The role of Mg++-ATPase (actomyosin-like protein) in maintaining the biconcave shape of erythrocytes

Tellurite effect on ATPase activity of contractile membrane protein

The effect of tellurite on ATPase activity of the contractile membrane protein in human erythrocytes was studied. Tellurite, even at a concentration of 0.01 mM, inhibited 25 per cent of the saponin-stimulated ATPase activity of the contractile membrane protein; the inhibition increased with increasing tellurite concentration, and was reversible. On the other hand, in erythrocytes preincubated with tellurite, the ATPase activity of the membrane contractile protein, non-stimulated by saponin, increased, and the increase was further enhanced by washing the erythrocytes. The behaviour is analogous to the tellurite effect on erythrocyte morphology: incubation of erythrocytes with tellurite caused morphological changes which were more pronounced after removing the tellurite by washing. The complex effect of tellurite is discussed.

Relationship of hemolysis buffer structure, pH and ionic strength to spontaneous contour smoothing of isolated erythrocyte membranes

Isolated human erythrocyte membranes crenate when suspended in isotonic medium, but can use MgATP to reduce their net positive curvature, yielding smooth discs and cup forms that eventually undergo endocytosis. An earlier report from this laboratory (Patel, V.P. and Fairbanks, G. (1981) J. Cell Biol. 88, 430-440), has described a phenomenon of ATP-independent shape change in which ghosts prepared by hemolysis and washing in synthetic zwitterionic buffers crenated at 0 degree C, but underwent conversion to smooth discs and cups when warmed in the absence of MgATP. We have further explored the effect of the hemolysis condition on the requirement for ATP in ghost shape change. 25 hemolysis buffers were applied at 10 mM (pH 7.4, 0 degree C). Eight anionic buffers with relatively high ionic strength (e.g., phosphate and diethylmalonic acid (DMA] yielded ghosts requiring ATP for shape change, while two cationic buffers (Bistris and imidazole) and ten synthetic zwitterionic buffers (e.g., Tricine and Hepes) with lower ionic strength produced ghosts that smoothed spontaneously at 30 degrees C. Hemolysis at intermediate ionic strength yielded mixed populations in which spontaneous smoothing was expressed in all-or-none fashion. Maximal ATP-independent shape change was induced by hemolysis at pH 7.3-7.7, while ATP was required after hemolysis at pH less than or equal to 7.1 even when the ionic strength at hemolysis was low. Ghosts requiring ATP could be converted to ATP independence by washing at low ionic strength, but ATP independence could not be reversed readily by washing at high ionic strength. Exposure to low ionic strength at pH greater than 7.1 presumably changes membrane organization in a way that alters the temperature dependence of tensions within the bilayer or skeleton of the composite membrane.

Is there any connection between heat inactivation of spectrin-dependent ATPase and loss of smooth biconcave shape of red cells?

Spectrin-dependent ATPase activity was measured in membranes from native human erythrocytes and erythrocytes heated for 20 min at different temperatures. This activity was found to decline when the erythrocytes were heated at 48 degrees C and higher. The break in ATPase activity corresponds to morphological changes in erythrocytes found by Crome and Mollison [Brit. J. Haematol. (1964) 10, 137]. The role of spectrin-dependent ATPase in erythrocyte shape maintenance is discussed.

Does the conformation of Mg-ATPase (spectrin-dependent ATPase) influence the passive permeability to K+?

The processing of human erythrocytes disclosed changes in Mg-ATPase activity following action of Pb2+ and Nile blue, and changes of permeability of K+ after treatment with Nile blue. The obtained results and those from previous papers can be summarized as follows : Substances decreasing the activity of stimulated membrane Mg-ATPase (spectrin-dependent ATPase) in red blood cells increase the passive permeability to K+, and substances increasing the stimulated Mg-ATPase activity decrease the passive permeability to K+. A hypothesis is proposed that the conformation of Mg-ATPase is secondarily reflected in the state of the proper path for K+ transport through the membrane; thus the rate of passive permeability to K+ is influenced.

New models of cellular control: membrane cytoskeletons, membrane curvature potential, and possible interactions

The concepts of "membrane cytoskeletons" (proteins attached to the cytoplasmic face of the membrane to give rigidity and control of lateral protein diffusion) and of membrane curvature potential are briefly reviewed. Possible modes of attachment of the membrane cytoskeleton to the bilayer are discussed, and a detailed calculation of possible sources of membrane curvature potential in the red cell is made. The 2 control systems are then used to illustrate possible mechanisms for some cellular processes, such as vesicle formation and release, pseudopod formation, and red cell aging. It is concluded that combination of these concepts allows control mechanisms which appear to act at a distance, or have other unusual systems properties.