Access the full text.
Sign up today, get DeepDyve free for 14 days.
Loading next page...
/lp/wiley/ultraviolet-b-and-visible-light-penetration-into-needles-of-two-znPGmsKpwQ
References (33)
-
M. Caldwell (1968)
Solar Ultraviolet Radiation as an Ecological Factor for Alpine PlantsEcological Monographs, 38
-
M. Caldwell, R. Robberecht, W. Billings (1980)
A STEEP LATITUDINAL GRADIENT OF SOLAR ULTRAVIOLET-B RADIATION IN THE ARCTIC-ALPINE LIFE ZONE'Ecology, 61
-
Robberecht Robberecht, Caldwell Caldwell (1983)
Protective mechanisms and acclimation to solar ultraviolet‐B radiation in Oenothera striciaPlant, Cell and Environment, 6
-
E. Wellmann (1975)
UV dose‐dependent induction of enzymes related to flavonoid biosynthesis in cell suspension cultures of parsleyFEBS Letters, 51
-
M. Tevini, A. Teramura (1989)
UV‐B EFFECTS ON TERRESTRIAL PLANTSPhotochemistry and Photobiology, 50
-
R. Robberecht, M. Caldwell, W. Billings (1980)
Leaf Ultraviolet Optical Properties Along a Latitudinal Gradient in the Arctic‐Alpine Life ZoneEcology, 61
-
M. Tevini, J. Braun, G. Fieser (1991)
THE PROTECTIVE FUNCTION OF THE EPIDERMAL LAYER OF RYE SEEDLINGS AGAINST ULTRAVIOLET‐B RADIATIONPhotochemistry and Photobiology, 53
-
T. Vogelmann, J. Bornman, S. Josserand (1989)
Photosynthetic Light Gradients and Spectral Regime within Leaves of Medicago sativaPhilosophical Transactions of the Royal Society B, 323
-
E. Wollenweber (1982)
Flavones and FlavonolsChemInform, 26
-
R. Kerr (1991)
Ozone destruction worsens.Science, 252 5003
-
DeLucia DeLucia, Day Day, Vogelmann Vogelmann (1991)
Ultraviolet‐B radiation and the Rocky Mountain environment: measurement of incident light and penetration into foliageCurrent Topics in Plant Biochemistry and Physiology (University of Missouri-Columbia), 10
-
Bornman Bornman (1989)
Target sites of UV‐B radiation in photosynthesis of higher plantsJournal of Photochemistry and Photobiology, 4
-
S. Flint, P. Jordan, M. Caldwell (1985)
PLANT PROTECTIVE RESPONSE TO ENHANCED UV‐B RADIATION UNDER FIELD CONDITIONS: LEAF OPTICAL PROPERTIES and PHOTOSYNTHESISPhotochemistry and Photobiology, 41
-
R. Robberecht, M. Caldwell (1981)
Protective mechanisms and acclimation to solar ultraviolet-b radiation in oenothera stricta. Final report -
J. Clark, G. Lister (1975)
Photosynthetic Action Spectra of Trees: II. The Relationship of Cuticle Structure to the Visible and Ultraviolet Spectral Properties of Needles from Four Coniferous Species.Plant physiology, 55 2
-
Day Day, DeLucia DeLucia, Smith Smith (1989)
Influence of cold soil and snowcover on photosynthesis and leaf conductance in two Rocky Mountain conifersOecologia, 80
-
J. Bornman (1989)
New trends in photobiology: Target sites of UV-B radiation in photosynthesis of higher plantsJournal of Photochemistry and Photobiology B-biology, 4
-
J. Bornman, T. Vogelmann (1988)
Penetration of blue nad UV radiation measured by fiber optics in spruce and fir needlesPhysiologia Plantarum, 72
-
William Sisson, Martyn Caldwell (1976)
Photosynthesis, Dark Respiration, and Growth of Rumex patientia L. Exposed to Ultraviolet Irradiance (288 to 315 Nanometers) Simulating a Reduced Atmospheric Ozone Column.Plant physiology, 58 4
-
J. Sullivan, A. Teramura (1988)
EFFECTS OF ULTRAVIOLET‐B IRRADIATION ON SEEDLING GROWTH IN THE PINACEAEAmerican Journal of Botany, 75
-
Pukacki Pukacki, Giertych Giertych (1982)
Seasonal changes in light transmission by bud scales of spruce and pinePlanta, 154
-
M. Caldwell, A. Teramura, M. Tevini (1989)
The changing solar ultraviolet climate and the ecological consequences for higher plants.Trends in ecology & evolution, 4 12
-
W. Sisson, M. Caldwell (1977)
Atmospheric Ozone Depletion: Reduction of Photosynthesis and Growth of a Sensitive Higher Plant Exposed to Enhanced u.v.-B RadiationJournal of Experimental Botany, 28
-
N. Murali, A. Teramura (1986)
Intraspecific differences in Cucumis sativus sensitivity to ultraviolet‐B radiationPhysiologia Plantarum, 68
-
M. Caldwell, R. Robberecht, S. Flint (1983)
Internal filters: Prospects for UV‐acclimation in higher plantsPhysiologia Plantarum, 58
-
Vogelmann Vogelmann, Martin Martin, Chen Chen, Buttry Buttry (1991)
Fibre optic microprobes and measurements of the light microenvironment within plant tissuesAdvances in Botanical Research, 18
-
T. Vogelmann, L. Björn (1984)
Measurement of light gradients and spectral regime in plant-tissue with a fiber optic probePhysiologia Plantarum, 60
-
Day Day, Vogelmann Vogelmann, DeLucia DeLucia (1992)
Are some plant life forms more effective than others in screening out ultraviolet‐B radiationOecologia, 83
-
Robberecht Robberecht, Caldwell Caldwell (1978)
Leaf epidermal transmittance of ultraviolet radiation and its implications for plant sensitivity to ultraviolet‐radiation induced injuryOecologia, 32
-
M. Blumthaler, W. Ambach (1990)
Indication of increasing solar ultraviolet-B radiation flux in alpine regions.Science, 248 4952
-
J. McClure (1975)
Physiology and Functions of Flavonoids -
H. Gausman, R. Rodríguez, D. Escobar (1975)
Ultraviolet Radiation Reflectance, Transmittance, and Absorptance by Plant Leaf Epidermises1Agronomy Journal, 67
-
M. Caldwell, R. Robberecht, R. Nowak, W. Billings (1982)
DIFFERENTIAL PHOTOSYNTHETIC INHIBITION BY ULTRAVIOLET RADIATION IN SPECIES FROM THE ARCTIC-ALPINE LIFE ZONEArctic and alpine research, 14
- Publisher
- Wiley
- Copyright
- Copyright © 1992 Wiley Subscription Services, Inc., A Wiley Company
- ISSN
- 0140-7791
- eISSN
- 1365-3040
- DOI
- 10.1111/j.1365-3040.1992.tb01024.x
- Publisher site
- See Article on Publisher Site
Abstract
ABSTRACT The depth of penetration of Ultraviolet‐B (UV‐B, 300 and 320 nm) and visible (680 nm) light was measured in foliage of Abies lasiocarpa and Picea engelmannii using a fibre‐optic microprobe. Measurements were made on foliage at four times during development: needles were sampled from within expanding buds (in bud); within 72 h of emergence from the bud scales (emergent); from elongating branches (elongating); and from foliage that emerged the previous summer (mature). Light attenuation in pre‐emergent needles of both species was steep and showed strong wavelength dependence. Short wavelength 300‐nm light was attenuated strongly in the developing epidermal layer, but a significant proportion of this potentially damaging UV‐B radiation penetrated into the mesophyll. For A. lasiocarpa and P. engelmannii, 99% attenuation of 300‐nm light occurred at 51 and 96 μm, respectively, well within the mesophyll. At this stage, however, the bud scales were opaque to light below 400nm. As the epidermal cell walls and cuticle continued to develop and chlorophyll accumulated following emergence from the bud scales, light attenuation, particularly of UV‐B radiation, increased. Although no UV‐B is transmitted through the epidermis‐hypodermis of mature needles, small but measurable quantities of 300‐ and 320‐nm light were measured in the photosynthetic mesophyll of post‐emergent and elongating needles. Thus, shortly after emergence from the bud scales in mid‐June to mid‐July, when incident UV doses are highest, absorption of UV‐B radiation by potentially sensitive chromophores in the mesophyll may disrupt physiological and developmental processes in these species. Soluble UV‐absorbing pigments accumulated during needle maturation for P. engelmannii but not A. lasiocarpa, suggesting that, for A. lasiocarpa at least, the development of effective UV screening properties in the epidermis may not be related to the induction of soluble flavonoids.
Journal
Plant Cell & Environment – Wiley
Published: Oct 1, 1992