Literature DB >> 23269848

Buckling as an origin of ordered cuticular patterns in flower petals.

Rea L Antoniou Kourounioti1, Leah R Band, John A Fozard, Anthony Hampstead, Anna Lovrics, Edwige Moyroud, Silvia Vignolini, John R King, Oliver E Jensen, Beverley J Glover.   

Abstract

The optical properties of plant surfaces are strongly determined by the shape of epidermal cells and by the patterning of the cuticle on top of the cells. Combinations of particular cell shapes with particular nanoscale structures can generate a wide range of optical effects. Perhaps most notably, the development of ordered ridges of cuticle on top of flat petal cells can produce diffraction-grating-like structures. A diffraction grating is one of a number of mechanisms known to produce 'structural colours', which are more intense and pure than chemical colours and can appear iridescent. We explore the concept that mechanical buckling of the cuticle on the petal epidermis might explain the formation of cuticular ridges, using a theoretical model that accounts for the development of compressive stresses in the cuticle arising from competition between anisotropic expansion of epidermal cells and isotropic cuticle production. Model predictions rationalize cuticle patterns, including those with long-range order having the potential to generate iridescence, for a range of different flower species.

Mesh:

Year:  2012        PMID: 23269848      PMCID: PMC3565735          DOI: 10.1098/rsif.2012.0847

Source DB:  PubMed          Journal:  J R Soc Interface        ISSN: 1742-5662            Impact factor:   4.118


  22 in total

1.  Floral iridescence, produced by diffractive optics, acts as a cue for animal pollinators.

Authors:  Heather M Whitney; Mathias Kolle; Piers Andrew; Lars Chittka; Ullrich Steiner; Beverley J Glover
Journal:  Science       Date:  2009-01-02       Impact factor: 47.728

Review 2.  An overview on plant cuticle biomechanics.

Authors:  Eva Domínguez; Jesús Cuartero; Antonio Heredia
Journal:  Plant Sci       Date:  2011-05-04       Impact factor: 4.729

3.  The Arabidopsis ABCG13 transporter is required for flower cuticle secretion and patterning of the petal epidermis.

Authors:  David Panikashvili; Jian Xin Shi; Lukas Schreiber; Asaph Aharoni
Journal:  New Phytol       Date:  2011-01-14       Impact factor: 10.151

4.  Flower colour intensity depends on specialized cell shape controlled by a Myb-related transcription factor.

Authors:  K Noda; B J Glover; P Linstead; C Martin
Journal:  Nature       Date:  1994-06-23       Impact factor: 49.962

5.  Nanoridges that characterize the surface morphology of flowers require the synthesis of cutin polyester.

Authors:  Yonghua Li-Beisson; Mike Pollard; Vincent Sauveplane; Franck Pinot; John Ohlrogge; Fred Beisson
Journal:  Proc Natl Acad Sci U S A       Date:  2009-12-03       Impact factor: 11.205

6.  WIN1, a transcriptional activator of epidermal wax accumulation in Arabidopsis.

Authors:  Pierre Broun; Patricia Poindexter; Erin Osborne; Cai-Zhong Jiang; José Luis Riechmann
Journal:  Proc Natl Acad Sci U S A       Date:  2004-03-22       Impact factor: 11.205

7.  The SHINE clade of AP2 domain transcription factors activates wax biosynthesis, alters cuticle properties, and confers drought tolerance when overexpressed in Arabidopsis.

Authors:  Asaph Aharoni; Shital Dixit; Reinhard Jetter; Eveline Thoenes; Gert van Arkel; Andy Pereira
Journal:  Plant Cell       Date:  2004-08-19       Impact factor: 11.277

Review 8.  Building lipid barriers: biosynthesis of cutin and suberin.

Authors:  Mike Pollard; Fred Beisson; Yonghua Li; John B Ohlrogge
Journal:  Trends Plant Sci       Date:  2008-04-24       Impact factor: 18.313

Review 9.  Sealing plant surfaces: cuticular wax formation by epidermal cells.

Authors:  Lacey Samuels; Ljerka Kunst; Reinhard Jetter
Journal:  Annu Rev Plant Biol       Date:  2008       Impact factor: 26.379

10.  SHINE transcription factors act redundantly to pattern the archetypal surface of Arabidopsis flower organs.

Authors:  Jian Xin Shi; Sergey Malitsky; Sheron De Oliveira; Caroline Branigan; Rochus B Franke; Lukas Schreiber; Asaph Aharoni
Journal:  PLoS Genet       Date:  2011-05-26       Impact factor: 5.917
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  5 in total

1.  Analysing photonic structures in plants.

Authors:  Silvia Vignolini; Edwige Moyroud; Beverley J Glover; Ullrich Steiner
Journal:  J R Soc Interface       Date:  2013-07-24       Impact factor: 4.118

2.  Polarity in cuticular ridge development and insect attachment on leaf surfaces of Schismatoglottis calyptrata (Araceae).

Authors:  Venkata A Surapaneni; Tobias Aust; Thomas Speck; Marc Thielen
Journal:  Beilstein J Nanotechnol       Date:  2021-12-01       Impact factor: 3.649

3.  Acetylation of cell wall is required for structural integrity of the leaf surface and exerts a global impact on plant stress responses.

Authors:  Majse Nafisi; Maria Stranne; Lorenzo Fimognari; Susanna Atwell; Helle J Martens; Pai R Pedas; Sara F Hansen; Christiane Nawrath; Henrik V Scheller; Daniel J Kliebenstein; Yumiko Sakuragi
Journal:  Front Plant Sci       Date:  2015-07-22       Impact factor: 5.753

4.  PeERF1, a SHINE-Like Transcription Factor, Is Involved in Nanoridge Development on Lip Epidermis of Phalaenopsis Flowers.

Authors:  Pei-Han Lai; Li-Min Huang; Zhao-Jun Pan; Wann-Neng Jane; Mei-Chu Chung; Wen-Huei Chen; Hong-Hwa Chen
Journal:  Front Plant Sci       Date:  2020-01-30       Impact factor: 5.753

5.  How to build an effective research network: lessons from two decades of the GARNet plant science community.

Authors:  Geraint Parry; Yoselin Benitez-Alfonso; Daniel J Gibbs; Murray Grant; Andrea Harper; C Jill Harrison; Eirini Kaiserli; Sabina Leonelli; Sean May; Sarah McKim; Steven Spoel; Colin Turnbull; Renier A L van der Hoorn; James Murray
Journal:  J Exp Bot       Date:  2020-12-31       Impact factor: 6.992
  5 in total

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