Electrophoretic Separation of Different Phophosproteins Associated with Ca-ATPase and Na,K-ATPase in Human Red Cell Ghosts

Ca has been found to increase the quantity of ³²P incorporated into red cell ghosts from [γ-³²P]ATP over the levels obtained by incubation with Mg alone or with Mg + Na, in correlation with the effect of Ca on the associated ATPase activities. When the ³²P-labeled ghosts were solubilized in sodium dodecyl sulfate (SDS) and electrophoresed on acrylamide gels only two bands could be detected either by autoradiography or by counting the sliced gels. The faster moving band (P-2) had the same mobility and the same molecular weight (103,000) as the phosphoprotein found either with Mg alone or with Mg + Na. The slower moving band (P-1) was not found in extensively washed ghosts labeled in the absence of Ca. The molecular weight of P-1 is approximately 150,000. P-1 like P-2 was not affected by pretreatment of intact cells with Pronase before labeling indicating that neither the phosphorylating mechanism nor the phosphoprotein are accessible to externally applied Pronase. The demonstration that a Ca-phosphoprotein is separable from the Na-stimulated phosphoprotein suggests that the Ca-ATPase is distinct from and independent of the Na,K-ATPase. The fact that Ca blocks the dephosphorylation by K of the Na-phosphoprotein indicates that caution is required in interpreting results when the activities of the different phosphoproteins have not been separately determined.     

The Active Transport of Sodium by Ghosts of Human Red Blood Cells

The outflux of Na²⁴ from prelabeled ghosts was measured under various conditions. Prelabeling was accomplished by hypotonic hemolysis of intact human cells in the presence of tracer Na²⁴. The resultant ghosts when subsequently washed were found to retain 10 to 20 per cent of the initial Na²⁴. Separate experiments indicated that this trapped amount resides in only a portion of ghosts comprising the total population. The characteristics of the outflux of this residual Na²⁴ indicated that the ghost system closely resembles intact red cells. The outflux of Na from ghosts could be divided into three components: active and passive transport and exchange diffusion. The active transport system, necessarily driven by metabolism, required the presence of K in the extracellular phase and was blocked by strophanthidin. The concentration dependence of the Na pump flux on the external K and internal Na appeared the same in ghosts as in intact cells. Certain other features of this ghost system are also discussed.     

Membrane compartmentalized ATP and its preferential use by the Na, K-ATPase of human red cell ghosts

This paper describes work which begins to define the molecular organization in the region of the membrane that comprises the functional domain of the Na:K pump. The membrane-bound phosphoglycerate kinase (PGK) and Na, K-ATPase appear to be directly linked via a compartmentalized form of ATP. Evidence for the membrane pool of ATP is based on the labeling characteristics of the phosphoproteins by [γ-(32)P]ATP of ghosts incubated under various conditions. Preincubation of ghosts in the presence of ATP at 37 degrees C, but not at 0 degrees C, completely obscures the formation of the Na-phosphoprotein in ghosts washed and subsequently incubated in the presence of [gamma-(32)P]ATP. In contrast to the Na component, the Mg component of phosphorylation is only slightly altered by preincubation with ATP. ATPase activity measured as (32)P(i) liberated during the subsequent incubation at 0 degrees C, reflects completely the differential effects of preincubation with ATP on (32)P incorporation into phosphoprotein. ATP placed within the pool by preincubation can be removed by operating the Na, K-ATPase or the PGK reaction in the reverse direction by use of exogenous substrates. Alternatively, the membrane pool of ATP can be formed also from exogenous substrates by running the PGK reaction in the forward direction. These results, while providing direct support for a membrane compartment of ATP, also indicate the location of this compartment in relation to the PGK and the Na, K-ATPase. In addition, these results also imply that the Mg and Na components are different enzymatic entities since substrate ATP can be derived from separate sources.     

Change in a nuclear phosphoprotein during in vitro myogenesis

Synthesis and phosphorylation of total myoblast nuclear proteins have been studied during three stages of in vitro myogenesis: myoblast proliferation (22 h), pre-fusion mitotic arrest (44 h), and in myotubes (68 h). Phosphorylation in intact cells with [³²P]orthophosphate followed by SDS slab gel electrophoresis and radioautography of nuclear proteins reveals a striking decline in phosphorylation of a 100 000 D band at 44 h. This phosphoprotein band is not detectable at 68 h. Phosphorylation of isolated nuclei with γ-[³²P]ATP reveals the 100 000 D band as the major phosphoprotein which declines to 40% by 68 h. Assessment of content and synthesis of individual nuclear proteins by Coomassie Blue staining and [ -³⁵S]methionine labelling reveals no appreciable changes in co-migrating 100 000 D bands, suggesting that the decline in phosphorylation is caused by either decreased kinase or increased phosphatase activity.     

Identification of the 64 kilodalton chloroplast stromal phosphoprotein as phosphoglucomutase

Phosphorylation of the 64 kilodalton stromal phosphoprotein by incubation of pea (Pisum sativum) chloroplast extracts with [γ-³²P]ATP decreased in the presence of Glc-6-P and Glc-1,6-P₂, but was stimulated by glucose. Two-dimensional gel electrophoresis following incubation of intact chloroplasts and stromal extracts with [γ-³²P]ATP, or incubation of stromal extracts and partially purified phosphoglucomutase (EC 2.7.5.1) with [³²P]Glc-1-P showed that the identical 64 kilodalton polypeptide was labeled. A 62 kilodalton polypeptide was phosphorylated by incubation of tobacco (Nicotiana sylvestris) stromal extracts with either [γ-³²P]ATP or [³²P]Glc-1-P. In contrast, an analogous polypeptide was not phosphorylated in extracts from a tobacco mutant deficient in plastid phosphoglucomutase activity. The results indicate that the 64 (or 62) kilodalton chloroplast stromal phosphoprotein is phosphoglucomutase.     

Phosphoprotein phosphate activity at the outer surface of intact normal and transformed 3T3 fibroblasts

Using ³²P-labeled phosphocasein or phosphohistones as exogenous substrates it was possible to detect a phosphoprotein phosphate activity on the outer surface of intact normal and transformed 3T3 fibroblasts. Incubation of monolayers of intact cells in buffered salt solution with the radioactively labeled substrate resulted in the release of alkali-labile ³²P counts into the surrounding medium. The reaction was: (a) linear with time (at least up to 20 min); (b) proportional to the cell density; (c) dependent on the temperature and pH of the incubation medium; (d) stimulated by K⁺; and (e) inhibited by sodium fluoride, inorganic pyrophosphate, zinc chloride and relatively impermeant sulfhydryl reagents. Less than 2% of the externally located phosphoprotein phosphatase activity was detectable in pooled cell-free washings of the intact cell monolayer. Phosphocasein did not cause any detectable leakage of intracellular lactate dehydrogenase or soluble phosphoprotein phosphatase activity into the external medium; incubation of the cells with phosphohistones, on the other hand, resulted in appreaciable leakage of both these cytoplasmic activities. Neoplastic transformation was associated with a nearly two-fold decrease in the activity of the surface phosphoprotein phosphatase. Addition of serum to either non-transformed 3T3 or spontaneously transformed 3T6 cells resulted in a rapid and remarkable drop in the cell surface dephosphorylating activity. Acrylamide gel electrophoresis of the dephosphorylated casein or histone substrate revealed no proteolytic degradation or change in electrophoretic mobility. The intact cells showed no damage upon microscopic examination as a result of exposure to phosphocasein or phosphohistones.     

Backdoor phosphorylation of basolateral plasma membranes of small intestinal epithelial cells: characterization of a furosemide-induced phosphoprotein related to the second sodium pump

Enterocyte has two different Na+-stimulated ATPases, the ouabain-sensitive Na+/K+ ATPase and a furosemide-inhibitable Na+ ATPase. To identify the polypeptide associated with the Na+-ATPase, 32Pi phosphorylation into basolateral membranes of enterocyte was investigated. Both, ouabain and furosemide induced Mg2+-dependent, vanadate-sensitive 32Pi incorporation into a 100kDa polypeptide. K(m) for Pi was 17.7+/-1.82 microM and 16.8+/-0.69 microM for ouabain-induced and furosemide-induced phosphorylation, respectively. K(m) for furosemide was 1.3+/-0.21 mM. Furosemide-induced 32Pi incorporation was sensitive to alkaline pH and hydroxylamine suggesting an acyl-phosphate bond. Na+ and K+ inhibited 32Pi incorporation induced by ouabain. In contrast, Na+ stimulated furosemide-induced phosphorylation with a K(m) of 16.5+/-5.59 mM while K+ had no effect. Purified Na+/K+ ATPase only presented ouabain-induced phosphoprotein, indicating that furosemide-induced phosphorylation is not related to this enzyme and appears to correspond to a new member of P-type ATPases associated with the second Na+ pump.     

Resolution of erythrocyte membrane proteins by two-dimensional electrophoresis.

A two-dimensional electrophoresis method has been developed which solubilizes erythrocyte membrane proteins, and which resolves the components of the band that migrates in detergent gels as if its molecular mass were 95,000 daltons. This method uses gel electrophoresis with sodium dodecyl sulfate in the first dimension and phenol, aqueous urea, and acetic acid in the second dimension. The 95,000 dalton band is known to contain several different membrane proteins, including those associated with anion transport, glucose transport, and (Na+,K+) transport. Two-dimensional electrophoresis resolved this band into one major spot and several minor ones. Pronase digestion of whole erythrocytes, followed by preparation of ghosts and two-dimensional electrophoresis, showed that only the major component of this band was digested by pronase.     

Glyceraldehyde-3-phosphate dehydrogenase in the isolated human erthrocyte membrane: selective displacement by bilirubin.

When unsealed erythrocyte ghosts in 6 mm phosphate buffer (pH 8.0, 4 °C) were incubated with bilirubin in excess of 0.1 mm and washed with buffer, a single polypeptide component (band 6 in sodium dodecyl sulfate-polyacrylamide-gel electrophoresis) diminished and was recovered in the supernatant fraction. Release of this component was virtually complete at 1 mm initial bile pigment. Since band 6 was believed to be the protomer of membrane-bound glyceraldehyde-3-phosphate dehydrogenase (G3PD), assays for this enzyme in bilirubin-treated ghosts were carried out. These revealed that enzymatic activity decreased concurrently with the disappearance of band 6. The molecular weight of the eluted polypeptide was found to be 36,000, in agreement with the known value for the G3PD protomer. When Mg²⁺-resealed ghosts were washed after exposure to 1 mm bilirubin, less than 20% of the G3PD was eluted, which is consistent with the fact that the enzyme is attached to the cytoplasmic face of the membrane. NAD⁺ in concentrations up to 2 mm displaced no more than 15% of the G3PD from unsealed ghosts. However, after preincubation with NAD⁺ (1 mm) followed by bilirubin (1 Mm) and washing, loss of G3PD was similar to that observed in the absence of cofactor. Since NAD⁺ did not attenuate release of the enzyme, it appears unlikely that such release is attributable to binding of bilirubin at the active site. Protoporphyrin acted similarly to bilirubin on unsealed ghosts, whereas rose bengal had a more pronounced effect, removing all enzymatic activity when the dye concentration reached 0.2 mm. Electrophoretic analysis of ghosts after rose bengal treatment, however, revealed a diminution not only of band 6 but bands 1, 2, and 5 as well.     

Possible identity of a membrane-bound with a soluble cyclic AMP-independent erythorocyte protein kinase that phosphorylates spectrin

A soluble casein kinase isolated and purified to homogeneity from the human erythrocyte cytosol by phosphocellulose and Sephadex G-200 chromatographies is indistinguishable from the membrane-bound casein (spectrin_kinase according and site-specificity criteria. The soluble enzyme shows an M_r of about 30 000 by gel filtration and comigrates with the purified membrane spectrin kinase as a single polypeptide of 32 000 Da on sodium dodecyl sulfate polyacrylamide gels. The soluble kinase phosphorylates spectrin in situ in spectrin kinase-depleted ghosts and catalyzes the in vitro phosphorylation of partially dephosphorylated spectrin with saturation kinetics identical to those displayed by the membrane spectrin kinase. When component 2 of spectrin that has been phosphorylated with [γ-³²P]ATP by either the soluble or the membrane kinases was subjected to limited proteolysis, the same 21500 Da papain-generated phosphopeptide was found to have been produced by the two enzymes. The same 21 500 Da phosphopeptide was identified after papain digestion of spectrin isolated from intact cells that had been incubated with ³²P_i. However, this particular peptide was not labeled in spectrin that had been phosphorylated in vitro by the catalytic subunit of cyclic AMP-dependent protein kinase. Identical phosphopeptide patterns were obtained by gel filtration and two-dimensional peptide maps of trypsin-cleaved component 2 of spectrin that had been labeled in situ, in intact ghosts or in spectrin kinase-depleted ghosts supplemented with the soluble kinase. These findings indicate a possible identity of the soluble with the membrane-bound casein (spectrin) kinase.     

Characterization and Intraorganellar Distribution of Protein Kinases in Amyloplasts Isolated from Cultured Cells of Sycamore (Acer pseudoplatanus L.)

Incubation of amyloplasts isolated from cultured cells of sycamore (Acer pseudoplatanus L.) with [γ-³²P]ATP resulted in the rapid phosphorylation (half-time of 40 seconds at 25 degrees Celcius) of organellar polypeptides. The preferred substrate for amyloplast protein kinases was Mg²⁺. ATP, and recovery of only [³²P]serine after partial acid hydrolysis indicated the predominance of protein serine kinases in the organelle. These activities were located in the envelope and stromal fractions of the plastid, which showed different specificities toward exogenous protein substrates and distinct patterns of phosphorylation of endogenous polypeptides. A 66-kilodalton polypeptide, inaccessible to an exogenously added protease, was one of the major phosphorylated products found in intact amyloplasts at low [γ-³²P] adenosine triphosphate concentrations. This polypeptide represented the major phosphoprotein observed with the isolated envelope fraction. The patterns of polypeptide phosphorylation found in intact amyloplasts and chloroplasts from cultured cell lines of sycamore were clearly distinguishable. The overall results indicate the presence of protein phosphorylation systems unique to this reserve plastid present in nonphotosynthetic tissues.     

Differential Labeling of Components in Human Erythrocyte Membranes Associated with the Transport of Glucose

The irreversible inhibition of glucose transport by 1-fluoro-2,4-dinitrobenzene (FDNB) has been used to identify membrane proteins possibly associated with glucose transport in human crythrocytes. D-Glucose was shown to enhance significantly the rate of FDNB inhibition of transport when present during the reaction, whereas cytochalasin B (CB) and D-maltose retarded this FDNB inhibition of transport. This modulation of the inhibition reaction formed the basis for a double isotopic differential labeling technique using [¹⁴C]- and [³H]FDNB followed by SDS-polyacrylamide gel electrophoresis to distinguish transport-associated polypeptides from bulk membrane dinitrophenylated proteins.

Reactions in the presence of CB or maltose revealed the presence of a differentially labeled polypeptide(s), with a molecular weight of approximately 60,000-65,000 daltons. This effect could in part be reversed in the presence of D-glucose but not L-glucose. Reactions in the presence of D-glucose resulted in two regions of differential labeling. One region was around 200,000 daltons and the other corresponded to a 90,000-dalton band.

Extraction of membrane proteins with p-chloromercuribenzene sulfonate resulted in no loss of the 60,000-dalton peak, indicating that this labeled polypeptide(s) was firmly anchored in the hydrophobic core of the membrane.

These results indicate that as many as three membrane polypeptides are differentially labeled by FDNB under conditions strongly associated with the inhibition of the glucose transport system and may be involved in the regulation of glucose transport.     

Protein kinase activity of purified rat liver glucocorticoid receptor

Molybdate-stabilized nonactivated rat liver glucocorticoid receptor (GR) was purified to near homogeneity using a biospecific affinity adsorbent, Bio Gel A 0.5 m and DEAE-Sephacel. The purified GR sedimented in the 9-10S region in 5-20% sucrose gradients containing 0.10M KCl and 20mM Na2MoO4. SDS-polyacrylamide gel electrophoresis revealed a major single band with an apparent molecular weight of 90,000 +/- 2,000. Affinity labeling of GR with [3H]-dexamethasone mesylate showed association of the radioactivity with a peptide of 90,000 molecular weight. Purified receptor preparation was dialyzed to remove molybdate and was incubated with different protein substrates in the presence of 50 microM [gamma-32P]-ATP and divalent cations. Radioactive phosphate from [gamma-32P]-ATP was seen to be incorporated into calf thymus histones, turkey gizzard myosin light chain kinase and rabbit skeletal muscle kinase in the presence of Mg2+ and Ca2+ ions. Addition of steroid ligand exogenously to the reaction mixture appeared to increase the extent of protein phosphorylation. No autophosphorylation of GR was evident under the above conditions. The data suggest that purified rat liver GR displays protein kinase activity.     

Labeling of human erythrocyte membranes with eosin probes used for protein diffusion measurements. Inhibition of anion transport and photo-oxidative inactivation of acetylcholinesterase

The binding of eosin-isothiocyanate (eosin-NCS) and iodoacetamido-eosin (IA-eosin) to band 3 proteins in the membrane of human erythrocytes is characterized by studying the effect of these probes on the anion transport system. Although the unbrominated fluorescein precursors do not affect anion transport, both eosin labels are strong inhibitors of sulphate exchange in intact erythrocytes. 50% inhibition is obtained by binding 4.7 · 10⁵ or 6.0 · 10⁵ molecules/cell for eosin-NCS and IA-eosin, respectively. Both eosin probes are irreversibly bound and occupy common binding sites with 4,4′-diisothiocyano-1,2-diphenyl-ethane-2,2′-disulfonic acid (H₂DIDS), although other sites are labeled as well. The inhibition of anion transport is light independent and can therefore not be attributed to a photosensitizing action of the eosin probes. Both eosin derivatives, however, inactivate acetylcholinesterase upon illumination of air-equilibrated samples of hemoglobin-free labeled ghosts. The inactivation of the enzyme is accompanied by the formation of protein aggregates as visualized by polyacrylamide gel electrophoresis. These effects are not observed when intact erythrocytes are illuminated in the presence of eosin probes suggesting a protective effect of hemoglobin during the labeling procedure. Protection of ghosts from photo-oxidation is achieved by displacing air with argon. These results are discussed in relation to the use of these and similar probes to measure protein diffusion in membranes.     

The exchange of erythrocyte membrane phospholipids with rat liver extracts in vitro

Intact rat or human erythrocytes and their isolated (ghost) membranes were incubated with the high speed supernatant fraction of homogenates derived from ³²P-labeled rat livers. Phospholipid molecules were transferred between the red cell membranes and the liver extracts, as reflected by the convergence of their specific radioactivities with time. Whereas ghosts usually approached isotopic equilibrium with the liver supernatant fraction during a few hours of incubation at 37° C, the exchange of phospholipids by intact cells was no more than one-half, even after 18 hr. Phosphatidylcholine, phosphatidylethanolamine, phosphatidylserine and sphingomyelin were all exchanged in both intact cells and ghosts, albeit to different extents. (A control experiment, incubating ³²P-labeled rat erythrocytes or ghosts with unlabeled rat liver extracts, also demonstrated the exchange of all four major phospholipids.) These data may signify that the phospholipids on the cytoplasmic side of the membrane of intact erythrocytes do not exchange with the phospholipids in exogenous liver extracts. If so, all four major phospholipid classes would appear to be present to some extent at both membrane surfaces. The first inference is in agreement with several other studies on this membrane, while the second inference is not.     

Studies on the characterization of the sodium-potassium transport adenosinetriphosphatase. XII. Evidence for interaction of the acyl phosphate at the active site with neighboring groups

The sodium-potassium adenosinetriphosphatase (NaK ATPase), partially purified from beef brain, has been phosphorylated with [γ-³²P]ATP in the presence of Na and Mg and digested with pronase. A single ³²P-labeled peptide spot has been identified on paper electrophoresis, accounting for 60% of the radioactivity in the ³²P-labeled enzyme, the remainder of the radioactivity being [³²P]-orthophosphate resulting from breakdown of the highly labile acyl phosphate during pronase digestion. The ³²P in the pronase peptide was released as [³²P]-orthophosphate by N-propylhydroxylamine—as to be expected of an acyl phosphate compound. The pH stability of the acyl phosphate in the denatured phosphorylated NaK ATPase, in the pronase peptide and in acetyl phosphate were quite different. The phosphorylated protein had the lowest stability of higher pHs, acetyl phosphate had the highest stability, and the pronase peptide had an intermediate stability. These results indicate that the neighboring groups in the polypeptide chain containing the acyl phosphate residue influence the stability of the acyl phosphate bond.     

Fluorescence labeling of the human erythrocyte anion transport system. Subunit structure studied with energy transfer

The anion transport system of human red cells was isolated in vesicles containing the original membrane lipids and the 95 000 dalton polypeptides (band 3) by the method of Wolosin et al. (J. Biol. Chem. (1977) 252, 2419–2427). The vesicles have a functional anion transport system since they display sulfate transport that is inhibited by the fluorescent probe 8-anilinonaphthalene 1-sulfonate (ANS) with similar potency as in red cells. The vesicles were labeled with the SH-specific probe fluorescein mercuric acetate (FMA). Labeling lowers FMA fluorescence, and is prevented or reversed by dithiothreitol, suggesting that the reaction is with a thiol group on the protein. Fluorescence titrations show a maximum labeling stoichiometry of 1.3 ± 0.4 mol FMA/mol 95 000 dalton polypeptide. The polarization of bound FMA fluorescence is high indicating that the probe is highly immobilized. Pretreatment with Cu²⁺ + o-phenanthroline under conditions that crosslink band 3 in ghosts decreases FMA labeling 50%. Differences in kinetics of FMA labeling in sealed and leaky vesicles suggest that the reactive SH group is located in the intravesicular portion of the protein (corresponding to the cytoplasmic surface of the red cell) and that FMA can cross the membrane. Inhibitors of anion transport have no effect on FMA labeling kinetics suggesting it is not transported via the anion     

Peptide heterogeneity in the band 3 protein of rabbit erythrocyte plasma membranes

We have examined the band 3 protein(s) of rabbit erythrocyte membranes by a combination of differential extraction and surface labeling methods. Only one major peptide was labeled when intact red cells were exposed to ¹²⁵I^? and lactoperoxidase; this coincided with band 3. When intact cells were exposed to galactose oxidase followed by [³H]borohydride, numerous surface glycoproteins were labeled, one of which clearly coincided with band 3. Differential extraction with lithium diiodosalicylate revealed one major band 3 glycoprotein which contained both the ¹²⁵I^? and ³H surface labels and three peptides which were unlabeled; these three peptides are apparently not exposed at the cell surface.     

Role of membrane-bound Ca in ghost permeability to Na and K

Summary The permeability of red cell ghosts to K is determined by the amount of membrane-bound Mg which, in turn, depends on internal Mg. Contrasting with such effect, an increase in cellular Ca raises K permeability. To test whether this, action is due to a competitive displacement of membrane Mg, the free Ca content of human red cell ghosts was altered by means of Ca-EGTA buffers. Net Na and K movements as well as Ca and Mg bindings, were assessed after incubation in a Na-medium at 37°C. Raising Ca from 3×10^–7 to 1×10^–2M caused a large K efflux with very little Na gain. Under similar conditions, Ca binding was increased without affecting membranebound Mg. Both Ca binding and K loss were markedly diminished by either adding ATP to the hemolytic medium or increasing internal Mg at a fixed Ca concentration. A Scatchard analysis showed three Ca binding sites, two of them having high affinity. It is concluded that Ca action does not arise from a displacement of membrane-bound Mg but from binding to different sites in the membrane. Presumably, high affinity sites are involved in the control of K permeability.