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Modeling germination and shoot-radicle elongation of Ambrosia artemisiifolia

Published online by Cambridge University Press:  12 June 2017

Anil Shrestha ,
Erivelton S. Roman ,
A. Gordon Thomas  and
Clarence J. Swanton
Anil Shrestha
Affiliation:
Department of Plant Agriculture, University of Guelph, Guelph, Ontario, Canada N1G 2W1
Erivelton S. Roman
Affiliation:
Department of Plant Agriculture, University of Guelph, Guelph, Ontario, Canada N1G 2W1
A. Gordon Thomas
Affiliation:
Agriculture and Agri-Food Canada, Saskatoon Research Centre, Saskatoon, Canada S7N 0X2
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Abstract

Laboratory studies were conducted to describe germination and seedling elongation of Ambrosia artemisiifolia L. (common ragweed) seed. The germination process was tested for the interaction of temperature and water potential across eight thermo-periods (7.5, 12.5, 17.5, 22.5, 27.5, 32.5, 37.5, and 42.5 C) and 12 water potentials (0, −0.03, −0.06, −0.1, −0.2, −0.4, −0.6, −0.9, −1.2, −1.5, −1.8, and −2.1 mPa). The rate of seedling shoot and radicle elongation was described as a function of temperature and tested for eight day: night temperature treatments (10: 5, 15 : 10, 20 : 15, 25 : 20, 30 : 25, 35 : 30, 40 : 35, and 45 : 40 C). The rate of germination was mathematically modeled by a Weibull function. Probit analysis was used to determine the cardinal temperatures (base, optimum, and maximum) and base water potential (αb ). The base temperature (T b), optimum temperature (T opt), maximum temperature (T max), and αb for A. artemisiifolia germination were estimated as 3.6, 30.9, and 40 C and −0.8 mPa, respectively. The rates of shoot and radicle elongation were described by regression models. The T b , T opt, and T max for shoot and radicle elongation were estimated as 7.7 and 5.1, 29.5 and 31.4, and 43.0 and 44.3 C, respectively. A mathematical model describing the process of A. artemisiifolia seed germination in terms of hydrothermal time (θHT) was derived. The θHT model described the phenology of A. artemisiifolia seed germination using a single curve generated from the relationship of temperature and water potential. This model can help in predicting germination and emergence of A. artemisiifolia under field conditions.

Keywords

Ambrosia artemisiifolia L. AMBEL, common ragweedBase temperaturebase water potentialcardinal temperaturesWeibull functionhydrothermal timeecophysiological modelsintegrated weed managementAMBEL
Type
Weed Biology and Ecology
Information
Weed Science , Volume 47 , Issue 5 , October 1999 , pp. 557 - 562
Copyright
Copyright © 1999 by the Weed Science Society of America 

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References

Literature Cited

Addae, P. C. and Pearson, C. J. 1992. Thermal requirements for germination and seedling growth of wheat. Aust. J. Agric. Res. 43:585594.Google Scholar
Bahler, C., Hill, R. R., and Byers, R. A. 1989. Comparison of logistic and Weibull functions: the effect of temperature on cumulative germination of alfalfa. Crop Sci. 29:142146.Google Scholar
Bethea, R. M., Duran, S., and Boullion, T. L. 1995. Statistical Methods for Engineers and Scientists. New York: Marcel Dekker, pp. 305362.Google Scholar
Bradford, K. J. 1990. A water relations analysis of seed germination rates. Plant Physiol. 94:840849.Google Scholar
Carberry, P. S. and Campbell, L. C. 1989. Temperature parameters useful for modeling the germination and emergence of pearl millet. Crop Sci. 29:220223.CrossRefGoogle Scholar
Chikoye, D., Weise, S. F., and Swanton, C. J. 1995. Influence of common ragweed (Ambrosia artemisiifolia) time of emergence and density on white bean (Phaseolus vulgaris). Weed Sci. 43:375380.CrossRefGoogle Scholar
Christensen, M., Meyer, S. E., and Allen, P. S. 1996. A hydrothermal time model of seed after-ripening in Bromus tectorum L. Seed Sci. Res. 6:155163.CrossRefGoogle Scholar
Collet, D. 1994. Modelling Survival Data in Medical Research. New York: Chapman and Hall, pp. 7178.Google Scholar
Dahal, P. and Bradford, K. J. 1994. Hydrothermal time analysis on tomato seed germination at suboptimal temperature and reduced water potential. Seed Sci. Res. 4:7180.CrossRefGoogle Scholar
Dracup, M., Davis, C., and Tapscott, H. 1993. Temperature and water requirements for germination and emergence of lupin. Aust. J. Exp. Agric. 33:759766.Google Scholar
Dumur, D., Pilbeam, C. J., and Craigon, J. 1990. Use of the Weibull function to calculate cardinal temperatures in faba bean. J. Exp. Bot. 41:14231430.Google Scholar
Ellis, R. H. and Barrett, S. 1994. Alternating temperatures and rate of seed germination in lentil. Ann. Bot. 74:519524.Google Scholar
Ellis, R. H., Covell, S., Roberts, E. H., and Summerfield, R. J. 1986. The influence of temperature on seed germination rate in grain legumes. II. Intraspecific variation in chickpea (Cicer arietinum L.) at constant temperatures. J. Exp. Bot. 37:15031515.Google Scholar
Ellis, R. H., Simon, G., and Covell, S. 1987. The influence of temperature on seed germination rate in grain legumes. III. A comparative of five faba bean genotypes at constant temperatures using a new screening method. J. Exp. Bot. 38:10331043.CrossRefGoogle Scholar
Fernandez-Quintanilla, C., Andujar, J. L., and Appleby, A. P. 1990. Characterization of the germination and emergence response to temperature and soil moisture of Avena fatua and A. sterilis . Weed Res. 30:289295.Google Scholar
Frick, B. and Thomas, A. G. 1992. Weed surveys in different tillage systems in southwestern Ontario field crops. Can. J. Plant Sci. 72:13371347.Google Scholar
Fyfield, T. P. and Gregory, P. J. 1989. Effects of temperature and water potential on germination, radicle elongation and emergence of mungbean. J. Exp. Bot. 40:667674.Google Scholar
Garcia-Huidobro, J., Monteith, J. L., and Squire, G. R. 1982. Time, temperature and germination of pearl millet (Pennisetum typhoides S & H.). I. Constant temperature. J. Exp. Bot. 33:288296.CrossRefGoogle Scholar
Gummerson, R. J. 1986. The effect of constant temperature and osmotic potentials on the germination of sugar beet. J. Exp. Bot. 37:729741.Google Scholar
Hardegree, S. P. and Emmerich, W. E. 1994. Seed germination response to polyethylene glycol solution depth. Seed Sci. Technol. 22:17.Google Scholar
McLaughlin, N. B., Bowes, G. R., Thomas, A. G., Dyck, F. B., Lindsay, T. M., and Wise, R. F. 1985. A new design for a seed germinator With 100 independently temperature controlled cells. Weed Res. 25:161173.Google Scholar
Michel, B. E. 1983. Evaluation of water potentials of solutions of polyethylene glycol 8000 both in the absence and presence of other solutes. Plant Physiol. 72:6670.Google Scholar
Ni, B. R. and Bradford, K. J. 1992. Quantitative models characterizing seed germination responses to abcissic acid and osmoticum, Plant Physiol. 98:10571068.Google Scholar
Oryokot, J.O.E., Murphy, S. D., Thomas, A. G., and Swanton, C. J. 1997. Temperature- and moisture-dependent models of seed germination and shoot elongation in green and redroot pigweed (Amaranthus powellii, A. retroflexus). Weed Sci. 45:488496.CrossRefGoogle Scholar
Ralston, M. L. and Jennrich, R. I. 1978. DUD, a derivative-free algorithm for non-linear least squares. Technometrics 1:714.CrossRefGoogle Scholar
Raynal, D. J. and Bazzaz, F. A. 1973. Establishment of early successional plant populations on forest and prairie soil. Ecology 54:13351341.Google Scholar
Roman, E. S., Thomas, A. G., Murphy, S. D. and Swanton, C. J. 1999. Modeling germination and seedling elongation of common lambsquarters (Chenopodium album L.). Weed Sci. 47:149155.CrossRefGoogle Scholar
Samimy, C. and Khan, A. A. 1983. Effect of field application of growth regulators on secondary dormancy of common ragweed (Ambrosia artemisiifolia) seeds. Weed Sci. 31:299303.Google Scholar
[SAS] Statistical Analysis Systems. 1990. SAS User's Guide. Version 6.06. Cary, NC: Statistical Analysis Systems Institute.Google Scholar
Swanton, C. J. and Murphy, S. D. 1996. Weed science beyond the weeds: the role of integrated weed management (IWM) in agroecosystem health. Weed Sci. 44:437445.Google Scholar
Thomas, A. G., Lefkovitch, L. P., Woo, S. L., Bowes, G. G., and Peschken, D. P. 1994. Effect of temperature on germination within and between diploid and tetraploid populations of Matricaria perforata Merat. Weed Res. 34:187198.Google Scholar
Tollenaar, M., Daynard, T. B., and Hunter, R. B. 1979. Effect of temperature on rate of leaf appearance and flowering date in maize. Crop Sci. 19:363366.Google Scholar
Warrington, I. J. and Kanemasu, E. T. 1983. Corn growth response to temperature and photoperiod. I. Seedling emergence, tassel initiation and anthesis. Agron. J. 75:749754.Google Scholar
Weaver, S. E., Tan, C. S., and Brain, P. 1988. Effect of temperature and soil moisture on time of emergence of tomatoes and four weed species. Can. J. Plant Sci. 68:877886.Google Scholar
Wheeler, T. R. and Ellis, R. H. 1991. Seed quality, cotyledon elongation at suboptimal temperatures, and the yield of onion. Seed Sci. Res. 1. 5767.Google Scholar
Willemsen, R. W. 1975. Effect of stratification temperature and germination temperature on germination and the induction of secondary dormancy in common ragweed seeds. Am. J. Bot. 62:15.Google Scholar