Seasonal variation in the reflectance of photosynthetically active radiation from epicuticular waxes of Scots pine (Pinus sylvestris) needles

Epicuticular waxes influence leaf reflectance, but the spatiotemporal dynamics in their reflectance properties have not been properly characterized, and its consequences remain unknown. In this study, we analysed the seasonal changes in wax reflectance of Scots pine needles. It tended to decrease with needle age and towards lower positions within the canopy. In addition, we also identified a clear seasonal pattern of variation superimposed on the of above-mentioned wax weathering effect. We conclude that spatiotemporal dynamics in wax optical properties need to be considered in studies that implicitly assume constant light absorption, particularly when different leaf age classes, canopy positions or seasons are compared, and especially in species with substantial amount of waxes. We suggest that the observed dynamics in wax reflectance could represent a new photoprotective mechanism operating at the seasonal scale as they modulate the absorption of the photosynthetically active radiation (PAR) over time.

[1]  G. Öquist,et al.  Photostasis in Plants, Green Algae and Cyanobacteria: The Role of Light Harvesting Antenna Complexes , 2003 .

[2]  S. Huttunen,et al.  Scots pine needle surfaces on radial transects across the north boreal area of Finnish Lapland and the Kola Peninsula of Russia. , 1996, Environmental pollution.

[3]  A. Porcar-Castell,et al.  A high-resolution portrait of the annual dynamics of photochemical and non-photochemical quenching in needles of Pinus sylvestris. , 2011, Physiologia plantarum.

[4]  Eero Nikinmaa,et al.  Station for Measuring Ecosystem-Atmosphere Relations: SMEAR , 2013 .

[5]  J. Bäck,et al.  Pine needle growth and fine structure after prolonged acid rain treatment in the subarctic , 1994 .

[6]  P. Hari,et al.  Characterization of atmospheric trace gas and aerosol concentrations at forest sites in southern and northern Finland using back trajectories , 2000 .

[7]  B. Fernández-Marín,et al.  Salt crystal deposition as a reversible mechanism to enhance photoprotection in black mangrove , 2012, Trees.

[8]  T. Painter,et al.  Reflectance quantities in optical remote sensing - definitions and case studies , 2006 .

[9]  T. Keller,et al.  Some effects of long-term ozone fumigation on Norway spruce , 1987, Trees.

[10]  Linda Chalker-Scott,et al.  Environmental Significance of Anthocyanins in Plant Stress Responses , 1999 .

[11]  Albert Porcar-Castell,et al.  Physiology of the seasonal relationship between the photochemical reflectance index and photosynthetic light use efficiency , 2012, Oecologia.

[12]  Albert Porcar-Castell,et al.  Seasonal acclimation of photosystem II in Pinus sylvestris. II. Using the rate constants of sustained thermal energy dissipation and photochemistry to study the effect of the light environment. , 2008, Tree physiology.

[13]  N. Huner,et al.  Photosynthesis of overwintering evergreen plants. , 2001, Annual review of plant biology.

[14]  S. Huttunen,et al.  A review of the response of epicuticular wax of conifer needles to air pollution , 1990 .

[15]  Gregory P. Asner,et al.  A Revised Measurement Methodology for Conifer Needles Spectral Optical Properties: Evaluating the Influence of Gaps between Elements , 1999 .

[16]  H. Mooney,et al.  The energy balance of leaves of the evergreen desert shrub Atriplex hymenelytra , 1977, Oecologia.

[17]  R. Hill,et al.  The impact of epicuticular wax on gas-exchange and photoinhibition in Leucadendron lanigerum (Proteaceae) , 2007 .

[18]  D. Shilling,et al.  Evaluation of Epicuticular Wax Removal from Whole Leaves with Chloroform , 1993, Weed Technology.

[19]  E. Baker,et al.  EROSION OF WAXES FROM LEAF SURFACES BY SIMULATED RAIN. , 1986, The New phytologist.

[20]  Masahiro Kasahara,et al.  Chloroplast avoidance movement reduces photodamage in plants , 2002, Nature.

[21]  K. Percy,et al.  Effects of ozone and acidic fog on red spruce needle epicuticular wax production, chemical composition, cuticular membrane ultrastructure and needle wettability. , 1992, New Phytologist.

[22]  Z. Cerovic,et al.  Optical Properties of Plant Surfaces , 2007 .

[23]  E. Baker THE INFLUENCE OF ENVIRONMENT ON LEAF WAX DEVELOPMENT IN BRASSICA OLERACEA VAR. GEMMIFERA , 1974 .

[24]  T. Mulroy,et al.  Spectral properties of heavily glaucous and non-glaucous leaves of a succulent rosette-plant , 2004, Oecologia.

[25]  K. Niyogi,et al.  Non-photochemical quenching. A response to excess light energy. , 2001, Plant physiology.

[26]  Craig S. T. Daughtry,et al.  A new technique to measure the spectral properties of conifer needles , 1989 .

[27]  A. Gilmore,et al.  Mechanistic aspects of xanthophyll cycle‐dependent photoprotection in higher plant chloroplasts and leaves , 1997 .

[28]  Qingmin Han,et al.  Photoprotective role of rhodoxanthin during cold acclimation in Cryptomeria japonica , 2003 .

[29]  W. W. Adams,et al.  Carotenoid composition and down regulation of photosystem II in three conifer species during the winter , 1994 .

[30]  M. G. Holmes,et al.  Effects of pubescence and waxes on the reflectance of leaves in the ultraviolet and photosynthetic wavebands: a comparison of a range of species , 2002 .

[31]  Stefan Jansson,et al.  Intermittent low temperatures constrain spring recovery of photosynthesis in boreal Scots pine forests , 2004 .

[32]  J. Burkhardt Hygroscopic particles on leaves: nutrients or desiccants? , 2010 .

[33]  Rj Cameron,et al.  Light intensity and the growth of Eucalyptus seedlings. II. The effect of cuticular waxes on light absorption in leaves of Eucalyptus species. , 1970 .

[34]  Yanhong Tang,et al.  Flexible Leaf Orientations of Arisaema heterophyllum Maximize Light Capture in a Forest Understorey and Avoid Excess Irradiance at a Deforested Site , 1998 .

[35]  W. D. Billings,et al.  REFLECTION OF VISIBLE AND INFRARED RADIATION FROM LEAVES OF DIFFERENT ECOLOGICAL GROUPS , 1951 .

[36]  D A Reicosky,et al.  Physiological Effects of Surface Waxes: I. Light Reflectance for Glaucous and Nonglaucous Picea pungens. , 1978, Plant physiology.

[37]  K. Percy,et al.  Effects of simulated acid rain on epicuticular wax production, morphology, chemical composition and on cuticular membrane thickness in two clones of Sitka spruce [Picea sitchensis (Bong.) Carr.] , 1990 .

[38]  D. Fowler,et al.  The weathering of scots pine epicuticular wax in polluted and clean air , 1986 .

[39]  J. Clark,et al.  Photosynthetic Action Spectra of Trees: II. The Relationship of Cuticle Structure to the Visible and Ultraviolet Spectral Properties of Needles from Four Coniferous Species. , 1975, Plant physiology.