Abstract
Exposure of flowering cereal crops to frost can cause sterility and grain damage, resulting in significant losses. However, efforts to breed for improved low temperature tolerance in reproductive tissues (LTR tolerance) has been hampered by the variable nature of natural frost events and the confounding effects of heading time on frost-induced damage in these tissues. Here, we establish conditions for detection of LTR tolerance in barley under reproducible simulated frost conditions in a custom-built frost chamber. An ice nucleator spray was used to minimize potential effects arising from variation in naturally occurring extrinsic nucleation factors. Barley genotypes differing in their field tolerance could be distinguished. Additionally, an LTR tolerance quantitative trait locus (QTL) on the long arm of barley chromosome 2H could be detected in segregating families. In a recombinant family, the QTL was shown to be separable from the effects of the nearby flowering time locus Flt-2L. At a minimum temperature of −3.5°C for 2 h, detection of the LTR tolerance locus was dependent on the presence of the nucleator spray, suggesting that the tolerance relates to freezing rather than chilling, and that it is not the result of plant-encoded variation in ice-nucleating properties of the tiller surface.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Ashworth EN, Kieft TL (1995) Ice nucleation activity associated with plants and fungi. In: Lee RE, Warren CJ, Gusta LV (eds) Biological ice nucleation and its applications. Am Phytopathological Soc, St. Paul, pp 137–162
Chen A, Baumann U, Fincher GB, Collins NC (2009a) Flt-2L, a locus in barley (Hordeum vulgare L.) controlling flowering time, spike density and plant height. Funct Integr Genomics 9(2):243–254
Chen A, Brûlé-Babel A, Baumann U, Collins NC (2009b) Structure-function analysis of the barley genome: the gene-rich region of chromosome 2HL. Funct Integr Genomics 9:67–79
Chen A, Reinheimer JL, Brûlé-Babel A, Baumann U, Fincher GB, Collins NC (2009c) Genes and traits associated with barley 2H and 5H chromosome regions controlling sensitivity of reproductive tissues to frost. Theor Appl Genet 118(8):1465–1476
Fu D, Szűcs P, Yan L, Helguera M, Skinner JS, von Zitzewitz J, Hayes PM, Dubcovsky J (2005) Large deletions within the first intron in VRN-1 are associated with spring growth habit in barley and wheat. Mol Gen Genomics 273:54–65
Fuller MP, Fuller AM, Kaniouras S, Christophers J, Fredericks T (2007) The freezing characteristics of wheat at ear emergence. Eur J Agron 26:435–441
Gomez-Macpherson H, Richards RA (1995) Effect of sowing time on yield and agronomic characteristics of wheat in south-eastern Australia. Aust J Agric Res 46:1381–1399
Gusta LV, Wisniewski M, Nesbitt NT, Tanino KT (2003) Factors to consider in artificial freeze tests. Acta Hortic (ISHS) 618:493–507
Gusta LV, Wisniewski M, Nesbitt NT, Gusta ML (2004) The effect of water, sugars, and proteins on the pattern of ice nucleation and propagation in acclimated and nonacclimated canola leaves. Plant Physiol 135:1642–1653
Huang T, Nicodemus J, Zarka DG, Thomashow MF, Wisniewski M, Duman JG (2002) Expression of an insect (Dendroides canadensis) antifreeze protein in Arabidopsis thaliana results in a decrease in plant freezing temperature. Plant Mol Biol 50:333–344
Kóti K, Karsai I, Szűcs P, Horváth C, Mészáros K, Kiss GB, Bedő Z, Hayes PM (2006) Validation of the two-gene epistatic model for vernalization response in a winter × spring barley cross. Euphytica 152:17–24
Limin AE, Fowler DB (2006) Low-temperature tolerance and genetic potential in wheat (Triticum aestivum L.): response to photoperiod, vernalization, and plant development. Planta 224:360–366
Marcellos H, Single WV (1975) Temperatures in wheat during radiation frost. Aust J Exp Agric Anim Husband 15:818–822
Marcellos H, Single WV (1984) Frost injury in wheat ears after ear emergence. Aust J Plant Physiol 11:7–15
Mazur P, Seki S, Pinn IL, Kleinhans FW, Edashige K (2005) Extra- and intracellular ice formation in mouse oocytes. Cryobiology 51:29–53
Missous G, Thammavongs B, Dieuleveux V, Guéguen M, Panoff JM (2007) Improvement of the cryopreservation of the fungal starter Geotrichum candidum by artificial nucleation and temperature downshift control. Cryobiology 55:66–71
Pallotta MA, Asayama S, Reinheimer JM, Davies PA, Barr AR, Jefferies SP, Chalmers KJ, Lewis J, Collins HM, Roumeliotis S, Logue SJ, Coventry SJ, Lance RCM, Karakousis A, Lim P, Verbyla AP, Eckermann PJ (2003) Mapping and QTL analysis of the barley population Amagi Nijo × WI2585. Aust J Agric Res 54:1141–1144
Paulsen GM, Heyne EG (1983) Grain production of winter-wheat after spring freeze injury. Agron J 75:705–707
Pearce RS (2001) Plant freezing and damage. Ann Bot 87:417–424
Pearce RS, Fuller MP (2001) Freezing of barley studied by infrared video thermography. Plant Physiol 125:227–240
Prášil IT, Prášilová P, Pánková K (2004) Relationships among vernalization, shoot apex development and frost tolerance in wheat. Ann Bot 94:413–418
Rebbeck M, Lynch C, Hayman PT, Sadras VO (2007) Delving of sandy surfaced soils reduces frost damage in wheat crops. Aust J Agric Res 58:105–112
Reinheimer JL, Barr AR, Eglinton JK (2004) QTL mapping of chromosomal regions conferring reproductive frost tolerance in barley (Hordeum vulgare L.). Theor Appl Genet 109:1267–1274
Single WV (1966) Studies on frost injury to wheat. 3. Screening of varieties for resistance to ear and stem frosting. Aust J Agric Res 17:601–610
Single WV (1985) Frost injury and the physiology of the wheat plant—Farrer memorial oration, 1984. J Aust Inst Agric Sci 51:128–134
Single WV (1988) Resistance to frost injury during stem elongation and early heading. In: Frost injury of wheat: proceedings of a workshop of the NSW Wheat Research Council. NSW Department of Agriculture, Haymarket, NSW, pp 7–18
Single WV, Marcellos H (1974) Studies on frost injury to wheat. 4. Freezing of ears after emergence from the leaf sheath. Aust J Agric Res 25:679–686
Skirvin RM, Kohler E, Steiner H, Ayers D, Laughnan A, Norton MA, Warmund M (2000) The use of genetically engineered bacteria to control frost on strawberries and potatoes. Whatever happened to all of that research? Sci Hortic 84:179–189
von Zitzewitz J, Szűcs P, Dubcovsky J, Yan L, Francia E, Pecchioni N, Casas A, Chen THH, Hayes PM, Skinner JS (2005) Molecular and structural characterization of barley vernalization genes. Plant Mol Biol 59:449–467
Wisniewski M, Glenn DM, Fuller MP (2002) Use of a hydrophobic particle film as a barrier to extrinsic ice nucleation in tomato plants. J Am Soc Hortic Sci 127:358–364
Woodruff DR (1992) ‘Wheatman’ a decision support system for wheat management in subtropical Australia. Aust J Agric Res 43:1483–1499
Zadoks JC, Chang TT, Konzak CF (1974) A decimal code for the growth stages of cereals. Weed Res 14:415–421
Acknowledgments
We gratefully acknowledge our funding bodies, the Australian Research Council, the Grains Research and Development Corporation, the South Australian Government and the University of Adelaide for financial support. We also thank Ursula Langridge and Robin Hosking for their assistance in the maintenance of growth rooms and greenhouses, and Joan Vickers from the University of Southern Queensland for helpful discussions and for provision of SNOMAX.
Author information
Authors and Affiliations
Corresponding author
Additional information
Communicated by F. Ordon.
Electronic supplementary material
Below is the link to the electronic supplementary material.
Rights and permissions
About this article
Cite this article
Chen, A., Gusta, L.V., Brûlé-Babel, A. et al. Varietal and chromosome 2H locus-specific frost tolerance in reproductive tissues of barley (Hordeum vulgare L.) detected using a frost simulation chamber. Theor Appl Genet 119, 685–694 (2009). https://doi.org/10.1007/s00122-009-1079-1
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00122-009-1079-1