Technical Advance: Reduction of Fe(III)-Chelates by Mesophyll Leaf Disks of Sugar Beet. Multi-Component Origin and Effects of Fe Deficiency

doi:10.1093/pcp/pce012

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Plant and Cell Physiology, 2001, Vol. 42, No. 1 94-105
© 2001 Oxford University Press

Technical Advance: Reduction of Fe(III)-Chelates by Mesophyll Leaf Disks of Sugar Beet. Multi-Component Origin and Effects of Fe Deficiency

Ajmi Larbi¹, Fermín Morales¹, Ana Flor López-Millán¹, Yolanda Gogorcena¹, Anunciación Abadía¹, Petra R. Moog² and Javier Abadía^,1^,3

¹ Departamento de Nutrición Vegetal, Estación Experimental de Aula Dei, C.S.I.C., Apdo. 202, E-50080 Zaragoza, Spain ² Botanisches Institut, Johann Wolfgang Goethe-Universität, Senckenberganlage 31-33, D-60054 Frankfurt/Main, Germany

The characteristics of the Fe(III)-chelate reductase activityhave been investigated in mesophyll disks of Fe-sufficient andFe-deficient sugar beet leaves. The Fe(III)-chelate reductaseactivity of mesophyll disks was light dependent and increasedmarkedly when the epidermis was removed. Iron(III)-citrate wasphoto-reduced directly by light in the absence of plant tissue.Total reductase activity was the sum of enzymatic mesophyllreduction, enzymatic reduction carried out by organelles exposedat the disk edge and reduction caused by the release of substancesboth by exposed mesophyll cells and at the disk edge. Compoundsexcreted were shown by HPLC to include organic anions, mainlyoxalate, citrate and malate. When expressed on a leaf surfacebasis, Fe deficiency decreased the total mesophyll Fe(III)-chelatereductase activity. However, Fe-sufficient disks reduced lessFe than the Fe-deficient ones when expressed on a chlorophyllbasis. The optimal pH values for Fe(III) reduction were alwaysin the range 6.0–6.7. In control leaves Fe(III)-citrateand Fe(III)-malate were the substrates that led to the highestFe reduction rates. In Fe-deficient leaves Fe(III)-malate ledto the highest Fe reduction rates, followed by Fe(III)-EDTAand then Fe(III)-citrate. K_m values for the total reductaseactivity, enzymatic mesophyll reduction and enzymatic reductioncarried out by organelles at the disk edge were obtained.

³ Corresponding author: E-mail, jabadia@eead.csic.es; Fax, +34976 716145.

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