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Quantitative aspects of antigen-antibody reactions. I. A theory and its corollaries1

Published online by Cambridge University Press:  15 May 2009

Torsten Teorell
Affiliation:
From the Institute of Physiology, University of Uppsala, Uppsala, Sweden
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1. A quantitative theory has been developed for the reactions between antigens and antibodies, applicable in particular to the precipitin reaction. The theory is equally applicable to unspecific precipitations, for instance the reaction between proteins and protein precipitating agents such as nucleic acids, etc.

2. The theory is based on the concept that the antigen-antibody interaction is governed by the same principles as the dissociation of a polybasic acid, HNT, where the antibody corresponds to the hydrogen ion H, and the antigen to the anion T. In their mutual reactions the antigen G is supposed to be polyvalent and the antibody A monovalent: hence the result of the interaction is a mixture of compounds ANG, AN-1G, …, AG.

3. A mathematical deduction is performed starting from the law of mass action, which leads to expressions for the amounts of total precipitate and its constituents in terms of the quantities of antigen and antibody which were mixed and the known equilibria constants.

4. A numerical example is given for a tetravalent antigen. Three cases are represented in graphical forms: the ‘X case’ without inhibition zones, the ‘Y case’ with one and the ‘Z case’ with two inhibition zones. Certain characteristics are described and the significance of the ‘equivalence point’ is analysed.

5. A discussion deals with the irreversibility in relation to the Danysz phenomenon and the dilution effect, and finally the parameters of the theory are more closely considered.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1946

References

Adams, E. Q. (1916). J. Amer. Chem. Soc. 38, 1503.CrossRefGoogle Scholar
Arrhenius, S. & Madsen, (1907). Immunochemie, by S., Arrhenius. Leipzig.Google Scholar
Bjerrum, J. (1941). Metal ammine formation in aqueous solution. Diss. Copenhagen.Google Scholar
Björnesjö, C. B. & Teorell, T. (1945). Ark. Kemi, Min. Geol. (Stockholm), 19A, 1.Google Scholar
Bordet, J. (1939). Traité de l'immunité. Paris.Google Scholar
Boyd, V. C. & Hooker, S. B. (1934). J. Gen. Physiol. 17, 341.CrossRefGoogle Scholar
Boyd, V. C. & Hooker, S. B. (1936). J. Immunol. 30, 33.Google Scholar
Boyd, V. C. & Hooker, S. B. (1939). J. Gen. Physiol. 22, 281.CrossRefGoogle Scholar
Britton, H. T. S. (1942). Hydrogen Ions. London.Google Scholar
Burnet, F. M. (1931). J. Path. Bact. 34, 471.CrossRefGoogle Scholar
Campbell, & Fourt, (1936). J. Biol. Chem. 385, 129.Google Scholar
Haurowitz, F. (1939). Chemie der Antigene und der Antikörper, p. 19. Fortschr. der Allergielehre, ed. by P., Kallós, Basel. New York.Google Scholar
Heidelberger, M. (1938). J. Amer. Chem. Soc. 60, 242.CrossRefGoogle Scholar
Heidelberger, M. & Kendall, F. E. (1935). J. Exp. Med. 62, 467.CrossRefGoogle Scholar
Heidelberger, M. & Pedersen, K. O. (1937). J. Exp. Med. 65, 393.CrossRefGoogle Scholar
Hooker, S. B. & Boyd, W. C. (1942). J. Immunol. 45, 127.CrossRefGoogle Scholar
How, A. E. (1939). J. Immunol. 37, 77.CrossRefGoogle Scholar
Kleczkowski, A. (1941). Brit. J. Exp. Path. 22, 44.Google Scholar
Marrack, J. R. (1938). The Chemistry of Antigens and Antibodies. London: Medical Research Council.Google Scholar
Pauling, L. (1940). J. Amer. Chem. Soc. 62, 2643.CrossRefGoogle Scholar
Pauling, L., Pressman, D., Campbell, D. H. & Ikeda, C. (1942). J. Amer. Chem. Soc. 64, 3003.CrossRefGoogle Scholar
Porter, E. F. & Pappenheimer, A. W. (1939). J. Exp. Med. 69, 755.CrossRefGoogle Scholar
Stenhagen, E. Personal communication.Google Scholar
Teorell, T. (1943). Nature, Lond., 151, 696.CrossRefGoogle Scholar
Wegscheider, (1895). Mh. Chem. 16, 153.Google Scholar