Data

Xylomelum occidentale (Proteaceae) accesses relatively mobile soil organic phosphorus without releasing carboxylates

The University of Western Australia
Zhong, Hongtao ; Zhou, Jun ; Azmi, Azrul ; Arruda, André ; Doolette, Ashlea ; Smernik, Ronald ; Lambers, Hans ; Wan Azmi, Azrul ; Jardim Arruda, Andre ; Doolette, Ashlea L ; Smernik, Ronald J
Viewed: [[ro.stat.viewed]] Cited: [[ro.stat.cited]] Accessed: [[ro.stat.accessed]]
ctx_ver=Z39.88-2004&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Adc&rfr_id=info%3Asid%2FANDS&rft_id=info:doi10.5061/dryad.05qfttdz7&rft.title=Xylomelum occidentale (Proteaceae) accesses relatively mobile soil organic phosphorus without releasing carboxylates&rft.identifier=10.5061/dryad.05qfttdz7&rft.publisher=DRYAD&rft.description=1. Hundreds of Proteaceae species in Australia and South Africa typically grow on phosphorus (P)-impoverished soils, exhibiting a carboxylate-releasing P-mobilising strategy. In the Southwest Australian Biodiversity Hotspot, two Xylomelum (Proteaceae) species are widely distributed, but restricted within that distribution. 2. We grew X. occidentale in hydroponics at 1 μM P. Leaves, seeds, rhizosheath and bulk soil were collected in natural habitats. 3. Xylomelum occidentale did not produce functional cluster roots and occupied soils that are somewhat less P-impoverished than those in typical Proteaceae habitats in the region. Based on measurements of foliar manganese concentrations (a proxy for rhizosphere carboxylate concentrations) and P fractions in bulk and rhizosheath soil, we conclude that X. occidentale accesses organic P, without releasing carboxylates. Solution 31P-NMR revealed which organic P forms X. occidentale accessed. 4. Xylomelum occidentale uses a strategy that differs fundamentally from that typical in Proteaceae, accessing soil organic P without carboxylates. We surmise that this novel strategy is likely expressed also in co-occurring non-Proteaceae that lack a carboxylate-exuding strategy, and plants in similar habitats. These co-occurring species are unlikely to benefit from mycorrhizal associations, because plant-available soil P concentrations are too low. 5. Synthesis. Our findings show the first field evidence of effectively utilising soil organic P by X. occidentale without carboxylate exudation and explain their relatively restricted distribution in an old P-impoverished landscape, contributing to a better understanding of how diverse P-acquisition strategies coexist in a megadiverse ecosystem.&rft.creator=Zhong, Hongtao &rft.creator=Zhou, Jun &rft.creator=Azmi, Azrul &rft.creator=Arruda, André &rft.creator=Doolette, Ashlea &rft.creator=Smernik, Ronald &rft.creator=Lambers, Hans &rft.creator=Wan Azmi, Azrul &rft.creator=Jardim Arruda, Andre &rft.creator=Doolette, Ashlea L &rft.creator=Smernik, Ronald J &rft.date=2020&rft.relation=http://research-repository.uwa.edu.au/en/publications/a71600b9-8bf3-4b46-87fc-56d1b7d46adf&rft.relation=http://research-repository.uwa.edu.au/en/publications/a71600b9-8bf3-4b46-87fc-56d1b7d46adf&rft_subject=carboxylates&rft_subject=solution <sup>31</sup>P-NMR&rft_subject=<i>Xylomelum</i>&rft_subject=soil organic P&rft_subject=manganese&rft_subject=phosphatases&rft_subject=Proteaceae&rft_subject=ecophysiology&rft.type=dataset&rft.language=English Access the data
Cite Saved to MyRDA Save to MyRDA

Access:

Open

Full description

1. Hundreds of Proteaceae species in Australia and South Africa typically grow on phosphorus (P)-impoverished soils, exhibiting a carboxylate-releasing P-mobilising strategy. In the Southwest Australian Biodiversity Hotspot, two Xylomelum (Proteaceae) species are widely distributed, but restricted within that distribution. 2. We grew X. occidentale in hydroponics at 1 μM P. Leaves, seeds, rhizosheath and bulk soil were collected in natural habitats. 3. Xylomelum occidentale did not produce functional cluster roots and occupied soils that are somewhat less P-impoverished than those in typical Proteaceae habitats in the region. Based on measurements of foliar manganese concentrations (a proxy for rhizosphere carboxylate concentrations) and P fractions in bulk and rhizosheath soil, we conclude that X. occidentale accesses organic P, without releasing carboxylates. Solution 31P-NMR revealed which organic P forms X. occidentale accessed. 4. Xylomelum occidentale uses a strategy that differs fundamentally from that typical in Proteaceae, accessing soil organic P without carboxylates. We surmise that this novel strategy is likely expressed also in co-occurring non-Proteaceae that lack a carboxylate-exuding strategy, and plants in similar habitats. These co-occurring species are unlikely to benefit from mycorrhizal associations, because plant-available soil P concentrations are too low. 5. Synthesis. Our findings show the first field evidence of effectively utilising soil organic P by X. occidentale without carboxylate exudation and explain their relatively restricted distribution in an old P-impoverished landscape, contributing to a better understanding of how diverse P-acquisition strategies coexist in a megadiverse ecosystem.

Notes

External Organisations
Chinese Academy of Sciences; University of Adelaide; The University of Western Australia
Associated Persons
Jun Zhou (Contributor); Azrul Wan Azmi (Contributor); Andre Jardim Arruda (Creator)Azrul Azmi (Creator); André Arruda (Creator); Ashlea Doolette (Creator); Ronald Smernik (Creator); Ashlea L Doolette (Creator); Ronald J Smernik (Creator)

Issued: 2020-07-24

This dataset is part of a larger collection

Click to explore relationships graph
Help

Related Publications

Related Data

Related Organisations

Related People

Related Grants and Projects

Related Websites

Subjects
Xylomelum | Proteaceae | carboxylates | ecophysiology | manganese | phosphatases | soil organic P | solution 31P-NMR |

User Contributed Tags    

Login to tag this record with meaningful keywords to make it easier to discover

Identifiers
Similar data you may be interested in: