michele Barua, Deepak Bazant, Vaclav Black, Bryan M Brown, Peter Ceccantini, Gregorio DeRose, R Justin Villanueva Diaz, Jose Di Filippo, Alfredo Dolezal, Jiri Duchesne, Louis Earle, Christopher Fibich, Pavel Griesbauer, Hardy Helama, Samuli Klesse, Stefan Korznikov, Kirill Lindenmayer, David Liu, Shuhui Lopez, Lidio Mencuccini, Maurizio Nagel, Thomas A Pavlin, Jakob Pederson, Neil Piovesan, Gianluca Restaino, Christina Reich, Peter B Sauchyn, David Schöngart, Jochen Shaw, John D Smith, Dan Sunny, Ron Svoboda, Miroslav Villalba, Ricardo Wood, Lisa J Zhang, Chunyu Cycadopsida Magnoliopsida Trees Longevity Climate Soil Water Tree longevity is thought to increase in growth-limiting, adverse environments, but a quantitative assessment of drivers of global variation in tree longevity is lacking. We assemble a global database of maximum longevity for 739 tree species and analyse associations between longevity and climate, soil, and species' functional traits. Our results show two primary pathways towards long lifespans. The first is slow growth in resource-limited environments, consistent with the "adversity begets longevity" paradigm. The second pathway is through relief from abiotic constraints in productive environments. Despite notable exceptions, long-lived gymnosperms tend to follow the first path through slow growth in cold environments, whereas long-lived angiosperms tend to follow the second ("productivity") path reaching maximum longevity generally in humid environments. For angiosperms, we identify two mechanisms for increased longevity under humid conditions. First, higher water availability increases species' maximum tree height which is associated with greater longevities. Secondly, greater water availability increases stand density and inter-tree competition, limiting growth which may increase tree lifespan. The documented differences between gymnosperm and angiosperm longevity are likely rooted in intrinsic differences in hydraulic architecture that provide fitness advantages for gymnosperms under high abiotic stress, and for angiosperms under increased productivity or competition. |
| format | Artículo científico |
| id | pubmed_41413313 |
| institution | PubMed |
| language | en |
| publishDate | 2025 |
| publisher | Nature communications |
| record_format | pubmed |
| spellingShingle | Contrasting pathways to tree longevity in gymnosperms and angiosperms. Brienen, Roel J W Locosselli, Giuliano Maselli Krottenthaler, Stefan Gloor, Emanuel Wrigley, Robyn Voelker, Steven L Altman, Jan Altmanova, Nela Anderegg, Leander D L Baliva, Michele Barua, Deepak Bazant, Vaclav Black, Bryan M Brown, Peter Ceccantini, Gregorio DeRose, R Justin Villanueva Diaz, Jose Di Filippo, Alfredo Dolezal, Jiri Duchesne, Louis Earle, Christopher Fibich, Pavel Griesbauer, Hardy Helama, Samuli Klesse, Stefan Korznikov, Kirill Lindenmayer, David Liu, Shuhui Lopez, Lidio Mencuccini, Maurizio Nagel, Thomas A Pavlin, Jakob Pederson, Neil Piovesan, Gianluca Restaino, Christina Reich, Peter B Sauchyn, David Schöngart, Jochen Shaw, John D Smith, Dan Sunny, Ron Svoboda, Miroslav Villalba, Ricardo Wood, Lisa J Zhang, Chunyu Cycadopsida Magnoliopsida Trees Longevity Climate Soil Water Contrasting pathways to tree longevity in gymnosperms and angiosperms. Brienen, Roel J W Locosselli, Giuliano Maselli Krottenthaler, Stefan Gloor, Emanuel Wrigley, Robyn Voelker, Steven L Altman, Jan Altmanova, Nela Anderegg, Leander D L Baliva, Michele Barua, Deepak Bazant, Vaclav Black, Bryan M Brown, Peter Ceccantini, Gregorio DeRose, R Justin Villanueva Diaz, Jose Di Filippo, Alfredo Dolezal, Jiri Duchesne, Louis Earle, Christopher Fibich, Pavel Griesbauer, Hardy Helama, Samuli Klesse, Stefan Korznikov, Kirill Lindenmayer, David Liu, Shuhui Lopez, Lidio Mencuccini, Maurizio Nagel, Thomas A Pavlin, Jakob Pederson, Neil Piovesan, Gianluca Restaino, Christina Reich, Peter B Sauchyn, David Schöngart, Jochen Shaw, John D Smith, Dan Sunny, Ron Svoboda, Miroslav Villalba, Ricardo Wood, Lisa J Zhang, Chunyu Cycadopsida Magnoliopsida Trees Longevity Climate Soil Water Tree longevity is thought to increase in growth-limiting, adverse environments, but a quantitative assessment of drivers of global variation in tree longevity is lacking. We assemble a global database of maximum longevity for 739 tree species and analyse associations between longevity and climate, soil, and species' functional traits. Our results show two primary pathways towards long lifespans. The first is slow growth in resource-limited environments, consistent with the "adversity begets longevity" paradigm. The second pathway is through relief from abiotic constraints in productive environments. Despite notable exceptions, long-lived gymnosperms tend to follow the first path through slow growth in cold environments, whereas long-lived angiosperms tend to follow the second ("productivity") path reaching maximum longevity generally in humid environments. For angiosperms, we identify two mechanisms for increased longevity under humid conditions. First, higher water availability increases species' maximum tree height which is associated with greater longevities. Secondly, greater water availability increases stand density and inter-tree competition, limiting growth which may increase tree lifespan. The documented differences between gymnosperm and angiosperm longevity are likely rooted in intrinsic differences in hydraulic architecture that provide fitness advantages for gymnosperms under high abiotic stress, and for angiosperms under increased productivity or competition. |
| title | Contrasting pathways to tree longevity in gymnosperms and angiosperms. |
| topic | Cycadopsida Magnoliopsida Trees Longevity Climate Soil Water |
| url | https://pubmed.ncbi.nlm.nih.gov/41413313/ |