Characterization of morphological response of red cells in a sucrose solution

An explanation of the reversal of erythrocyte echinocytosis by incubation and storage by serum albumin

It is proposed that the specific reversal by serum albumin of the erythrocyte echinocytosis in an inorganic phosphate buffer saline or in a saline, either after 24 h in blood or after a storage of 6-7 weeks in SGAM or PAGGSM media, is due to a cell dehydration by a decrease of the total NaCl and KCl concentrations favoring the stomatocytogenic slow outward transport of inorganic phosphate with a hydrogen ion by band 3 anion exchanger, which was previously proposed to control the erythrocyte shape. This proposal would indicate that the opposition of the erythrocyte echinocytosis by serum albumin is not limited to binding to echinocytogenic amphiphiles, supported by the ability of the band 3-based mechanism of control of the erythrocyte shape to explain a variety of observations on the erythrocyte shape. It would also imply that this mechanism is a determinant of the erythrocyte rheological properties since influenced by cell shape and volume. It is shown that the above process of stomatocytosis can explain stomatocytoses by different agents as well as a knizocytosis induced in vitro and occurring in acquired and inherited disorders and other situations. Lastly, it can also explain the opposition of hemolysis by mannitol in SGAM and PAGGSM media.

The basis of echinocytosis of the erythrocyte by glucose depletion

Echinocytosis of erythrocytes by glucose depletion is attributed to adenosine triphosphate depletion, but its process still remains unknown. A mechanism of control of the erythrocyte shape has been previously proposed in which the anion exchanger Band 3, linked to flexible membrane skeleton, has a pivotal role. Recruitments of its inward facing (Band 3(i) ) and outward facing (Band 3(o) ) conformations contract and relax the membrane skeleton, thus promoting echinocytosis and stomatocytosis, respectively. The Band 3(o) /Band 3(i) equilibrium ratio increases with the increase of the Donnan equilibrium ratio, and preferential inward and outward transport by Band 3 of substrates slowly transported are echinocytogenic and stomatocytogenic, respectively. The mechanism suggests the following process. The major organic phosphate 2,3-bisphosphoglycerate is catabolized to lactate to form inorganic phosphate, 3-phosphoglycerate, and adenosine triphosphate. The last two products can be reversibly transformed into 1,3-bisphosphoglycerate and adenosine diphosphate by the glycolytic enzyme phosphoglycerate kinase, thus allowing 2,3-bisphosphoglycerate formation by 2,3-bisphosphoglycerate synthase/phosphatase. The catabolic and cyclic processes initially oppose echinocytosis by increasing the Donnan ratio and outward transport of slowly transported inorganic phosphate by Band 3 (its basic form is transported with a hydrogen ion). Echinocytosis occurs when inward transport of this product becomes predominant. This process can rationalize direct and indirect observations.

Reconstruction of erythrocyte shape during modified morphological response

Changes in erythrocyte shape during morphological response modified by benzalkonium chloride (BzA) were studied in sucrose solutions. Fixation of the cells with glutaraldehyde- and formaldehyde-containing fixatives at some time points is usually inadequate to maintain the current cell shape. Considering the reconstruction of erythrocyte shape, which takes into account the mode of fixative action, we showed that the echinocyte-forming activity of BzA depends on the concentration of this surfactant. It can induce a direct spherostomatocyte-spheroechinocyte transition without altering the near-spherical shape of the cells. On the other hand, the reverse spheroechinocyte-spherostomatocyte transition was always accompanied by some flattening of the cells, although in some instances discoidal shape was not achieved. The data point to asymmetric shape transitions of erythrocytes in sucrose solution, which contradicts the continuum and bilayer-couple models of shape regulation. It seems that the nonuniform structure of native erythrocyte membrane plays a more important role in morphological transitions of these cells than suggested earlier.