List of papers on 2D crystallization of proteins on phospholipid monolayers

Organized by theme:

• Papers utilizing phospholipid substrates:
• Methods-oriented: ( 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
• Structure-oriented: (3, 4, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50)
• Reviews: ( 15, 51, 52, 53, 54)
• Papers utilizing non-phospholipid substrates:
• Methods-oriented: ( 55, 56, 57)

Organized by protein:

• Electrostatic interactions:
• aerolysin : ( 33, 50)
• annexin : ( 14, 26, 29, 32, 48)
• -toxin : ( 30, 31, 49)
• -actinin: (46)
• creatine kinase : (40)
• 50S ribosomal subunit : (12)
• F-actin/thin filaments : (37, )
• RNA polymerase : (1, 18, 19, 20, 22, 42, 45)
• Specific binding:
• antibodies : ( 5, 6, 8, 10)
• avidin : ( 13, 21, 24)
• Botulinum toxin : ( 39)
• cholera toxin : ( 16, 25, 27, 34, 36)
• coagulation factor : ( 43)
• DNA gyrase B : ( 4, 17, 23, 41)
• reverse transcriptase : ( 3)
• tetanus toxin : ( 38)

1. F. J. Asturias and R. D. Kornberg (1995) A novel method for transfer of two-dimensional crystals from the air/water interface to specimen grids. EM sample preparation/lipid-layer crystallization. J. Struct. Biol., 114:60-66.

2. E. W. Kubalek, R. D. Kornberg and S. A. Darst (1991) Improved transfer of two dimensional crystals from the air/water interface to specimen support grids for high-resolution analysis by electron microscopy. Ultramicroscopy, 35:295-304.

3. E. W. Kubalek, S. F. LeGrice and P. O. Brown (1994) Two-dimensional crystallization of histidine-tagged HIV-1 reverse transcriptase promoted by a novel nickel-chelating lipid. J. Struct. Biol., 113:117-123.

4. L. Lebeau, S. Olland, P. Oudet and C. Mioskowski (1992) Rational design and synthesis of phospholipids for the two-dimensional crystallization of DNA gyrase, a key element in chromosome organization. Chemistry & Physics of Lipids, 62:93-103.

5. E. E. Uzgiris and R. D. Kornberg (1983) Two-dimensional crystallization technique for imaging macromolecules, with application to antigen-antibody-complement complexes. Nature, 301:125-129.

6. E. E. Uzgiris (1985) Antibody Crystallization on Phospholipid Films: Dynamics and the Effects of Antibody Conformation. J. Cell. Biochem., 29:239-251.

7. E. E. Uzgiris (1986) Supported phospholipid bilayers for two-dimensional protein crystallization. Biochem. Biophys. Res. Comm., 134:819-826.

8. E. E. Uzgiris (1987) Self-organization of IgE immunoglobulins on phospholipid films. Biochem. J., 242:293-296.

9. E. E. Uzgiris (1987) UV immobilized phospholipid bilayers. Biochem. Biophys. Res. Comm., 146:1116-1121.

10. E. E. Uzgiris (1990) Antibody organization on lipid films. Influence of pH and interchain disulphide reduction. Biochem. J., 272:45-49.

11. P. Fromhertz (1971) Electron microscopic studies of lipid protein films. Nature, 23:

12. A. J. Avila-Sakar, T.-L. Guan, T. Arad, M. F. Schmid, T. W. Loke, A. Yonath, J. Piefke, F. Franceschi and W. Chiu (1994) Electron cryomicroscopy of B. Stearothermophilus 50S ribosomal subunits crystallized on phospholipid monolayers. J. Mol. Biol., 239:689-697.

13. A. J. Avila-Sakar and W. Chiu (1996) Visualization of sheets and side chain clusters in 2-dimensional periodic arrays of streptavidin on phospholipid monolayers by electron crystallography. Biophys. J., 70:57-68.

14. A. Brisson, G. Mosser and R. Huber (1991) Structure of soluble and membrane-bound human annexin V. J. Mol. Biol., 220:199-203.

15. A. Brisson, A. Olofsson, P. Ringler, M. Schmutz and S. Stoylova (1994) Two-dimensional crystallization of proteins on planar lipid films and structure determination by electron crystallography. Biology of the Cell, 80:221-228.

16. D. Cabral-Lilly, G. E. Sosinsky, R. A. Reed, M. R. McDermott and G. G. Shipley (1994) Orientation of cholera toxin bound to model membranes. Biophys. J., 66:935-941.

17. H. Celia, L. Hoermann, P. Schultz, L. Lebeau, V. Mallouh, D. B. Wigley, J. C. Wang, C. Mioskowski and P. Oudet (1994) Three-dimensional model of Escherichia coli gyrase B subunit crystallized in two-dimensions on novobiocin-linked phospholipid films. J. Mol. Biol., 236:618-628.

18. S. A. Darst, H. O. Ribi, D. W. Pierce and R. D. Kornberg (1988) Two-dimensional Crystals of Escherichia coli Polymerase Holoenzyme on Positively Charged Lipid Layers. J. Mol. Biol., 203:269-273.

19. S. A. Darst, E. W. Kubalek and R. D. Kornberg (1989) Three-dimensional structure of Escherichia coli RNA polymerase holoenzyme determined by electron crystallography. Nature, 340:730-2.

20. S. A. Darst, A. M. Edwards, E. W. Kubalek and R. D. Kornberg (1991) Three-dimensional structure of yeast RNA polymerase II at 16 Å resolution. Cell, 66:121-8.

21. S. A. Darst, M. Ahlers, P. H. Meller, E. W. Kubalek, R. Blankenburg, H. O. Ribi, H. Ringsdorf and R. D. Kornberg (1991) Two-dimensional crystals of streptavidin on biotinylated lipid layers and their interactions with biotinylated macromolecules. Biophys. J., 59:387-396.

22. A. M. Edwards, S. A. Darst, W. J. Feaver, N. E. Thompson, R. R. Burgess and R. D. Kornberg (1990) Purification and lipid-layer crystallization of yeast RNA polymerase II. Proc. Natl. Acad. Sci. USA, 87:2122-2126.

23. L. Lebeau, E. Regnier, P. Schultz, J. C. Wang, C. Mioskowski and P. Oudet (1990) Two-dimensional crystallization of DNA gyrase B subunit on specifically designed lipid monolayers. FEBS letters, 267:38-42.

24. Z. Liu, H. Qin, C. Xiao, S. Wang and S. F. Sui (1995) Specific binding of avidin to biotin containing lipid lamella surfaces studied with monolayers and liposomes. European Biophysics Journal, 24:31-38.

25. D. S. Ludwig, H. O. Ribi, G. K. Schoolnik and R. D. Kornberg (1986) Two-dimensional crystals of cholera toxin B subunit-receptor complexes: projected structure at 17 Å resolution. Proc. Natl. Acad. Sci. USA, 83:8585-8.

26. G. Mosser, C. Ravanat, J. M. Freyssinet and A. Brisson (1991) Sub-domain structure of lipid-bound annexin-V resolved by electron image analysis. J. Mol. Biol., 217:241-245.

27. G. Mosser, V. Mallouh and A. Brisson (1992) A 9 Å two-dimensional projected structure of cholera toxin B-subunit-Gm1 complexes determined by electron crystallography. J. Mol. Biol., 226:23-28.

28. R. Newman, A. Tucker, C. Ferguson, D. Tsernoglou, K. Leonard and M. J. Crumpton (1989) Crystallization of p68 on lipid monolayers and as three-dimensional single crystals. J. Mol. Biol., 206:213-219.

29. R. H. Newman, K. Leonard and M. J. Crumpton (1991) 2D crystal forms of annexin IV on lipid monolayers. FEBS Letters, 279:21-24.

30. A. Olofsson, U. Kavéus, I. Hacksell, M. Thelestam and H. Herbert (1990) Crystalline Layers and Three-dimensional Structure of Staphylococcus aureus -Toxin. J. Mol. Biol., 214:299-306.

31. A. Olofsson, H. Hebert and M. Thelestam (1991) The structure of Staphylococcus aureus alpha-toxin: effects of trypsin treatment. J. Struct. Biol., 106:199-204.

32. A. Olofsson, V. Mallouh and A. Brisson (1994) Two-dimensional structure of membrane-bound annexin V at 8Å resolution. J. Struct. Biol., 113:199-205.

33. M. W. Parker, J. T. Buckley, J. P. M. Postma, A. D. Tucker, K. Leonard, F. Pattus and D. Tsernoglou (1994) Structure of the Aeromonas toxin proaerolysin in its water-soluble and membrane-channel states. Nature, 367:292-295.

34. R. A. Reed, J. Mattai and G. G. Shipley (1987) Interaction of cholera toxin with ganglioside Gm1 receptors in supported monolayers. Biochemistry, 26:824-832.

35. H. O. Ribi, P. Reichard and R. D. Kornberg (1987) Two-dimensional crystals of enzyme-effector complexes: ribonucleotide reductase at 18 Å resolution. Biochemistry, 26:7974-7979.

36. H. O. Ribi, D. S. Ludwig, K. L. Mercer, G. K. Schoolnik and R. D. Kornberg (1988) Three-dimensional structure of cholera toxin penetrating a lipid membrane. Science, 239:1272-1276.

37. L. Rioux and C. Gicquaud (1985) Actin paracrystalline sheets formed at the surface of positively charged liposomes. J. Ultrastruct. Res., 93:42-49.

38. J. P. Robinson, M. F. Schmid, D. G. Morgan and W. Chiu (1988) Three-dimensional structural analysis of tetanus toxin by electron crystallography. J. Mol. Biol., 200:367-375.

39. M. F. Schmid, J. P. Robinson and B. R. DasGupta (1993) Direct visualization of botulinum toxin-induced channels in phospholipid vesicles. Nature, 364:827-830.

40. T. Schnyder, M. Cyrklaff, K. Fuchs and T. Wallimann (1994) Crystallization of mitochondrial creatine kinase on negatively charged lipid layers. J. Struct. Biol., 112:136-147.

41. P. Schultz, J. C. Wang, C. Mioskowski and P. Oudet (1990) Two-dimensional crystallization of DNA gyrase B subunit on specifically designed lipid monolayers. FEBS Letters, 267:38-42.

42. P. Schultz, H. Célia, S. A. Darst, P. Colin, R. D. Kornberg, A. Sentenac and P. Oudet (1990) Structural study of the yeast RNA polymerase A. Electron microscopy of lipid-bound molecules and two-dimensional crystals. J. Mol. Biol., 216:353-362.

43. S. Stoylova, K. G. Mann and A. Brisson (1994) Structure of membrane-bound human factor Va. FEBS Letters, 351:330-334.

44. K. A. Taylor and D. W. Taylor (1992) Formation of 2-D paracrystals of F-actin on phospholipid layers mixed with quaternary ammonium surfactants. J. Struct. Biol., 108:140-147.

45. P. Schultz, H. Celia, M. Riva, A. Sentenac and P. Oudet (1993) Three-dimensional model of yeast RNA polymerase I determined by electron microscopy of two-dimensional crystals. EMBO J., 12:2601-2607.

46. K. A. Taylor and D. W. Taylor (1993) Projection image of smooth muscle alpha-actinin from two-dimensional crystals formed on positively charged lipid layers. J. Mol. Biol., 230:196-205.

47. A. Tomioka, H. O. Ribi, M. Tokunaga, T. Furuno, H. Sasabe, K. Miyano and T. Wakabayashi (1991) Structural analysis of muscle thin filament. Advances in Biophysics, 27:169-183.

48. D. Voges, R. Berendes, A. Burger, P. Demange, W. Baumeister and R. Huber (1994) Three-dimensional structure of membrane-bound annexin V. A correlative electron microscopy-X-ray crystallography study. J. Mol. Biol., 238:199-213.

49. R. J. Ward and K. Leonard (1992) The Staphyloccoccus aureus alpha-toxin channel complex and the effect of Ca² ions on its interaction with lipid layers. J. Struct. Biol., 109:129-141.

50. H. U. Wilmsen, K. R. Leonard, W. Tichelaar, J. T. Buckley and F. Pattus (1992) The aerolysin membrane channel is formed by heptamerization of the monomer. EMBO J., 11:2457-2463.

51. R. A. Kornberg and H. O. Ribi (1987) Formation of two-dimensional crystals of proteins on lipid layers. In: Protein Structure, Folding and Design, ed. by D. L. Oxender, Alan R. Liss, NY, pp. 175-186.

52. B. K. Jap, M. Zulauf, T. Scheybani, A. Hefti, W. Baumeister, U. Aebi and A. Engel (1992) 2D crystallization: from art to science. Ultramicroscopy, 46:45-84.

53. R. D. Kornberg and S. A. Darst (1991) Two dimensional crystals of proteins on lipid layers. Curr. Opin. Struct. Biol., 1:632-646.

54. M. Ahlers, S. A. Darst, D. W. Grainger, R. D. Kornberg, W. Müller, A. Reichert, H. Ringsdorf, E. Rump and C. Salesse (1990) Interaction of proteins with functional monolayers: recognition, 2D-crystallization and function: pp. 608-609. In: Proc. XIIth Int'l. Cong. Electron Microsc., Seattle, WA.

55. H. Yoshimura, M. Matsumoto and K. Nagayama (1990) Two-dimensional crystallization of proteins on mercury. Ultramicroscopy, 32:265-274.

56. H. Yoshimura, T. Scheybani, W. Baumeister and K. Nagayama (1994) Two-dimensional array growth in thin layers of protein solution on aqueous subphases. langmuir, 10:3290-3295.

57. K. Aoyama, K. Ogawa, Y. Kimura and Y. Fujiyoshi (1995) A method for 2D crystallization of soluble proteins at liquid-liquid interface. Ultramicroscopy, 57:345-354.

Created: may 30th 1996
Last modified: may 30th 1996