Does the Prostrate-leaved Geophyte Brunsvigia orientalis Utilize Soil-derived CO2 for Photosynthesis?

doi:10.1093/aob/mcm019

AOBPreview published online on March 8, 2007
Annals of Botany, doi:10.1093/aob/mcm019

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Does the Prostrate-leaved Geophyte Brunsvigia orientalis Utilize Soil-derived CO₂ for Photosynthesis?

M. D. Cramer¹^,2^,*, C. Kleizen¹ and C. Morrow¹

¹ Department of Botany, University of Cape Town, Private Bag X1, Rondebosch 7701, South Africa
² School of Plant Biology, Faculty of Natural and Agricultural Sciences, University of Western Australia, 35 Stirling Highway, WA 6009, Australia

^* For correspondence. E-mail michael.cramer{at}uct.ac.za

Received: 2 October 2006 Returned for revision: 21 November 2006 Accepted: 5 January 2007

Background and Aims: A test was made of the hypothesis that the prostrate growthhabit of the leaves of the geophyte Brunsvigia orientalis enablesutilization of soil-derived CO₂ and is related to the presenceof lysigenous air-filled channels characteristic of B. orientalisleaves.

Methods Brunsvigia orientalis: was sampled at a field site. Leaf anatomy, stomatal density,leaf/soil gas exchange characteristics and soil atmosphere andleaf ${delta}$ ¹³C isotope abundances were examined.

Key Results: The leaves of B. orientalis have large lysigenous air-filledchannels separating the upper and lower surfaces of the leaves.The upper surface comprised approx. 70 % of the leaf mass and75 % of the leaf N (mmol g^–1). Between 20 % and 30 % ofthe stomatal conductance and CO₂ assimilation was through thelower surface of the leaf. CO₂ efflux rates from the soil surfacewere up to 5·4 µmol m^–2 s^–1 while photosyntheticfluxes through the lower surface of the leaves were approx.7 µmol m^–2 s^–1. However, the utilization ofsoil-derived CO₂ only altered the leaf ${delta}$ ¹³C isotope abundanceof the prostrate leaves by a small amount. Using ${delta}$ ¹³C valuesit was estimated that 7 % of the leaf tissue C was derived fromsoil-derived CO₂.

Conclusions: A small proportion of photosynthetically fixed CO₂ was derivedfrom the soil, with minimal associated transpirational H₂O lossinto the space between the leaf and soil. The soil-derived CO₂,taken up through the lower surface was probably assimilatedby the palisade tissue in the upper surface of the leaf whichwas exposed to sunlight and where most of the leaf N was located.The occurrence of lysigenous air channels in the leaves mayprovide longitudinal strength without impaired transfer of CO₂taken up through the lower surface to the upper surface.

Key words: Brunsvigia orientalis, carbon dioxide, soil efflux, photosynthesis, carbon isotope, prostrate, geophyte, lysigenous

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