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The lipid bilayer and aquaporins: parallel pathways for water movement into plant cells

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Abstract

The plant plasma membrane is the the major barrier to water flow between cells and their surroundings. Water movement across roots involves pathways comprising many cells and their walls. There are three possible pathways which water can follow, (i) a trans-cellular pathway, which involves serial movement into and out from radial files of cells, (ii) a symplasmic pathway through the plasmodesmata, which creates a cytoplasmic continuum and (iii) a tortuous, extracellular pathway through the cell walls, the apoplasmic pathway. In each of these pathways water movement across cell membranes occurs at some stage. The possible role of water-channels in membranes is discussed in relation to this movement. The molecular identity of water-channel proteins in plasma membranes of plants has been confirmed but there remain a number of unresolved questions about their role in cell and tissue water relations, their interaction with the lipid components of membranes and the relationship between water movement through membranes by diffusion in the bilayer.

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Authors and Affiliations

  1. CEBAS-CSIC, PO Box 4195, 30080-, Murcia, Spain

    Micaela Carvajal

  2. IACR-Long Ashton Research Station, Department of Agricultural Sciences, University of Bristol, Long Ashton, Bristol, BS18 9AF, UK

    David T. Cooke & David T. Clarkson

Authors
  1. Micaela Carvajal
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  2. David T. Cooke
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  3. David T. Clarkson
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Carvajal, M., Cooke, D.T. & Clarkson, D.T. The lipid bilayer and aquaporins: parallel pathways for water movement into plant cells. Plant Growth Regulation 25, 89–95 (1998). https://doi.org/10.1023/A:1005918305552

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