Vascularization of the Selaginella rhizophore: anatomical fingerprints of polar auxin transport with implications for the deep fossil record

The Selaginella rhizophore is a unique and enigmatic organ whose homology with roots, shoots, or neither of the two remains unresolved. Nevertheless, rhizophore-like organs have been documented in several fossil lycophytes. Here we test the homology of these organs through comparisons with the archi...

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Bibliographic Details
Published in:The New phytologist 2017-10, Vol.216 (2), p.419-428
Main Authors: Matsunaga, Kelly K. S., Cullen, Nevin P., Tomescu, Alexandru M. F.
Format: Article
Language:English
Subjects:
Auxins
Biological Transport
Body organs
Curvature
Fingerprints
fossil
Fossils
Homology
Imaging, Three-Dimensional
Indoleacetic Acids - metabolism
lycophyte
Models, Biological
Organs
Plant Shoots - metabolism
Plant Vascular Bundle - anatomy & histology
polar auxin transport
rhizophore
Sectioning
Selaginella
Selaginellaceae - anatomy & histology
Selaginellaceae - metabolism
Shoots
Species Specificity
tracheid
Transport
Vascularization
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Summary:The Selaginella rhizophore is a unique and enigmatic organ whose homology with roots, shoots, or neither of the two remains unresolved. Nevertheless, rhizophore-like organs have been documented in several fossil lycophytes. Here we test the homology of these organs through comparisons with the architecture of rhizophore vascularization in Selaginella. We document rhizophore vascularization in nine Selaginella species using cleared wholemounts and histological sectioning combined with three-dimensional reconstruction. Three patterns of rhizophore vascularization are present in Selaginella and each is comparable to those observed in rhizophore-like organs of fossil lycophytes. More compellingly, we found that all Selaginella species sampled exhibit tracheids that arc backward from the stem and side branch into the rhizophore base. This tracheid curvature is consistent with acropetal auxin transport previously documented in the rhizophore and is indicative of the redirection of basipetal auxin from the shoot into the rhizophore during development. The tracheid curvature observed in Selaginella rhizophores provides an anatomical fingerprint for the patterns of auxin flow that underpin rhizophore development. Similar tracheid geometry may be present and should be searched for in fossils to address rhizophore homology and the conservation of auxin-related developmental mechanisms from early stages of lycophyte evolution.
ISSN:0028-646X
1469-8137
DOI:10.1111/nph.14478