Abstract
Problems posed to plants by metal toxicity in the soils of the world are basically of two kinds. The first kind are of natural origin. These arise either as a consequence of the nature of the parent material from which a particular soil is derived, or from the processes of soil formation. Such events tend to lead to toxicities due to the products of soil mineral decomposition under acid conditions, predominantly to aluminium and/or manganese and iron. The soils characterised by aluminium and manganese toxicities comprise some 40% of the world’s land area given over to arable farming (Clark 1982), and as such, potentially pose a major constraint to the world’s agricultural production.
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References
Abrigo WM, Novero AU, Coronel VP, Cabuslay GS, Blanco LC, Parao FT, Yoshido AS (1985) Somatic cell culture at IRRI. Biotechnology in International Agricultural Research. IRRI, Manila, Philippines, p 149
Al-Hiyaly SAK (1989) Evolution of zinc tolerance under electricity pylons. PhD Thesis, University of Liverpool, Liverpool
Al-Khatib M (1991) Salinity tolerance breeding in lucerne. PhD Thesis, University of Liverpool, Liverpool
Allen WR, Sheppard PM (1971) Copper tolerance in some Californian populations of the monkey flower, Mimulus guttatus. Proc R Soc Lond Ser B 177: 177–196
Andrew CS, Hegarty MP (1969) Comparative responses to manganese excess of eight tropical and four temperate legumes. Aust J Agric Res 20: 687–696
Aniol A (1990) Genetics of tolerance to aluminium in wheat (Triticum aestivum L. Thell). Plant Soil 123: 223–227
Aniol A, Gustafson JP (1984) Chromosome location of genes controlling aluminium tolerance in wheat, rye, and triticale. Can J Genet Cytol 26: 701–705
Ashraf M, McNeilly T, Bradshaw AD (1986) The potential for evolution of salt ( NaCl) tolerance in seven grass species. New Phytol 103: 299–309
Bahia AFC, Franca GE, Pitta GVE, Magnavaca R, Mendes JF, Bahia FGFTC, Pereira P (1978) Evaluation of corn inbred lines and populations in soil acidity conditions. XI Annu Brasilian Maize Sorghum Conf, Piracicaba SP, Brasil, pp 51–58 (in Portugese)
Baker AJM (1978) Ecophysiological aspects of zinc tolerance in Silene maritima With. New Phytol 80: 635–642
Baker AJM, Brooks RR (1989) Terrestrial higher plants which hyper-accumulate metallic elements - a review of their distribution, ecology, and phytochemistry. Biorecovery 1: 81–126
Baker AJM, Walker PL (1989) Physiological responses of plants to heavy metals and the quantification of tolerance and toxicity. Chem Spec Bioavail 1: 7–17
Baligar VC, Kinraide TB, Wright RJ, Bennett OL (1987) Al effects on growth and P, Ca and Mg uptake efficiency in red clover cultivars. J Plant Nutr 10: 131–1137
Bastos CR (1982) Inheritance study of aluminium tolerance in sorghum in nutrient culture. PhD Thesis, Mississippi State University, Mississippi State
Baumeister W (1954) Uber den Einfluss des Zinks bei Silene inflata Smith. I Mitteilung. Ber Dtsch Bot Ges 67: 205–213
Baumeister W, Burghardt H (1956) Uber den Einfluss des Zinks bei Silene inflata (With) II Mitteilung: CO2-Assimilation und Pigmentgehalt. Ber Dtsch Bot Ges 69: 161–168
Blum A (1988) Plant breeding for stress environments. CRC, Boca Raton, 223 pp
Borgonovi RA, Schaffert RE, Pitta GVE, Magnavaca R, Alves VMC (1987) Aluminium tolerance in Sorghum. In: Gabelman WH, Loughman BC (eds) Genetic aspects of plant mineral nutrition. Nijhoff, Dordrecht, pp 213–221
Boye-Goni SR (1982) Combining ability and inheritance of aluminium tolerance in grain sorghum [Sorghum bicolor (L.) Moench]. PhD Thesis, University of Arizona, Tucson
Boye-Goni SR, Macarian V (1985) Diallel analysis of aluminium tolerance in selected lines of grain sorghum. Crop Sci 25: 749–752
Bradshaw AD, McNeilly T (1981) Evolution and pollution. Arnold, London Briggs KE, Nyachiro JM (1988) Genetic variation for aluminium tolerance in Kenyan wheat cultivars. Commum Soil Sci Plant Anal 19: 1273–1284
Broker W (1963) Genetisch-physiologische Untersuchungen uber die Zinkvertraglichkeit von Silene inflata Sm. Flora 153: 122–156
Brooks RR, Malaisse F (1989) Mineral enriched sites in South Central Africa. In: Shaw AJ (ed) Heavy metal tolerance in plants: evolutionary aspects. CRC, Boca Raton, p 53
Camargo CEO (1984) Genetic evidence of aluminium tolerance in rice. Bragantia 43: 95–110 (in Portuguese)
Campbell AT, Nuernberg NJ, Foy CD (1989) Differential response of alfalfa to aluminium stress. J Plant Nutr 12: 291–305
Campbell LG, Lafever TN (1976) Correlation of field and nutrient culture techniques of screening wheat for aluminium tolerance. In: Wright M (ed) Plant adaptation to mineral stress in problem soils. Cornell Univ Agric Stn, Ithaca, NY, pp 277–286
Cardus JR (1987) Intraspecific variation for tolerance to aluminium toxicity in white clover. J Plant Nutr 10: 821–830
Carter OG, Rose I A, Reading PF (1975) Variation in susceptibility to manganese in 30 soybean lines. Crop Sci 15: 730–732
Cartwright B, Rathgen AJ, Sparrow DHB, Paull JG, Zarcinas BA (1987) Boron tolerance in Australian varieties of wheat and barley. In: Gabelman HW, Loughman BC (eds) Genetic aspects of plant mineral nutrition. Nijhoff, Dordrecht, pp 131–151
Carver BF, Inskeep WP, Wilson NP, Westerman RL (1988) Seedling tolerance to aluminium toxicity in hard red winter wheat germplasm. Crop Sci 28: 463–467
Chandhry MA, Yoshida S, Vergara BS (1986) Induced mutations for aluminium tolerance after N-methyl-N-nitrosourea treatment of fertilized egg cells in rice. Environ Exp Bot 27: 37–43
Clark RB (1982) Plant response to mineral element toxicity and deficiency. In: Christiansen MN, Lewis CF (eds) Breeding plants for less favourable environments. Wiley, New York, pp 71–142
Clarkson DT (1966) Aluminium tolerance in species within the genus Agrostis. J Ecol 54: 167–178
Clymo RS (1962) An experimental approach to part of the calcicole problem. J Ecol 50: 707–731
Cook SCA, Lefebre C, McNeilly T (1972) Competition between metal tolerant and normal plant populations on normal soil. Evolution 26: 366–372
Culvenor RA (1985) Tolerance of Phalaris aquatica L. populations and some agricultural species, and the effect of aluminium on manganese tolerance of P. aquatica. Aust J Agric Res 36: 695–708
Culvenor RA, Oram RN, Fazekas de Groth C (1986a) Variation in tolerance in Phalaris aquatica L. and a related species to aluminium in nutrient solution and soil. Aust J Agric Res 37: 383–395
Culvenor RA, Oram RN, Wood JT (1986b) Inheritance of aluminium tolerance in Phalaris aquatica L. Aust J Agric Res 37: 397–408
Dessereaux L, Ouelette CJ (1958) Tolerance of alfalfa to manganese toxicity in sand culture. Can J Soil Sci 38: 8–13 Devine TE (1982) Genetic fitting of crops to problem soils. In: Christiansen MN, Lewis CF (eds) Breeding plants for less favourable environments. Wiley, New York, pp 143–173
Devine TE, Foy CD, Fleming AL, Hanson TA, Campbell TA, McMurtrey JE, Schwartz JW (1976) Development of alfalfa strains with differential tolerance to aluminium toxicity. Plant Soil 44: 73–79
Duncan RR (1988) Sequential development of acid soil–tolerant sorghum genotypes under field stress conditions. Commun Soil Sci Plant Anal 19: 1295–1305
Evans J, Scott BL, Lill WJ (1987) Manganese tolerance in subterranean clover ( Trifolium subterraneum L.) genotypes grown with nitrate or symbiotic nitrogen. Plant Soil, 97: 207–215
Foy CD (1974) Effects of aluminium in plant growth. In: Clarkson EW (ed) The plant root and its environment. University Press of Virginia, Charlottesville, pp 57–97
Foy CD (1983a) Plant adaptation to mineral stress in problem soils. Iowa State J Res 57: 339–354
Foy CD (1983b) The physiology of plant adaptation to mineral stress. Iowa State J Res 57: 355–391
Foy CD (1988) Plant adaptation to acid, aluminium–toxic soils. Commun Soil Sci Plant Anal 19: 959–987
Foy CD, Lafaver NH, Schwartz JW, Fleming AL (1974) Aluminium tolerance of wheat cultivars related to region of origin. Agron J 66: 751–758
Furlani PR, Clark RB (1987) Plant traits for evaluation of responses of sorghum genotypes to aluminium. In: Gabelman HW, Loughman BC (eds) Genetic aspects of plant nutrition. Nijhoff, The Hague, pp 247–254
Furlani PR, Clark RB, Ross WM, Maranville JW (1983) Variability and genetic control of aluminium tolerance in sorghum genotypes. In: Saric MR, Loughman BC (eds) Genetic aspects of plant nutrition. Nijhoff, The Hague, pp 453–461
Garcia O, da Silva WJ, Massei MAS (1979) An efficient method for screening maize inbreds for aluminium tolerance. Maydica 24: 75–82
Gartside DW, McNeilly T (1974) The potential for evolution of heavy metal tolerance in plants III. Copper tolerance in normal populations of different species. Heredity 32: 335–348
Gourley LM (1987) Identifying aluminium tolerance in sorghum genotypes grown on tropical acid soils. In: Gabelman HW, Loughman BC (eds) Genetic aspects of plant mineral nutrition. Nijhoff, Dordrecht, pp 89–98
Gourley LM, Rogers SA, Ruiz-Gomez C, Clark RB (1990) Genetic aspects of aluminium tolerance in sorghum. Plant Soil 123: 211–216
Gries B (1966) Zellphysiologische Untersuchungen uber die Zinkresistenz bei Galmeiok-otypen und Normalformen von Silene cucubalis Wib. Flora 156: 271–290
Grime JP, Hodgson JG (1969) An investigation of the ecological significance of lime chlorosis by means of large–scale comparative experiments. In: Rorison IH (ed) Ecological aspects of the mineral nutrition of plants. Blackwell, Oxford, pp 67–99
Heenan DP, Carter OG (1975) Response of two soybean cultivars to manganese toxicity as affected by pH and calcium levels. Aust J Agric Res 26: 967–974
Heenan DP, Carter OG (1976) Tolerance of soybean cultivars to manganese toxicity. Crop Sci 16: 389–391
Heenan DP, Carter OG (1977) Influence of temperature on the expression of manganese tolerance by two soybean varieties. Plant Soil 47: 219–227
Heenan DP, Campbell LC, Carter OG (1981) Inheritance of tolerance to high manganese supply in soybeans. Crop Sci 21: 626–627
Helyar KR (1978) Effects of aluminium and manganese toxicity on legume growth. In: Andrews CS, Kamprath EJ (eds) Mineral nutrition of legumes in tropical and subtropical soils. CSIRO, Melbourne, pp 207–231
Helyar KR, Anderson A J (1970) Some effects of the soil pH on different species and on the soil solution for a soil high in exchangeable aluminium. Proc XI Int Grassland Congr, Surfer’s Paradise, Queensland University. Queensland Press, Brisbane, pp 431–434
Hill PR, Alrichs JL, Ejeta G (1989) Rapid evaluation of sorghum for aluminium tolerance. Plant Soil 114: 85–90Hoffer GN, Carr RH (1923) Accumulation of aluminium and iron compounds in corn plants and its probable relation to root rots. J Agric Res 23: 801–824
Horst WJ (1987) Aluminium tolerance and calcium efficiency in cowpea genotypes. J Plant Nutr 10: 1121–1129
Howeler RH, Cadavid LF (1976) Screening for rice cultivars for tolerance to aluminium toxicity in nutrient solutions compared with a field screening method. Agron J 68: 551–555
Humphreys MO, Nicholls MK (1984) Relationships between tolerance to heavy metals in Agrostis capillaris L. (A. tenuis Sibth.) New Phytol 98: 177–190
Ingram C (1987) The evolutionary basis of ecological amplitude of plant species. PhD Thesis, University of Liverpool, Liverpool Ingrouille MJ, Smirnoff N (1986) Thalaspi caerulescens J & C Presl (T. alpestre L.) in Britain. New Phytol 102: 219–233
Ittu G, Saulescu NN (1988) Ameliorarea tolerantei la toxicitatea de alumini la triticale. Probl Gen Teor si Aplic 20: 67–74
Jowett D (1958) Populations of Agrostis spp tolerant to heavy metals. Nature 182: 816–817
Kerridge PC, Kronstad WE (1968) Evidence of genetic resistance to aluminium toxicity in wheat (Triticum aestivum Vill. Host ). Agron J 60: 710–711
Kruckeberg AR (1984) California serpentines. University of California Press, Berkeley
Lafever HN, Campbell LG (1978) Inheritance of aluminium tolerance in wheat. Can J Genet Cytol 20: 355–364
Lawrence MJ (1984) The genetic analysis of ecological traits. In: Shorrocks B (ed) Evolutionary ecology. Blackwell, London pp 27–64
Lefebvre C (1967) Etude de la position des populations d’Armeria calaminaires de Belgique et des environs d’Aix la Chapelle par rapport a des types alpines et maritimes d’Armeria maritima (Mill) Willd. Bull Soc R Bot Belg 100: 231–239
Lefebvre C (1968) Note sur un indice de tolerance chez des populations d’Armeria maritima (Mill) Willd. Bull Soc R Bot Belg 102: 5
Lerner IM (1958) The genetic basis of selection. Wiley, New York Little R (1988) Plant soil interaction at low pH. Problem solving–the genetic approach. Commun Soil Sci Plant Anal 19: 1239–1257
MacLean A A, Chiasson TC (1966) Differential performance of two barley cultivars to varying aluminium concentrations. Can J Soil Sci 46: 147–153
Macnair MR (1989) The genetics of metal tolerance in natural populations. In: Shaw AJ (ed) Heavy metal tolerance in plants: evolutionary aspects. CRC, Boca Raton, pp 235–253
Magnavaca R, Gardner GO, Clark RB (1987a) Evaluation of inbred maize lines for aluminium tolerance in nutrient solution. In: Gabelman HW, Loughman BC (eds) Genetic aspects of plant mineral nutrition. Nijhoff, Dordrecht, pp 255–265
Magnavaca R, Gardner GO, Clark RB (1987b) Inheritance of aluminium tolerance in maize. In: Gabelman HW, Loughman BC (eds) Genetic aspects of plant mineral nutrition. Nijhoff, Dordrecht, pp 201–212
Martini J A, Kochann RA, Gomes EP, Langer F (1977) Response of wheat cultivars to liming in some acid high aluminium oxisols of Rio Grande del Sol, Brazil. Agron J 69: 612–616
Mather K (1960) Evolution in polygenic systems. Evol e Genetica, Acad Nazi Lincei, Rome, pp 131–152
Mather K (1966) Variability and selection. Proc R Soc Lond Ser B 164: 328–340
Mather K (1973) Genetical structure of populations. Chapman and Hall, London
McLean A A, Gilbert BE (1927) The relative aluminium tolerance of crop plants. Soil Sci 24: 163–174
McNeilly T (1968) Evolution in closely adjacent populations III Agrostis tenuis on a small copper mine. Heredity 23: 99–108
McNeilly T (1982) A rapid method for screening barley for aluminium tolerance. Euphytica 31: 237–239
Moore DP, Kronstad WE, Metzger RJ (1976) Screening for aluminium tolerance. In: Wright MJ (ed) Plant adaptation to mineral stress in problem soils. Cornell University Press, Ithaca, NY, p 287
Morrey DR, Blackwill K, Blackwill MJ (1989) Studies on serpentine flora: Preliminary analyses of soils and vegetation associated with serpentine rock formations in the South–Eastern Transvaal. S Afr J Bot 55: 171–177
Naspolini V, Bahia AFC, Viana RT, Gama EFG (1981) Performance of inbreds and single crosses in corn in soils under cerrado vegetation. Cienc Cult 33: 722–727
Neeling AJ de, Ernst WHO (1986) Response of an acidic and a calcareous population of Chamaenerion angustifolium ( L.) to iron, manganese and aluminium. Flora 178: 85–92
Nicholls MK (1977) Ecological genetics of copper tolerance in Agrostis tenuis Sibth. PhD Thesis, University of Liverpool, Liverpool
Ouelette CJ, Dessereaux L (1958) Chemical composition of alfalfa as related to degree of tolerance to manganese and aluminium. Can J Plant Sci 38: 206–214
Pegtel DM (1986) Responses of plants to aluminium, manganese, and iron, with particular reference to Succisa pratensis Moench. Plant Soil 93: 43–55
Pitta GVE, Trevisian WL, Schaffert RE, de Franca GE, Bahia AFC (1976) Evaluation of Sorghum lines under high acidity conditions. In: Geres GC (ed) Proc Xlth Brazilian Maize Sorghum Rev, Piracicaba, Brazil pp 553–557
Pitta GVE, Schaffert RE, Borgonovi RA, Vasconsellos CA, Bahia AFC, Oliviera AC (1979) Evaluation of sorghum lines to high soil acidity conditions. In: dos Santos AF (ed) Proc Xllth Brazilian Corn Sorghum Res Conf, Gioana, Brazil, p 217
Polle E, Konsak CF, Kittrick JA (1978) Visual detection of aluminium tolerance levels in wheat by haematoxylin staining of seedling roots. Crop Sci 18: 823–827
Poison DE, Adams MW (1970) Differential response of navy beans (Phaseolus vulgaris) to zinc. Differential growth and elemental composition at excessive zinc levels. Agron J 62: 557–560
Prat S (1934) Die Erblichkeit der Resistenz gegen Kupfer. Ber Dtsch Bot Ges 102: 65–67
Ramarkrishnan PS (1968) Nutritional requirements of the edaphic ecotypes of Melilotus alba Medic. II Aluminium and manganese. New Phytol 67: 301–308
Ramarkrishnan PS (1969) Nutritional factors influencing the distribution of the calcareous and acidic populations in Hypericum perforatum. Can J Bot 47: 175–181
Rechcigl JE, Reneau RB, Zelazny LW (1988) Soil solution aluminium as a measure of aluminium toxicity to alfalfa in acid soils. Commun Soil Sci Plant Anal 19: 989–1001
Reid DA (1976) Genetic potential for solving problems of soil mineral stress: Aluminium and manganese tolerances in the cereal grains. In: Wright MJ (ed) Plant adaptation to mineral stress in problem soils. Cornell University Press, Ithaca, NY, pp 55–64
Reid DA, Slootmaker La, Craddock JC (1980) Registration of Composite Cross XXXIV. Crop Sci 20: 416–417
Repp G (1963) Die Kupferresistenz des Protoplasmas hoherer Pflanzen auf Kupfererzbo- den. Protoplasma 57: 643–659
Rhue RD, Grogan CO (1977) Screening corn for aluminium tolerance using different calcium and magnesium concentrations. Agron J 69: 775–760
Rhue RD, Grogan CO, Stockmeyer EW, Everett HL (1978) Genetic control of aluminium tolerance in corn. Crop Sci 18: 1063–1067
Richards RA (1983) Should selection for yield in saline regions be made on saline or non- saline soils? Euphytica 32: 431–438
Richards RA, Dennett CW (1980) Variation in salt concentration in a wheat field. University of California Cooperative Extension. Soil Water 44: 8–9
Robinson NJ (1989) Metal binding polypeptides in plants. In: Shaw A J (ed) Heavy metal tolerance in plants: evolutionary aspects. CRC, Boca Raton, pp 195–214
Rorison IH (1960) Some experimental aspects of the calcicole-calcifuge problem II. The effects of mineral nutrition on seedling growth in nutrient solution. J Ecol 48: 679–688
Rorison IH (1969) Ecological inferences from laboratory experiments on mineral nutrition. In: Rorison IH (ed) Ecological aspects of the mineral nutrition of plants. Blackwell, Oxford, pp 155–175
Salisbury PA, Downes RW (1982) Breeding lucerne for tolerance to acid soils. In: Yates JJ (ed) Proc 2nd Aust Agron Conf, Wagga, NSW, Australian Society for Agronomy, Parkville, Victoria, pp 339–346
Schat H, Bookum WM (1992) Genetic control of copper tolerance in Silene vulgaris. Heredity 68: 219–229
Scott BJ, Fisher J A (1989) Selection of genotypes tolerant of aluminium and manganese. In: Robson AD (ed) Soil acidity and plant growth. Academic Press, Mattickville, Australia, pp 167–203
Scott BJ, Burke DR, Bostrom TE (1987) Australian research on tolerance to toxic manganese. In: Gabelmann HW, Loughman BC (eds) Genetic aspects of plant mineral nutrition. Nijhof, Dordrecht, pp 153–163
Silva AR da (1976) Application of the plant genetic approach to wheat culture in Brazil. In: Wright EJ (ed) Plant adaptation to mineral stress in problem soils. Cornell University Press, Ithaca, NY, pp 223–231
Stolen O, Anderson S (1978) Inheritance of tolerance to low soil pH in barley. Hereditas 88: 101–105
Symeonidis L, McNeilly T, Bradshaw AD (1985) Interpopulation variation in tolerance to cadmium, copper, lead, nickel, and zinc in nine populations of Agrostis capillaris ( L. ). New Phytol 101: 317–324
Tagaki H, Namai H, Murakami K (1983) Exploration of aluminium tolerant genes in wheat. Proc 6th Int Wheat Genetics Symp. Maruzen, Kyoto, Japan, p 143
Taylor GJ (1988) The physiology of aluminium tolerance in higher plants. Commun Soil Sci Plant Anal 19: 1179–1194
Thompson J (1987) Population biology of Anthoxanthum odoratum, Plantago lanceolata, and Rumex acetosa on zinc and lead mine spoil. PhD Thesis, University of Liverpool, Liverpool
Verkleij JAK Schat H (1989) Mechanisms of metal tolerance in higher plants. In: Shaw AJ (ed) Heavy metal tolerance in plants: evolutionary aspects. CRC, Boca Raton, pp 179–193
Vose PB, Jones DG (1963) The interaction of manganese and calcium on nodulation and growth in three varieties of Trifolium repens. Plant Soil 18: 372–385
Wachsmann C (1961) Wasserkultur zur Wirkung von Blei, Kupfer und Zink auf die Gartenform und Schwermetallbiotypen von Silene inflata. Thesis, University of Miinster, Miinster
Walley Ka, Khan MS, Bradshaw AD (1974) The potential for evolution of heavy metal tolerance in plants I. Copper and zinc tolerance in Agrostis tenuis. Heredity 32: 309–319
Walsh LM, Steevens DR, Siebel HD, Weis GE (1972) Effect of high rates of zinc on several crops grown on an irrigated plainfield sand. Commun Soil Sci Plant Anal 3: 187–195
White MC, Decker AM, Chaney RL (1979) Differential cultivar tolerance in soybean tosoil zinc I. Range of cultivar response. Crop Sci 71: 121–125
Wild H (1964) The endemic species of the Chimanimani Mountains and their significance. Kirkia 4: 125–157
Wild H (1965) The flora of the Great Dyke of Southern Rhodesia with special reference to the serpentine soils. Kirkia 5: 49–86
Wild H, Bradshaw AD (1977) The evolutionary effects of metalliferous and other anomalous soils in south central Africa. Evolution 31: 282–293
Wilkins DA (1957) A technique for the measurement of lead tolerance in plants. Nature 180: 37–38
Wilkins DA (1960) The measurement and genetic analysis of lead tolerance in Festuca ovina. Ann Rep Scott Plant Breed Stn 1960: 85–98
Williams CH (1980) Soil acidification under clover pasture. Aust J Exp Agric Anim Husb 20: 561–567
Woolhouse H (1983) Toxicity and tolerance in the response of plants to metals. In: Lange OL, Nobel PS, Osman CB, Ziegler H (eds) Physiological plant ecology. III. Response to the chemical and biological environment. Springer Berlin, Heidelberg New York, p 254
Wright MJ (1976) Plant adaptation to mineral stress in problem soils. Cornell University Press, Ithaca, NY, 420 pp
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McNeilly, T. (1994). Metal Toxicity. In: Yeo, A.R., Flowers, T.J. (eds) Soil Mineral Stresses. Monographs on Theoretical and Applied Genetics, vol 21. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-84289-4_7
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