Влияние охлаждения на структуру и осмотические свойства эритроцитов человека
Диссертация
Процесс нуклеации дефектов. по-видимому, носит неспецифический характер, и может быть обусловлен действием физико-химических, химических, биохимических и фармакологических факторов. В изотонических условиях криогемолиз эритроцитов наблюдается в присутствии бактериальных токсинов, продуктов окисления, ко рот ко цепочных фосфолипидов [2231 .'Это означает, что важным прогностическим фактором при… Читать ещё >
Содержание
- ОБЗОР ЛИТЕРАТУРЫ
- 1. Структурная организация мембран эритроцитов
- 2. Холодовой шок эритроцитов
- РЕЗУЛЬТАТЫ СОБСТВЕННЫХ ИССЛЕДОВАНИЙ И ИХ ОБСУЖДЕНИЕ
- 3. Материалы и методы исследования
- 4. Изменение объема и формы эритроцитов в гипертонических средах как начальный этап модификации барьерных свойств мембраны
- 5. Влияние температуры на поведение эритроцитов при изменении осмотических условий среды
- 6. Влияние состава и рН среды на чувствительность к охлаждению клеток, подвергнутых инкубации при +37 и 0°С
- 7. Влияние температуры инкубации (0 и +37°С) на устойчивость эритроцитов к замораживанию в присутствии не проникающего крио-протектора (ПЭ0−1500)
Список литературы
- Бейли Н. Статистические методы в биологии.-М., Мир, 1963.-171 с.
- Белоус A.M., Бондаренко В. А. Структурные изменения биологических мембран при охлаждении.-Киев, Наукова. думка, 1982.-255 с.
- Белоус A.M., Бондаренко В.А.1 Механизмы криоповреждений: Молекул ярно-клеточная концепция.-В сб.:Вторая Всесоюзная конференция по теоретическим и прикладным вопросам криобиологии. Тезисы докладов, т. I, Харьков, 1984, с. 9.
- Белоус A.M., Бондаренко В. А., Бондаренко Т. П. Молекулярные механизмы криоповреждения биомембран.-В кн.^Физико-химические механизмы криоповреждений биологических структур.М.(Итоги науки и техники / ВИНИТИ. Биофизика, 1978, т.9) с.80−114.
- Бергельсон Л.Д. Биологические мембраны.-М.Наука, 1975.-183 с.
- Бондаренко Т.П. Роль липидов в повреждении мембран митохондрий и эритроцитов при охлаждении:Автореф.дисс. канд.биол. наук.-Харьков, 1981. -23 с.
- Бондаренко Т.П., Бондаренко В. А., Белоус A.M. Температурные изменения структуры эритроцитов: значение фазовых переходов липидов и формы клеток.-Материалы П Всесоюз. симпозиума «Липиды биологических мембран», Ташкент, 1980, с.24−25.- 174
- Владимиров Ю.А., Добрецов Г. Е. Флуоресцентные зонды з исследовании биологических мембран.-М., Наука, 1980. -320 с.
- Добрецов Г. Е. Исследование пространственной структуры мембран и липопротеидов флуоресцентными зондами.-Укр.биохим.журн., 1984, т.5б,№ 2, с. 211−222.
- Добрецов Г. Е. Дубур Г. Я.Дубуре Р. Р., Спирин М. М. Деме А.К. Флуоресцентные зонды производные пиридина для исследования конструкции биологических мембран.-Журн.прикладной спектро -скопииД983,т.39Д° б, с. 377.
- Добрецов Г. Е. Чекрыгин О.В. Анализ синглет-синглетного переноса энергии в мембранах. П. Перенос с точечного белка на флуоресцентный зонд. расположенный на. двух поверхностях липид-ного бислоя.-Биофизика, 1981, т.26, № 2, с. 376.
- Куницын В.Г., Остравская Т. А. Феденков В.И. Некоторые меха -низмы структурных изменений эритроцитарных мембран при действии сдвига рН.-Цитология, 1979, т.21,№ 2, с.207−210.
- Лозина-Лозинский Л. К. Очерки по криобиологии.-ЛНаука, 1972. 262 с.
- Маркин B.C. Организация мембран в плоскости слоя и форма клеток.Статистический подход.-Биофизика.Д980,т.25,№ 5,с.941−952.
- Мвшкова Н.П., Алексахина. Н. В. Определение фосфоклицериновой кислоты.-Успехи биол. химии, 1954, вып.2,с.285−288.
- Пушкарь Н.С., Белоус A.M. Введение в криобиологию.-Киев, Нау-кова. думка, 1975. -343 с.
- Пушкарь Н.С., Шраго М. И., Белоус A.M., Калугин Ю. В. Криопротек-торы.Киев, Наукова думка, 1978. -204 с.
- Рождественская М.А. Определение гемоглобина в плазме консервированной крови.-В кн.:Актуальные вопросы переливания крови. Л., 1955, вып.5, с.55−57.- 175
- Свиридов Б.Е., Левин С. В. .Янушка А. Л., Сабаляускас И. О., Комиссар Й. Ю., Мошеева Ф. И. Слабосвязанные белки и ультраструкгура, мембран теней эритроцитов.-Цитология, 1976, т.18,№ 2,с.178−182.
- Семенченко А. Ю. Бондаренко В.А., Белоус A.M. Влияние дифиль-ных соединений на диффузию белков в растворе.-В сб.'.Криобиология и криомедицина.-Киев, На, укова думка, 1984, вып.14,с.37−39.
- Смит 0. Биологическое действие замораживания и переохлаждения. -М., Изд-в о Иностр. лит-ра, 1963. -503 с.
- Финеан Дж., Коллин Р., Мичеля Р. Мембраны и их функции в клетке.М., Мир, 1977. -200 с.
- Хочачка П., Сомеро Д. Стратегия биохимической адаптации.М., Мир, 1977. 379 с.
- Чекрыгин О. В. Добрецов Г. Е. Анализ синглет-синглетного переноса энергии в мембранах.1У.Измерение площади, занимаемой белками на поверхности мембраны.-Биофизика, 1981, т.26,№ 2, с. Ъ16.
- Черницкий Е.А. .Воробей А. Б. Структура и функции эритроцитар-ных мембран.-Минск, Наука и техника, 1981. -213 с.
- Черницкий Е .А. .Слобожанина Е. И., Козлова Н. М. Додан В.Б. рН Агрегация спектрина в эритроцитарных мембранах.-Изв.АН БССР, Сер.биол.и.1977, вып.6, с.32−36.
- Шраго М.И. О криозащитном действии полимеров окиси этилена на эритроциты человека при глубоком охлаждении (к проблеме консервирования крови): Автореф.дисс.. докт.биол.наук, -Л., 1971. 33 с.
- Aldwinckle T.J., Ahkong Q.F., Bangham A.D., et al. Effectsof poly (ethyleneglycol) on liposomes and erythrocytes. Permeability changes and membrane fusion. Biochim. Biophys. Acta, 1982, v. 689, N3, p.548−561.
- Aloni В., Eitan A., Livne A. The erythrocyte membrane site for the effect of temperature on osmotic fragility. Biochim. Biophys. Acta, 1977, v.465, N1, p.46−54.
- Araki Т., Rollofsen В., Den Kamp J.a.P.Op, Van Deenen L.L.M. Temperature-dependent veaiculation of human erythrocytes caused by hypertonic salt: a phenomenon involving lipid segregation. Cryobiology, 1932, v. 19, 114, p.353−361.
- Arnold K., Pratsch L., Gawrisch K. Effect of poly (ethylene-glycol) on phospholipid hydration and polarity of the external phase. Biochim. Biophys. Acta, 1983, v.728, N1, p.121−129.
- Atkinson M.A.L., Morrow J.S., Marchesi Y.T. The polymeric state of actin in the human erythrocyte cytoskeleton. J. Cell. Biol., 1982, v.18, N4, p.493−506.
- Baker R.V., Hope D.V. The effect of gradual changes in temperature on the release of hormones from nerve endings isolated from bovine neural lobes. J. ileurochem., 1976, v.27, 1T1, p.197−202.
- Barenholz Y., Thompson Т.Е. Sphyngomyelius in bilayers and biological membranes. Biochim. Biophys. Acta, 1980, v.604, N2, p.129−159.
- Beck J.S. Echinocyte formation: a test case for mechanisms of cell shape changes. J. Theor. Biol., 1976, v.71, N4, p. 515−525.
- Bennett V., Branton D. Selective association of spectrinwith the cytoplasmic surface of human erythrocyte plasma mem32branes. Quantitative determination with purified P spectrin. — J. Biol. Chem., 1977, v.252, N8, p.2753−2763.
- Bernhardt I., Glaser R. Investigations on the control of ion transport in human erythrocytes. II. Influence of transmembrane, exterior surface potential and intracellular pH on the 22Na efflux. Acta Biol. Med. Ger., 1982, v.41, N6, p.541−549.- 177
- Beaaia M. La forme et la deformabilite dea erythrocytes nor-maux et dana certaina anemiea hemolytiquea congenitalea. -Nouv. rev. franc, hematol., 1977, v.18, N1, p.75−94.
- Beutler E. Red cell metaboliam. A manual of biochemical me-thoda. Hew York, Grune and Stratton, 1975. — 100p.
- Bitol M., Leterrier P. Spin-label atudy of erythrocyte membrane submitted to a bending atreaa. Biorheology, 1982, v. 19, 114, p.495−507.
- Bjerrum P.J. Hemoglobin-depleted human erythrocyte gho3ta: characterization of morphology and tranaport functiona. J. Membrane Biol., 1979, v.48, N1, p.43−67.
- Blank M., Britten J.S. Membrane proteina and membrane rheo-logy. Biorheology, 1975, v.12, N5, p.271−274.
- Blank M., Soo L., Abbott R.E. The ionic permeability of ad-aorbed membrane protein monolayers. J. Electrochem. Soc., 1979, v.126, N9, p.1471−1474.
- Blaurock A.E., Gamble R.C. Small phosphatidylcholine viaic-lea appear to be faceted below the thermal phaae transition.-J. Membrane Biol., 1979, v.50, N2, p.187.
- Bola И.О., Gip J.M.K., Wolff B.R. Trout red blood cells trea- 178 ted with proteases fuse when placed on glass slides. Bioscience Rep., 1984, v.4, N1, p.65−71.
- Eoni L.T., Stewart T.P., Alderfer J.L., Hui S.W. Lipid-poly-ethylene glycol interactions: I. Induction of fusion between liposomes. J. Membrane Biol., 1981, v.62, N1−2, p.65−71.
- Brahm J. Temperature-dependent changes of chloride transport kinetics in human red cells. J. Gen. Physiol., 1977, v.70, N3, p.283−306.
- Brahm J. Water transport through the red cell membrane. -Period. Biol., 1983, v.85, N2, p.109−116.
- Branton D. Membrane cytoskeletal interactions in the human erythrocytes. In: Cold Spring. Harbor. Symp., 1981, v. 46, part 1, p.1−6.
- Brumen M., Glaser R., Svetina S. Osmotic states of the red blood cell. Bioelectrochem. Bioenerg., 1979, v.6, N2, p.227−243.
- Calvert R., Bennett P., Gratzer W. Properties and structural role of the subunits of human spectrin. Eur. J. Biochem., 1980, v.107, N2, p.355−361.
- Cauham P.B. The minimum energy of bending as a possible explanation of the biconcave shape of the human red blood cell.-J. Theor. Biol., 1970, v. 26, N1, p.61−81.
- Cass A., Dalmark M. Equilibrium dialysis of ions in nystatin-treated red cells. Nat. New Biol., 1973, v.244, N1, p.47−49.- 179
- Cassoly R., Daveloose D., Wolf C., Leterrier P. Etude de la spectrine par marquage do spin. C.r. Acad, sci., 1978, v. D286, N12, p.1009−1012.
- Caasoly R., Davelooae D., Leterrier P. Spin labeling of human apectrin. Effects of temperature, divalent cations and re-aaaociation with erythrocyte membrane. Biochim. Biophys. Acta, 1980, v.601, Ю, p.478−489.
- Cohen C.M., Foley S.P. Spectrin-dependent and independent as-aociation of P-actin with the erythrocyte membrane. J. Cell Biol., 1980, v.86, N2, p.694−698.
- Cohen C.M., Tyler J.M., Branton D. Spectrin-actin association studied by electron microscopy of shadowed preparations. -Cell, 1980, v.21, N3, p.875−883.
- Coleman R., Holdsworth G. Effects of detergents on erythrocyte membranes: different patterns of solubilization of the membrane proteins by dihydroxy and trihydroxy bile salts. -Biochem. Soc. Trans., 1975, v.4, N5, p.747−748.
- Coulon T., Outlired R. The temperature dependence of erythrocyte water diffusion permeability. Biochim. Biophys. Acta, 1978, v. 11, 113, p.408−419.
- Cotterrell D., Whittman R. The influence of the chloride gradient across red cell membranes on sodium and potassium movements. J. Physiol., 1971, v.214, N3, p.509−536.
- Crandall E.D., Gritz A.M., Osher A.S., et al. Influence ofpH on elastic deformability of the human erythrocyte membrane. Amer. J. Physiol., 1978, v.235, 115, p.269−273.
- Cullis R.R., Decruijff В., Hope M.J., et al. Structural properties of lipids and their functional roles in biological membranes. In: Membrane fluidity in biology, 1983, v.1, edited by Aloia R.C. Academic Press (Hew York), p. 39−83.- 180
- Cuppoletti J., Mayheio E., Zobel C.R., Yung C.Y. Erythroso-mes-large proteoliposomes derived from crosa-linked human erythrocyte cyto3keletons and exogenous lipid. Proc. Hat. Acad. Sci. US-Biol. Sci., 1981, v.78, N5, p.2786−2790.
- Dalmark M. Chloride and water distribution in human red cells. J. Physiol., 1975, v.250, N1, p.65−84.
- Dalmark M., Wieth J.O. Temperature dependence of chloride, bromide, iodide, thiocyanate and salicylate transport in human red cells. J. Physiol., 1972, v.224, N3, p.583−610.
- Darin-Bennett A., White I.G. Influence of the cholesterol content of mammalian spermatozoa on succeptibility of cold shock. Oryobioloccy, 1977, v. 14,4, p.466−470.
- David E. Golan, Ы. Robert Alecio, Veatoh W.R., Rando R.R. Lateral mobility of phospholipid and cholesterol in the human erythrocyte membrane: effects of protein-lipid interaotions.-Riochemistry, 1984, v.23, 112, p.332−34°.
- Davidson S.J., Song S.W. A thermally induced alteration in 1узозоте membranes: salt permeability at 0°and 37 °C. Biochim. Biophys. Acta, 1975, v.375, 1T2, p.274−285.
- D’Avila II.M. A spin label study of erythrocyte membranes during simulation of freezing. J. Membrane Biol., 1981, v.60, IT2, p.155−163.
- Dembo M., Glushko V., Aberlin M.E., Sonenberg M. A method for measuring membrane microviscosity using pyrene excimer formation. Application to human erythrocyte ghosts. Biochim. Biophys. Acta, 1979, v.522, N2, p.201−212.
- Demel R.A., Kruyff B. de. The function of sterols in membranes. Biochim. Biophys. Acta, 1976, v.457, N2, p.109−132.
- Deuling H.J., Helfrich V/. Red blood cell shapes as explained on the basis of curvature elasticity. Biophys. J., 1976, — 181 -v.16, Ц8, p.861−868.
- Deuticke В., Ruaka С. Changes of nonelectrolyte permeability in cholesterol-loaded, erythrocytes. Biochim. Biophys. Acta, 1976, v.433, M, p.638−653.
- Dijck P.W.M. van, Zoelen E.J.J, van, Seldenrijk R., et al. Calorimetric behaviour of individual phospholipid classes from human and bovine erythrocyte membranes. Chem. Phys, Lipids, 1976, v.17, N2−3, p.336−343.
- Donlon J.A., Rothstein A. The cation permeability of erythrocytes in lov/ ionic strength media of various tonicities. -J. Membrane Biol., 1969, v.1, N1, p.37−51.
- Donner M., Andre J.-C., Bonchy M. Kinetics of partly diffusion-controlled reactions. VII. Pyrene excimer formation in erythrocyte membranes. Biochim. Bipphys. Acta, 1980, v.97, N3, p.1183−1192.
- Drost-Hansen W. Structure and functional aspects of inter-facial (vicinal) water as related to membrane and cellular systems. Colloq. int. CNRS, 1976, H246, p.177−186.
- Dubbelman T.M.A.R., De Bruijne A.W., Ghristianse K., Van Ste-veninck S. Hypertonic cryochemolysis of human red blood cells. J. Membrane Biol., 1979, N3−4, p.225−241.
- Elg3aeter A., Shotton D.M., Branton D. Intermembrane par -ticle aggregation in erythrocyte ghosts. II. The influence of spectrin aggregation. Biochim. Biophys. Acta, 1976, v.42, N1, p.101−122.
- Emmelot P., Van Hoeven R.P. Phospholipid unsaturation and plasma membrane organization. Chem. Phys. Lipids, 1975, v.14, N3, p.236−246.
- Evans E.A., Kukan B. Free energy potential for aggregation of erythrocytes and phosphotidylcholine /phosphatidylserine- 182 vesicles in dextran (36,500 mW), solutions arrd in plasma. -Biophys. J., 1983, v.44, N2, p.255−261.
- Flamm M., Schachter D. Acanthocytosis and cholesterol er-richment decrease lipid fluidity of only the outer human erythrocyte membrane leaflet. Nature, 1982, v.298, IT5871, p.292−294.
- Forsdyke D.R., Ford P.M. Rouleauz formation аз a measure of the plaama separating ability of plasma. J. Theor. Biol., 1983, v.103, N3, p.467−473.
- Forsyth P.A., Mareelja Б., Mitchell D.J., Iliuhane B.W. Pha-ae transitions in charged lipid membranes. Biochim. Biophys. Acta, 1977, v.469, N3, p.335−344.
- Fowler Y.M., Luna E.J., Harguaves W.K., et al. Spectrin promotes the association of F-action with the cytoplasmic surface of the human erythrocyte membrane. J. Cell. Biol., 1981, v.88, N2, p.388−395.
- Funder J., Wieth J.O. Chloride erythrocytes in human erythrocytes and ghosts: a quantitative comparison. J. Physiol., 1976, v.262, N4, p.679−696.
- Fung Y.C.B., Tong P. Theory of the sphering of red blood cells. Biophys. J., 1968, v.8, 112, p. 175−193.
- Gaines K.C. Connections between cytoplasmic proteins and the erythrocyte membrane. Trends Biochem. Sci., 1981, v.6, 1T1, p.13−16.
- Galla-H.-J., Luisetti J. Lateral and transversal diffusion and phase transitions in erythrocyte membranes. An excimer fluorescence study. Biochim. Biophys. Acta, 1980, v.596, N1, p.108−118.
- Gershfeld IJ.L. Equilibrium studies of lecithin-cholesterol interactions. I. Stoichiometry of lecithin-cholesterol com- 183 plexes in bulk systems. Biophys. J., 1978, v.22, N3, p.469−489.
- Girand P., Claret M. Л study of cholesterol transfers between erythrocytes and lipid vesicles: possible involvement of interparticular collisions. FEBS Lett., 1979, v.103,, p.186−192.
- Glaser R. Factors influencing the form of human erythrocytes.-Biophys. Membrane Transp, Sch. Proc. Part 2, Y/roclaw, 1976, p.147−184.
- Glaser R. The shape of red blood cells as a function of membrane potential and temperature. J. Membrane Biol., 1979, v.51, Ю, p.217−228.
- Glaser R., Brumen M., Svetina S. Stationare loneuzustaude menschliecher Brythrozyten. Biol. Zentralblatt., 1980, B.99, H4, S.429−442.
- Glaser R., Leitmannova A. Transformation of human red cell shape with regard to fluid-mosaic structure of the membrane.-Stud. Biophys., 1975, v.48, I’D, p.219−229.
- Goekoop J.G., Spies P., Bierman-van Steeg C., Vriclink R., et al. pH-dependent behaviour of erythrocyte membrane elevations. Cell. Biol. Int. Repth., 1978, v.2, IT2, p.139−145.
- Goodman S.R., Branton D. Spectrin bending and the control of membrane protein mobility. J. Supramol. Struct., 1978, v.8, Ы4, p.455−465.
- Goodman S.R., Yu J., Whitfield C.P., et al. Erythrocyte membrane skeletal protein bands 4.1 a and b are sequence-related phosphoproteins. J. Biol. Chem., 1982, v.257, N8, p.4564−4582.
- Gottlieb M.H., Eanes E.D. On phase transitions in erythrocyte membranes and extracted membrane lipids. Biochim. Bio- 184 phys. Acta, 1974, v.373, N3, p.519−522.
- Gratzer W.B. The red cell membrane and its cytoskeleton. -Biochem. J., 1981, v.198, N1, p.1−8.
- Green L.A.G., Hui H.L., Green P.A., et al. The role of choline phoapholipida in hypertonic cryohemolyaia. Cryobiolo-gy, 1983, v.20, N1, p.25−30.
- Green P.A., Jung C.Y. Gold-induced hemolysis in a hypertonic milieu. J. Membrane Biol., 1977, v.33, H3−4, p.249−262.
- Green P. A., Jung C.Y., Cuppoletti J., 0wen3 IT. Hypertonic cryochemolysia and the cytoakeletal syatem. Biochim. Bio-phys. Acta, 1981, v. 648, N3, p.225−230.
- Grunze M., Porat В., Deuticke B. Dual effect of membrane cholesterol on aimple and mediated tranaport proceaaea in human erythrocytes. Biochim. Biophya. Acta, 1980, v.600, N3, p.860−869.
- Guun R.B. A titratable carrier model for both mono- and divalent anion tranaport in human red blood cells. In: Oxygen affinity of hemoglobin and red cell acid baae atatua. Ed. by M. Rorth and P. Aatrup. Muukagaard, Copenhagen, 1972, p.823−827.
- Gunn R.B. A titratable carrier model for monovalent and divalent inorganic aniona in red blood cells. In: Erythrocytes, thrombocytes, leukocytes. E. Gerlach, K. Williams editors. Georg Thieme Yerlag, Stuttgart, 1973, p.77−79.
- Gunn R.B., Dalmark M., Tosteson D.G., Wieth J.O. Characteristics of chloride transport in human red blood cells. -J. Gen. Physiol., 1973, v.61, N2, p.185−206.
- Haest C.W.M. Interactions between membrane sceleton proteins and the intrinsic membrane domains. Biochim. Biophys.- 185
- Acta, 1982, v.48, H4, p.331−352.
- Haest C.W.M., De Gier J., Van E.G.A., et al. The effect of lipid phase transitions on the architecture of bacterial membranes. -Biochim. Biophys. Acta, 1974, v.356, N1, p.17−26.
- Haest C. Y/.M., Heller K., Schwi3ter K., et al. Concomitant changes of membrane leak permeability and phospholipid dynamics in erythrocytes subjected to chemical and physical membrane perturbation. Biomed. Biochim. Acta, 1983, v.42, N11−12, p.127−130.
- Haest C.W.M., Plasa G., Kamp D., Deuticke B. Spectrin asa stabilizer of the phospholipid assymetry in the human erythrocyte membrane. Biochim. Biophys. Acta, 1978, v.509, N1, p.21−32.
- Hainfeld J.P., Steek T.L. The sub-membrane reticulum ofthe human erythrocyte: a scanning electron microscope study.-J. Supramol. Struct., 1977, v.6, N3, p.301−313.
- Hammerstedt R.H., Amann R.P., Rucinsky Т., et al. Use of spin labels and electron spin resonance spectroscopy to characterise membranes of bovine sperm: effect of butylated hydroxytoluene and cold shock-biol. reproduct., 1976, v.14, N4, p.381−397.
- Hargreaves W.R., Gield K.W., Verkleij A., Branton D. Reas-sociation of ankyrin with band 3 in erythrocyte membranes and in lipid vesicles. J. Biol. Chem., 1980, v.255, N24, p.11 965−11 973.
- Herrmenn A., Arnold K., Pratsch L., Lassmann G. Influence of polyethylene glycol on the structure of the erythrocyte membrane: an ESR study. Biomed. Biochim. Acta, 1983, v.42, N9, p.1151−1157.
- Herrmann A., Pratsch L., Arnold K, Lassmann G. Effect of poly (ethylene glycol) on the polarity of aqueous solutions and on the structure of vesicle membranes. Biochim. Biophys. Acta, 1983, v.733, N1, p.87−95.
- Hertz R., Barenholz Y. Permeability and integrity properties of lecithin-sphingomyelin liposomes. Chem. Phys. Lipids, 1975, v. 15, IT2, p.138−156.
- Holzwarth G., Yu J., Steck T.L. Heterogenety in the conformation of different protein fractions from the human erythrocyte membrane. J. Supramol.Struct., 1976, v.4, N2, p.161−168.
- Hong J.S., Poisner A.M. Effect of low temperature on the release of vasopressin from isolated bovine neurohyphyris. -Endocrinology, 1974, v.94, N1, p.234−240.
- Hope M.J., Cullis P.R. The bilayer stability of inner monolayer lipids from the human erythrocyte. FEBS Lett., 1979, v.107, N2, p.323−326.
- Hui S.W., Stewart С.Ы., Carpenter M.P., Stewart T.P. Effects of cholesterol on lipid organization in human erythrocyte membrane. J. Cell. Biol., 1980, v.85, N2, p.283−291.
- Inoue K. Permeability properties of liposomes, prepared from dipalmitoyl lecithin, dimyristoyllecithin, egg lecithin, rat liver lecithin and beef sphingomyelin. Biochim. Biophys. Acta, 1974, v.339, N3, p.390−402.
- Jacobs M.H., Parpart A.K. Osmotic properties of the erythrocyte. II. The influence of pH, temperature and oxygen tension on hemolysis in hypotonic solutions. Biol. Bull, 1931, v.60, N1, p.95−119.
- Jain M.K. Honrandom lateral organization in bilayers and biomembranes. In: Membrane fluidity in biology, 1983, v.1, — 187 edited by Aloia R.C., Academic press (New York), p.1−39.
- Jan K.M. Role of hydrogen bonding in red cell aggregation.-J.Cell Physiol., 1979, 1П, p.49−55.
- Jay A.W., Rowlands S. The stages of osmotic hemolysis. -J. Physiol., 1975, v.252, N3, p.817−832.
- Ji Т.Н., Kiehm D.J., Middaugh G.R. Presence of spectrin tetramer on the erythrocyte membrane. J. Biol. Chem., 1980, v.255, N7, p.2990−2993.
- Johnson R.M. The kinetics of resealing of washed erythrocyte ghosts. J. Membrane Biol., 1975, v.22, N3−4, p.231−253.
- Johnson R.M., Robinson J. Morphological changes in assymet-ric erythrocyte membranes induced by electrolytes. Bio-chem. Biophys. Res. Communs., 1976, v.70, 113, p.925−931.
- Johnson R.M., Taylor G., Meyer D.E. Shape and volume changes in erythrocyte ghosts and spectrin-actin netv/orks. J. Cell. Biol., 1980, v.85, N2, p.371−376.
- Kahane I., Gitler C. Red cell membrane glycophorin labeling from within the lipid bilayers. Science, 1978, v.201, N4353, p.351−352.
- Kamada Т., Setowama S., Chuman Y., Otsuji S. Metabolic dependence of the fluidity of intact erythrocyte membrane. -Biochem, Biophys. Res. Commun., 1983, v.116, N2, p.541−547.
- Kapitsa H.-G., Saekmann E. Local measurement of lateral motion in erythrocyte membranes by photobleaching technique.-Biochim. Biophys. Acta, 1980, v.595, N1, p.56−65.
- Kirk R.G., Andrews S.B., Lee P. The correlation of composition and morphology during the high to low potassium transition. J. Membrane Biol., 1983, v.76, N3, p.281−289.
- Kirpatrick P.H., Sandberg H.E. Effect of anionic surfoe-tants, non-ionic surfoetants and neutral salts on the con- 188 formation of spin-labelled erythrocyte membrane proteins. -Biochim. Biophys. Acta, 1973, v.298, H2, p.209−218.
- Kitagawa Т., Tanaka Y., Inoue K., IJojima S. Effect of temperature and bovine serum albumin on lysis of erythrocyte induced by dilaroyl glycerophospholine and dilecanoylglyce-rophosphacholine. Biochim. Biophys. Acta, 1977, v.467, N2, p.137−145.
- La Celle P.L. Effect of sphering on erythrocyte deformabi-lity. Biorheology, 1972, v.9, IJ1, p.51−59.
- La Celle P.L., Rothstein A. The passive permeability of the red blood cell to cations. J. Gen. Physiol., 1966, v.50, N1, p.171−188.
- Lange J., Hadesman K.A., Steck T.Z. Role of the reticulim in the stability and shape of the isolated human erythrocyte membrane. J. Cell. Biol., 1982, v.92, ЫЗ, p.714−722.
- Lange Y., Gough A., Steck T.L. Role of the bilayer in the shape of the isolated erythrocyte membrane. J. Membrane Biol., 1982, v.69, N2, p.113−124.
- Lee A.G. Lipid phase transitions and phase diagrams. I. Lipid phase transitions. Biochim. Biophys. Acta, 1977, v.472, N2, p.237−281.
- Lee A.G. An overlapping site model for the lipid annual of membrane proteins. PEBS Lett., 1983, v.151, N2, p.297−303.
- Leibo S.P. Freezing damage of bovine erythrocytes: simulation using glycerol concentration changes at subzero temperatures. Cryobiology, 1976, v. 13, If6, p.587−598.
- Lepke S., Passow H. The permeability of the human red blood cell to sulfate ions. J. Membrane Biol., 1971, v.6, N2, p.158−182.
- Lerche D., Glaser R. Investigation of artificial aggregati- 189 on of washed human erythrocytes caused by decreased pH reduced ionic strength. Acta biol. med. Ger., 1970, v.39, N8−9, p.913−918.
- Levi G., Coletti А., Росе U., Raiteri M. Decrease of uptake and exchange of neurotransmitter amino acids after depletion of their synaptosomal pools. Brain Res, 1976, v.103, N1, p.103−116.
- Leiber M.R., Steck T.L. A description of the holes in human erythrocyte membrane ghosts. J, Biol. Chem., 1982, v.257, N19, p.11 651−11 659.
- Leiber M.R., Steck T.L. Dynamics of the holes in human erythrocyte membrane ghogts. J. Biol. Chem., 1982, v. 257,1. 19, p. 11 660−11 679.
- Liljas L., Lundahl P., Hjerten S. The majoir sialoglycopro-tein of the human erythrocyte membrane. Release with a non-ionic detergent and purification. Biochim. Biophys. Acta, 1976, v.426, N3, p.526−534.
- Lin P. S. Electron microscopic study of hemolysis: a proposal of formation of weak-structural region in the erythrocyte membrane. Cell.Biol. Int. Repth., 1981, v.5, N2, p.159−169.
- Linden C.D., Wright K.L., McConnel H.M., Pox C.P. Lateral phase separations in membrane lipids and the mechanism of sugar transport in Escherichia coli. Proc. ITatl. Acad. Sci. USA, 1973, v.70, N6, p.2271−2275.
- Liu S.C., Palek J. Spectrin tetramerdimer equilibrium and the stability of erythrocyte membrane skeletons. Nature, 1980, v. 285, N5766, p.586−588.
- Liu S.C., Windisch P., Kim S., Palek J. Oligomeric states of spectrin in normal erythrocyte membranes: biochemical and electron microscopic studies. Cell, 1984, v.37, N2, p.587
- Livne A., Raz A. Erythrocyte fragility and potassium efflux as affected by temperature and homolyzing rate. FEBS Lett., 1971, v.16, N2, p.99−101.
- Lovelock J.E. Physical instability and thermal shock in red cells. Nature, 1954, v.173, N4406, p.659−661.
- Lovelock J.E. The denaturation of lipid-protein complexes as a cause of damage by freezing. Proc. Roy. Soc., Ser. B, 1957, v.147, N4, p.427−433.
- Luer C.A., Wong K.P. The effects of pH and temperature on the circular dichroism of human erythrocyte membranes. -Biophys. Chem., 1978, v.9, N1, p.15−22.
- Luthra M.G., Friedman I.M., Sears D.A. Effects of the pH and temperature on the interaction of an impermeant probe with surface proteins of the human red blood cell. J. Biol. Chem., 1978, v.253, N16, p.5647−5653.
- Macleod R.A., Caleott P.H. Cold 3hock and freezing damageto microbes. In: Surv. vegetative microbes. 26th Symp. Soc. Microbiol. Univ. Cambridge, 1976. Cambridge, 1976, p.81−109.
- Maggio В., Ahkong A.P., Lucy A. Polyethylene glycol surface potential and cell fusion. Biochem. J., 1976, v.158, N3, p.647−650.
- Mann T. The biochemistry of semen and of the male reproductive tract. Methuen, London, 1964, p.356−363.
- Marchesi V.T. Review: the red cell membrane skeleton: recent progress. Blood, 1983, v. 61, IT1, p.1−12.
- Marchesi V.T., Furthmayr H., Tomita M. The red cell membrane. Annu. Rev. Biochem. v.45, Palo Alto, Calif., 1976, p.667−698.
- Marikovsky Y., Khodadad J. K, Weinstein R.S. Influence of- 191 red. cell ahape on surface charge topography. Exp. Cell. Res., 1978, v.116, N1, p.191−197.
- Marinetti G.V., Crain R.C. Topology of amino-phospholipids in the red cell membrane. J. Supramol. Struct., 1978, v.8, N2, p.1−23.
- Маззоп W.T., Abrahamson E.W. Phase transitions in vertebrate and invertebrate photoreceptor membranes. J. Membrane Biol., 1974, v.15, H4, p.383−392.
- McGregor R.D., Tobias C.A. Molecular seiving of red cell membranes during gradual osmotic hemolysis. J. Membrane Biol., 1972, v.10, N4, p.345−356.
- Meduski J.W., Hochstein P. Hot-cold hemolysis: the role of positively charged membrane phospholipids. Experienta, 1972, v.28, N5, p.565−566.
- Mikkelsen A., Stokke B.T., Elgsaeter A. An electro-optic study of human erythrocyte spectrin dimers. The presence of calcium ions does not alter spectrin flexibility. Biochim. Biophys. Acta, 1984, v.45, N5, p.95−103.
- Minetti M., Ceecarini M. Protein-dependent lipid lateral phase reparation as a mechanism of human erythrocyte ghost resealing. J. Cell. Biochem., 1982, v. 19, 111, p.59−77.
- Mombera C., Van Dijck P.W.M., Van Deenen L.L.M., et al. The interaction of spectrin-actin and synthetic phospholipids. -Biochim. Biophys. Acta, 1977, v.470, ГТ2, p. 152−160.
- Morariu V.V., Pop V.I., Popeacu 0., Benga G. Effects of temperature and pH on the water exchange through erythrocyte membranea: nuclear magnetic resonance studies. J. Membrane Biol., 1981, v.62, N1−2, p.1−7.
- Morris G.J. Lipid loas and haemolyaia by thermal shock* lack of correlation. Cryobiology, 1975, v.12, N3, p.192−201.
- Morris G.J., Farrant J. Effect of cooling rate on thermal shock hemolysis. Gryobiology, 1973, v.10, N2, p.119−125.
- Morrison M., Mueller T.J., Edwards И.Н. Protein architecture of the erythrocyte membrane. Progr. Clin. Biol. Res., 1981, v.51, p.16−34.
- Morrow J.S., Ilaigh W.B., Marchesi V.T. Spectrin oligomers: a structure feature of the erythrocyte cytoskeleton. J. Supramol. Str. Cell Bochem., 1981, v.17, N3, p.275−289.
- Morrow J.S., Marchesi V.T. Self-assembly of spectrin oligomers in vitro: a basis for a dynamic cytoskeleton. J. Cell Biol., 1981, v.88, N2, p.463−468.
- Mucara I.G., Cantley L.C. The structure and function of band 3. In: Cell membranes: methods and reviews, v.1, Edited by Elson E., Frazier V/., Glazer L. Plenum Publishing Corp. (New York), 1983. — 197 p.
- Murphy S. Erythrocyte osmotic fragility and cell water influence of pH and temperature. J. Lab. Clin. Med., 1969, v.71, N4, p.319−331.
- Nicolson G.L., Painter R.G. Anionic sites of human erythrocyte тетЬгапез- II. Transmembrane effects of aktin-spectrin on the topography of bound positively charged colloidal particles. J. Cell. Biol., 1973, v.59, N4, p.395−406.
- Nigg E.A., Cherry R.J. Anchorage of a band 3 population at the erythrocyte cytoplasmic membrane surface: protein rotational diffusion measurements. Proc. Wat. Acad. Sci. USA, Biol. Sci., 1980, v.77, N8, p.4702−4706.
- Uishio Т., Hirota S., Yamashita J., Kobayashi K., et al. Erythrocyte changes in aqueous polyethylene glycol solutions containing sodium chloride. J. Pharm. Sci., 1982, v.71, N9, p.977−980.
- Oku IT., Nojima S., Inoue K. Selective release of non-electrolytes from liposomes upon perturbation of bilayers by temperature change of polyene antibiotics. Biochim. Bio-phys. Acta, 1980, v.595, N2, p.277−291.
- Pinto da Silva P. Translational mobility of the membrane intercalated particles of human erythrocyte ghosts, pH dependent, reversible aggregation. J. Cell. Biol., 1972, v.53, 118, p.777−787.
- Ralston G.B. Physical-chemical studies of spectrin. J. Supramol. Struct., 1978, v.8, из, p.361−373.
- Ralston G.B. The structure of spectrin and the shape of the red blood cell. Trends. Biochem. Sci., 1978, v.3, N9, p.195−198.
- Ramjeesingh M., Grinstein S., Rothstein A. Intrinsic segments of band 3 that are associated with anion transport across red blood cell membranes. J. Membrane Biol., 1980, v.51, N2, p.95−103.
- Roelofsen В., Meer G., Kamp J.A.P. The lipids of red cell membranes: compositional, structural and functional aspects.-Scand. J. Clin. Lab. Invest., 1981, v.41, N156, p.111−116.
- Roelofsen В., Schatzman H.J. The lipid requirement of the2+ 2+
- Ca + Mg) ATPase in the human erythrocyte membrane, as studied by various highly purified phospholipaaes. — Biochim. Biophys. Acta, 1977, v.464, N1, p.17−26.
- Rousselet A., Guthmann C., Matricon J., et al. Study of the transverse diffusion of spin labelled phospholipids in biological membranes. I. Human red blood cells. Biochim. Biophys. Acta, 1976, v.426, N3, p.357−371.
- Saez R., Alonso A., Villena A., Goui P.M.O. Detergent-like properties of polyethyleneglycols in relation to model mem- 194 branes. FEBS Lett., 1982, v.137, N2, p.323−326.
- Samsel R.W., Perelson A.S. Kinetics of roulean formation. II. Reversible reactions. -Biophys. J., 1984, v.45, N4, p.805−825.
- Schachter D., Cogan U., Abbott R. E, Asymmetry of lipid dynamics in human erythrocyte membranes studied with permeant fluorophores. Biochemistry (USA), 1982, v.21, N9, p.2146−2151.
- Schmid-Schoubein H. Microreology of erythrocytes, blood, viscosity and the flow in the microcirculation. In: International review of physiology. Cardiovascular physiology. II. A.C. Guyton (Ed.), Park Press, 1976, v.9, p.1−62.
- Seeman P., Sanks Т., Argent W., Kwant W.O. The effect of membrane-strain rate and of temperature on erythrocyte fragility and eritical hemolytic volume. Biochim. Biophys. Acta, 1969, v.183, N3, p.476−489.
- Shaklai N., Yguerabide J., Ranney H.M. Interaction of hemoglobin with red blood cell membranes as shown by a fluorescent chromophore. Biochemistry, 1977, v.16, N25, p.5585−5592.
- Sheetz M.P. Membrane skeletal dynamics: role in modulation of red cell deformability, mobility of transmembrane proteina and shape. Semin. Hematol., 1983, v, 20, N3, p.175−189.
- Sheelz M.P., Casaly J. Phosphate metabolite regulation of spectrin interactions. Scand. J. Clin. Lab. Invest., 1981, v.41, N156, p.117−122.
- Shiga T., Maeda N. Influence of membrane fluidity on erythrocyte functions. Biorheology, 1981, v.17, N5, p.485−500.
- Shiga Т., Suda Т., Maeda N. Spin label studies on the human erythrocyte membrane. Two sites and two phases for fatty acid spin labels. Biochim. Biophys. Acta, 1977, v.466, N2, p.231−244.
- Shinitzky M., Inbar M. Microviscosity parameters and protein mobility in biological membranes. Biochim. Biophys. Acta, 1976, v.433, N1, p.133−149.
- Shohet S.B. Possible roles for the membrane cytoskeleton in regulation red cell stability and deformability. -Scand. J. Clin. Lab. Invest., 1981, v.41, N156, p.123−130.
- Shohet S.B., Card R.T., Clark M., et al. The erythrocyte cytoskeleton and its apparent role in cellular functions. -Progr. Clin. Biol. Res., 1981, v.51, p.35−58.
- Shotton D.M., Burke B.E., Branton D.I. The molecular structure of human erythrocyte spectrin. Biophysical and electron microscopic studies. J. Mol. Biol., 1979, v.131, N2, p.303−329.
- Shramm M., Eiseukradt В., Barlcai E. Cold-induced leakage of amilaae from zymogen granule and sealing of its membrane by specific lipids. Biochim. Biophys. Acta, 1967, v.135, N1, p.44−52.
- Skalak R., Zarda P.R., Jan K.-M, Chien S. Mechanics ofroulean formation. Biophys. J., 1981, v.35, N3, p.771−783.
- Smyth C.J., Mollby R., Wadstrom T. Phenomenon of hot-cold hemolysis: chelator-induced lysis of sphingomycelinase-tre-ated erythrocytes. Infect, and Immun., 1975, v.12, N5, p.1104−1111.
- Snabre P., Mills P., Quemada D. Experimental and theoretical determination of red blood cell. Adhesiveness induced by dextran. Stud. Biophys., 1982, v.90, p.237−238.
- Solomon A.K., Chason В., Dix J.A., et al. Biomembranes and cell function. Annals of the New York Academy of Sciences, v.414. Ed. :by Kummerow P.A., Benga G., Holmes R.P. New York Academy of Sciences, 1983, p.97−125.
- Sudhot T.C. Core structure, internal osmotic pressure and irreversible structural changes of chromaffin granules during osmometer behaviour. Biochim. Biophys. Acta, 1982, v.684, N1, p.27−40.
- Takahashi Т., Williams R.J. Thermal shock hemolysis in human red cells. 1. The effects of temperature, time and osmotic stress. Cryobiology, 1983, v.20, N6, p.507−520.
- Tamura A., Fujii T. Roles of charged groups on the surface of membrane lipid bilayer of human erythrocytes in induction of shape change. J. Biochem., 1981, v.90, N3, p.629−635.
- Tanaka Y., Mashino K., Inoue K., Nojima S. Mechanism of human erythrocyte hemolysis induced by short-chain phosphati- 197 dylcholines and lysophosphatidylcholine. J. Biochem. Tokyo, 1983, v.94, Ю, p.833−841.
- Tanaka K.-I., Ohniahi S.I. Heterogeneity in the fluidity of intact erythrocyte membrane and ita homogenization upon hemolysis. Biochim. Biophys. Acta, 1976, v.426, N2, p, 213−231.
- Tanford G. The hydrophobic effect and the organization of living matter. Science, 1978, v.202, N4345, p.1012−1018.
- Tanner M.J.A. Erythrocyte glycoproteins. Gurr. Topics Membranes and Тгапзр. Vol. 11. New York, 1978, p.279−325.
- Taupin Gh., Dvolaitzky M., Sauterey G. Osmotic pressure induced pores in phospholipid vesicles. Biochemistry, 1975, v.14, N21, p.4771−4776.
- Terwilliger T.G., Solomon A.K. Osmotic water permeability of human red cells. J. Cell Physiol., 1981, v.11, N5, p.549−570.
- Trommler A., Wolf H. Quantitative estimation of adhesion force of human erythrocytes on glass surfaces. Stud. Biophys., 1979, v.73, N3, p.233−235.
- Tyler J.M., Branton D. Molecular interactions govering red cell membrane structure. Progr. Glin. Biol. Res., 1980, v.56, p.79−94.
- Tyler J.M., Reinhardt B.N., Branton D. Aasociations of erythrocyte membrane proteins. Binding of purified bands 2.1 and 4.1 to spectrin. J. Biol. Ghem., 1980, v.255, N14, p.7034−7039.
- Ungewickell E., Gratzer W. Self-association of human spectrin. A thermodynamic and kinetic study. Eur. J. Biochem., 1978, v.88, N2, p.379−385.
- Van Deenen L.L.M., De Gier J. Lipids of the red cell membrane. In: The red blood cell, Surgenor B, Ed. N.Y., San Prancisko and London, Academic Ргезз, 1974, p.147−211.
- Verma S.P., Wallach D.P.H. Erythrocyte membranes undergo cooperative, pH-sensitive state transitions in the physiological temperature range: evidence from Raman spectroscopy.-Proc. Nat. Acad. Sci USA, 1976, v.73, N 10, p.3558−3561.
- Wallach D.P.H., Verma S.P., Pooksou J. Application of laser Raman and infrared spectroscopy to the analysis of membrane structure. Biochim. Biophys. Acta, 1979, v.559, N2−3,p.153−208.
- Weinstein R.S. Electron microscopy of surfaces of red cell membranes. In: Red cell membrane: structure and function. G.A. Jamieson, T.J.Greenwalf eds., Philadelphia, 1969, p.36.
- Weltzien H.U., Kalkoff H.G. Quantitative studies on 1узо1е-cithin metiated hemolysis. Benzylated lysolecithin as a probe to study effects of temperature and red cell species on the hemolytic reaction. Biochim. Biophys. Acta, 1976, v.455, H1, p.56−65.
- Weltzien H.U. Cytolytic and membrane-perturbing properties of lysophosphatidylcholine. Biochim. Biophys. Acta, 1979, v.559, N2−3, p.259−287.
- Wilbrandt W. Osmotische natur sogennante nicht-osmotishe hamolyse. Pflugers Arch. Gesamte Physiol., 1941, v.245, N1, p.22−52.
- Willbrandt W., Shatzmann H.J. Changes in passive cation permeability of erythrocytes in low electrolyte media. -In: Regulation of inorganic ion content of cells. London, 1960, p.34−52.
- Williams R.G., Shaw S.K. The relationship between cell injury and osmotic volume reduction. II. Red cell lysis correlates with cell volume rather than intracellular salt concentration. Cryobiology, 1980, v.17, N6, p.530−540.
- Williamson P., Bateman J., Kozarsky K. et al. Involvement of spectrin in the maintenance of phase-state asymmetry in the erythrocyte membrane. Cell, 1982, v.30, p.725−733.
- Woolgar A.E. Hemolysis of human red blood cells by freezing and thawing in solutions containing sucrose? relationship with posthypertonic hemolysis and solute movements.. Cryobiology, 1974, v.11, N1, p.44−51.
- Woolgar A.E., Morris G.T. Some combined effects of hypertonic solutions and changes in temperature on posthypertonic hemolysis of human rea blood cells. Cryobiology, 1973, v.10, N1, p.82−86.
- Yamaguchi Т., Kuroki S., Tanaka M., Kimoto E. Effects of temperature and cholesterol on human erythrocyte membranes.
- J. Biochem., 1982, v.92, ИЗ, p.673−678.
- Yung C.Y., Carlson L.LI., Balzer C.J. Characteristics of the permeability barrier of human erythrocytes chosts to n nonelectrolytes. Biochim. Biophys. Acta, 1973, v.298, И1, p.101−107.
- Yung C.Y., Green P.A. Hypertonic cryohemolysis: ionophore and pH effects. J, Membrane Biol., 1978, v.39, N2−3,p.273−284.
- Zade-Oppen A.M.M. Posthypertonic hemolysis in sodium chloride systems. Acta Physiol. Scand., 1968, v.73, N4, p.341−364.
- Zwaal R.F.A. Membrane and lipid involvement in blood coagulation. Biochim. Biophys. Acta, 1978, v.515, N2, p.163−206.