Lead and plants

  • Wolfgang Höll
  • Rüdiger Hampp
Conference paper
Part of the Residue Reviews book series (RECT, volume 54)


Because of its low melting point, its malleability, and its inertness, lead has been a favored metal of man since pre-Christian times. With progressing civilization lead has been mined in increasing amounts from natural sources and has been partly returned into the environment after its technological use.


Lead Concentration Lead Content Lead Nitrate High Lead Spinach Leave 
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  1. Afonova, V. N.: Changes in some reactive groups of serum proteins in chronic lead poisoning. Farmakol. Toksikol. 21, 64 (1958).PubMedGoogle Scholar
  2. Amesz, J. P. van den Bos, and M. P. Dirks: Oxidation-reduction potentials of photosynthetic intermediates. Biochim. Biophys. Acta 197, 324 (1970).Google Scholar
  3. Atkins, P.: Lead in a suburban environment. J. Air Pollution Control Assoc. 19, 591 (1969).Google Scholar
  4. Baumhardt, G. R.: Absorption by and growth of corn (Zea mays L.) with soil-applied lead. Master’s thesis, Univ. Ill. 51 pp. (1970).Google Scholar
  5. Bell, B. W.: Influence of lead on normal and abnormal cell-growth. Lancet 206, 267 (1924).Google Scholar
  6. Berry, R. A.: The manurial properties of lead nitrate. J. Agr. Sci. 14, 58 (1923).Google Scholar
  7. Bersin, Th.: Enzymgifte der Autoabgase. Vitalstoffe 3, 160 (1958).Google Scholar
  8. Blanchard, R. L.: Relationship between polonium-210 and lead-210 in man and his environment. In: Proceedings Internat. Symp. “Radioecological Concentration Process” pp. 281–294. New York: Pergamon Press (1966).Google Scholar
  9. Bonnet, E.: Action of soluble lead salts on plants. Compt. Rend. Acad. Sci. (Paris) 174, 488 (1922).Google Scholar
  10. Bovay, E.: Les dépots de plombs sur la végétation le long des autoroutes. Essai d’affouragement de vaches laitières avec du foin souillé par du plomb. Mitt. aus dem Gebiet der Lebensmitteluntersuchung und Hygiene, Bern 61, 303 (1970).Google Scholar
  11. Bradshaw, A. D.: Populations of Agrostis tenuis resistant to lead and zinc poisoning. Nature 169, 1098 (1952).PubMedGoogle Scholar
  12. Briggs, D.: Population differentiation in Marchantia polymorpha L. in various lead pollution levels. Nature 238, 166 (1972).PubMedGoogle Scholar
  13. Broyer, T., C. Johnson, and R. Paull: Some aspects of lead in plant nutrition. Plantx and Soil 36, 301 (1972).Google Scholar
  14. Büttner, H.: Erste Ergebnisse von Bleiuntersuchungen in der Luft im Rahmen eine DFG-Meßprogramms. In: Komm. f. Umweltgefahren des Bundesgesundheitsamtes, Arbeitsgruppe Blei, Sitzung v. 2.12.1970; als Manuskript gedruckt v. Verein f. Wasser-, Boden- und Lufthygiene E. V. Berlin: BRD (1972).Google Scholar
  15. Cannon, H. L., and J. M. Bowles: Contamination of vegetation by tetraethyl lead. Sciencs 137, 765 (1962).Google Scholar
  16. Chow: T. J.: Lead accumulation in roadside soil and grass. Nature 225, 295 (1970).PubMedGoogle Scholar
  17. -, and J. L. Earl: Lead aerosols in the atmosphere: Increasing concentrations. Science 169, 577 (1970).PubMedGoogle Scholar
  18. -, and C. C. Patterson: The occurrence and significance of lead isotopes in pelagic sediments. Geochim. Cosmochim. Acta 26, 263 (1962).Google Scholar
  19. Clymo, R. S.: Ion exchange in Sphagnum and its relation to bog ecology. Ann. Bot. 27, 309 (1963).Google Scholar
  20. Committee on Biologic Effects of Atmospheric Pollutants: Lead. Airborne lead in perspective. Washington, D.C.: Nat. Acad. Sci. (1972).Google Scholar
  21. Crafts, A. S., and C. E. Crisp: Phloem transport in plants, p. 191, San Francisco: Freeman & Co. (1971).Google Scholar
  22. Daines, R., H. Motto, and D. Chilko: Atmospheric lead, its relationship to traffic volume and proximity to highways. Environ. Sci. Technol. 4, 318 (1970).Google Scholar
  23. Dale, A. G.: A study of aging of Pb aerosols. II. A numerical model simulating coagulation and sedimentation of a leaded aerosol in the presence of an unleaded background aerosol. Atmos. Environ. 6, 451 (1972).Google Scholar
  24. -, and J. W. Winchester: A study of aging of Pb aerosols. I. Observation. Atmos. Environ. 6, 443 (1972).Google Scholar
  25. Danielson, L.: Gasoline containing lead. Ecolog. Res. Committee, No. 6. Stockholm: Nat. Sci. Res. Council, (1970).Google Scholar
  26. Dilung, W. I.: Influence of lead and the metallic ions of copper, zinc, thorium, beryllium and thallium on the germination of seeds. Ann. Applied Biol. 13, 160 (1926).Google Scholar
  27. Djuhič, D., Z. Kerin, L. Graovac-Leposavic, L. Novak, and M. Kop: Environmental contamination by lead from a mine and smelter. A preliminary report. Arch. Environ. Health 23, 275 (1971).Google Scholar
  28. Dunn, J. T., and H. C. L. Bloxam: The occurrence of lead, copper, zinc, and arsenic compounds in atmospheric dust and the source of these impurities. J. Soc. Chem. Ind. 52, 189 (1933).Google Scholar
  29. Edelhoch, H.: The effect of various protein dénaturants on the kinetics of pepsin inactivation. J. Amer. Chem. Soc. 80, 6648 (1958).Google Scholar
  30. Ehrenberg, P., and O. Nolte: Kritische Gedanken über die Empfehlung von Reizdüngemitteln. Fühlings Landw. Ztg. 65, 559 (1916).Google Scholar
  31. Eidg. Kommission für Lufthygiene: Das Problem der Benzinverbleiung. Beilage B, Nr. 3/1971 zum Bulletin des Eidg. Gesundheitsamtes, Bern (1971).Google Scholar
  32. Everett, J. C., C. L. Day, and D. Reynolds: Comparative survey of lead at selected sites in the British Isles in relation to air pollution. Food Cosmetic Toxicol. 5, 29 (1967).Google Scholar
  33. Fidora, B.: Der Bleigehalt von Pflanzen verkehrsnaher Standorte in Abhängigkeit von der Vegetationsperiode. Ber. Deutsch. Bot. Ges. 85, 219 (1972).Google Scholar
  34. Fletcher, K.: Direct determination of lead in plant materials by atomic absorption spectrophotometry. J. Sci. Food Agr. 22, 260 (1971).Google Scholar
  35. Francis, C. W., G. Chesters, and L. A. Haskin: Determinations of 210-Pb mean residence time in atmosphere. Environ. Sci. Technol. 4, 586 (1970).Google Scholar
  36. Garber, K.: Luftverunreinigung durch schwermetallhaltige Stäube. Wirkung auf Pflanzen. Landw. Forschung 25, 59 (1970).Google Scholar
  37. - Luftverunreinigungen, eine Literaturübersicht. In W. Bosshard (ed.): Ber. Nr. 102 der Eidg. Anstalt für das forstliche Versuchswesen, CH-8903 Birmensdorf (1973).Google Scholar
  38. Gilbert, P.: Mineral nutrition and the balance of life. Ann. Applied Biol. 13, 246 (1926).Google Scholar
  39. Goren-Suchodoller, A., and H. Wanner: Die Absorption von Blei und Mangan durch Wurzeln von Hordeum vulgare. Z. Pflanzenphysiol. 61, 122 (1969).Google Scholar
  40. Griffith, J. J.: Influence of mines upon land and lifestock in Cardiganshire. J. Agr. Sci. 9, 366 (1919).Google Scholar
  41. Hammett, F. S.: Studies in the biology of metals. I. The localisation of lead by growing roots. Protoplasma 4, 183 (1928 a). - Studies in the biology of metals. III. The localization of lead within the cell of the growing root. Protoplasma 5, 135 (1928 b).Google Scholar
  42. - The influence of lead on mitosis and cell size in the growing root. Protoplasma 5, 535 (1928 c).Google Scholar
  43. - The nature of lead compound deposited in the growing root. Protoplasma 5, 447 (1928 d).Google Scholar
  44. Hampp, R.: Bleigehalt von Blattspreiten (Acer platanoides L.) als Indikator für die verkehrsabhängige Bleibelastung im Stadtgebiet von München. Ber. Bayer. Bot. Ges. 44, 211 (1972 a).Google Scholar
  45. - Über die Konzentration von Bleiverbindungen in Pflanzenteilen und die Wirkung des Bleiions auf pflanzenphysiologische und biochemische Prozesse. Ph.D. Thesis, München (1973 b).Google Scholar
  46. -, and W. Höll: Radial and axial gradients of lead concentration in bark and xylem of hardwoods. Arch. Environ. Contam. Toxicol. In press (1974).Google Scholar
  47. -, H. Ziegler, and I. Ziegler: Die Wirkung von Bleiionen auf die 14CO2-Fixietrung und die ATP-Bildung von Spinatchloroplasten. BBP 164, 126 (1973 a).Google Scholar
  48. - - - Der Einfluβ von Bleiionen auf Enzyme des reduktiven Pentosephosphatcyclus. BPP 164, 588 (1973 b).Google Scholar
  49. Hammond, P. B., and A. L. Aronson: Lead poisoning in cattle and horses in the vicinity of a smelter. Ann. N.Y. Acad. Sci. 111, 595 (1964).PubMedGoogle Scholar
  50. Hassler, A.: Retention of copper in soil. Mitt. Lebensm. Hyg. (Bern) 34, 79 (1943).Google Scholar
  51. Heilenz, S.: Untersuchungen über den Bleigehalt von Pflanzen an verkehrsreichen Standorten. Landw. Forschung 25, 73 (1970).Google Scholar
  52. Hevesy, G.: LIII. The absorption and translocation of lead by plants. A contribution to the application of the method of radioactive indicators in the investigation of the change of substance in plants. Biochem. J. 17, 439 (1923).PubMedGoogle Scholar
  53. Hirschler, D. A., and L. F. Gilbert: Nature of lead in automobile exhaust gas. Amer. Med. Assoc. Environ. Health, p. 297 (1964).Google Scholar
  54. Hooper, M. C.: An investigation of the effect of lead on plants. Ann. Applied Biol. 24, 690 (1937).Google Scholar
  55. Hopkinson, J. M., R. H. Wilson, and B. N. Smith: Lead levels in plants. Naturwissenschaften 59, 421 (1972).Google Scholar
  56. Jones, L. H. P., S. C. Jarvis, and D. W. Cowling: Lead uptake from soils by perennial ryegrass and its relation to the supply of essential element (sulphur). Plant and Soil 38, 605 (1973).Google Scholar
  57. Jowett, D.: Populations of Agrostis ssp. tolerant of heavy metals. Nature 182, 816 (1958).Google Scholar
  58. - Population studies on lead tolerant Agrostis tenuis. Evolution 18, 70 (1964).Google Scholar
  59. Keaton, C. M.: The influence of lead compounds on the growth of barley. Soil Sci. 43, 401 (1937).Google Scholar
  60. Keller, Th., and H. Preis: Der Bleigehalt von Fichtennadeln als Indikator einer verkehrsbedingten Luftverunreinigung. Schweiz. Z. Forstwes. 118, 143 (1967).Google Scholar
  61. -, and R. Zuber: Über die Bleiaufnahme und Bleiverteilung in jungen Fichten. Forstwiss. Centralbl. 89, 20 (1970).Google Scholar
  62. Kerin, D.: The determination of heavy metals on plant material for the detection and determination of air pollution damage from metallurgy. Presented XVth Congress Internat. Union Forest Research Org., IUFRO-Working Group on Fume Damage, Sect. 24, Gainsville, Fla. (1971).Google Scholar
  63. -, and Z. Kerin: Bleikontamination von Milch und Honig durch Bleiaerosole der Industrie. Protectio vitae (Stuttgart, Kohlhammer) 82, 61 (1971).Google Scholar
  64. Kerin, Z.: Verunreinigungen von Gemüse aus Emissionen einer Bleihütte. Qual. Plant. Mat. veget, Den Haag 15, 372 (1968).Google Scholar
  65. - Relationship between the lead concentration in the tubers and the soil (Slovakian, summary in English). Agrochemija, Beograd, No. 9/10, p. 341 (1970).Google Scholar
  66. Kloke, A., and H. O. Leh: Verunreinigungen von Kulturpflanzen mit Blei aus Kraftfahrzeugabgasen. In: Air pollution. Proc. 1st Eur. Congress on Air Pollution on Plants and Animals. Wageningen, 1968, p. 295 (1969).Google Scholar
  67. -, and K. Riebartsch: Verunreinigungen von Kulturpflanzen mit Blei aus Kraftfahrzeugabgasen. Naturwissenschaften 51, 369 (1964).Google Scholar
  68. Koeppe, D. E., and R. J. Miller: Lead effects on corn mitochondrial respiration. Science 167, 1376 (1970).PubMedGoogle Scholar
  69. Lagerwerff, J. V., and A. W. Specht: Contamination of roadside soil and vegetation with cadmium, nickel, lead, and zinc. Environ. Sci. Technol. 4, 583 (1970).Google Scholar
  70. - - Uptake of cadium, lead and zinc by radish from soil and air. Soil Sci. 111, 129 (1971).Google Scholar
  71. Laveskog, A.: A method for determination of tetramethyl lead (TML) and tetraethyl lead (TEL) in air. Presented 2nd Internat. Clean Air Congress, Internat. Union Air Pollution Prevention Assoc, Washington, D.C. (1970).Google Scholar
  72. Lee, J. A.: Lead pollution from a factory manufacturing antiknock compounds. Nature 238, 165 (1972).PubMedGoogle Scholar
  73. Leh, H. O.: Verunreinigungen von Kulturpflanzen mit Blei aus Kraftfahrzeugabgasen. Gesunde Pflanzen 18, 21 (1966).Google Scholar
  74. Lipman, C. B., and P. S. Burgess: The effect of Cu, Zn, Fe, and Pb salts on ammonification and nitrification in soils. Univ. Calif. Publ. Agr. Sci. 1, 127 (1914).Google Scholar
  75. Maclean, A. J., R. L. Halstead, and B. J. Finn: Extractability of added lead in soils and its concentrations in plants. Can. J. Soil Sci. 49, 327 (1969).Google Scholar
  76. Martinez, J. D., M. Nathany, and V. Dharmarajan: Spanish moss, a sensor for lead. Nature 233, 564 (1971).PubMedGoogle Scholar
  77. Miles, C. D., J. R. Brandle, D. J. Daniel, O. Chu-Der P. D. Schnare, and D. J. Uhlik: Inhibition of photosystem II in isolated chloroplasts by lead. Plant Physiol. 49, 820 (1972).PubMedGoogle Scholar
  78. Mitchell, R. L., and J. W. S. Reith: The lead content of pasture herbage J. Sci. Food. Agr. 17, 437 (1966).Google Scholar
  79. Motto, H. L., R. H. Daines, D. M. Chilko, and C. K. Motto: Lead in soils and plants: Its relationship to traffic volume and proximity to highways. Environ. Sci. Technol. 4, 231 (1970).Google Scholar
  80. Mueller, P. K.: Discussion: Characterization of particulate lead in vehicle exhaust-experimental techniques. Environ. Sci. Technol. 4, 248 (1970).Google Scholar
  81. Murozumi, M., T. J. Chow, and C. C. Patterson: Chemical concentrations of pollutant lead aerosols, terrestrial dusts, and sea salts in Greenland and Antarctic snow strata. Geochim. Cosmochim. Acta 33, 1247 (1969).Google Scholar
  82. Nilsson, J.: Accumulation of metals in spruce needles and needle litter. Oikos 23, 132 (1972).Google Scholar
  83. Page, A., and T. J. Ganje: Accumulation of lead in soils for regions of high and low motor vehicle traffic density. Environ. Sci. Technol. 4, 140 (1970).Google Scholar
  84. - -, and M. S. Joshi: Lead quantities in plants, soils, and air near some major highways in southern California. Hilgardia 41, 1 (1971).Google Scholar
  85. Paluch, J., and St. Karweta: Die Akkumulierung von Zink und Blei im Boden und in Pflanzen. Referate VI. Internat. Arbeitstg. Forstl. Rauchschaden-Sachverst., Katowiče 9. - 14. 9. 1968, p. 127 (1968).Google Scholar
  86. - - Zink- und Bleiimmissionen aus einem Hüttenkombinat und ihre Wirkung auf Pflanzen und Böden. Ochrana powietrza 6, 2 (1970).Google Scholar
  87. Patterson, C. C.: Contaminated and natural lead environments of man. Arch. Environ. Health 11, 344 (1965).PubMedGoogle Scholar
  88. Peterson, P. J.: The distribution of zinc-65 in Agrostis tenuis Sibth. and A. stolonifera L. tissues. J. Exp. Bot. 20, 863 (1969).Google Scholar
  89. Prat, S.: The absorption of lead by plants. Amer. J. Bot. 14, 633 (1927).Google Scholar
  90. Ponert, J.: Einfluβ von Blei, Silber, Kupfer und Kalium auf den Gehalt an Kardenoliden in Blättern. Naturwissenschaften 51, 320 (1964).Google Scholar
  91. Quinche, J., R. Zuber, and E. Bovay: Les dépots de plomb provenant des gaz d’échapprement des véhicules automobiles le long des routes àforte densité de circulation. Phytopathol. Z. 66, 259 (1969).Google Scholar
  92. Raines, D. W.: Lead accumulation by wild oats (Avena fatua) in a contaminated area. Nature 233, 210 (1971).Google Scholar
  93. Rasmussen, E. K., and W. H. Henry: Effects of lead on the growth of sweet orange seedlings in nutrient solution cultures. Proc. Soil Sci. Soc. (Fla.) 23, 70 (1963).Google Scholar
  94. Report of the Eidgenössische Komission für Lufthygiene (1971).Google Scholar
  95. Report of the Committee on Biological Effects of Atmosphere Pollutant (1972).Google Scholar
  96. Robinson, E., F. L. Ludwig, J. E. DeVRIES, and P. E. Hopkins: Variations of atmospheric lead concentrations and type with particle size. Final Report PA-4211, Stanford Res. Inst. (1963).Google Scholar
  97. Rohmedeh, E., and E. Weber: Fichtenvergiftung durch Flugzeugabgase. Forstwis. Centbl. 89, 335 (1970).Google Scholar
  98. RÜHLING, A., and G. Tyler: Sorption and retention of heavy metals in the woodland moss Hylocomium splendens Hedw. Br. et Sch. Oikos 21, 92 (1970).Google Scholar
  99. Scharrer, K., and W. Schropp: Über die Wirkung des Bleis auf das Pflanzenwachstum. Z. Pfl. Erneahr. Düng. 43, 34 (1936).Google Scholar
  100. Seel, F.: Grundlagen der analytischen Chemie, 2. Aufl. Weinheim: BRD (1960).Google Scholar
  101. Singer, M. J., and L. Hanson: Lead accumulation in soils near highways in the Twin Cities metropolitan area. Soil Sci. Soc. Amer. Proc. 33, 152 (1969).Google Scholar
  102. Skaar, H., E. Ophus, and B. M. Gullvåg: Lead accumulation within nuclei of moss leaf cells. Nature 241, 215 (1973).Google Scholar
  103. Sommer, G., A. Rosopulo, and A. Klee: Die Bleikontamination von Pflanzen und Böden durch Kraftfahrzeugabgase. Z. Pflanzenernährung, Düngung u. Bodenkunde 130, 193 (1971).Google Scholar
  104. Stewart, J.: Chelation in the absorption and translocation of mineral elements. Ann. Rev. Plant Physiol. 14, 295 (1963).Google Scholar
  105. Stoklasa, J. M.: Influence of uranium and lead upon vegetation. Compt. rend. Acad. Sci. (Paris) 156, 153 (1913).Google Scholar
  106. Stutzer, A.: Weitere Erfahrungen mit der Anwendung sog. Reizstoffe. Dtsch. Landw. Pr. 41, 1 (1914).Google Scholar
  107. Suchodoller, A.: Untersuchungen über den Bleigehalt von Pflanzen in der Nähe von Straßen und über die Aufnahme und Translokation von Blei durch Pflanzen. Ber. Schweiz. Bot. Ges. 77, 266 (1967).Google Scholar
  108. Swaine, D. J., and R. L. Mitchell: Trace-element distribution in soil profiles. J. Soil Sci. 11, 347 (1960).Google Scholar
  109. Tammes, P. M. L., and J. van Die: Studies on phloem exudation from Yucca flaccida Haw. Translocation of macro- and micro-nutrients by the phloem sap stream. Koninkl. Ned. Acad. Wetenschap. Proc. (C) 69, 656 (1966).Google Scholar
  110. Ter Haar, G. L.: Air as a source of lead in edible crops. Environ. Sci. Technol. 4, 226 (1970).Google Scholar
  111. -, R. B. Holtzman, and H. F. Lucas, Jr.: Lead and lead 210 in rainwater. Nature 216, 353 (1967).PubMedGoogle Scholar
  112. -, and M. A. Bayard: Composition of airborne lead particles. Nature 232, 553 (1971).PubMedGoogle Scholar
  113. Trebst, A.: Neue Reaktionen und Substanzen im photosynthetischen Elektronentransport. Ber. Dtsch. Bot. Ges. 83, 373 (1970).Google Scholar
  114. Tso, T. C., and I. Fisenne: Translocation and distribution of lead-210 and polonium-210 supplied to tobacco plants. Radiation Bot. 8, 457 (1968).Google Scholar
  115. -, N. Harley, and L. T. Alexander: Source of lead-210 and polonium-210 in tobacco. Science 153, 880 (1966).PubMedGoogle Scholar
  116. Tunney, H., G. A. Fleming, A. N. O’Sullivan, and J. P. Molloy: Effects of lead-mine concentrates on lead content of ryegrass and pasture herbage. Irish J. Agr. Res. 11, 85 (1972).Google Scholar
  117. Tuominen, Y.: Studies on the strontium uptake on the Cladonia alpestris thallus. Ann. Bot. Fenn. 4, 1 (1967).Google Scholar
  118. Turner, R. G., and C. Marshall: The accumulation of 65Zn by root homogenates of zinc-tolerant and non-tolerant clones of Agrostis tenuis Sibth. New Phytol. 70, 539 (1971a).Google Scholar
  119. - - The accumulation of zinc by subcellular fractions of roots of Agrostis tenuis Sibth. in relation to zinc tolerance. New Phytol. 71, 671 (1971 b).Google Scholar
  120. Vallee, B. L., and D. D. Ulmer: Biochemical effects of mercury, cadmium, and lead. Ann. Rev. Biochem. 41, 91 (1972).PubMedGoogle Scholar
  121. Vakhmistrov, D. B.: Combined action of adenine and agents blocking the protein component of cell membranes on potassium accumulation by barley shoots. (In Russian) Fiziol. Rast. 16, 255 (1969).Google Scholar
  122. Völcker, J. A.: The Woburn pot culture experiments. J. R. Agr. Soc. (Eng.) 75, 306 (1914).Google Scholar
  123. Warren, H. V., and R. E. Delavault: Lead in some food crops and trees. J. Sci. Food Agr. 13, 96 (1962).Google Scholar
  124. Welkins, D. A.: A technique for the measurement of lead tolerance in plants. Nature 180, 37 (1957).Google Scholar
  125. Yodaiken, R. E.: Cited by Skaar et al. (1973).Google Scholar
  126. Ziegler, H.: Untersuchungen über die Leitung und Sekretion der Assimilate. Planta 47, 447 (1956).Google Scholar
  127. Zlochevskaya, A.: Toxic effect of a lead complex with DL-cysteine on Aspergillus niger. (In Russian). Mikrobiologiya 37, 848 (1968).Google Scholar
  128. Zuber, R.: Die Bestimmung des Bleis in pflanzlichem Material mit Hilfe des Atomabsorptionssektrophotometers. Mitt. Lebensmittelunters. Hyg., Bern 63, 229 (1972).Google Scholar
  129. -, and E. Bovay: L’assorbimento del piombo da parte della pianta tramite la radice. Esperimenti preliminari sul problema in questione. Parte prima. Schweiz. Landw. Forsch. 11, 381 (1972).Google Scholar
  130. Zweig, G., and M. Avron: On the oxidation-reduction potentials of the photoproduced reductant of isolated chloroplasts. Biochem. Biophys. Res. Comm. 19, 397 (1965).PubMedGoogle Scholar

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© Springer-Verlag New York Inc 1975

Authors and Affiliations

  • Wolfgang Höll
  • Rüdiger Hampp
    • 1
  1. 1.Department of BotanyTechnical UniversityMünchen 2Germany

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