Beta-galactosidase fused to the hydrophobic domain of cytochrome b5 spontaneously associates with liposomes

Since liver microsomal cytochrome b5 spontaneously associates with liposomes and membranes by means of its C-terminal hydrophobic domain (HP), chimeric proteins containing HP prepared by genetic fusion might also spontaneously associate with liposomes or cellular membranes. Synthetic DNA corresponding to the hydrophobic domain of cytochrome b5 was enzymatically fused in-frame to cloned DNA corresponding to the C-terminus of the Escherichia coli enzyme, beta-galactosidase. This protein, LacZ:HP, synthesized in E. coli and purified from a crude E. coli membrane extract, was shown to spontaneously associated with liposomes, as does cytochrome b5. Association is rapid and stable in the presence of salt and high pH and the fusion protein behaves as an integral membrane protein. LacZ:HP can be readily and extensively purified from crude extracts by association with liposomes and this procedure may provide a convenient purification scheme for proteins not otherwise readily purified, for example polypeptides from cloned gene fragments to be used for antibody production. These hybrid proteins may represent a new potentially useful class of polypeptides capable of hydrophobic interactions with membranes.     

Rotational diffusion of the erythrocyte integral membrane protein band 3: effect of hemichrome binding.

Human erythrocyte band 3 was covalently labeled within the integral membrane domain by incubating intact erythrocytes with the phosphorescent probe eosinyl-5-maleimide. The rotational diffusion of band 3 in membranes prepared from these labeled cells was measured using the technique of time-resolved phosphorescence anisotropy. Three rotational correlation times ranging from 16 to 3800 microseconds were observed, suggesting that band 3 exists in different aggregate states within the plane of the membrane. The oxidizing agent phenylhydrazine was used to induce hemichrome formation within intact erythrocytes. The immobilization of band 3 in membranes prepared from these erythrocytes suggests that the binding of hemichromes induces clustering of band 3. The addition of purified hemichromes to erythrocyte ghosts leads to a similar effect. We have also examined the mobility of the cytoplasmic domain of band 3. This region was labeled indirectly using a phosphorescently labeled antibody which binds to an epitope within the cytoplasmic domain. We observed very rapid motion of the cytoplasmic region of band 3, which was only partially restricted upon hemichrome binding. This suggests that the integral and cytoplasmic domains of band 3 may be independently mobile.     

The hydrophobic domain of cytochrome b5 is capable of anchoring beta-galactosidase in Escherichia coli membranes.

Cytochrome b5 is inserted posttranslationally into membranes in vivo and spontaneously into liposomes in vitro by a short carboxyl-terminal hydrophobic membrane-anchoring sequence. DNA corresponding to this hydrophobic sequence has been synthesized, and two gene fusions with the Escherichia coli enzyme beta-galactosidase have been constructed by locating the hydrophobic domain in one case at the EcoRI site near the C terminus and in the other at the normal C terminus of the enzyme. The latter fusion protein was enzymatically active, having approximately 50% of the specific activity of beta-galactosidase, and cells expressing this protein grew normally with lactose as the sole carbon source. Both fusion proteins were localized to the E. coli inner membrane, converting beta-galactosidase from a cytoplasmic enzyme to a membrane-associated enzyme. The hydrophobic domain of cytochrome b5 therefore contains the information required to target polypeptides containing this domain to the membrane. Use of the cytochrome b5 hydrophobic peptide, either alone or in conjunction with other localizing sequences such as signal sequences, provides a general procedure for associating proteins with membranes. Polypeptides bearing this hydrophobic peptide may have considerable use as pharmaceuticals when associated with liposomes or cellular membranes.     

Effects of surface proteins of human erythrocyte membrane on the interaction with lipopolysaccharides from <Emphasis Type="Italic">Escherichia coli</Emphasis> O55:B5

The role of erythrocytic surface membrane proteins and membrane charge in the interactions of the erythrocytes with lipopolysaccharides (LPS) isolated from Escherichia coli O55:B5 (LPS _{E. coli} , S-form) has been examined by two independent methods, flow cytometry and cell electrophoresis. Treatment of erythrocytes with trypsin that modifies stereochemical properties of cell surface resulted in a 16% increase in the level of the erythrocyte fluorescence measured after their incubation with fluorescently labeled LPS _{E. coli} . Electrophoretic mobility (EM) of the trypsin-treated erythrocytes was reduced by 16%. The removal of sialic acids from the erythrocyte surface with neuraminidase had no considerable effect either on the relative EM values or fluorescence intensity after the incubation of cells with LPS. The results suggest that the major role in the incorporation of the S-form LPS into the membrane of human erythrocytes is played by stereochemical factors, whereas the cell surface charge is less significant.     

Resolution of the paradox of red cell shape changes in low and high pH

The molecular basis of cell shape regulation in acidic pH was investigated in human erythrocytes. Intact erythrocytes maintain normal shape in the cell pH range 6.3-7.9, but invaginate at lower pH values. However, consistent with predicted pH-dependent changes in the erythrocyte membrane skeleton, isolated erythrocyte membranes evaginate in acidic pH. Moreover, intact cells evaginate at pH greater than 7.9, but isolated membranes invaginate in this condition. Labeling with the hydrophobic, photoactivatable probe 5-[125I]iodonaphthyl-1-azide demonstrated pH-dependent hydrophobic insertion of an amphitropic protein into membranes of intact cells but not into isolated membranes. Based on molecular weight and on reconstitution experiments using stripped inside-out vesicles, the most likely candidate for the variably labeled protein is glyceraldehyde-3-phosphate dehydrogenase. Resealing of isolated membranes reconstituted both the shape changes and the hydrophobic labeling profile seen in intact cells. This observation appears to resolve the paradox of the contradictory pH dependence of shape changes of intact cells and isolated membranes. In intact erythrocytes, the demonstrated protein-membrane interaction would oppose pH-dependent shape effects of the spectrin membrane skeleton, stabilizing cell shape in moderately abnormal pH. Stabilization of erythrocyte shape in moderately acidic pH may prevent inappropriate red cell destruction in the spleen.     

Transfer of cytochrome b 5 and NADPH cytochrome c reductase between membranes

NADPH-cytochrome c reductase also reduces cytochrome b 5. The reduction is very slow when the proteins are in solution or bound to different membranes. Only when both proteins share a common membrane, is cytochrome b 5 reduced rapidly by NADPH. The difference in reaction rates indicates recombination on a common membrane of cytochrome b 5 and NADPH reductase originally bound to different vesicles. The recombination of the two proteins occurs with a variety of biological membranes (previously enriched with either reductase or cytochrome b 5) as well as with liposomes. We explain this process as protein transfer rather than vesicle fusion for several reasons: 1. The vesicles do not alter shape or size during incubation. 2. The rate of this process corresponds to the rate of incorporation of the single proteins into liposomes carrying the 'complementary' protein. 3. The exchange of proteins between biological membranes and liposomes occupied by protein does not change the density of either membrane. Protein transfer between membranes appears to be limited to those proteins which had spontaneously recombined with a preformed membrane. In contrast, proteins incorporated into liposomes by means of a detergent were not transferred, nor were endogenous cytochrome b 5 and NADPH-cytochrome c reductase transferred from microsomes to Golgi membranes or lipid vesicles. We conclude that the endogenous proteins and proteins incorporated in the presence of a detergent are linked to the membrane in another manner than the same proteins which had been inserted into a preformed membrane.     

Human erythrocyte membranes contain a cytochrome b561 that may be involved in extracellular ascorbate recycling

Human erythrocytes contain an unidentified plasma membrane redox system that can reduce extracellular monodehydroascorbate by using intracellular ascorbate (Asc) as an electron donor. Here we show that human erythrocyte membranes contain a cytochrome b(561) (Cyt b(561)) and hypothesize that it may be responsible for this activity. Of three evolutionarily closely related Cyts b(561), immunoblots of human erythrocyte membranes showed only the duodenal cytochrome b(561) (DCytb) isoform. DCytb was also found in guinea pig erythrocyte membranes but not in erythrocyte membranes from the mouse or rat. Mouse erythrocytes lost a majority of the DCytb in the late erythroblast stage during erythropoiesis. Absorption spectroscopy showed that human erythrocyte membranes contain an Asc-reducible b-type Cyt having the same spectral characteristics as recombinant DCytb and biphasic reduction kinetics, similar to those of the chromaffin granule Cyt b(561). In contrast, mouse erythrocytes did not exhibit Asc-reducible b-type Cyt activity. Furthermore, in contrast to mouse erythrocytes, human erythrocytes much more effectively preserved extracellular Asc and transferred electrons from intracellular Asc to extracellular ferricyanide. These results suggest that the DCytb present in human erythrocytes may contribute to their ability to reduce extracellular monodehydroascorbate.     

Domains of receptor mobility and endocytosis in the membranes of neonatal human erythrocytes in the membranes of neonatal human erythrocytes and reticulocytes are deficient in spectrin

It has previously shown (Schekman, R., and S.J. Singer, Proc. Natl. Acad. Sci. U.S.A. 73:4075-4079) that receptors in the membranes of neonatal human erythrocytes show a restricted degree of lateral mobility, whereas in adult human erythrocytes the receptors are essentially immobile. This restricted mobility is exhibited, for example, when concanavalin A (Con A) induces a limited clustering of its receptors in the neonatal erythrocyte membrane, resulting in the formation of invaginations and endocytic vesicles. This does not happen with adult cells. By the use of indirect immunoferritin labeling of ultrathin frozen sections of Con A-treated neonatal blood cells, we now show that the invaginations and endocytotic vesicles do not stain for spectrin, whereas the adjacent unperturbed membrane is heavily stained. The reticulocytes in the neonatal cell population undergo substantially more Con A-induced invagination and endocytosis than do the erythrocytes. These results lend strong support to the hypothesis that specialized discrete domains exist, or are induced, in the membranes of these neonatal cells, in which receptors are laterally mobile, whereas in the remaining (and predominant) part of the membrane the receptors are immobile. Such mobile domains are characterized by an absence of spectrin. During the maturation of the neonatal reticulocyte to erythrocyte, it is proposed that these domains are in large part, but not completely, eliminated.     

Effects of domain-specific erythrocyte membrane modulators on acetylcholinesterase and NADH:cytochrome b5 reductase activities

Previously, we showed using electron paramagnetic resonance that the physical state of one side of erythrocyte membranes could be modulated by agents which interact with the opposite side (reviewed in Butterfield, 1989, Biological and Synthetic Membranes, A. R. Liss, Inc., New York). The present study was undertaken to determine whether membrane-bound enzymes would exhibit a similar transmembrane modulation effect. The effects of known, domain-specific modulators of the physical state of erythrocyte membranes on the activity of two membrane-bound enzymes were investigated. Acetylcholinesterase, an enzyme having its active site situated on the extracellular side of the membrane, seemed to be unaffected by most of the modulators employed in this study, with the exception of reversible inhibition by benzyl alcohol. Conversely, the activity of NADH:cytochrome b5 reductase, an enzyme whose active site is located on the cytoplasmic side of the erythrocyte membrane, was increased by those agents that interact primarily with skeletal proteins to increase skeletal protein-protein interactions; however, those agents which interact primarily with the skeleton to decrease protein-protein interactions decreased the activity of NADH:cytochrome b5 reductase. This enzyme's activity was also significantly altered by lectins which bind specifically to the external face of glycophorin A on the opposite side of the membrane, but it's activity was unaffected by concanavalin A, a lectin which binds to the external face of band 3. The results of these biochemical studies suggested that NADH:cytochrome b5 reductase can interact with and its activity can be modulated by skeletal or transmembrane proteins. In addition, these results support the hypothesis that in transmembrane signaling processes, biophysical and biochemical changes are correlated.     

Discrete domains within the rotavirus VP5* direct peripheral membrane association and membrane permeability

Cleavage of the rotavirus spike protein, VP4, is required for rotavirus-induced membrane permeability and viral entry into cells. The VP5* cleavage product selectively permeabilizes membranes and liposomes and contains an internal hydrophobic domain that is required for membrane permeability. Here we investigate VP5* domains (residues 248 to 474) that direct membrane binding. We determined that expressed VP5 fragments containing residues 248 to 474 or 265 to 474, including the internal hydrophobic domain, bind to cellular membranes but are not present in Triton X-100-resistant membrane rafts. Expressed VP5 partitions into aqueous but not detergent phases of Triton X-114, suggesting that VP5 is not integrally inserted into membranes. Since high-salt or alkaline conditions eluted VP5 from membranes, our findings demonstrate that VP5 is peripherally associated with membranes. Interestingly, mutagenesis of residue 394 (W-->R) within the VP5 hydrophobic domain, which abolishes VP5-directed permeability, had no effect on VP5's peripheral membrane association. In contrast, deletion of N-terminal VP5 residues (residues 265 to 279) abolished VP5 binding to membranes. Alanine mutagenesis of two positively charged residues within this domain (residues 274R and 276K) dramatically reduced (>95%) binding of VP5 to membranes and suggested their potential interaction with polar head groups of the lipid bilayer. Mutations in either the VP5 hydrophobic or basic domain blocked VP5-directed permeability of cells. These findings indicate that there are at least two discrete domains within VP5* required for pore formation: an N-terminal basic domain that permits VP5* to peripherally associate with membranes and an internal hydrophobic domain that is essential for altering membrane permeability. These results provide a fundamental understanding of interactions between VP5* and the membrane, which are required for rotavirus entry.     

Effects of human cytochrome b5 on CYP3A4 activity and stability in vivo

Cytochrome P450s (P450) form a superfamily of membrane-bound proteins that play a key role in the primary metabolism of both xenobiotics and endogenous compounds such as drugs and hormones, respectively. To be enzymically active, they require the presence of a second membrane-bound protein, NADPH P450 reductase, which transfers electrons from NADPH to the P450. Because of the diversity of P450 enzymes, much of the work on individual forms has been carried out on purified proteins, in vitro, which requires the use of complex reconstitution mixtures to allow the P450 to associate correctly with the NADPH P450 reductase. There is strong evidence from such reconstitution experiments that, when cytochrome b5 is included, the turnover of some substrates with certain P450s is increased. Here we demonstrate that allowing human P450 reductase, CYP3A4, and cytochrome b5 to associate in an in vivo-like system, by coexpressing all three proteins together in Escherichia coli for the first time, the turnover of both nifedipine and testosterone by CYP3A4 is increased in the presence of cytochrome b5. The turnover of testosterone was increased by 166% in whole cells and by 167% in preparations of bacterial membranes. The coexpression of cytochrome b5 also resulted in the stabilization of the P450 during substrate turnover in whole E. coli, with 109% of spectrally active CYP3A4 remaining in cells after 30 min in the presence of cytochrome b5 compared with 43% of the original P450 remaining in cells in the absence of cytochrome b5.     

Ultrastructural localization of erythrocyte cytoskeletal and integral membrane proteins in Plasmodium falciparum-infected erythrocytes

The distributions of ankyrin, spectrin, band 3, and glycophorin A were examined in Plasmodium falciparum-infected erythrocytes by immunoelectron microscopy to determine whether movement of parasite proteins and membrane vesicles between the parasitophorous vacuole membrane and erythrocyte surface membrane involves internalization of host membrane skeleton proteins. Monospecific rabbit antisera to spectrin, band 3 and ankyrin and a mouse monoclonal antibody to glycophorin A reacted with these erythrocyte proteins in infected and uninfected human erythrocytes by immunoblotting. Cross-reacting malarial proteins were not detected. The rabbit sera also failed to immunoprecipitate [3H]isoleucine labeled malarial proteins from Triton X-100 and sodium dodecyl sulfate (SDS) extracts of infected erythrocytes. These three antibodies as well as the monoclonal antibody to glycophorin A bound to the membrane skeleton of infected and uninfected erythrocytes. The parasitophorous vacuole membrane was devoid of bound antibody, a result indicating that this membrane contains little, if any, of these host membrane proteins. With ring-, trophozoite- and schizont-infected erythrocytes, spectrin, band 3 and glycophorin A were absent from intracellular membranes including Maurer's clefts and other vesicles in the erythrocyte cytoplasm. In contrast, Maurer's clefts were specifically labeled by anti-ankyrin antibody. There was a slight, corresponding decrease in labeling of the membrane skeleton of infected erythrocytes. A second, morphologically distinct population of circular, vesicle-like membranes in the erythrocyte cytoplasm was not labeled with anti-ankyrin antibody. We conclude that membrane movement between the host erythrocyte surface membrane and parasitophorous vacuole membrane involves preferential sorting of ankyrin into a subpopulation of cytoplasmic membranes.     

The carboxy-terminal 10 amino acid residues of cytochrome b5 are necessary for its targeting to the endoplasmic reticulum.

Cytochrome b5 is an integral membrane protein located on the outer surface of the endoplasmic reticulum (ER). This cytochrome is considered to be synthesized on free ribosomes and to be inserted post-translationally into the ER membrane, without participation of a signal recognition particle. To elucidate the signal responsible for targeting of cytochrome b5 to the ER membrane in vivo, DNAs encoding various derivatives of the cytochrome were constructed and introduced into cultured mammalian COS cells, and the subcellular distributions of the derivatives expressed in the cells were then analyzed. The deletion of more than 11 amino acid residues at the carboxy-terminal end of cytochrome b5 abolished the targeting and anchoring of the cytochrome to the ER membrane. Fusion proteins consisting of the carboxy-terminal 10 amino acid residues of cytochrome b5 and passenger proteins with the hydrophobic portion could be localized in the ER membrane. Thus, the last 10 amino acid residues of cytochrome b5 carry information necessary for the cytochrome to be targeted to the ER membrane.     

Association of spectrin with its membrane attachment site restricts lateral mobility of human erythrocyte integral membrane proteins

Interactions between spectrin and the inner surface of the human erythrocyte membrane have been implicated in the control of lateral mobility of the integral membrane proteins. We report here that incubation of “leaky” erythrocytes with a water-soluble proteolytic fragment containing the membrane attachment site for spectrin achieves a selective and controlled dissociation of spectrin from the membrane, and increases the rate of lateral mobility of fluorescein isothiocyanate-labeled integral membrane proteins (> 70% of label in band 3 and PAS-1). Mobility of membrane proteins is measured as an increase in the percentage of uniformly fluorescent cells with time after fusion of fluorescent with nonfluorescent erythrocytes by Sendai virus. The cells are permeable to macromolecules since virus-fused erythrocytes lose most of their hemoglobin. The membrane attachment site for spectrin has been solubilized by limited proteolysis of inside-out erythrocyte vesicles and has been purified (V). Bennett, J Biol Chem 253:2292 (1978). This 72,000-dalton fragment binds to spectrin in solution, competitively inhibits association of ³²P-spectrin with inside-out vesicles with a K_i of 10^?7M, and causes rapid dissociation of ³²P-spectrin from vesicles. Both acid-treated 72,000-dalton fragment and the 45,000 dalton-cytoplasmic portion of band 3, which also was isolated from the proteolytic digest, have no effect on spectrin binding, release, or membrane protein mobility. The enhancement of membrane protein lateral mobility by the same polypeptide that inhibits binding of spectrin to inverted vesicles and displaces spectrin from these vesicles provides direct evidence that the interaction of spectrin with protein components in the membrane restricts the lateral mobility of integral membrane proteins in the erythrocyte.     

Effects of an antimalarial quinazoline derivative on human erythrocytes and on cell membrane molecular models

Plasmodium, the parasite which causes malaria in humans multiplies in the liver and then infects circulating erythrocytes. Thus, the role of the erythrocyte cell membrane in antimalarial drug activity and resistance has key importance. The effects of the antiplasmodial N(6)-(4-methoxybenzyl)quinazoline-2,4,6-triamine (M4), and its inclusion complex (M4/HPβCD) with 2-hydroxypropyl-β-cyclodextrin (HPβCD) on human erythrocytes and on cell membrane molecular models are herein reported. This work evidences that M4/HPβCD interacts with red cells as follows: a) in scanning electron microscopy (SEM) studies on human erythrocytes induced shape changes at a 10μM concentration; b) in isolated unsealed human erythrocyte membranes (IUM) a concentration as low as 1μM induced sharp DPH fluorescence anisotropy decrease whereas increasing concentrations produced a monotonically decrease of DPH fluorescence lifetime at 37°C; c) X-ray diffraction studies showed that 200μM induced a complete structural perturbation of dimyristoylphosphatidylcholine (DMPC) bilayers whereas no significant effects were detected in dimyristoylphosphatidylethanolamine (DMPE) bilayers, classes of lipids present in the outer and inner monolayers of the human erythrocyte membrane, respectively; d) fluorescence spectroscopy data showed that increasing concentrations of the complex interacted with the deep hydrophobic core of DMPC large unilamellar vesicles (LUV) at 18°C. All these experiments are consistent with the insertion of M4/HPβCD in the outer monolayer of the human erythrocyte membrane; thus, it can be considered a promising and novel antimalarial agent.     

Comparison of cytochromes b5 from insects and vertebrates

We report a 1.55 A X-ray crystal structure of the heme-binding domain of cytochrome b(5) from Musca domestica (house fly; HF b(5)), and compare it with previously published structures of the heme-binding domains of bovine microsomal cytochrome b(5) (bMc b(5)) and rat outer mitochondrial membrane cytochrome b(5) (rOM b(5)). The structural comparison was done in the context of amino acid sequences of all known homologues of the proteins under study. We show that insect b(5)s contain an extended hydrophobic patch at the base of the heme binding pocket, similar to the one previously shown to stabilize mammalian OM b(5)s relative to their Mc counterparts. The hydrophobic patch in insects includes a residue with a bulky hydrophobic side chain at position 71 (Met). Replacing Met71 in HF b(5) with Ser, the corresponding residue in all known mammalian Mc b(5)s, is found to substantially destabilize the holoprotein. The destabilization is a consequence of two related factors: (1) a large decrease in apoprotein stability and (2) extension of conformational disruption in the apoprotein beyond the empty heme binding pocket (core 1) and into the heme-independent folding core (core 2). Analogous changes have previously been shown to accompany replacement of Leu71 in rOM b(5) with Ser. That the stabilizing role of Met71 in HF b(5) is manifested primarily in the apo state is highlighted by the fact that its crystallographic Calpha B factor is modestly larger than that of Ser71 in bMc b(5), indicating that it slightly destabilizes local polypeptide conformation when heme is in its binding pocket. Finally, we show that the final unit of secondary structure in the cytochrome b(5) heme-binding domain, a 3(10) helix known as alpha6, differs substantially in length and packing interactions not only for different protein isoforms but also for given isoforms from different species.     

Soluble and membrane-bound forms of cytochrome b5 are the products of a single gene in chicken

In order to determine the relationship of the soluble cytochrome b5 found in erythrocytes to the membrane-bound form found in other tissues, a cDNA clone encoding cytochrome b5 in chicken erythrocytes was isolated by using mixed oligonucleotides based on a partial amino acid sequence of the protein. Complete nucleotide sequence identity between the erythrocyte cDNA and the sequence of a cDNA clone of the liver protein suggests that they are transcribed from the same gene. The isolation and structural analysis of genomic clones was also consistent with the presence of only one cytochrome b5 gene in chicken. These results suggest that the formation of soluble erythrocyte cytochrome b5 occurs by proteolytic processing of the membrane-bound form. Thus, previous reports indicating that the carboxyl terminal amino acid residue of the erythrocyte form differs from the corresponding residue of the membrane-bound form may suggest the existence of a novel post-translational modification.     

Orientation of succinate dehydrogenase and cytochrome b558 in the Bacillus subtilis cytoplasmic membrane.

The orientation of the three subunits of the membrane-bound succinate dehydrogenase (SDH)-cytochrome b558 complex in Bacillus subtilis was studied in protoplasts ("right side out") and isolated membranes (random orientation), using immunoadsorption and surface labeling with [35S]diazobenzenesulfonate. Anti-SDH antibodies were adsorbed by isolated membranes but not by protoplasts. The SDH Mr 65,000 flavoprotein subunit was labeled with [35S]diazobenzenesulfonate in isolated membranes but not in protoplasts. The flavoprotein subunit is thus located on the cytoplasmic side of the membrane. The location of the SDH Mr 28,000 iron-protein subunit was not definitely established, but most probably the iron-protein subunit also is located on the cytoplasmic side of the membrane. Antibodies were not obtained to the hydrophobic cytochrome b558. The cytochrome was strongly labeled with [35S]diazobenzenesulfonate in protoplasts, and labeling was also obtained with isolated membranes. Cytochrome b558 is thus exposed on the outside of the membrane. In B. subtilis SDH binds specifically to cytochrome b558, which suggests that the cytochrome is exposed also on the cytoplasmic side of the membrane. The results obtained suggest that the B. subtilis SDH is exclusively located on the cytoplasmic side of the membrane where it is bound to cytochrome b558, which spans the membrane.