Hydrophobic Effects. Opinions and Facts
Tóm tắt
The term hydrophobic interactions denotes the tendency of relatively apolar molecules to stick together in aqueous solution. These interactions are of importance in many chemical disciplines, including the chemistry of in vivo processes. Enzyme‐substrate interactions, the assembly of lipids in biomembranes, surfactant aggregation, and kinetic solvent effects in water‐rich solutions are all predominantly governed by hydrophobic interactions. Despite extensive research efforts, the hydration of apolar molecules and the noncovalent interactions between these molecules in water are still poorly understood. In fact, the question as to what the driving force for hydrophobic intractions is shifts the study into a quest for a detailed understanding of the remarkable properties of liquid water. This review highlights some of the novel insights that have been obtained in the past decade. The emphasis is on both hydrophobic hydration and hydrophobic interactions since both phenomena are intimately connected. Several traditional views have been found to be deeply unsatisfactory, and courageous attempts have been made to conceptualize the driving force behind pairwise and bulk hydrophobic interactions. The review presents an admittedly personal selection of the recent experimental and theoretical developments, and when necessary, reference is made to relevant studies of earlier date.
Từ khóa
Tài liệu tham khảo
Water Compr. Treatise 1972–1982 1973 1–7
Tanford C., 1980, The Hydrophobic Effect
Luck W. A. P., 1974, Structure of Water and Aqueous Solutions
M. H.Abraham P. L.Grellier R. A.McGill J. Chem. Soc. Perkin Trans. 21988 339.
See [12].
Huidt A., 1992, Protein Interactions, 327
J. L.Finney Water Compr. Treatise 1972–1982 1979 Vol. 5 Chap. 2.
H. J. C.Berendsen Water Compr. Treatise 1972–19821979 Vol. 5 Chap. 6.
See [42].
Dugas H., 1986, Bioorganic Chemistry
Roberts S. M., 1989, Molecular Recognition: Chemical and Biochemical Problems
Vögtle F., 1991, Supramolecular Chemistry
Schneider H.‐J., 1991, Frontiers in Supramolecular Organic Chemistry and Photochemistry
G. H.Giles D. G.Duff Water Compr. Treatise 1972–19821979 Vol. 4 Chap. 5.
Stryer L., 1981, Biochemistry
Fuhrhop J.‐H., 1990, J. Am. Chem. Soc., 112, 4207
Evans D. F., 1989, Water Science Reviews
Lumry R., 1986, The Fluctuating Enzyme
Israelachvili J. N., 1991, Intermolecular and Surface Forces
Kjellander R., 1985, Chem. Scr., 25, 73
Ahlström A., 1989, Chem. Scr. A, 29, 97
M. D.ZeidlerWater Compr. Treatise 1972–19821973 2 Chap. 10.
G. E.Walrafen Water Compr. Treatise 1972–1982 1973 1 Chap. 5.
W. A. P.Luck Water Compr. Treatise 1972–19821973 2 Chap. 5.
M. J.Blandamer Water Compr. Treatise 1972–19821973 2 Chap. 9.
J. C.DoreinWater Science Reviews Vol. 1 (Ed.: F. Franks) Cambridge 1985 p. 3.
J. E.Enderby G. W.Neilson Water Compr. Treatise 1972–19821979 6 Chap. 1.
J. B. F. N.Engberts Water Compr. Treatise 1972–19821979 6 Chap. 4.
H.‐J.Schneider N. K.Sangwan J. Chem. Soc. Perkin Trans. 21989 1223
I.Hunt C. D.Johnson J. Chem. Soc. Perkin Trans. 21991 1051.
Lumry R., 1978, Proc. 6th Int. Biophys. Congr., 7, 554
Lumry R., 1980, Bioenergetics and Thermodynamics, Model Systems
Matteoli E., 1990, Fluctuation Theory of Mixtures
McQuarrie D. A., 1976, Statistical Mechanics
Gurney R. W., 1953, Ionic Processes in Solution
See [243].
See [244].
See [168].
Sinanoglu O., 1968, Molecular Association in Biology, 427
J. J.Moura‐Ramos M.Lemmers R.Ottinger M. L.Stien J.Reisse J. Chem. Res. Synop.1977 56.
Moura‐Ramos J. J., 1984, Rev. Port. Quim., 26, 61
See [343].
Added in proof:B.Guillot Y.Guissani J. Chem. Phys in press.