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Received: 2004-08-09

Revision Accepted: 2004-09-20

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Journal of Zhejiang University SCIENCE B 2005 Vol.6 No.2 P.119~124

http://doi.org/10.1631/jzus.2005.B0119


Light quality and temperature effects on antirrhinum growth and development


Author(s):  KHATTAK Abdul Mateen, PEARSON Simon

Affiliation(s):  Department of Horticulture, NWFP Agricultural University, Peshawar, Pakistan; more

Corresponding email(s):   amkhatta@brain.net.pk, Simon.Pearson@marks-and-spencer.com

Key Words:  Antirrhinum, Light quality, Temperature, Spectral filters, Photoreceptors


KHATTAK Abdul Mateen, PEARSON Simon. Light quality and temperature effects on antirrhinum growth and development[J]. Journal of Zhejiang University Science B, 2005, 6(2): 119~124.

@article{title="Light quality and temperature effects on antirrhinum growth and development",
author="KHATTAK Abdul Mateen, PEARSON Simon",
journal="Journal of Zhejiang University Science B",
volume="6",
number="2",
pages="119~124",
year="2005",
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doi="10.1631/jzus.2005.B0119"
}

%0 Journal Article
%T Light quality and temperature effects on antirrhinum growth and development
%A KHATTAK Abdul Mateen
%A PEARSON Simon
%J Journal of Zhejiang University SCIENCE B
%V 6
%N 2
%P 119~124
%@ 1673-1581
%D 2005
%I Zhejiang University Press & Springer
%DOI 10.1631/jzus.2005.B0119

TY - JOUR
T1 - Light quality and temperature effects on antirrhinum growth and development
A1 - KHATTAK Abdul Mateen
A1 - PEARSON Simon
J0 - Journal of Zhejiang University Science B
VL - 6
IS - 2
SP - 119
EP - 124
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Y1 - 2005
PB - Zhejiang University Press & Springer
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DOI - 10.1631/jzus.2005.B0119


Abstract: 
An experiment was carried out to examine the effects of light quality on the growth and development of antirrhinum under three different temperatures 19 °C, 24 °C and 27 °C in glasshouses. Five different colour filters (i.e. ‘Red absorbing’, ‘Blue absorbing’, ‘Blue and Red absorbing’ and two ‘partially Blue absorbing’ materials) were tested, with one clear polythene as a control. Plant height, internode length and leaf area were significantly affected by the spectral filters as well as the temperature. Analysis of color filter’s effect on presumed photoreceptors to exist indicated that antirrhinum plant height was regulated by the action of a blue acting photoreceptor (BAP) and not the phytochrome. There was no evidence for an effect of phytochrome or BAP on time to flowering, however, increasing temperature levels effectively decreased the time to flowering. To predict the effects of different spectral qualities and temperature, simple models were created from data on plant height, internode length and time to flowering. These models were then applied to simulate the potential benefits of spectral filters and temperature in manipulation of growth control and flowering in antirrhinum.

Darkslateblue:Affiliate; Royal Blue:Author; Turquoise:Article

Reference

[1] Carr-Smith, H.D., Johnson, C.B., Thomas, B., 1989. Action spectrum for the effect of day-extensions on flowering and apex elongation in green, light-grown wheat (Triticum aestivum L.). Plants, 179:428-432.

[2] Casal, J.J., 1994. Stem extension responses to blue light require Pfr in tomato seedlings but are not reduced by low phytochrome levels of the aurea mutant. Physioligia Plantaru, 91:263-267.

[3] Erwin, J.E., Heins, R.D., Karlsson, M.G., 1989. Thermomorphogenesis in Lilium longiflorum. Amer. J. Bot., 76:47-52.

[4] Hayward, P.M., 1984. Determination of Phytochrome Parameters from Radiation Measurements. In: Smith, H., Holmes, M.G. (Eds.), Techniques in Photomorphogenesis. Academic Press, London, p.159-173.

[5] Heins, R.D., Erwin, J.E., 1990. Understanding and applying D.I.F. Greenhouse Grower, 8(20):73-78.

[6] Karlsson, M.G., Heins, R.D., Erwin, J.E., Berghage, R.D., Carlson, W.H., Biernbaum, J.A., 1989. Temperature and photosynthetic photon flux influence chrysanthemum shoot development and flower initiation under short-day conditions. J. Amer. Soc. Hort. Sci., 114(1):158-163.

[7] Khattak, A.M., Pearson, S., 1997. The effects of light quality and temperature on the growth and development of chrysanthemums cvs. Bright golden Ann and Snowdon. Acta Horti, 435:113-122.

[8] McMahon, M.J., Kelly, J.W., 1990. Influence of spectral filters on height, leaf chlorophyll, and flowering of Rose x hybrida ‘Meirutral’. J. Environ. Hort, 8:209-211.

[9] McMahon, M.J., Kelly, J.W., Decoteau, D.R., 1991. Growth of Dendranthema×Grandiflorum (Ramat.) Kitamura under Various Spectral Filters. J. Amer. Soc. Hort. Sci., 116(6):950-954.

[10] Moe, R., Willumsen, K., Ihlebekk, I.H., Stupa, A.I., Glomsrud, N.M., Mortensen, L.M., 1995. DIF and temperature drop responses in SDP and LDP, a comparison. Acta Horti, 378:27-32.

[11] Mortensen, L.M., 1990. Effects of temperature and light quality on growth and flowering of Begonia hiemalis Fotsch. and Campanula iaophylla Moratti. Scientia Horti, 44:309-314.

[12] Mortensen, L.M., Stromme, E., 1987. Effects of light quality on some greenhouse crops. Scientia Horti, 33:27-36.

[13] Mortensen, L.M., Larsen, G., 1989. Effects of temperature and light quality on growth of six foliage plants. Scientia Horti, 39:149-159.

[14] Pearson, S., Wheldon, A.E., Hadley, P., 1995. Radiation transmission and fluorescence of nine greenhouse cladding materials. J. Agri. Eng. Res, 62:61-70.

[15] Rajapakse, N.C., Kelly, J.W., 1991. Influence of CuSO4 filters and exogenous gibberellic acid on growth of Dendranthema grandiflorum (Ramat.) Kitamura ‘Bright Golden Ann’. J. Plant Growth Regulat, 10:207-214.

[16] Rajapakse, N.C., Kelly, J.W., 1992. Regulation of chrysanthemum growth by spectral filters. J. Amer. Soc. Hort. Sci., 117(3):481-485.

[17] Rajapakse, N.C., Kelly, J.W., 1993. Spectral filters influence transpiration water loss in chrysanthemum. HortSci, 28(10):999-1001.

[18] Rajapakse, N.C., Kelly. J.W., 1995. Spectral filters and growing season influence growth and carbohydrate status of chrysanthemum. J. Amer. Soc. Hort. Sci, 120(1):78-83.

[19] Rajapakse, N.C., Pollock, R.K., McMahon, M.J., Kelly, J.W., Young, R.E., 1992. Interpretation of light quality measurements and Plant Response in Spectral filter Research. Hort Sci, 27(11):1208-1211.

[20] Rajapakse, N.C., McMahon, M.J., Kelly, J.W., 1993. End of day far-red light reverses height reduction of chrysanthemum induced by CuSO4 spectral filters. Scientia Horti, 53:249-259.

[21] Schafer, E., Beggs, C.J., Fukchansky, L., Holmes, M.G., Jabben, M., 1981. A method to check the involvement of additional photoreceptor to phytochrome in photomorphogenesis. Eur. Symp. Light Med. Plant Dev, 9:14 (Bischofmais, Germany).

[22] Smith, H., 1982. Light Quality, Photoperception, and Plant Strategy. Ann. Rev. Plant physiol, 33:481-518.

[23] Smith, H., 1995. Physiological and Ecological function with in the phytochrome family. Annu. Rev. Plant Physiol. Plant Mol. Biol, 46:289-315.

[24] Thomas, B., Dickinson, H.G., 1979. Evidence for two photoreceptors controlling growth in de-etiolated seedling. Planta, 146:545-550.

[25] Van Haeringen, C.S., West, J.R., Davis, F.J., Gilbert, A., Hadley, P., Pearson, S., Wheldon, A.E., Henbest, R.G.C., 1998. The development of solid spectral filters for the regulation of plant growth. Photochem. and Photobiol, 62:119-128.

[26] Young, J.E., 1981. Light quality and stem growth in Impatiens parviflora DC. New Phytol, 89:47-59.

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