Shoot structure and photosynthetic efficiency along the light gradient in a Scots pine canopy.

We examined the effects of structural and physiological acclimation on the photosynthetic efficiency of Scots pine (Pinus sylvestris L.) shoots. We estimated daily light interception (DLI) and photosynthesis (DPHOT) of a number of sample shoots situated at different positions in the canopy. Photosynthetic efficiency (epsilon) was defined as the ratio of DPHOT to the potential daily light interception (DLI(ref)) defined as the photosynthetically active radiation (PAR) intercepted per unit area of a sphere at the shoot location. To calculate DLI(ref), DLI and DPHOT, the radiation field surrounding a shoot in the canopy was first modeled using simulated directional distributions of incoming PAR on a clear and an overcast day, and estimates of canopy gap fraction in different directions provided by hemispherical photographs. A model of shoot geometry and measured data on shoot structure and photosynthetic parameters were used to simulate the distribution of PAR irradiance on the needle surface area of the shoot. Photosynthetic efficiency (epsilon) was separated into light-interception efficiency (epsilon(I) = DLI/DLI(ref)) and conversion efficiency (epsilon(PHOT) = DPHOT/DLI). This allowed us to quantify separately the effect of structural acclimation on the efficiency of photosynthetic light capture (epsilon(l)), and the effect of physiological acclimation on conversion efficiency (epsilon(PHOT)). The value of epsilon increased from the top to the bottom of the canopy. The increase was largely explained by structural acclimation (higher epsilon(I)) of the shade shoots. The value of epsilon(PHOT) of shade foliage was similar to that of sun foliage. Given these efficiencies, the clear-day value of DPHOT for a sun shoot transferred to shade was only half that of a shade shoot at its original position. The method presented here provides a tool for quantitatively estimating the role of acclimation in total canopy photosynthesis.

[1]  Benjamin Y. H. Liu,et al.  The interrelationship and characteristic distribution of direct, diffuse and total solar radiation , 1960 .

[2]  J. Harborne Encyclopedia of plant physiology, New series , 1978 .

[3]  M. G. R. Cannell,et al.  Phyllotactic arrangements of needles on elongating conifer shoots: a computer simulation , 1978 .

[4]  O. Björkman Responses to Different Quantum Flux Densities , 1981 .

[5]  H. Smolander,et al.  Photosynthesis of a Scots pine shoot: The effect of shoot inclination on the photosynthetic response of a shoot subjected to direct radiation , 1983 .

[6]  Canopy structure and light climate in a young Scots pine stand. , 1983 .

[7]  Jon D. Johnson A rapid technique for estimating total surface area of pine needles. , 1984 .

[8]  J. M. Norman,et al.  Partitioning solar radiation into direct and diffuse, visible and near-infrared components , 1985 .

[9]  G. Carter,et al.  Influence of shoot structure on light interception and photosynthesis in conifers. , 1985, Plant physiology.

[10]  Photosynthesis of a scots pine shoot: Test of a shoot photosynthesis model in a direct radiation field , 1987 .

[11]  A. Koppel,et al.  Net photosynthetic response to light intensity of shoots from different crown positions and age in picea abies (L.) karst , 1987 .

[12]  R. K. Dixon,et al.  An optimal sampling strategy for determining CO2 exchange rate as a function of photosynthetic photon flux density , 1987 .

[13]  Heikki Smolander,et al.  The Ratio of Shoot Silhouette Area to Total Needle Area in Scots Pine , 1988, Forest Science.

[14]  D. Sprugel The Relationship of Evergreenness, Crown Architecture, and Leaf Size , 1989, American Naturalist.

[15]  T. Hinckley,et al.  Shoot structure, leaf area index and productivity of evergreen conifer stands. , 1990, Tree physiology.

[16]  Influence of Shoot Structure on the Photosynthesis of Sitka Spruce (Picea sitchensis) , 1993 .

[17]  H. Smolander,et al.  Dependence of light interception efficiency of Scots pine shoots on structural parameters. , 1994, Tree physiology.

[18]  Ichiro Terashima,et al.  Comparative ecophysiology of leaf and canopy photosynthesis , 1995 .

[19]  O. Kull,et al.  Effects of light availability and tree size on the architecture of assimilative surface in the canopy of Picea abies: variation in needle morphology. , 1995, Tree physiology.

[20]  P. Stenberg,et al.  Photosynthetic Light Capture and Processing from Cell to Canopy , 1995 .

[21]  J. Leverenz Shade-shoot structure, photosynthetic performance in the field, and photosynthetic capacity of evergreen conifers. , 1996, Tree physiology.

[22]  Han Y. H. Chen,et al.  Effects of light on growth, crown architecture, and specific leaf area for naturally established Pinuscontorta var. latifolia and Pseudotsugamenziesii var. glauca saplings , 1996 .

[23]  D. Sprugel,et al.  Effects of light on shoot geometry and needle morphology in Abies amabilis. , 1996, Tree physiology.

[24]  Ü. Niinemets,et al.  Acclimation to low irradiance in Picea abies: influences of past and present light climate on foliage structure and function. , 1997, Tree physiology.

[25]  Pauline Stenberg,et al.  Shoot structure, light interception, and distribution of nitrogen in an Abies amabilis canopy. , 1998, Tree physiology.

[26]  P. Stenberg Implications of shoot structure on the rate of photosynthesis at different levels in a coniferous canopy using a model incorporating grouping and penumbra , 1998 .

[27]  W. Smith,et al.  Interrelationships among light, photosynthesis and nitrogen in the crown of mature Pinus contorta ssp. latifolia. , 1999, Tree physiology.

[28]  P. Stenberg,et al.  Shoot structure, canopy openness, and light interception in Norway spruce , 1999 .

[29]  William E. Winner,et al.  Foliage physiology and biochemistry in response to light gradients in conifers with varying shade tolerance , 1999, Oecologia.

[30]  P. Stenberg,et al.  A method for estimating light interception by a conifer shoot. , 2001, Tree physiology.