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Germination Characteristics of the Dimorphic Seeds of Spreading Orach (Atriplex patula)

Published online by Cambridge University Press:  20 January 2017

Robert E. Nurse*
Affiliation:
Agriculture and Agri-Food Canada, Greenhouse and Processing Crops Research Centre, 2585 County Road 20, Harrow, ON, N0R 1G0 Canada
W. Daniel Reynolds
Affiliation:
Agriculture and Agri-Food Canada, Greenhouse and Processing Crops Research Centre, 2585 County Road 20, Harrow, ON, N0R 1G0 Canada
Colleen Doucet
Affiliation:
Agriculture and Agri-Food Canada, Greenhouse and Processing Crops Research Centre, 2585 County Road 20, Harrow, ON, N0R 1G0 Canada
Susan E. Weaver
Affiliation:
Agriculture and Agri-Food Canada, Greenhouse and Processing Crops Research Centre, 2585 County Road 20, Harrow, ON, N0R 1G0 Canada
*
Corresponding author's E-mail: [email protected]

Abstract

Spreading orach is an annual weed that colonizes roadsides, field edges, and increasingly, no-till agricultural fields. It produces dimorphic seeds with different levels of physiological dormancy, but little is known about the germination ecology of the two seed types. Field and controlled-environment studies were conducted to determine seed responses to light and stratification, the pattern of seedling emergence in the field, and the effect of soil water content on the length of cold stratification required to break dormancy for each seed type. The large, brown seeds have three times the mass of the smaller, black seeds, primarily because of a larger embryo, but have a thinner seed coat. Germination of brown and black seeds in petri dishes was 98 and 90%, respectively, after stratification for 3 mo at 5 C, whereas germination of unstratified seeds was 19 and 12%, respectively. Light stimulated germination of both stratified and unstratified black seeds but did not increase germination in stratified brown seeds. Up to 40% of brown seeds germinated in situ during stratification, compared with only 2% for black seeds. Germination in petri dishes and emergence in the field were more rapid for brown seeds than for black seeds. Maximum germination of black seeds occurred after stratification for 2 or 3 mo at 5 C on soil that was waterlogged (pore-water matric potential, ψ = 0 kPa), wet (ψ = −0.38 kPa), or at field capacity (ψ = −10 kPa). For shorter periods of stratification, total germination and germination rate of black seeds declined as soil water content decreased from waterlogged to dry (ψ = −500 kPa). Seed dimorphism in spreading orach may provide a mechanism to enhance survival in uncertain or variable habitats such as disturbed agricultural fields.

Type
Weed Biology and Ecology
Copyright
Copyright © Weed Science Society of America 

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References

Literature Cited

Ansley, R. J. and Abernethy, R. H. 1985. Environmental factors influencing Gardner saltbrush seed dormancy alleviation. J. Range Manag. 38:331335.CrossRefGoogle Scholar
Bartlett, M. S. 1947. The use of transformations. Biometrics. 3:3952.Google Scholar
Baskin, C. C. and Baskin, J. M. 1998. Seeds: Ecology, Biogeography, and Evolution of Dormancy and Germination. San Diego Academic. 666. p.Google Scholar
Bassett, I. J. and Munro, D. B. 1987. The biology of Canadian weeds, 79: Atriplex patula L., A. prostrata Boucher ex DC., and A. rosea L. Can. J. Plant Sci. 67:10691082.Google Scholar
Batlla, D. and Benech-Arnold, R. L. 2004. A predictive model for dormancy loss in Polygonum aviculare L. seeds based on changes in population hydrotime parameters. Seed Sci. Res. 14:277286.Google Scholar
Batlla, D. and Benech-Arnold, R. L. 2006. The role of fluctuations in soil water content on the regulation of dormancy changes in buried seeds of Polygonum aviculare L. Seed Sci. Res. 16:4759.CrossRefGoogle Scholar
Bewley, J. D. and Black, M. 1994. Seeds: Physiology of Development and Germination. 2nd ed. New York Plenum. 445. p.CrossRefGoogle Scholar
Bradford, K. J. 2002. Applications of hydrothermal time to quantifying and modelling seed germination and dormancy. Weed Sci. 50:248260.Google Scholar
Carter, C. T., Brown, L. S., and Ungar, I. A. 2003. Effect of temperature regimes on germination of dimorphic seeds of Atriplex prostrata . Biol. Plant. (Prague) 47:269272.Google Scholar
Crawford, R. M. M. 1993. Anoxia tolerance in germinating seeds, rhizomes, stolons and tubers. Pages 4145. in Hendry, G. A. F. and Grime, J. P. Methods in Comparative Plant Ecology. London Chapman & Hill.Google Scholar
Drury, C. F., Tan, C. S., Welacky, T. W., Oloya, T. O., Hamill, A. S., and Weaver, S. E. 1999. Red clover and tillage influences soil temperature, moisture and corn emergence. Agron. J. 91:101108.CrossRefGoogle Scholar
Dwyer, L. M., Ma, B. L., deJong, R., and Tollenaar, M. 2000. Assessing corn seedbed conditions for emergence. Can. J. Soil Sci. 80:5361.CrossRefGoogle Scholar
Etherington, J. R. and Evans, C. E. 1986. Technique for ecological studies of seed germination in relation to soil water potential. Plant Soil. 95:285288.Google Scholar
Fortin, M. C. and Pierce, F. J. 1991. Timing and nature of mulch retardation of corn vegetative development. Agron. J. 83:258263.CrossRefGoogle Scholar
Galinato, M. I. and Van der Valk, A. G. 1986. Seed germination traits of annuals and emergents recruited during drawdowns in the Delta Marsh, Manitoba, Canada. Aquat. Bot. 26:89102.Google Scholar
Garvin, S. C. and Meyer, S. E. 2003. Multiple mechanisms for seed dormancy regulation in shadscale (Atriplex confertifolia: Chenopodiaceae). Can. J. Bot. 81:601610.Google Scholar
Gosling, P. G., Samuel, Y., and Peace, A. 2003. The effect of moisture content and prechill duration on dormancy breakage of Douglas fir seeds (Pseudotsuga menziesii var. menziesii [Mirb.] Franco). Seed Sci. Res. 13:239246.Google Scholar
Maganti, D. M. 2001. Effects of soil compaction and soil moisture on growth of Atriplex patula and Chenopodium album . London, UK University of Western Ontario. . 106. p.Google Scholar
Mandák, B. and Pyšek, P. 2001. The effects of light quality, nitrate concentration and presence of bracteoles on germination of different fruit types in the heterocarpous Atriplex sagittata . J. Ecol. 89:149158.Google Scholar
Meyer, S. E., Carlson, S. L., and Garvin, S. C. 1998. Seed germination regulation and field seed bank carryover in shadscale (Atriplex confertifolia: Chenopodiaceae). J. Arid Environ. 38:255267.CrossRefGoogle Scholar
Nobs, M. A. and Hagar, W. G. 1976. Analysis of germination and flowering rates of dimorphic seeds from Atriplex hortensis . Pages 859867. in. Annual report of the Department of Plant Biology. Stanford, CA Carnegie Institution of Washington.Google Scholar
Reynolds, W. D. 2007. Saturated hydraulic properties: laboratory methods. Pages 10131024. in. M. R. Carter and E. G. Gregorich, eds. Soil Sampling and Methods of Analysis. Canadian Society of Soil Science. Boca Raton, FL CRC.Google Scholar
Reynolds, W. D. and Topp, G. C. 2007. Soil water desorption and imbibition: tension and pressure techniques. Pages 981997. in. M. R. Carter and E. G. Gregorich, eds. Soil Sampling and Methods of Analysis. Canadian Society of Soil Science. Boca Raton, FL CRC.Google Scholar
Roberts, H. A. and Neilson, J. E. 1980. Seed survival and periodicity of seedling emergence in some species of Atriplex, Chenopodium, Polygonum, and Rumex . Ann. Appl. Biol. 94:111120.CrossRefGoogle Scholar
Ungar, I. A. 1971. Atriplex patula var. hastata seed dimorphism. Rhodora. 73:548551.Google Scholar
Webster, T. M., Cardina, J., and Norquay, H. M. 1998. Tillage and seed depth effects on velvetleaf (Abutilon theophrasti) emergence. Weed Sci. 46:7682.Google Scholar