BaseSpace
Import Your Data
Literature

FAQ

More FAQs

Back to top
Clear Search sequence regions
(e.g. calcium channel activity, Leukemia, Leukocyte, Personalized medicine, Doxorubicin)
Bookmark Forward

Mathematical analysis of long-distance polar auxin transport data of pin mutants questions the role of PIN1 as postulated in the chemi-osmotic theory.

Kees J M Boot, Sander C Hille, Kees R Libbenga, Marijke Libbenga-Nijkamp, Omid Karami, Bert Van Duijn, Remko Offringa

Physiologia plantarum 2025 Mar-Apr


filter terms:
  • arabidopsis (1)
  • arabidopsis proteins (3)
  • arabidopsis thaliana (1)
  • AUX1 (1)
  • auxin (2)
  • auxin efflux (1)
  • auxin influx (1)
  • auxin transport (7)
  • cell membranes (2)
  • embryogenesis (1)
  • gene (3)
  • gene plant (1)
  • PIN1 (4)
  • pin1 protein, arabidopsis (1)
  • plant (3)
  • plant growth regulators (2)
  • transport proteins (2)
    • Sizes of these terms reflect their relevance to your search.

    The plant hormone auxin (Indole-3-Acetic Acid, IAA) is a key player in nearly every aspect of plant growth and development ranging from cell division and cell elongation to embryogenesis and root formation. The IAA level in specific tissues and cells is regulated by synthesis, conjugation, degradation and transport. Especially long-range polar auxin transport (PAT) has been the subject of numerous studies. The chemi-osmotic theory predicts that intercellular PAT is caused by an asymmetric distribution of auxin efflux transporters in cell membranes of transporting cells, resulting in increased local membrane permeability for IAA. Members of the PIN gene family are generally considered to encode the postulated carriers. The objective of this study was to use the chemi-osmotic theory in an experimental program aimed at describing and interpreting long-range PAT data from mutants of the PIN gene family of Arabidopsis thaliana. Therefore, we put the chemi-osmotic theory in a broader theoretical framework. We find that the observed decrease in both auxin flux and transport velocity in pin1 loss-of-function mutants is not caused by decreased basal membrane permeability, as would be expected according to the chemi-osmotic theory, but is an indirect effect caused by a change in the dynamics of auxin transport due to a decrease in the expression of all four AUX1/LAX1-3 auxin influx carriers in pin1 mutants. On the basis of our findings, we conclude that the exact role of PIN1 in long-distance PAT, as postulated in the chemi-osmotic theory, should be reconsidered. © 2025 The Author(s). Physiologia Plantarum published by John Wiley & Sons Ltd on behalf of Scandinavian Plant Physiology Society.

    Citation

    Kees J M Boot, Sander C Hille, Kees R Libbenga, Marijke Libbenga-Nijkamp, Omid Karami, Bert Van Duijn, Remko Offringa. Mathematical analysis of long-distance polar auxin transport data of pin mutants questions the role of PIN1 as postulated in the chemi-osmotic theory. Physiologia plantarum. 2025 Mar-Apr;177(2):e70139

    Expand section icon Mesh Tags

    Expand section icon Substances


    PMID: 40079179

    View Full Text
    • Copyright © 2025 Illumina Inc. All rights reserved.