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Plant Biol (Stuttg) 2002; 4(4): 503-507
DOI: 10.1055/s-2002-34126
Original Paper
Georg Thieme Verlag Stuttgart ·New York

Seasonal Direct Light Availability Affects Mean Leaf Orientation in a Herbaceous Multi-Species Canopy

K. Zobel, L. Eek
  • Department of Botany and Ecology, Tartu University, Tartu, Estonia
Further Information

Publication History

Received: January 12, 2001

Accepted: April 29, 2002

Publication Date:
18 September 2002 (online)

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Abstract

Relationship between leaf orientation in natural or semi-natural herbaceous communities and the local abundance of direct light has rarely been investigated. We present evidence from a permanent plot experiment that seasonal direct light availability in 40 × 40 cm plots significantly affects mean leaf orientation in a semi-natural wooded meadow. In sunny years and in well-illuminated conditions, the leaf surface is exposed predominantly to the north, and vice versa. Two groups of species are responsible for such a response: of the variation in leaf orientation, 41 % is explainable through direct light availability for light-demanding species, and 26 % for graminoid species. In shade-tolerant species and in forbs there is no sign of a regression between leaf orientation and direct light abundance. Ability to plastically react to variation in seasonal and local direct light availability appears to be a trait under considerable selective pressure only in light-demanding plants, and more characteristic of species with graminoid growth form.

Key words

Grassland - direct light availability - leaf orientation - herbaceous canopy

References

  • 1 Anderson,  M. C.. (1966);  Stand structure and light penetration. II. A theoretical analysis.  Journal of Applied Ecology. 3 41-54
    PubMedGoogle Scholar
  • 2 Baldocchi,  D. D.,, Hutchinson,  B. A.,, Matt,  D. R.,, and McMillen,  R. T.. (1985);  Canopy radiative transfer models for spherical and known leaf inclination angle distributions: A test in an oak-hickory.  Journal of Applied Ecology. 22 539-555
    PubMedGoogle Scholar
  • 3 Berg,  V. S., and Heuchelin,  S.. (1990);  Leaf orientation of soybean seedlings. I. Effect of water potential and photosynthetic photon flux density on paraheliotropism.  Crop Science. 30 631-638
    PubMedGoogle Scholar
  • 4 Caldwell,  M. M.,, Meister,  H.-P.,, Tenhunen,  J. D.,, and Lange,  O. L.. (1986);  Canopy structure, light microclimate and leaf gas exchange of Quercus coccifera L. in a Portugese macchia: measurements in different canopy layers and simulations with a canopy model.  Trees. 1 25-41
    PubMedGoogle Scholar
  • 5 Campbell,  G. S.. (1986);  Extinction coefficients for radiation in plant canopies calculated using an ellipsoidal inclination angle distribution.  Agricultural and Forest Meteorology. 36 317-321
    CrossrefPubMedGoogle Scholar
  • 6 Eek,  L., and Zobel,  K.. (1997);  Effects of additional illumination and fertilization on seasonal changes in fine-scale community structure.  Journal of Vegetation Science. 8 255-234
    PubMedGoogle Scholar
  • 7 Eek,  L., and Zobel,  K. . (2000);  Structure and diversity of a species-rich grassland community, treated with additional illumination, fertilization and mowing.  Ecography. 24 157-164
    PubMedGoogle Scholar
  • 8 Ehleringer,  J. R., and Forseth,  I. N.. (1989) Diurnal leaf movements and productivity in canopies. In Plant canopies: their growth, form and function. Russell, G., Marshall, B., and Jarvis, P. G., eds. Cambridge; Cambrigde Univ. Press pp. 129-142
    Google Scholar
  • 9 Ellenberg,  H.,, Weber,  H. E.,, Düll,  R.,, Wirth,  V.,, Werner,  W.,, Paulissen,  D.. (1991);  Ziegerwerte von Pflanzen in Mitteleuropa.  Scripta Geobotanica. 18 1-248
    PubMedGoogle Scholar
  • 10 Gibson,  D.,, Casal,  J. J.,, and Deregibus,  V. A.. (1992);  The effects of plant density on shoot and leaf lamina angles in Lolium multiflorum and Paspalum dilatatum.  Annals of Botany . 70 69-73
    PubMedGoogle Scholar
  • 11 Goudriaan,  J.. (1988);  The bare bones of leaf-angle distribution in radiation models for canopy photosynthesis and energy exchange.  Agricultural and Forest Meteorology. 43 155-169
    CrossrefPubMedGoogle Scholar
  • 12 Herbert,  T. J.. (1991);  Variation in interception of the direct solar beam by top canopy layers.  Ecology. 72 17-22
    PubMedGoogle Scholar
  • 13 Hebert,  T. J., and Nilson,  T.. (1991);  A model of variance of photosynthesis between leaves and maximization of whole plant photosynthesis.  Photosynthetica. 25 597-606
    PubMedGoogle Scholar
  • 14 Hikosaka,  K., and Hirose,  T., . (1997);  Leaf angle as a strategy for light competition: optimal and evolutionary stable light extinction coefficient within a leaf canopy.  Écoscience. 4 501-507
    PubMedGoogle Scholar
  • 15 Kao,  W. Y., and Tsai,  T. T.. (1998);  Tropic leaf movements, photosynthetic gas exchange, leaf δ13 C and cholorophyll a fluorescence of three soybean species in response to water availability.  Plant, Cell and Environment. 21 1055-1062
    CrossrefPubMedGoogle Scholar
  • 16 Liira,  J., and Zobel,  K.. (2000);  Vertical structure of a species-rich grassland canopy, treated with additional illumination, fertilization and mowing.  Plant Ecology. 146 185-195
    PubMedGoogle Scholar
  • 17 Liira,  J.,, Zobel,  K.,, Mägi,  R.,, and Molenberghs,  G.. (2002);  Vertical structure of herbaceous canopies: the importance of plant growth-form and species-specific traits.  Plant Ecology,. in press
    PubMedGoogle Scholar
  • 18 Machado,  J.-L., and Reich,  P. B.. (1999);  Evaluation of several measures of canopy openness as predictors of photosynthetic photon flux density in deeply shaded conifer-dominated forest understory.  Canadian Journal of Forest Research. 29 1438-1444
    CrossrefPubMedGoogle Scholar
  • 19 McMillen,  G. G., and McClendon,  J. H.. (1979);  Leaf angle: an adaptive feature of sun and shade leaves.  Botanical Gazette. 140 437-442
    CrossrefPubMedGoogle Scholar
  • 20 Myers,  D. A.,, Jordan,  D. N.,, and Vogelmann,  T. C.. (1997);  Inclination of sun and shade leaves influences chloroplast light harvesting and utilization.  Physiologia Plantarum. 99 395-404
    CrossrefPubMedGoogle Scholar
  • 21 Ryel,  R. J., and Beyschlag,  W.. (1995);  Benefits associated with steep foliage orientation in two tussock grasses of the American Intermountain West. A look at water-use-efficiency and photoinhibition.  Flora. 190 251-260
    PubMedGoogle Scholar
  • 22 Scott,  D., and Wells,  J. S.. (1969);  Leaf orientation in barley, lupin, and lucerne stands.  New Zealand Journal of Botany. 7 372-388
    PubMedGoogle Scholar
  • 23 Tappeiner,  U., and Cernusca,  A.. (1989);  Canopy structure and light climate of different alpine plant communities: analysis by means of a model.  Theoretical and Applied Climatology. 40 81-92
    CrossrefPubMedGoogle Scholar
  • 24 Urbas,  P., and Zobel,  K.. (2000);  Adaptive and inevitable morphological plasticity of three herbaceous species in a multi-species community: Field experiment with manipulated nutrients and light.  Acta Oecologica. 21 139-147
    CrossrefPubMedGoogle Scholar
  • 25 Utsugi,  H.. (1999);  Angle distribution of foliage in individual Chamaecyparis obtusa canopies and effect of angle on diffuse light penetration.  Trees - Structure and Function. 14 1-9
    PubMedGoogle Scholar
  • 26 Wang,  Y. P., and Jarvis,  P. G.. (1988);  Mean leaf angles for the ellipsoidal inclination angle distribution.  Agricultural and Forest Meteorology. 43 319-321
    CrossrefPubMedGoogle Scholar

K. Zobel

Department of Botany and Ecology
Tartu University

40 Lai St.
51005 Tartu
Estonia

Email: kzobel@ut.ee

Section Editor: R. Aerts

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