Deficiency of alpha-spectrin synthesis in burst-forming units-erythroid in lethal hereditary spherocytosis.

A child diagnosed in utero with hydrops fetalis and a hematocrit of 6.4% was studied to determine the etiology of the anemia. Fetal red blood cells (RBCs) obtained during in utero transfusion had extremely abnormal osmotic fragility. A maternal history of mild autosomal dominant hereditary spherocytosis was present, and the father, who was hematologically normal, had a slightly abnormal osmotic fragility test. The patient was transfusion dependent after birth, with circulating nucleated RBCs but less than 1% reticulocytes. The patient's anemia failed to respond to splenectomy. Because mature RBCs of the patient were not available for study, progenitor-derived erythroblasts grown in culture were investigated. Immunodot assays of the patient's progenitor-derived cells showed a total cell spectrin content 26% of normal. Immunoprecipitation of whole burst-forming units-erythroid-derived cells and solubilized membranes from cells pulse-labeled with 35S-methionine showed a severe deficiency in alpha-spectrin synthesis and a markedly reduced amount of alpha- and beta-spectrin on cell membranes. No alpha-spectrin degradation products were found within the cells or were produced during membrane preparation. Ankyrin content and band 3 synthesis were not different from control. Inheritance of two genetic defects causing severely reduced alpha-spectrin synthesis is proposed as the cause of the lethal anemia, resulting in cell fragmentation during precursor enucleation or during egress from bone marrow.

Role of pertussis toxin-sensitive guanosine triphosphate-binding proteins in the response of erythroblasts to erythropoietin.

Human progenitor-derived erythroblasts have been recently shown to respond to erythropoietin (Epo) with an increase in intracellular free calcium concentration [Cac]. To explore the role of guanosine triphosphate (GTP)-binding proteins in mediating the rise in [Cac], single day 10 erythroid burst forming unit (BFU-E)-derived erythroblasts loaded with Fura-2 were pretreated with pertussis toxin (PT), stimulated with Epo, and [Cac] measured over 18 minutes with fluorescence microscopy coupled to digital video imaging. The [Cac] increase in day 10 erythroblasts stimulated with Epo was blocked by pretreatment with PT in a dose-dependent manner but not by heat-inactivated PT. These observations provided strong evidence that a PT-sensitive GTP-binding protein is involved. To further characterize the GTP-binding protein, day 10 erythroblast membrane preparations were solubilized, electrophoresed, and immunoblotted with antibodies specific for the known PT-sensitive G-protein subunits: the three subtypes of Gia (1,2, and 3) and Goa, Gia1 or Gia3 and Gia2 were identified but no Goa was found. To examine the influence of Epo on adenylate cyclase activity, day 10 erythroblasts were initially treated with Epo, isolated membrane preparations made, and cyclic adenosine monophosphate (cAMP) production by adenylate cyclase in membrane preparations in the presence of theophylline measured. Epo did not inhibit but significantly stimulated adenylate cyclase activity. However, the mechanism of increase of [Cac] appears to be independent of adenylate cyclase stimulation because treatment of erythroblasts with the cell-permeant dibutyryl cAMP failed to increase [Cac]. In summary, pertussis toxin blocks the increase in [Cac] in erythroblasts after Epo stimulation suggesting that this response is mediated through a pertussis toxin-sensitive GTP-binding protein. Candidate PT-sensitive GTP-binding proteins identified on day 10 erythroblasts were Gia 1, 2, or 3, but not Goa.

Spectrin and related molecules.

This review begins with a complete discussion of the erythrocyte spectrin membrane skeleton. Particular attention is given to our current knowledge of the structure of the RBC spectrin molecule, its synthesis, assembly, and turnover, and its interactions with spectrin-binding proteins (ankyrin, protein 4.1, and actin). We then give a historical account of the discovery of nonerythroid spectrin. Since the chicken intestinal form of spectrin (TW260/240) and the brain form of spectrin (fodrin) are the best characterized of the nonerythroid spectrins, we compare these molecules to RBC spectrin. Studies establishing the existence of two brain spectrin isoforms are discussed, including a description of the location of these spectrin isoforms at the light- and electron-microscope level of resolution; a comparison of their structure and interactions with spectrin-binding proteins (ankyrin, actin, synapsin I, amelin, and calmodulin); a description of their expression during brain development; and hypotheses concerning their potential roles in axonal transport and synaptic transmission.

Human erythrocyte membrane proteins of zone 4.5 exist as families of related proteins.

An analysis of the polypeptide composition of zone 4.5 of human erythrocyte membranes has been done by immunoautoradiographic and two-dimensional peptide mapping techniques. Results of these studies demonstrated that the Coomassie blue profile was constant, with 14 well-resolved bands present. Zone 4.5 polypeptides existed as at least four families of two or more components with closely related polypeptide backbones. The families could be distinguished on the basis of their extraction characteristics, immunological cross-reactivity, and two-dimensional peptide maps. One family was related to protein 4.1, one family was related to band 3, and two families were independent and not similar to other larger membrane proteins. The data show that all of the visualized bands in zone 4.5 do not have the same protein composition and that several closely related forms of some polypeptides are present.

Hexose transport modification of rat hearts during development of chronic diabetes.

Transport of 3-o-methylglucose into hearts of chronic diabetic rats was studied to determine if loss of transporter activity could be accounted for by higher concentrations of citrate and triglyceride and to determine if 7 days post alloxan was a representative time period for study of myocardial changes in chronic diabetes. Chronic diabetes was induced in rats by rapid i.v. injection of alloxan (37.5 mg/kg body weight), and the rats were studied 1 to 5 weeks afterward. Basal sugar transport rate in isolated perfused hearts declined after 2 weeks of diabetes and was nearly undetectable at 3 to 5 weeks. Stimulation of transport by insulin was also very low. Triglyceride concentrations were 50% of normal and G6P concentrations were elevated, but citrate concentrations were not different from control. Results of these studies showed that tissue triglyceride and citrate concentrations were not correlated with transport inhibition in chronic diabetic rat hearts. Loss of basal transport activity and lowered insulin sensitivity in these hearts is more likely due to a loss of transporters from the sarcolemma. These studies also show that transport rate and metabolite concentrations continue to change over 5 weeks of diabetes, and, therefore, one time point cannot be defined as representative of chronic diabetes.

A spectrin-like protein from mouse brain membranes: phosphorylation of the 235,000-dalton subunit.

A mouse brain spectrin-like protein, which was an immunoreactive analogue of erythrocyte spectrin, has been isolated from demyelinated membranes. This spectrin analogue was a 10.5 S, 972,000 molecular weight (Mr) (alpha beta)2 tetramer containing subunits of 240,000 (alpha) and 235,000 (beta) Mr. We demonstrated that in vivo only the 235,000 Mr beta subunit of the mouse brain spectrin-like protein was phosphorylated, which was an analogous situation to mouse erythrocyte spectrin in which only the 220,000 Mr beta subunit was phosphorylated. Incubation of isolated membrane fractions with [gamma-32P]ATP +/- adenosine 3',5'-cyclic monophosphate (cAMP) indicated that mouse brain spectrin-like protein, mouse erythrocyte spectrin, and human erythrocyte spectrin's beta subunits were all phosphorylated in vitro by membrane-associated cAMP-independent protein kinases.

Senescent cell antigen is immunologically related to band 3.

IgG autoantibodies in human serum selectively bind to a glycopeptide antigen that appears on senescent and damaged cells in situ. We identified the membrane protein from which the senescent cell antigen is derived by using a phagocytosis-inhibition assay and immunoautoradiographic gel staining and electroblotting techniques. Results of the phagocytosis-inhibition assay revealed that only the purified transmembrane glycoprotein designated "band 3" and senescent cell antigen inhibited the phagocytosis of erythrocytes induced by IgG eluted from senescent erythrocytes. Purified spectrin, syndein, band 4.1, actin, glycophorin A, and intact or desialylated sialoglycoprotein periodic acid/Schiff (PAS) staining bands 1-4 containing glycophorins A, B, and C did not inhibit phagocytosis. Specific antibodies against the senescent cell antigen and erythrocyte band 3 were used to identify the membrane protein from which the senescent cell antigen is derived. Band 3-related polypeptides (MrS approximately equal to 60,000, 42,000, and 18-26,000) were identified in erythrocyte ghosts prepared in the presence of diisopropyl fluorophosphate, phenylmethylsulfonyl fluoride, and EDTA by immunoautoradiography with antiband 3. Antibodies to senescent cell antigen reacted with band 3 and the same lower Mr band 3-related polypeptides. Thus, the senescent cell antigen is immunologically related to band 3.

Species-dependent variations in erythrocyte membrane skeletal proteins.

Two mammalian species (porcine and murine) have erythrocytes that are being widely used to study membrane protein synthesis and red cell aging. Erythrocytes of these species however, are significantly smaller than those of the human. Before results obtained from study of these red cells can be applied to human cells, the membrane skeleton of these species must be investigated to determine if the skeletal elements are equivalent. Both pig and mouse bands 4.1b were of lower molecular weight than human 4.1b, and the a/b ratio was lower. In each species, 4.1a and b were sequence-related phosphoproteins, and yielded substantially different one-dimensional peptide maps. Band 3 of pig and mouse erythrocytes had a higher molecular weight than human band 3 and also had differing one-dimensional peptide maps after limited proteolytic cleavage with three different enzymes. In each species, free band 3 and band 3 bound to the membrane skeleton had identical peptide maps. Other major membrane skeletal components (spectrin, actin, and bands 2.1 and 4.2) seem to be very similar in molecular weight in various species. These results demonstrate that the molecular weights and relative proportions of the membrane skeletal elements are species dependent.

A spectrin-like protein from mouse brain membranes: immunological and structural correlations with erythrocyte spectrin.

Membrane-associated mouse brain spectrin is a 972,000 Mr, 10.5S, (alpha beta)2 tetramer containing two approximately 240,000 Mr subunits and two approximately 235,000 Mr subunits. Two-dimensional [125I]tryptic peptide mapping indicates that these subunits share only limited and equivalent overlap with the alpha- and beta-subunits of red blood cell (RBC) spectrin. Both the 220,000 Mr beta-subunit of RBC spectrin and the 235,000 Mr beta-subunit of brain spectrin are phosphorylated in the intact mouse. In vitro analysis suggests that both are phosphorylated by a cAMP-independent protein kinase. Antibodies against pure native mouse red blood cell spectrin cross-react with brain spectrin, and antibodies against pure brain spectrin cross-react with both the alpha- and beta-subunits of mouse RBC spectrin. Both antibodies have been utilized to localize brain spectrin within distinct cellular entities of the mouse cerebellum. Granule cell neurons of the internal granule layer and Purkinje cell neurons demonstrated intense fluorescence of the cortical cytoplasm immediately adjacent to the plasma membrane and unstained nuclei, when either RBC or brain spectrin antibodies were utilized for staining. The molecular layer of the cerebellum stained only lightly, and oligodendrocytes and astrocytes appeared to have little fluorescence. Therefore, while brain is a tissue rich in nonerythroid spectrin, the concentration of these immunoreactive analogues is quite variable within distinct cellular entities of the cerebellum.

Erythrocyte membrane skeletal protein bands 4.1 a and b are sequence-related phosphoproteins.

Bands 4.1 a and b are proteins of 80,000 and 78,000 molecular weight, which are both present at approximately 100,000 copies per erythrocyte ghost. Both proteins are components of the erythrocyte membrane skeleton. Bands 4.1 a and b are labeled when intact erythrocytes are incubated with [32P]orthophosphoric acid, and, therefore, are phosphoproteins. One-dimensional partial proteolytic mapping analysis of 32P-labeled bands 4.1 a and 4.1 b and two-dimensional peptide mapping analysis of 125I-labeled bands 4.1 a and 4.1 b clearly demonstrated that the two proteins are sequence-related phosphoproteins. Band 4.1 purified by standard techniques (Tyler, J. M., Hargreaves, W. R., and Branton, D. (1979) Proc. Natl. Acad. Sci. U. S. A. 76, 5192-5196) contains bands 4.1 a and 4.1 b. Bands 4.1 a and 4.1 b bind to spectrin heterodimers in solution. We conclude that the erythrocyte skeletal proteins bands 4.1 a and 4.1 b are sequence-related phosphoproteins, both capable of binding spectrin.

Locus of N-ethylmaleimide action on sugar transport in nucleated erythrocytes.

Goose red blood cells were studied as a model for metabolic regulation of sugar transport. In contrast to their action in human erythrocytes, sulfhydryl-blocking agents such as N-ethylmaleimide (NEM) stimulated 3-O-methylglucose transport markedly in goose red blood cells. The effect of NEM was further enhanced when adenosine 5'-triphosphate (ATP) was first depleted by 2,4-dinitrophenol treatment or anoxia. Only sulfhydryl-blocking agents that enter the cell were effective transport stimulators, and the effect was not altered by substrates of the transporter. In nucleated red blood cell ghosts, NEM inhibited 3-O-methylglucose transport. Results of these studies with intact cells were consistent with the hypothesis that free sulfhydryl groups are essential for regulation of transporter activity rather than for the transport process itself. The locus of NEM action appears to be either on the cytoplasmic side of the membrane or partially located in the cytoplasm. ATP depletion may expose previously masked sulfhydryl groups, producing an enhanced reaction with sulfhydryl-blocking agents and a highly stimulated rate of sugar transport.

Effect of insulin on kinetics of sugar transport in heart muscle.

Insulin increased the maximal rate of sugar transport in the perfused rat heart, but had essentially no effect on the Michaelis constant of sugar entry or half-maximal constant for equilibrium exchange. In control hearts, the following kinetic parameters of 3-O-methylglucose transport were measured: Michaelis constant for entry, 7-10 mM; equilibrium exchange constant, 7 mM; and activity constant (Vmax/Km) from 0.02 to 0.1 ml/g.min. In insulin-treated hearts, these values were 6 mM, 3 MM, and 2.2 ml/g.min, respectively. These changes in transport constants were consistent with a model in which 1) sequestered carrier was released by the hormone or 2) carrier movement, in all forms and directions, was accelerated. Measurements of glucose transport in control hearts indicated that the Michaelis constant for entry was 4 mM and the activity constant, 0.5 ml/g.min. In insulin-treated hearts, quantitation of transport parameters was prevented by accumulation of intracellular glucose.

Sugar transport in reversibly hemolyzed avian erythrocytes.

The technique of reversible hemolysis represents one approach which may be used to study transport regulation in nucleated red cells. After 1 h of incubation at 37 degrees C, 88% of the ghosts regained their permeability barrier to L-glucose. In these ghosts, the carrier-mediated rate of entry of 3-O-methylglucose was more than 10-fold greater than the rate in intact cells. Glyceraldehyde-3-phosphate dehydrogenase prevented ghosts from resealing when it was present at the time of hemolysis. Albumin, lactic dehydrogenase and peroxidase did not have this effect. Sugar transport rate could not be tested in the unsealed ghosts. Two possible mechanisms for the effect of hypotonic hemolysis on sugar transport rate were discussed: (1) altered membrane organization and (2) loss of intracellular compounds which bind to the membrane and inhibit transport in intact cells.