Hostname: page-component-78c5997874-m6dg7 Total loading time: 0 Render date: 2024-11-07T17:29:45.031Z Has data issue: false hasContentIssue false
  • English
  • Français

Seed germination and seedling growth response of selected weedy species to ultraviolet-B radiation

Published online by Cambridge University Press:  20 January 2017

Qiujie Dai  and
Mahesh K. Upadhyaya
Qiujie Dai
Affiliation:
Faculty of Agricultural Sciences, University of British Columbia, Vancouver, BC V6T 1Z4, Canada
Get access Rights & Permissions [Opens in a new window]

Abstract

Ultraviolet-B (UVB, 280 to 320 nm) radiation levels reaching the earth's surface are increasing because of depletion of the stratospheric ozone layer. Adverse biological effects of this harmful radiation are a serious concern. The effects of UVB radiation on spotted chickweed, dandelion, downy brome, green foxtail, redstem filaree, and common catsear seed germination, shoot and radicle elongation, and seedling growth and development in a UVB-free environment after exposure to UVB were investigated in a greenhouse study. UVB radiation (4, 7, or 11 kJ m−2 d−1) did not influence seed germination of any species except downy brome. Postgermination UVB exposure (8 h d−1, for 10 d), however, inhibited radicle elongation in all species, except in spotted catsear. Shoot elongation was also inhibited in some species but to a lesser extent than radicle elongation. A significant inhibition by UVB treatment (11 kJ m−2 d−1) of root and shoot biomass, leaf area, and leaf number was observed in some species after transfer of UVB-treated seedlings to a UVB-free environment for 3 wk. The inhibition of postgermination shoot and radicle elongation by UVB radiation, the continuation of growth inhibition after transfer of the treated seedlings to a UVB-free environment, and the differential responses of weedy species could have significant implications for their ability to compete with each other and with associated crops in a UVB-enriched environment that is likely as the stratospheric ozone layer gets depleted.

Keywords

Common chickweed, Stellaria media (L.) Vill. STEMEdandelion, Taraxacum officinale Weber in Wiggers TAROFdowny brome, Bromus tectorum L. BROTEgreen foxtail, Setaria viridis (L.) Beauv. SETVIredstem filaree (stork's-bill in Canada), Erodium cicutarium (L.) L'Her. ex Ait. EROCIspotted catsear, Hypochoeris radicata L. HRYRAUltraviolet radiationultaviolet Bseed germinationseedling growth
Type
Research Article
Information
Weed Science , Volume 50 , Issue 5 , October 2002 , pp. 611 - 615
Copyright
Copyright © Weed Science Society of America 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Literature Cited

Allen, D. J., Nogués, S., and Baker, N. R. 1998. Ozone depletion and increased UV-B radiation: is there a real threat to photosynthesis? J. Exp. Bot. 49:17751788.Google Scholar
Ambler, J. E., Krizek, D. T., and Semeniuk, P. 1975. Influence of UV-B radiation on early seedling growth and translocation of 65Zn from cotyledons in cotton. Physiol. Plant 34:177181.Google Scholar
Barnes, P. W., Flint, S. D., and Caldwell, M. M. 1990. Morphological responses of crop and weed species of different growth forms to ultraviolet-B radiation. Am. J. Bot. 77:13541360.Google Scholar
Björn, L. O. and Murphy, T. M. 1985. Computer calculation of solar ultraviolet radiation at ground level. Physiol. Veg. 23:555561.Google Scholar
Caldwell, M. M. 1971. Solar UV radiation and the growth and development of higher plants. Pages 131177 In Giese, A. C., ed. Photophysiology. Volume 6. New York: Academic Press.CrossRefGoogle Scholar
Frankland, B. 1981. Germination in shade. Pages 187204 In Smith, H., ed. Plants and the Daylight Spectrum. New York: Academic Press.Google Scholar
Furness, N. H., Upadhyaya, M. K., and Ormrod, D. P. 1999. Seedling growth and leaf surface morphological responses of three rangeland weeds to ultraviolet-B radiation. Weed Sci. 47:427434.Google Scholar
Greene, O. 1995. Emerging challenges for the Montreal Protocol. Globe 27:56.Google Scholar
Jansen, M.A.K., Gaba, V., and Greenberg, B. M. 1998. Higher plants and UV-B radiation: balancing damage, repair and acclimation. Trends Plant Sci. 3:131135.Google Scholar
Krizek, D. T. 1975. Influence of ultraviolet radiation on germination and early seedling growth. Physiol. Plant 34:182186.Google Scholar
Krupa, S. V. and Kickert, R. N. 1989. The greenhouse effect: impacts of ultraviolet-B (UV-B) radiation, carbon dioxide (CO2), and ozone (O3) on vegetation. Environ. Pollut. 61:263393.Google Scholar
Madronich, S., McKenzie, R. L., Caldwell, M. M., and Björn, L. O. 1995. Changes in ultraviolet radiation reaching the earth's surface. Ambio 24:143152.Google Scholar
Nogués, S., Allen, D. J., Morison, J.I.L., and Baker, N. R. 1998. Ultraviolet-B radiation effects on water relation, leaf development, and photosynthesis in droughted pea plants. Plant Physiol. 117:173181.Google Scholar
Nolan, D. G. and Upadhyaya, M. K. 1988. Primary dormancy in Centaurea diffusa and Centaurea maculosa . Can. J. Plant Sci. 68:775783.CrossRefGoogle Scholar
Ormrod, D. P., Schmidt, A. M., and Livingston, N. J. 1997. Effect of UV-B radiation on the shoot dry matter production and stable carbon isotope composition of two Arabidopsis thaliana genotypes. Physiol. Plant. 101:497502.Google Scholar
Pal, M., Sharma, A., and Sengupta, U. K. 1995. Effect of UV-B radiation on germination and seedling growth in mungbean (Vigna radiata L. Wilczek). Indian J. Plant Physiol. 38:293297.Google Scholar
Qi, M. Q., Upadhyaya, M. K., and Turkington, R. A. 1996. Dynamics of seed banks and survivorship of meadow salsify (Tragopogon pratensis) populations. Weed Sci. 44:100108.Google Scholar
Roberts, E. H., ed. 1972. Viability of Seeds. London: Chapman and Hall. pp. 321359.CrossRefGoogle Scholar
Runeckles, V. C. and Krupa, S. V. 1994. The impact of UV-B radiation and ozone on terrestrial vegetation. Environ. Pollut. 83:191213.Google Scholar
Sauer, J. and Struik, G. 1964. A possible ecological relation between soil disturbance, light-flash and seed germination. Ecology 45:884886.Google Scholar
Searles, P. S., Caldwell, M. M., and Winter, K. 1995. The response of five tropical dicotyledon species to solar ultraviolet-B radiation. Am. J. Bot. 82:445453.Google Scholar
Shindell, D. T., Rind, D., and Lonergan, P. 1998. Increased polar stratospheric ozone losses and delayed eventual recovery owing to increasing greenhouse-gas concentration. Nature 292:589592.Google Scholar
Taylorson, R. B. 1970. Changes in dormancy and viability of weed seeds in soils. Weed Sci. 18:265269.Google Scholar
Teramura, A. H. 1983. Effect of ultraviolet-B radiation on the growth and yield of crop plants. Physiol. Plant. 58:415427.Google Scholar
Tosserams, M., Bolink, E., and Rozema, J. 1997. The effect of enhanced ultraviolet-B radiation on germination and seedling development of plant species occurring in a dune grassland ecosystem. Plant Ecol. 128:139147.Google Scholar
Wagne, C. 1966. Effect of UV light on lettuce seed germination and on the unfolding of grass leaves. Physiol. Plant. 19:128133.CrossRefGoogle Scholar
Wesson, G. and Wareing, P. F. 1967. Light requirements of buried seeds. Nature 213:600601.Google Scholar
Wesson, G. and Wareing, P. F. 1969. The role of light in the germination of naturally occurring populations of buried weed seeds. J. Exp. Bot. 20:402413.Google Scholar
WMO. 1995. Scientific assessment of ozone depletion. 1994. World Meteorological Organization, Global Ozone Research and Monitoring Project. Report No. 37. Geneva: World Meteorological Organization.Google Scholar
Wooley, J. T. and Stoller, E. W. 1978. Light penetration and light-induced seed germination in soil. Plant Physiol. 61:597600.Google Scholar