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Castor Toxin Adsorption to Clay Minerals

Published online by Cambridge University Press:  01 January 2024

William F. Jaynes ,
Richard E. Zartman ,
Cary J. Green ,
Michael J. San Francisco  and
John C. Zak
William F. Jaynes*
Affiliation:
Plant and Soil Science Department, Texas Tech University, Lubbock, Texas 79409, USA
Richard E. Zartman
Affiliation:
Plant and Soil Science Department, Texas Tech University, Lubbock, Texas 79409, USA
Cary J. Green
Affiliation:
Plant and Soil Science Department, Texas Tech University, Lubbock, Texas 79409, USA
Michael J. San Francisco
Affiliation:
Biological Sciences Department, Texas Tech University, Lubbock, Texas 79409, USA
John C. Zak
Affiliation:
Biological Sciences Department, Texas Tech University, Lubbock, Texas 79409, USA
*
*E-mail address of corresponding author: [email protected]
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Abstract

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The extremely toxic protein, ricin, is derived from castor beans and is a potential terrorist weapon. Adsorption to clays might minimize the environmental persistence and toxic effects of this toxin. Ricin adsorption to clay minerals was measured using batch adsorption isotherms. Enzyme-linked immunoassay methods were used to quantify aqueous ricin concentrations. Montmorillonite, sepiolite and palygorskite effectively adsorbed ricin from aqueous solutions and yielded mostly Langmuir-type isotherms. The monolayer adsorption capacity from a Langmuir equation fit at pH 7 was 444 g ricin/kg for montmorillonite (SWy-2), but was only 5.6 g ricin/kg for kaolinite (KGa-1b). Monolayer capacities for sepiolite (SepSp-1) and palygorskite (PFl-1) at pH 7 were 59.2 and 58.1 g ricin/kg. The high-charge montmorillonite (SAz-1) effectively adsorbed ricin at pH 7, but yielded a linear isotherm with K = 5530 L/kg. At pH 5, both montmorillonites (SWy-2 and SAz-1) yielded Langmuir-type isotherms with monolayer capacities of 694 and 641 g ricin/kg. Clay samples with higher cation exchange capacities generally adsorbed more ricin, but adsorption also followed specific surface area. X-ray diffraction of <2 μm SWy-2 treated with 470 g ricin/kg indicated expansion up to 34.6 Å at buffered pHs of 4 and 7, but not at pH 10. Furthermore, ricin adsorption was greatest at pH 4 and 7, but minimal at pH 10. Treatment with 1.41 kg of purified ricin/kg clay at pH 5 yielded a 35.3 Å peak and adsorption of ~1.2 kg ricin/kg. Similar treatment with lower-purity ricin yielded less expansion and lower adsorption. The 35.3 Å peak interpreted either as a d002 or d001 reflection indicates a 70.6 Å or a 35.3 Å ricin/SWy-2 complex. This implies that adsorption and air drying have compressed interlayer ricin molecules by 18 to 65%. Effective ricin adsorption by montmorillonite suggests that it could be used to minimize the toxic effects of dispersed ricin.

Keywords

AdsorptionCation Exchange CapacityKaoliniteLectinMontmorillonitePalygorskitepHProteinRicinSepioliteSpecific Surface Area
Type
Research Article
Information
Clays and Clay Minerals , Volume 53 , Issue 3 , June 2005 , pp. 268 - 277
Copyright
Copyright © The Clay Minerals Society 2005

References

Boroda, E. Jaynes, W.F. Zartman, R.E. Green, C.J. San Francisco, M.J. and Zak, J.C., (2004) Enzyme-linked immunosorbent assay measurement of castor toxin in soils Communications in Soil Science and Plant Analysis 35 11851195.Google Scholar
Bouyoucos, G.J., (1962) Hydrometer method improved for making particle size analysis of soils Agronomy Journal 54 464465.Google Scholar
Bradford, M.M., (1976) A refined and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding Analytical Biochemistry 11 248254.Google Scholar
Brindley, G.W. (1980) Order-disorder in clay mineral structures. P. 172 in: Crystal Structures of Clay Minerals and their X-ray Identification (Brindley, G.W. and Brown, G. editors). Monograph 5, Mineralogical Society, London.Google Scholar
Carter, D.L. Mortland, M.M. Kemper, W.D. and Klute, A., (1986) Specific surface Methods of Soil Analysis. Part I. Physical and Mineralogical Methods 2nd Wisconsin Soil Science Society of America, Madison 413423.Google Scholar
Ding, X. and Henrichs, S.M., (2002) Adsorption and desorption of proteins and polyamino acids by clay minerals and marine sediments Marine Chemistry 77 225237.Google Scholar
Francis, C.W., (1973) Adsorption of polyvinylpyrrolidone on reference clay minerals Soil Science 115 4054.Google Scholar
Franz, D.R. Jaax, N.K. and Zajtchuk, R., (1997) Ricin toxin. Chapter 32 Medical Aspects of Chemical and Biological Warfare. Textbook of Military Medicine USA Published by The Office of the Surgeon General, US Army, Falls Church, Virginia.Google Scholar
Fu, L. Weckhuysen, B.M. Verberckmoes, A.A. and Schoonheydt, R.A., (1996) Clay intercalated Cu(II) amino acid complexes: synthesis, spectroscopy and catalysis Clays and Clay Minerals 31 491500.Google Scholar
Fusi, P. Ristori, G.G. Calamai, L. and Stotzky, G., (1989) Adsorption and binding of protein on ‘clean’ (homoionic) and ‘dirty’ (coated with Fe oxyhydroxides) montmorillonite, illite and kaolinite Soil Biology and Biochemistry 21 911920.Google Scholar
Garwood, G.A. Mortland, M.M. and Pinnavaia, T.J., (1983) Immobilization of glucose oxidase on montmorillonite clay: hydrophobic and ionic modes of binding Journal of Molecular Catalysis 22 153163.Google Scholar
Goh, K.M., (1972) Amino acid levels as indicators of paleosols in New Zealand soil profiles Geoderma 7 3347.Google Scholar
Hartley, M.R. and Lord, J.M., (1993) Structure, function and applications of ricin and related cytotoxic proteins Plant Biotechnology 3 210239.Google Scholar
Hiemenz, P.C., (1986) Principles of Colloid and Surface Chemistry. New York Marcel Dekker 398407.Google Scholar
Jaynes, W.F. and Bigham, J.M., (1986) Multiple cationexchange capacity measurements on standard clays using a commercial mechanical extractor Clays and Clay Minerals 34 9398.Google Scholar
Jaynes, W.F. and Bigham, J.M., (1987) Charge reduction, octahedral charge, and lithium retention in heated, Lisaturated smectites Clays and Clay Minerals 35 440448.Google Scholar
Jaynes, W.F. and Boyd, S.A., (1991) Clay mineral type and organic compound sorption by hexadecyltrimethylammonium-exchanged clays Soil Science Society of America Journal 55 4348.Google Scholar
Katzin, B.J. Collins, E.J. and Robertus, J.D., (1991) The structure of ricin A chain at 2.5 Å Proteins: Structure, Function, and Genetics 10 251259.Google Scholar
Liener, I.E., (1997) Plant lectins: properties, nutritional significance, and function Antinutrients and Phytochemicals in Food 662 3143.Google Scholar
MacEwan, D.M.C. and Wilson, M.J., (1980) Interlayer and intercalation complexes of clay minerals Crystal Structures of Clay Minerals and their X-ray Identification 5 203.Google Scholar
Merck, , (2001) The Merck Index, An Encyclopedia of Chemicals, Drugs and Biologicals. New Jersey Merck Research Laboratories Division of Merck & Co., Inc. Whitehouse Station 8290.Google Scholar
Montfort, W. Villafranca, J.E. Monzingo, A.F. Ernst, S.R. Katzin, B. Rutenber, E. Xuong, N. Hamlin, R. and Robertus, J.D., (1987) The three-dimensional structure of ricin at 2.8 Â Journal of Biological Chemistry 262 53985403.Google Scholar
Mortland, M.M. and Raman, K.V., (1968) Surface acidity of smectites in relation to hydration, exchangeable cation, and structure Clays and Clay Minerals 16 393398.Google Scholar
Nicolson, G.L. and Blaustein, J., (1972) The interaction of Ricinus communis agglutinin with normal and tumor cell surfaces Biochimica Biophysics Acta 266 543547.Google Scholar
Norde, W., (2003) Colloids and Interfaces in Life Sciences. New York Marcel Dekker, Inc. 285311.Google Scholar
Olsnes, S. and Pihl, A., (1973) Different biological properties of the two constituent peptide chains of ricin, a toxic protein inhibiting protein synthesis Biochemistry 12 31213126.Google Scholar
Owens, D., (2000) Hidden Evidence. Forty True Crimes and How Forensic Science Helped Solve Them. New York Firefly Books, Inc., Buffalo.Google Scholar
Perez-Castells, R. Alvarez, A. Gavilanes, J. Lizarbe, M.A. Martinez Del Pozo, A. Olmo, N. and Santaren, J., (1985) Adsorption of collagen by sepiolite Proceedings of the International Clay Conference, Denver, 1985 359362.Google Scholar
Rausell-Colom, J.A. and Fornes, V., (1974) Monodimensional fourier analysis of some vermiculite-l-ornithine+ complexes American Mineralogist 59 790798.Google Scholar
Rausell-Colom, J.A. and Serratosa, J.M., (1987) Reactions of clays with organic substances Chemistry of Clays and Clay Minerals 6 392.Google Scholar
Rutenber, E. Katzin, B.J. Ernst, S. Collins, E.J. Mlsna, D. Ready, M.P. and Robertas, J.D., (1991) Crystallographic refinement of ricin to 2.5 Å Proteins: Structure, Function, and Genetics 10 240250.Google Scholar
Sigma, , (2000) Sigma 2000/2001 Catalog. USA Sigma-Aldrich Company. P.O. Box 14508. St. Louis, Missouri 63178 1477.Google Scholar
Singer, A., Dixon, J.B. and Schulze, D.G., (2002) Palygorskite and sepiolite Soil Mineralogy with Environmental Applications Wisconsin Published by the Soil Science Society of America, Madison 563.Google Scholar
Stryer, L., (1975) Introduction to protein structure and function. Chapter 2 Biochemistry. San Francisco, CA W.H. Freeman & Company..Google Scholar
Van Olphen, H. and Fripiat, J.J., (1979) Data Handbook for Clay Materials and Other Non-metallic Minerals. New York Pergamon Press.Google Scholar
Villafranca, J.E. and Robertas, J.D., (1977) Crystallographic study of the anti-tumor protein ricin Journal of Molecular Biology 116 331335.Google Scholar
Yu, C.H. Norman, M.A. Newton, S.Q. Miller, D.M. Teppen, B.J. and Schafer, L., (2000) Molecular dynamics simulations of the adsorption of proteins on clay mineral surfaces Journal of Molecular Structure 556 95103.Google Scholar