Can Ca2+ Fluxes to the Root Xylem Be Sustained by Ca2+-ATPases in Exodermal and Endodermal Plasma Membranes?

doi:10.1104/pp.104.041889

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Published on November 5, 2004; 10.1104/pp.104.041889

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Received March 1, 2004
Returned for revision June 9, 2004
Accepted June 10, 2004

Can Ca²⁺ Fluxes to the Root Xylem Be Sustained by Ca²⁺-ATPases in Exodermal and Endodermal Plasma Membranes?

Meghan L. Hayter and Carol A. Peterson ^*

Department of Biology, University of Waterloo, Waterloo, Ontario, Canada, N2L 3G1

^* Corresponding author; email: cpeterso{at}uwaterloo.ca.

The pathway of Ca²⁺ movement from the soil solution into theroot stele has been a subject of controversy. If transport throughthe endodermis is assumed to be through the cytoplasm, the limitingfactor is believed to be the active pumping of Ca²⁺ from thecytoplasm into the stele apoplast through the plasma membranelying on the stele side of the Casparian band. By analogy, forsimilar transport through the exodermis, the limiting step wouldbe the active pumping into the apoplast on the central corticalside of the layer. Such effluxes are mediated by Ca²⁺-ATPases.To assess whether or not known Ca²⁺ fluxes to the stele in onion(Allium cepa) roots could be supported by Ca²⁺-ATPases, thepercentages of total membrane protein particles required toeffect the transport were calculated using measured values ofmembrane surface areas, an animal literature value for Ca²⁺-ATPaseV_max, plant literature values for Ca²⁺-ATPase K_m, and proteindensities of relevant membranes. Effects of a putative symplasticmovement of Ca²⁺ from the exo- or endodermis into the next celllayer, which would increase the surface areas available forpumping, were also considered. Depending on the assumptionsapplied, densities of Ca²⁺ pumps, calculated as a percentageof total membrane protein particles, varied tremendously betweenthree and 1,600 for the endodermis, and between 0.94 and 1,900for the exodermis. On the basis of the data, the possibilityof Ca²⁺ transport through the cytoplasm and membranes of theexodermis and endodermis cannot be discounted. Thus, it is prematureto assign an entirely apoplastic pathway for Ca²⁺ movement fromthe soil solution to the tracheary elements of the xylem. Toverify any conclusion with certainty, more detailed data arerequired for the characteristics of exo- and endodermal Ca²⁺-ATPases.