Mechanical contribution of secondary phloem to postural control in trees: the bark side of the force.

To grow straight, plants need a motor system that controls posture by generating forces to offset gravity. This motor function in trees was long thought to be only controlled by internal forces induced in wood. Here we provide evidence that bark is involved in the generation of mechanical stresses in several tree species. Saplings of nine tropical species were grown tilted and staked in a shadehouse and the change in curvature of the stem was measured after releasing from the pole and after removing the bark. This first experiment evidenced the contribution of bark in the up-righting movement of tree stems. Combined mechanical measurements of released strains on adult trees and microstructural observations in both transverse and longitudinal/tangential plane enabled us to identify the mechanism responsible for the development of asymmetric mechanical stress in the bark of stems of these species. This mechanism does not result from cell wall maturation like in wood, or from the direct action of turgor pressure like in unlignified organs, but is the consequence of the interaction between wood radial pressure and a smartly organized trellis structure in the inner bark.

[1]  P. Baas,et al.  IAWA List of Microscopic Bark Features , 2016 .

[2]  Dietrich Böhlmann Zugbast bei Tilia cordata Mill. , 1971 .

[3]  S. Patiño,et al.  Functional explanations for variation in bark thickness in tropical rain forest trees , 2010 .

[4]  A. Déjardin,et al.  Non-cellulosic polysaccharide distribution during G-layer formation in poplar tension wood fibers: abundance of rhamnogalacturonan I and arabinogalactan proteins but no evidence of xyloglucan , 2017, Planta.

[5]  G. Scurfield Reaction Wood: Its Structure and Function , 1973, Science.

[6]  A. Oskolski,et al.  Bark anatomy of Adansonia digitata L. (Malvaceae) , 2017, Adansonia.

[7]  C. Coutand,et al.  Mechanosensing is involved in the regulation of autostress levels in tension wood , 2014, Trees.

[8]  Junji Sugiyama,et al.  Maturation Stress Generation in Poplar Tension Wood Studied by Synchrotron Radiation Microdiffraction[C][W][OA] , 2010, Plant Physiology.

[9]  D'arcy W. Thompson,et al.  On Growth and Form , 1917, Nature.

[10]  H. Dadswell,et al.  THE NATURE OF REACTION WOOD I. THE STRUCTURE AND PROPERTIES OF TENSION WOOD FIBRES , 2010 .

[11]  T. Alméras,et al.  Patterns of longitudinal and tangential maturation stresses in Eucalyptus nitens plantation trees , 2013, Annals of Forest Science.

[12]  A. Déjardin,et al.  Is the G-Layer a Tertiary Cell Wall? , 2018, Front. Plant Sci..

[13]  R. Ritchie,et al.  Bioinspired structural materials. , 2014, Nature Materials.

[14]  Dr. Robert R. Archer,et al.  Growth Stresses and Strains in Trees , 1987, Springer Series in Wood Science.

[15]  M. Westoby,et al.  Bark functional ecology: evidence for tradeoffs, functional coordination, and environment producing bark diversity. , 2014, The New phytologist.

[16]  Kevin W Eliceiri,et al.  NIH Image to ImageJ: 25 years of image analysis , 2012, Nature Methods.

[17]  Julieta A Rosell,et al.  Bark thickness across the angiosperms: more than just fire. , 2016, The New phytologist.

[18]  Bruno Moulia,et al.  Posture control and skeletal mechanical acclimation in terrestrial plants: implications for mechanical modeling of plant architecture. , 2006, American-Eurasian journal of botany.

[19]  C. Neinhuis,et al.  Reorientation in Tilted Stems of Papaya by Differential Growth , 2014, International Journal of Plant Sciences.

[20]  U. Zajączkowska,et al.  Interaction between secondary phloem and xylem in gravitropic reaction of lateral branches of Tilia cordata Mill. trees , 2016 .

[21]  F. Quignard,et al.  Mesoporosity changes from cambium to mature tension wood: a new step toward the understanding of maturation stress generation in trees. , 2015, The New phytologist.

[22]  Thomas Speck,et al.  Modelling primary and secondary growth processes in plants: a summary of the methodology and new data from an early lignophyte. , 2003, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[23]  J. Fisher,et al.  Reaction anatomy and reorientation in leaning stems of balsa (Ochroma) and papaya (Carica) , 1983 .

[24]  K J Niklas,et al.  The mechanical role of bark. , 1999, American journal of botany.

[25]  R Core Team,et al.  R: A language and environment for statistical computing. , 2014 .

[26]  T. E. Timell Compression Wood in Gymnosperms , 1986 .

[27]  M. Fournier,et al.  Biomechanical Action and Biological Functions , 2014 .

[28]  M. Fournier,et al.  Quantifying the motor power of trees , 2018, Trees.

[29]  Eric H. Metzler,et al.  Plant Biomechanics : An Engineering Approach to Plant Form and Function , 2017 .

[30]  T. Okuyama,et al.  Techniques for Measuring Growth Stress on the Xylem Surface Using Strain and Dial Gauges , 2002 .

[31]  Julieta A. Rosell,et al.  The evolution of bark mechanics and storage across habitats in a clade of tropical trees. , 2014, American journal of botany.

[32]  M. Fournier,et al.  Biomechanical design and long-term stability of trees: morphological and wood traits involved in the balance between weight increase and the gravitropic reaction. , 2009, Journal of theoretical biology.

[33]  Bruno Clair,et al.  Evidence of the late lignification of the G-layer in Simarouba tension wood, to assist understanding how non-G-layer species produce tensile stress. , 2015, Tree physiology.

[34]  B. Moulia,et al.  The power and control of gravitropic movements in plants: a biomechanical and systems biology view. , 2009, Journal of experimental botany.

[35]  T. Alméras,et al.  Critical review on the mechanisms of maturation stress generation in trees , 2016, Journal of The Royal Society Interface.

[36]  Bruno Clair,et al.  Diversity in the organisation and lignification of tension wood fibre walls – A review , 2017 .