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Overexpression of AE1 Prague, but not of AE1 SAO, inhibits wild-type AE1 trafficking in Xenopus oocytes (1995)

Chernova, M. N. ; Jarolim, P. ; Palek, J. ; [et al.]

Springer

The journal of membrane biology 148 (1995), S. 203-210

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ISSN: 1432-1424

Keywords: AE1 ; Band 3 ; Chloride/bicarbonate exchange ; Xenopus oocytes ; Hereditary spherocytosis ; Anemia

Source: Springer Online Journal Archives 1860-2000

Topics: Biology , Chemistry and Pharmacology

Notes: Abstract Mutations in the AE1 (band 3) anion exchanger of human erythrocytes have been associated with altered red cell shape and heritable disease.The Southeast Asian Ovalocytosis (SAO) AE1 mutation, a 27 nt deletion producing the Δ400–408 form of AE1, and the AE1 Prague mutation, a 10 nt insertion producing a frameshift after AE1 aa 821 leading to premature termination, are found only in the heterozygous state. We therefore examined accumulation and function of wt AE1 polypeptide in Xenopus oocytes when coexpressed with AE1 SAO and with AE1 Prague. Our SAO construct lacked the K56E (AE1 Memphis) polymorphism present in the endogenous AE1 SAO protein. Neither mutant AE1 mediated Cl−} uptake into cRNA-injected Xenopus oocytes. Coninjection of mutant and wt cRNAs led to dose-dependent inhibition of wt function by AE1 Prague, but not by SAO. Though in vitro translation of the two mutants revealed little difference in their insertion into microsomal membranes, AE1 Prague accumulated in Xenopus oocytes to lower levels than did AE1 SAO or wt. Unlike AE1 SAO polypeptide, AE1 Prague polypeptide was not detectable at the oocyte surface. Moreover, overexpression of AE1 Prague, in contrast to AE1 SAO, reduced the accumulation of wt AE1, at the oocyte surface. This inhibition occurred in the absence of detectable heteromer formation between the AE1 Prague and wt AE1 polypeptides.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00207276

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Membrane protein organization in ATP-depleted and irreversibly sickled red cells (1979)

Palek, J. ; Liu, S. C.

New York, N.Y. : Wiley-Blackwell

Journal of Supramolecular Structure 10 (1979), S. 79-96

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ISSN: 0091-7419

Keywords: red cell membrane proteins ; spectrin ; red cell shape ; deformability ; membrane protein cross-linking ; membrane protein disulfide coupling ; red cell adenosine triphosphate ; calcium ; membrane protein polymerization ; discocyte-echinocyte transformation ; irreversibly sickled cells ; sickle cell anemia ; Life Sciences ; Molecular Cell Biology

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Biology , Chemistry and Pharmacology , Medicine

Notes: It has been proposed that the spectrin-actin submembrane network participates in control of red cell shape and deformability. We have examined ATP- and calcium-dependent changes in organization of spectrin in the membrane employing cross-linking of the nearest membrane protein neighbors by spontaneous or catalyzed (CuSO4, O-phenanthroline) intermolecular disulfide couplings and two-dimensional sodium dodecyl sulfate polyacrylamide gel electrophoresis.Cross-linking of fresh red cells resulted in the formation of spectrin and actin dimers and tetramers. ATP-depleted red cells differed from fresh cells in the presence of an additional reducible polymer of MW 〉 1 × 106 selectively enriched in spectrin. This polymer formed spontaneously when red cells were depleted of ATP under aerobic conditions. After anaerobic ATP depletion, the polymer formed in ghosts after cross-linking by catalytic oxidation. Polymerization was prevented by maintenance of ATP and coincided with an ATP-dependent discocyte-echinocyte transformation. This suggests that, in ATP-depleted red cells, spectrin is rearranged to establish closer contacts, and that this may contribute to the discocyte-echinocyte transformation.The introduction of greater than 0.5 mM Ca++ into ghosts by inclusion in hemolysis buffer or into fresh red cells (but not ATP-depleted red cells) by treatment with ionophore A23187 spontaneously produced a nonreducible polymer which others have attributed to transamidative cross-linking of spectrin, band 3, and other proteins. Spontaneous formation of both polymer types (reducible in aerobically ATP-depleted red cells and nonreducible in fresh, Ca++ enriched red cells) resulted in stabilization (“autocatalytic fixation”) of spheroechinocytic shape.Irreversibly sickled cells, which have increased calcium and decreased ATP, and exhibit a permanent membrane deformation, failed to form any of the above polymers. This suggests that in contrast to normal cells depleted of ATP in vitro, fixation of ISC shape in vivo is not related to Ca- and ATP-dependent membrane protein polymerization. However, ISCs had an increased propensity to form the reducible, spectrin-rich polymer during a subsequent metabolic depletion in vitro. This was associated with transformation of ISCs into spheroechinocytes. Similar echinocytic ISCs were found to constitute 5-10% of the densest fractions of freshly separated ISCs. ISCs then exhibit sphero-echniocyte transformation, both in vitro and in vivo. We propose that this is due to spectrin reorganization that presumably results from the progressively increasing calcium and decreasing ATP of ISCs.These data provide evidence of altered spectrin organization in membranes of ATP-depleted, calcium-enriched red cells in vitro and in vivo.

Additional Material: 11 Ill.