Amphiphile-induced vesiculation in aged hereditary spherocytosis erythrocytes indicates normal membrane stability properties under non-starving conditions

References

• Agre, P., Casella, J. F., Zinkham, W. H., McMillan, C. and Bennett, V., 1985, Partia l deficiency of erythrocyte spectrin in hereditary spherocytosis. Nature, 314, 380 ± 383.
   PubMed Web of Science ®Google Scholar
• Allan, D., Billah, M. M., Finean, J. B. and Michell, R. H., 1976, Releas e of diacylglycerol-enriched vesicles from erythrocyte s with increased intracellula r (Ca2+). Nature, 261, 58 ± 60.
   PubMed Web of Science ®Google Scholar
• Backman, L. BjoÈrk-Jonasson, J. and Horstedt, P., 1998, Phosphoi- nositide metabolis m and shape control in sheep red blood cells. Molecular Membrane Biology, 15, 27 ± 32.
   Google Scholar
• Billington, D. and Coleman, R., 1978, Effects of bile salts on human erythrocytes. Plasma membrane vesiculation, phospholipid solu- bilization and their possible relationship to bile secretion. Biochimica et Biophysica Acta, 509, 33 ± 47.
   PubMedGoogle Scholar
• BjoÈrk, J., Reardon, D. M. and Backman, L., 1997, Phosphoinositide metabolis m in hereditary ovalocytic red blood cell membranes. Biochimica et Biophysica Acta, 1326, 342 ± 348.
   Google Scholar
• Bobrowska-HaÈgerstrand, M., HaÈgerstrand, H. and Iglic, A., 1998, Membrane skeleton and red blood cell vesiculation at low pH. Biochimica et Biophysica Acta, 1371, 123 ± 128.
   Google Scholar
• BuÈtikofer, P., Kuypers, F. A., Xu, C. M., Chiu, D. T. Y. and Lubin, B., 1989b, Enrichment of two glycosyl-phosphatidylinositol-anchored proteins, acetylcholinestera s e and decay accelerating factor, in vesicles releas ed from human red blood cells. Blood, 74, 1481 ± 1485.
   Google Scholar
• BuÈtikofer, P., Lin, Z. W., Kuypers, F. A., Scott, M. D., Xu, C. M., Wagner, G. M., Chiu, D. T. and Lubin, B., 1989a, Chlorpromazine inhibits vesiculation, alters phosphoinositide turnover and changes deformability of ATP-depleted RBCs. Blood, 73, 1699 ± 1704. Cho, M. R., Eber, S. W., Liu, S. C., Lux, S. E. and Golan, D. E., 1998, Regulation of band 3 rotational mobility by ankyrin in intact human red cells. Biochemistry, 37, 17828 ± 17835.
   Google Scholar
• de Franceschi, L., Olivieri, O., Miraglia del Giudice, E., Perrotta, S., Sabato, V., Corrocher, R. and Iolascon, A., 1997, Membrane cation and anion transport activitie s in erythrocyte s of hereditary spherocytosis: effects of different membrane protein defects. American Journal of Hematology, 55, 121 ± 128.
   Google Scholar
• de Jong, K., Larkin, S. K., E ber, S., Franck, P. F., Roelofs en, B. and Kuypers, F. A., 1999, Hereditary spherocytosis and elliptocytosis erythrocytes show a normal transbilaye r phospholipid distribution. Blood, 94, 319 ± 325.
   Google Scholar
• Delaunay, J., 1995, Genetic disorders of the red cell membrane. Critical Reviews in Oncology/Hematology, 19, 79 ± 110.
   PubMed Web of Science ®Google Scholar
• Delaunay, J., Alloisio, N. and Morle, L., 1996, Molecula r genetics of hereditary spherocytosis. Cellular Molecular Biology Letters, 1, 49 ± 65.
   Google Scholar
• Delaunay, J., Stewart, G. and Iolascon, A., 1999, Hereditary dehydrated and overhydrated stomatocytosis: recent advances. Current Opinions in Hematology, 6, 110 ± 114.
   Google Scholar
• Eber, S. W., Gonzalez, J. M., Lux, M. L., Scarpa, A. L., Tse, W. T., Dornwell, M., Herbers, J., Kugler, W., Ozcan, R., Pekrun, A., Gallagher, P. G., Schroter, W., Forget, B. G. and Lux, S. E., 1996, Ankyrin-1 mutations are a major cause of dominant and recessive hereditary spherocytosis. Nature Genetetics, 13, 214 ± 218.
   PubMed Web of Science ®Google Scholar
• Ellman, G. L., Courtney, K. D., Andres Jr., V. and Featherstone, R. M., 1961, A new and rapid colorimetric determination of acetylcholinestera s e activity. Biochemical Pharmacology, 7, 88 ± 95.
   Google Scholar
• Ferrell, J. E. and Huestis, W. H., 1984, Phosphoinositide metabolis m and the morphology of human erythrocytes. Journal of Cell Biology, 98, 1992 ± 1998.
   Google Scholar
• Gascard, P., Sauvage, M., Sulpice, J. C. and Giraud, F., 1993, Characterization of structural and functional phosphoinositide domains in human erythrocyte membranes. Biochemistry, 32, 5941 ± 5948.
   PubMed Web of Science ®Google Scholar
• Gimsa, J. and Ried, C., 1995, Do band 3 protein conformational changes mediate shape changes of human erythrocytes ? Molecular Membrane Biology, 12, 247 ± 254.
   PubMed Web of Science ®Google Scholar
• Haest, C. W. M., 1982, Interactions between membrane skeleton proteins and the intrinsic domain of erythrocyte membrane. Biochimica et Biophysica Acta, 694, 331 ± 352.
   PubMed Web of Science ®Google Scholar
• Haest, C. W. M., Fischer, T. M., Plasa, G. and Deuticke, B., 1980, Stabilization of erythrocyte shape by a chemical increas e in membrane stiffness. Blood Cells, 6, 539 ± 553.
   PubMedGoogle Scholar
• Hagelberg, C. and Allan, D., 1990, Restricted diffusion of integral membrane proteins and polyphosphoinositides leads to their depletion in microvesicle s releas ed from human erythrocytes. Biochemical Journal, 271, 831 ± 834.
   PubMed Web of Science ®Google Scholar
• HaÈgerstrand, H. and Isomaa, B., 1989, Vesiculation induced by amphiphiles in erythrocytes. Biochimica et Biophysica Acta, 982, 179 ± 186.
   Google Scholar
• HaÈgerstrand, H. and Isomaa, B., 1991, Amphiphile-induced anti- haemolysis is not causally related to shape changes and vesiculation. Chemico- Biologica l Interactions, 79, 335 ± 347.
   Google Scholar
• HaÈgerstrand, H. and Isomaa, B., 1992, Morphological characteriza- tion of exovesicles and endovesicles released from human erythrocytes following treatment with amphiphiles. Biochimica et Biophysica Acta, 1109, 117 ± 126.
   Google Scholar
• HaÈgerstrand, H. and Isomaa, B., 1994, Lipid and protein composition of exovesicles releas ed from human erythrocytes following treatment with amphiphiles. Biochimica et Biophysica Acta, 1190, 409 ± 415.
   Google Scholar
• HaÈgerstrand, H., Danieluk, M., Bobrowska-HaÈgerstrand, M., Iglic, A., Wrobel, A., Isomaa, B. and Nikinmaa, M., 2000, Influence of band 3 protein abs ence and skeletal structures on amphiphile and Ca2+ induced shape alterations in erythrocytes: a study with lamprey (Lampetra fluviatilis), trout (Onchorhynchus mykiss) and human erythrocytes. Biochimica et Biophysica Acta, 1466, 125 ± 138.
   Google Scholar
• HaÈgerstrand, H., Kralj-Iglic, V., Bobrowska-HaÈgerstrand, M. and Iglic, A., 1999, Membrane skeleton detachment in spherica l and cylindrica l microexovesicles. Bulletin of Mathematical Biology, 61, 1019 ± 1030.
   Google Scholar
• Holroyde, C. P. and Gardner, F. H., 1970, Acquisition of autophagic vacuoles by human erythrocytes. Physiological role of the spleen. Blood, 36, 566 ± 575.
   Google Scholar
• Iglic, A., 1997, A possible mechanism determining the stability of spiculated red blood cells. Journal of Biomechanics, 30, 35 ± 40.
   PubMed Web of Science ®Google Scholar
• Iglic, A. and HaÈgerstrand, H., 1999, Amphiphile induced spherical microexovesicle corresponds to an extreme local area difference between two monolayers of the membrane bilayer. Medical & Biological Engineering & Computing, 37, 125 ± 129.
   PubMed Web of Science ®Google Scholar
• Iglic, A., HaÈgerstrand, H., Bobrowska-HaÈgerstrand, M. and Kralj- Iglic, V., 1998, A possible physical mechanism of red blood cell vesiculation occurring due to incubation at high pH. Journal of Biomechanics, 31, 151 ± 156.
   Google Scholar
• Iglic, A., Svetina, S. and Zeks, B., 1995, Depletion of membrane skeleton in red blood cell vesicles. Biophysical Journal, 69, 274 ± 279.
   PubMedGoogle Scholar
• Inaba, M., Yawata, A., Koshina, I., Sato, K., Takeuchi, M., Takakuwa, Y., Manno, S., Yawata, Y. Kanzaki, A., Sakai, J.-I., Ban, A., Ono, K.-I. and Maede, Y., 1996, Defective anion transport and marked spherocytosis with membrane instability caus ed by hereditary total deficiency of red cell band 3 in cattle due to a nons ense mutation. Journal of Clinical Investigation, 97, 1804 ± 1817.
   Google Scholar
• Isomaa, B., HaÈgerstrand, H. and Paatero, G., 1987, Shape transformations induced by amphiphiles in erythrocytes. Biochi- mica et Biophysica Acta, 899, 93 ± 103.
   PubMed Web of Science ®Google Scholar
• Isomaa, B., HaÈgerstrand, H., Paatero, G. and Engblom, A. C., 1986, Permeability alterations and antihaemolysis induced by amphi- philes in human erythrocytes. Biochimica et Biophysica Acta, 860, 510 ± 524.
   PubMed Web of Science ®Google Scholar
• Joiner, C. H., Franco, R. S., Jiang, M., Franco, M. S., Barker, J. E. and Lux, S. E., 1995, Increas ed cation permeability in mutant mouse red blood cells with defective membrane skeletons. Blood, 86, 4307 ± 4314.
   Google Scholar
• Khodadad, J. K. and Weinstein, R. S., 1983, The band 3-rich membrane of llama erythrocytes ± studies on cell shape and the organization of membrane proteins. Journal of Membrane Biology, 72, 161 ± 171.
   PubMedGoogle Scholar
• Kralj-Iglic, V., Heinrich, V., Svetina, S. and Zeks, B., 1999, Free energy of closed membrane with anisotropic inclusions. European Physical Journal B, 10, 5 ± 8.
   Web of Science ®Google Scholar
• Kralj-Iglic, V., Iglic, A., Bobrowska-HaÈgerstrand, M. and HaÈgerstrand, H., 2001, Tethers connecting daugther vesicles and parent red blood cell may be formed due to ordering of anisotropic membrane constituents. Colloids and Surfaces A, 179, 57 ± 64.
   Google Scholar
• Kralj-Iglic, V., Iglic, A., HaÈgerstrand, H. and Peterlin, P., 2000, Stable tubular microexovesicle s of the erythrocyte membrane induced by dimeric amphiphiles. Physical Review E, 61, 4230 ± 4234.
   Web of Science ®Google Scholar
• Kralj-Iglic, V., Svetina, S. and Zeks, B., 1996, Shapes of bilayer vesicles with membrane embedded molecules. European Biophy- sical Journal, 24, 311 ± 321.
   PubMedGoogle Scholar
• Lange, Y., Hadesman, R. A. and Steck, T. L., 1982, Role of the reticulum in the stability and shape of the isolated human erythrocyte membrane. Journal of Cell Biology, 92, 714 ± 721.
   PubMed Web of Science ®Google Scholar
• Liu, S. C, Zhai, S., Palek, J., Golan, D. E ., Amator, D, Hass e, K., Nurse, G. T., Babona, D., Coetz er, T., Jarolim, P, Zaik, M. and Borwein, S., 1991, Molecular defect of the band 3 protein in the southeast asian ovalocytosis. New E ngland Journal of Medicine, 323, 1530 ± 1538.
   Google Scholar
• Low, P. S., Willardson, B. M., Mohandas, N., Rossi, M. and Shohet, S., 1991, Contribution of the band 3-ankyrin interaction to erythrocyte membrane mechanical stability. Blood, 77, 1581 ± 1586.
   Google Scholar
• Lutz, H. U., Liu, S.-C. and Palek, J., 1977, Release of spectrin-free vesicles from human erythrocytes during ATP depletion. I. Characterization of spectrin-free vesicles. Journal of Cell Biology, 73, 548 ± 560.
   PubMed Web of Science ®Google Scholar
• Mohandas, N. and Chasis, J. A., 1993, Red blood cell deformability, membrane material properties and shape: regulation by trans- membrane, skeletal and cytosolic proteins and lipids. Semininars in Hematology, 30, 171 ± 192.
   PubMed Web of Science ®Google Scholar
• Mohandas, N. and Evans, E., 1994, Mechanical properties of the red cell membrane in relation to molecular structur e and genetic defects. Annual Review of Biophysics and Biomolecular Struc- tures, 23, 787 ± 818.
   Google Scholar
• Mohandas, N., Chasis, J. A. and Shohet, S. B., 1983, The influence of membrane skeleton on red cell deformability, membrane material properties, and shape. Semininars in Hematology, 20, 225 ± 242.
   PubMed Web of Science ®Google Scholar
• Mohandas, N., Clark, M. R., Jacobs, M. S. and Shohet, S. B., 1980, Analysis of factors regulating erythrocyte deformabilty. Journal of Clinica l Investigation, 66, 563 ± 573.
   PubMed Web of Science ®Google Scholar
• Nakao, M., 1990, Function and structure of the red blood cell cytoskeleton. In Blood Cell Biochemistry. Erythroid cells, J. R. Harris, ed. (New York: Plenum Publishing Corporation), pp. 195 ± 225.
   Google Scholar
• Nakao, M., Nakaao, T. and Yamazoe, S., 1960, Adenosine tripho- sphate and maintenance of shape of the human red cells. Nature, 187, 945 ± 946.
   PubMed Web of Science ®Google Scholar
• Palek, J., 1987, Hereditary eliptocytos is, spherocytosis and related disorders: cons equences of a deficiency or a mutation of membrane skeletal proteins. Blood Reviews, 1, 147 ± 168.
   PubMedGoogle Scholar
• Palek, J. and Jarolim, P., 1993, Clinica l expression and laboratory detection of red blood cell membrane protein mutations. Seminars in Hematology, 30, 249 ± 283.
   Google Scholar
• Reed, C. W. and Swisher, S. N., 1966, Erythrocyte lipid loss in hereditary spherocytosis. Journal of Clinical Investigations, 45, 777 ± 781.
   Google Scholar
• Sheetz, M. P., 1983, Membrane skeletal dynamics: role in modula- tion of red cell deformability, mobility of transmembrane proteins and shape. Seminars in Hematology, 20, 175 ± 188.
   Google Scholar
• Sheetz, M. P. and Singer, S. J., 1974, A molecular mechanism of drug-erythrocyte interactions. Proceeding of the National Acad- emy of Sciences (USA), 71, 4457 ± 4461.
   PubMed Web of Science ®Google Scholar
• Sheetz, M. P. and Singer, S. J., 1976, Equilibrium and kinetic effects of drugs on the shape of human erythrocytes. Journal of Cell Biology, 70, 247 ± 251.
   PubMed Web of Science ®Google Scholar
• Sills, R. H., Tamburlin, J. H., Barrios, N. J., Glomski, C. A. and Yeagle, P. L., 1988, Formation of intracellula r vesicles in neonatal and adult erythrocytes: evidence against the concept of neonatal hyposplenism. Pediatric Res earch, 24, 703 ± 708.
   Google Scholar
• Snyder, L. M., Lutz, H. U., Sauberman, N., Jacobs, J. and Fortier, N. L., 1978, Fragmentation and myelin formation in hereditary xerocytosis and other hemolytic anemias. Blood, 52, 750 ± 761.
   Google Scholar
• Weed, R. I. and Bowdler, A. J., 1966, Metabolic dependence of the critica l hemolytic volume of human erythrocytes: relationship to osmotic fragility and autohemolysis in hereditary spherocytosis and normal red cells. Journal of Clinica l Investigations, 45, 1137 ± 1149.
   PubMedGoogle Scholar