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dc.contributor.authorAtwell, BJ
dc.contributor.authorHenery, ML
dc.contributor.authorRogers, GS
dc.contributor.authorSeneweera, SP
dc.contributor.authorTreadwell, M
dc.contributor.authorConroy, JP
dc.date.available2014-05-21T22:02:33Z
dc.date.issued2007-12-03
dc.identifier.citationAtwell, B. J., Henery, M. L., Rogers, G. S., Seneweera, S. P., Treadwell, M. & Conroy, J. P. (2007). Canopy development and hydraulic function in Eucalyptus tereticornis grown in drought in CO<inf>2</inf>-enriched atmospheres. Functional Plant Biology, 34 (12), pp.1137-1149. https://doi.org/10.1071/FP06338.
dc.identifier.issn1445-4408
dc.identifier.urihttp://hdl.handle.net/11343/28774
dc.descriptionC1 - Journal Articles Refereed
dc.description.abstract<jats:p> We report on the relationship between growth, partitioning of shoot biomass and hydraulic development of Eucalyptus tereticornis Sm. grown in glasshouses for six months. Close coordination of stem vascular capacity and shoot architecture is vital for survival of eucalypts, especially as developing trees are increasingly subjected to spasmodic droughts and rising atmospheric CO2 levels. Trees were exposed to constant soil moisture deficits in 45 L pots (30–50% below field capacity), while atmospheric CO2 was raised to 700 μL CO2 L–1 in matched glasshouses using a hierarchical, multi-factorial design. Enrichment with CO2 stimulated shoot growth rates for 12–15 weeks in well-watered trees but after six months of CO2 enrichment, shoot biomasses were not significantly heavier (30% stimulation) in ambient conditions. By contrast, constant drought arrested shoot growth after 20 weeks under ambient conditions, whereas elevated CO2 sustained growth in drought and ultimately doubled the shoot biomass relative to ambient conditions. These growth responses were achieved through an enhancement of lateral branching up to 8-fold due to CO2 enrichment. In spite of larger transpiring canopies, CO2 enrichment also improved the daytime water status of leaves of droughted trees. Stem xylem development was highly regulated, with vessels per unit area and cross sectional area of xylem vessels in stems correlated inversely across all treatments. Furthermore, vessel numbers related to the numbers of leaves on lateral branches, broadly supporting predictions arising from Pipe Model Theory that the area of conducting tissue should correlate with leaf area. Diminished water use of trees in drought coincided with a population of narrower xylem vessels, constraining hydraulic capacity of stems. Commensurate with the positive effects of elevated CO2 on growth, development and leaf water relations of droughted trees, the capacity for long-distance water transport also increased. </jats:p>
dc.formatapplication/pdf
dc.languageen
dc.publisherCSIRO Publishing
dc.subjectPlant Biology not elsewhere classified; Management of Gaseous Waste from Plant Production (excl. Greenhouse Gases)
dc.titleCanopy development and hydraulic function in Eucalyptus tereticornis grown in drought in CO<inf>2</inf>-enriched atmospheres
dc.typeJournal Article
dc.identifier.doi10.1071/FP06338
melbourne.peerreviewPeer Reviewed
melbourne.affiliationThe University of Melbourne
melbourne.affiliation.departmentAgriculture And Food Systems
melbourne.source.titleFunctional Plant Biology
melbourne.source.volume34
melbourne.source.issue12
melbourne.source.pages1137-1149
dc.research.codefor060799
dc.research.codeseo2008829801
melbourne.publicationid120373
melbourne.elementsid308662
melbourne.contributor.authorSeneweera, Saman
melbourne.accessrightsThis item is currently not available from this repository


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