Adenosine 3':5'-monophosphate-regulated phosphoprotein system of neuronal membranes. I. Solubilization, purification, and some properties of an endogenous phosphoprotein.

An endogenous substrate for adenosine 3':5'-monophosphate-dependent protein kinase has been solubilized, and purified about 5,000-fold to apparent homogeneity, from a particulate fraction of bovine cerebral cortex enriched in synaptic membranes. This endogenous substrate, referred to as Protein I, is apparently specific to nervous tissue, and is composed of two types of polypeptides, present in a proportion of 1 (Protein Ia, 86,000 daltons) to 2 (Protein Ib, 80,000 daltons). In the presence of cAMP-dependent Protein I kinase purified from the same membrane fractions, Proteins Ia and Ib incorporated 0.83 and 0.81 mol of phosphate into serine/mol of peptide, respectively. Proteins Ia and Ib have similar amino acid compositions and have isoelectric points of 10.3 and 10.2, respectively. Both types of polypeptide have a relatively high content of glycine and proline, and both are degraded to a peptide of 48,000 daltons by highly purified collagenase, suggesting that Proteins Ia and Ib contain some sequences similar to those observed in collagen. The sedimentation coefficient of Protein Ia and Protein Ib was determined to be 2.9 S. The data suggest that both Protein Ia and Protein Ib have an elongated shape.     

Limited proteolysis of type I collagen at hyperreactive sites by class I and II Clostridium histolyticum collagenases: complementary digestion patterns

The initial proteolytic events in the hydrolysis of rat tendon type I collagen by the class I and II collagenases from Clostridium histolyticum have been investigated at 15 degrees C. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis has been used to detect the initial cleavage fragments of both the alpha 1(I) and alpha 2 chains, which migrate at different rates in the buffer system employed. Experiments with the class I collagenases indicate that the first cleavage occurs across all three chains of the triple helix close to the C-terminus to produce fragments whose alpha chains have molecular weights of approximately 88,000. The second cleavage occurs near the N-terminus to reduce the molecular weight of the alpha chains to 80,000. Initial proteolysis by the class II collagenases occurs across all three chains at a site in the interior of the collagen triple helix to give N- and C-terminal fragments with alpha-chain molecular weights of 35,000 and 62,000, respectively. The C-terminal fragment is subsequently cleaved to give fragments with alpha-chain molecular weights of 59,000. These results indicate that type I collagen is degraded at several hyperreactive sites by these enzymes. Thus, initial proteolysis by these bacterial collagenases occurs at specific sites, much like the mammalian collagenases. These results with the individual clostridial collagenases provide an explanation for earlier data which indicated that collagen is degraded sequentially from the ends by a crude clostridial collagenase preparation.     

Phosphoproteins and the phosphoenolpyruvate: sugar phosphotransferase system in Salmonella typhimurium and Escherichia coli: evidence for IIImannose, IIIfructose, IIIglucitol, and the phosphorylation of enzyme IImannitol and enzyme IIN-acetylglucosamine

Phosphoproteins produced by the incubation of crude extracts of Salmonella typhimurium and Escherichia coli with either [32P]phosphoenolpyruvate or [gamma 32P]ATP have been resolved and detected using sodium dodecyl sulphate polyacrylamide gel electrophoresis and autoradiography. Simple techniques were found such that distinctions could be made between phosphoproteins containing acid-labile or stable phosphoamino acids and between N1-P-histidine and N3-P-histidine. Phosphoproteins were found to be primarily formed from phosphoenolpyruvate, but because of an efficient phosphoexchange, ATP also led to the formation of the major phosphoenolpyruvate-dependent phosphoproteins. These proteins had the following apparent subunit molecular weights: 65,000, 65,000, 62,000, 48,000, 40,000, 33,000, 25,000, 20,000, 14,000, 13,000, 9,000, 8,000. Major ATP-dependent phosphoproteins were detected with apparent subunit molecular weights of 75,000, 46,000, 30,000, and 15,000. Other minor phosphoproteins were detected. The phosphorylation of the 48,000- and 25,000-MW proteins by phosphoenolpyruvate was independent of the phosphoenolpyruvate:sugar phosphotransferase system (PTS). The PTS phosphoproteins were identified as enzyme I (soluble; MW = 65,000); enzyme IIN-acetylglucosamine (membrane bound; MW = 65,000); enzyme IImannitol (membrane bound; MW = 62,000); IIIfructose (soluble; MW = 40,000); IIImannose (partially membrane associated; MW = 33,000); IIIglucose (soluble; MW = 20,000); IIIglucitol (soluble; MW = 13-14,000); HPr (soluble; MW = 9,000); FPr (fructose induced HPr-like protein (soluble; MW = 8,000). HPr and FPr are phosphorylated on the N-1 position of a histidyl residue while all the others appear to be phosphorylated on an N-3 position of a histidyl residue. These studies identify some previously unknown proteins of the PTS and show the phosphorylation of others, which although previously known, had not been shown to be phosphoproteins.     

Interactions of synapsin I with small synaptic vesicles: distinct sites in synapsin I bind to vesicle phospholipids and vesicle proteins

Synapsin I is a major neuron-specific phosphoprotein that is specifically localized to the cytoplasmic surface of small synaptic vesicles. In the present study, the binding of synapsin I to small synaptic vesicles was characterized in detail. The binding of synapsin I was preserved when synaptic vesicles were solubilized and reconstituted in phosphatidylcholine. After separation of the protein and lipid components of synaptic vesicles under nondenaturing conditions, synapsin I bound to both components. The use of hydrophobic labeling procedures allowed the assessment of interactions between phospholipids and synapsin I in intact synaptic vesicles. Hydrophobic photolabeling followed by cysteine-specific cleavage of synapsin I demonstrated that the head domain of synapsin I penetrates into the hydrophobic core of the bilayer. The purified NH2-terminal fragment, derived from the head domain by cysteine-specific cleavage, bound to synaptic vesicles with high affinity confirming the results obtained from hydrophobic photolabeling. Synapsin I binding to synaptic vesicles could be inhibited by the entire molecule or by the combined presence of the NH2-terminal and tail fragments, but not by an excess of either NH2-terminal or tail fragment alone. The purified tail fragment bound with relatively high affinity to synaptic vesicles, though it did not significantly interact with phospholipids. Binding of the tail fragment was competed by holosynapsin I; was greatly decreased by phosphorylation; and was abolished by high ionic strength conditions or protease treatment of synaptic vesicles. The data suggest the existence of two sites of interaction between synapsin I and small synaptic vesicles: binding of the head domain to vesicle phospholipids and of the tail domain to a protein component of the vesicle membrane. The latter interaction is apparently responsible for the salt and phosphorylation dependency of synapsin I binding to small synaptic vesicles.     

Precursor in cotranslational secretion of diphtheria toxin.

By extracellular labeling of peptides of intact Corynebacterium diphtheriae, followed by fractionation of the cells and chain completion by isolated polysomes, it is shown that diphtheria toxin is formed and secreted cotranslationally by membrane-bound polysomes; free polysomes from none. Moreover, when the chains on these polysomes were completed in vitro, in the absence of membrane they were found to include not only diphtheria toxin of a molecular weight of 62,000, but also a larger precursor of a molecular weight of 68,000. The precursor was identified by several properties: immune precipitation; conversion into toxin fragments A and B; adenosine diphosphate ribosyl-transferase activity after activation with trypsin; and cleavage to 62,000 daltons by membrane enzymes. The precursor yields an N-terminal A fragment with a broadened molecular weight distribution, compared with that from authentic toxin, thus supporting the expectation that the extra segment of the precursor is N-terminal.     

Characterization of synapsin I binding to small synaptic vesicles

The binding of synapsin I, a synaptic vesicle-associated phosphoprotein, to small synaptic vesicles has been examined. For this study, synapsin I was purified under nondenaturing conditions from rat brain, using the zwitterionic detergent 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate (CHAPS), and characterized. Small synaptic vesicles were purified from rat neocortex by controlled pore glass chromatography as the last purification step, and binding was characterized at an ionic strength equivalent to 40 mM NaCl. After removal of endogenous synapsin I, exogenous dephospho-synapsin I bound with high affinity (Kd, 10 +/- 6 nM) to synaptic vesicles. The binding saturated at 76 +/- 40 micrograms synapsin I/mg of vesicle protein, which corresponded to the amount found endogenously in purified vesicles. Synapsin I binding exhibited a broad pH optimum around pH 7. Other basic proteins, specifically myelin basic protein and histone H2b, did not compete with synapsin I for binding to vesicles. Other membranes purified from rat brain and membranes derived from human erythrocytes did not show the high affinity binding site for synapsin I found in vesicles. The binding of three different forms of phosphosynapsin I to vesicles was investigated. Synapsin I, phosphorylated at sites 2 and 3 by purified calcium/calmodulin-dependent protein kinase II, bound with a 5-fold lower affinity to the vesicles than did dephospho-synapsin I. In contrast, synapsin I, phosphorylated at site 1 by purified catalytic subunit of cAMP-dependent protein kinase, bound with an affinity close to that of dephospho-synapsin I. Synapsin I phosphorylated on all three sites bound to the vesicles with an affinity comparable to that of synapsin I phosphorylated on sites 2 and 3. Under conditions of higher ionic strength (150 mM NaCl equivalent), synapsin I bound with a 5-fold lower affinity to vesicles, and no effect of phosphorylation on binding was observed under these conditions.     

Purification and characterization of a murine basement membrane collagen-degrading enzyme secreted by metastatic tumor cells

A type IV collagen-degrading enzyme activity secreted by a highly metastatic mouse tumor was purified by concanavalin A- and type IV collagen-agarose affinity chromatographies followed by gel filtration on Bio-Gel A-0.5 m. The apparent molecular weight of the enzyme was 160,000 but about 70,000 when Triton X-100 was added to the column buffer. The purified enzyme protein was resolved on sodium dodecyl sulfate-polyacrylamide gel electrophoresis into two polypeptide chains of about 68,000 and 62,000 daltons. The enzyme activity could be increased by preincubation with trypsin and it is possible that the two chains represent latent and active enzyme forms. The enzyme activity was not reduced in the presence of dithiothreitol, it had a pH optimum of 7.6 and was inhibited by EDTA but not N-ethylmaleimide, phenylmethylsulfonyl fluoride, or Trasylol. The inhibition with EDTA was reversible. The pro-alpha 1(IV) and pro-alpha 2(IV) chains of the type IV procollagen substrate were both degraded at a similar rate to form two pairs of degradation fragments corresponding in molecular weights to about 70 and 30% of the original size chains. The presence of Triton X-100 increased slightly the activity of the enzyme and diminished the reduction of its activity upon freezing, indicating that the enzyme is a hydrophobic protein.     

Identification of protein kinase C and its potential substrate in Entamoeba histolytica

1. Protein kinase C (PKC) activity has been identified in various strains of the human parasite, Entamoeba histolytica. 2. An amoebic protein of mol. wt 78,000 was recognized by polyclonal antibodies raised against the 82,000 mol. wt rat brain protein kinase C. 3. A partially purified PKC preparation from E. histolytica phosphorylated histone I in the presence of calcium, phospholipids and diacylglycerol, and specifically bound tritiated phorbol ester at an apparent KD of 9 nM. 4. A relocalization of the amoebic PKC activity from the cytosol to the membrane fraction was observed when trophozoites were actively phagocytising bacteria. Under these conditions, a labelled phosphoprotein of mol. wt 68,000 was identified. 5. Similar to what was found during macrophage activation, a myristoylated mol. wt 68,000 protein was detected in amoebae grown in the absence of bacteria, but not in amoebae which were active in phagocytosis.     

Native (Na-+ + K-+)-dependent adenosine triphosphatase has two trypsin-sensitive sites.

Sodium and potassium adenosine triphosphatase ((Na + K)-ATPase) consists of two polypeptides, a large molecular weight polypeptide (MW 84,000 to 102,000) and a sialoglycoprotein (MW 35,000 to 57,000). Trypsin treatment of this complex selectively cleaves the large polypeptide into two fragments with molecular weights of 62,000 and 43,000. Simultaneously with the appearance of these fragments, (Na + K)-APTase activity is destroyed. Trypsin treatment of phosphorylated enzyme shows that he 43,000 molecular weight fragment is phosphorylated. If (Na + K)-ATPase is digested with trypsin in the presence of ATP, a 90,000 molecular weight fragment is produced. Disappearance of the large polypeptide, and loss of ATPase activity parallel the production of this fragment. Addition of strophanthidin to this mixture significantly lowers the amount of the 90,000 molecular weight fragment produced. Experiments on (Na + K)-ATPase of the red cell membrane suggest that trypsin is cleaving (Na + K)-ATPase at the interior surface of the plasma membrane.     

Differential phosphorylation of multiple sites in purified protein I by cyclic AMP-dependent and calcium-dependent protein kinases

Protein I, a specific neuronal phosphoprotein, has previously been shown, using rat brain synaptosome preparations, to contain multiple sites of phosphorylation which were differentially regulated by cAMP and calcium. In the present study, Protein I was purified to homogeneity from rat brain and its phosphorylation was investigated using homogeneous cAMP-dependent protein kinase and a partially purified calcium-calmodulin-dependent protein kinase from rat brain. Employing various peptide mapping techniques, a minimum of three phosphorylation sites could be distinguished in Protein I; the phosphorylated amino acid of each site was serine. One phosphorylation site was located in the collagenase-resistant portion of Protein I and was the principal target for phosphorylation by the catalytic subunit of cAMP-dependent protein kinase. This site was also phosphorylated by calcium-calmodulin-dependent protein kinase. The other two phosphorylation sites were located in the collagenase-sensitive portion of Protein I. These latter sites were markedly phosphorylated by calcium-calmodulin-dependent protein kinase, but not by cAMP-dependent protein kinase in concentrations sufficient to phosphorylate maximally the site in the collagenase-resistant portion. Thus, the phosphorylation of purified Protein I by purified cAMP-dependent and calcium-calmodulin-dependent protein kinases provides an enzymological explanation for the regulation of phosphorylation of endogenous Protein I in synaptosome preparations by cAMP and by calcium observed previously. The studies suggest that certain of the synaptic actions of two distinct second messengers, cAMP and calcium, are expressed through the distinct specificities of cAMP- and calcium-dependent protein kinases for the multiple phosphorylation sites in one neuron-specific protein, Protein I.     

Regulation of Synaptotagmin I Phosphorylation by Multiple Protein Kinases

Synaptotagmin I has been suggested to function as a low-affinity calcium sensor for calcium-triggered exocytosis from neurons and neuroendocrine cells. We have studied the phosphorylation of synaptotagmin I by a variety of protein kinases in vitro and in intact preparations. SyntagI, the purified, recombinant, cytoplasmic domain of rat synaptotagmin I, was an effective substrate in vitro for Ca2+/calmodulin-dependent protein kinase II (CaMKII), protein kinase C (PKC), and casein kinase II (caskII). Sequencing of tryptic phosphopeptides from syntagI revealed that CaMKII and PKC phosphorylated the same residue, corresponding to Thr112, whereas caskII phosphorylated two residues, corresponding to Thr125 and Thr128. Endogenous synaptotagmin I was phosphorylated on purified synaptic vesicles by all three kinases. In contrast, no phosphorylation was observed on clathrin-coated vesicles, suggesting that phosphorylation of synaptotagmin I in vivo occurs only at specific stage(s) of the synaptic vesicle life cycle. In rat brain synaptosomes and PC12 cells, K+-evoked depolarization or treatment with phorbol ester caused an increase in the phosphorylation state of synaptotagmin I at Thr112. The results suggest the possibility that the phosphorylation of synaptotagmin I by CaMKII and PKC contributes to the mechanism(s) by which these two kinases regulate neurotransmitter release.     

Purification and properties of GM1 ganglioside beta-galactosidases from bovine brain

Two GM1-beta-galactosidases, beta-galactosidases I, and II, have been highly purified from bovine brain by procedures including acetone and butanol treatments, and chromatographies on Con A-Sepharose, PATG-Sepharose, and Sephadex G-200. beta-Galactosidase I was purified 30,000-fold and beta-galactosidase II 19,000-fold. Both enzymes appeared to be homogeneous, as judged from the results of polyacrylamide disc gel electrophoresis. Enzyme I had a molecular weight of 600,000-700,000 and enzyme II one of 68,000, as determined on gel filtration. On sodium dodecyl sulfate polyacrylamide slab gel electrophoresis under denaturing conditions, enzyme II gave a single band with a molecular weight of 62,000, while enzyme I gave two minor bands with molecular weights of 32,000 and 20,000 in addition to the major band at 62,000. Both enzymes liberated the terminal galactose from GM1 ganglioside and lactosylceramide but not from galactosylceramide. Enzyme I showed a pH optimum of 4.0 and was heat stable, while enzyme II showed a pH optimum of 5.0 and lost 50% of its activity in 15 min at 45 degrees C. Enzyme I showed a pI of 4.2 and enzyme II one of 5.9.     

The localization of the cAMP-dependent protein kinase phosphorylation site in the platelet rat protein, rap 1B

Rap 1B is a low molecular weight G protein which is phosphorylated by cAMP-dependent protein kinase. In order to identify the site of phosphorylation by cAMP-dependent protein kinase, purified rap 1B from human platelets was phosphorylated and subjected to limited proteolysis with trypsin. Single digestion fragment containing the phosphorylation site was obtained and purified by reversed-phase HPLC. Sequence analysis of the phosphorylated digestion fragment demonstrated that the sequence of the phosphorylation site was -Lys-Lys-Ser-Ser-. This sequence is near the carboxy terminus and is adjacent to the site of membrane attachment of the protein.     

Synapsin I is a highly surface-active molecule

Synapsin I is a neuron-specific phosphoprotein localized on the surface of small synaptic vesicles to which it binds with high affinity (Kd = 10 nM). Synapsin I exhibits a tendency to self-associate, suggesting that it might have amphiphilic properties. We have now found that synapsin I forms a stable monolayer at an air-water interface which can be compressed under a lateral force of up to 60 dynes/cm, indicating the presence of amphiphilic characteristics in its structure. This interpretation was also supported by circular dichroism spectra of synapsin I, which showed induction of secondary structure in the presence of trifluoroethanol. The various phosphorylated forms of synapsin I did not show any noticeable differences in the force-area isotherms. The monolayer properties of synapsin I fragments derived by cysteine-specific cleavage indicated the presence of amphiphilic characteristics throughout the entire sequence, although the C-terminal region showed less of such surfactant properties. Compositional studies of these fragments revealed that there is little interaction between the N-terminal and middle fragment regions, but that there may be some interaction between the C-terminal and middle fragment regions which affects the surface area occupied by these fragments. Based on this information, we propose a molecular topology for synapsin I consisting of amphiphilic regions and a hydrophilic region.     

Protein antigens of Theileria parva macroschizonts and immune precipitation studies

The proteins of purified macroschizonts from Theileria parva, T. lawrencei, and T. taurotragi were analyzed by sodium dodecyl sulfate polyacrylamide gel electrophoresis. The major proteins of all species had molecular weights of 120,000, 70,000, 65,000, 62,000, 55,000, 44,000, and 35,000. All further experiments were carried out with T. parva. Using 125I surface labelling it was established that proteins with molecular weights of 70,000, 50,000, and 44,000 were membrane constituents. Staphylococcus aureus protein A-mediated immune precipitation studies with 125I-labelled lysates of macroschizonts and a rabbit anti-macroschizont serum specifically recognized proteins with molecular weights of 120,000, 91,000, 70,000, 62,000, and 35,000. A small proportion of sera recovered from Theileria immune cattle specifically recognized proteins with molecular weights of 180,000 and 70,000 in macroschizont-lysates.     

Disulfide-linked cyanogen bromide peptides of bovine fibrinogen. I. Isolation of peptide F-CB3 and characterization of its single disulfide bond by cleavage with cyanide.

A fragment F-CB3 which originates from the alpha-chain constituent of bovine fibrinogen could be liberated by CNBr cleavage and was purified by molecular sieve and ion-exchange chromatography. This fragment had a molecular weight of 36 000 and consisted of a single polypeptide chain which is folded into a loop by a single disulfide bridge. Further cleavage of F-CB3 by cyanide or by 2-nitro-5-thiocyanobenzoic acid gave rise to three fragments, CN1, CN2 and CN3, with molecular weights of 23 000, 8000 and 7000, respectively. With both reagents the yield of cleavage did not exceed 50%. Radioactive labeling and amino acid analysis of the purified fragments indicated the order CN1-CN2-CN3 in intact F-CB3. A shorter and apparently degraded form of F-CB3 was observed in some fibrinogen preparations. The shortening involved a region of about 3000 daltons at the N-terminal site of F-CB3, i.e. in fragment CN1.     

Electrostatic and hydrophobic interactions of synapsin I and synapsin I fragments with phospholipid bilayers

Synapsin I, a major neuron-specific phosphoprotein, is localized on the cytoplasmic surface of small synaptic vesicles to which it binds with high affinity. It contains a collagenase-resistant head domain and a collagenase-sensitive elongated tail domain. In the present study, the interaction between synapsin I and phospholipid vesicles has been characterized, and the protein domains involved in these interactions have been identified. When lipid vesicles were prepared from cholesterol and phospholipids using a lipid composition similar to that found in native synaptic vesicle membranes (40% phosphatidylcholine, 32% phosphatidylethanolamine, 12% phosphatidylserine, 5% phosphatidylinositol, 10% cholesterol, wt/wt), synapsin I bound with a dissociation constant of 14 nM and a maximal binding capacity of about 160 fmol of synapsin I/microgram of phospholipid. Increasing the ionic strength decreased the affinity without greatly affecting the maximal amount of synapsin I bound. When vesicles containing cholesterol and either phosphatidylcholine or phosphatidylcholine/phosphatidylethanolamine were tested, no significant binding was detected under any conditions examined. On the other hand, phosphatidylcholine vesicles containing either phosphatidylserine or phosphatidylinositol strongly interacted with synapsin I. The amount of synapsin I maximally bound was directly proportional to the percentage of acidic phospholipids present in the lipid bilayer, whereas the Kd value was not affected by varying the phospholipid composition. A study of synapsin I fragments obtained by cysteine-specific cleavage showed that the collagenase-resistant head domain actively bound to phospholipid vesicles; in contrast, the collagenase-sensitive tail domain, though strongly basic, did not significantly interact. Photolabeling of synapsin I was performed with the phosphatidylcholine analogue 1-palmitoyl-2-[11-[4-[3-(trifluoromethyl)diazirinyl]phenyl] [2-3H]undecanoyl]-sn-glycero-3-phosphocholine; this compound generates a highly reactive carbene that selectively interacts with membrane-embedded domains of membrane proteins. Synapsin I was significantly labeled upon photolysis when incubated with lipid vesicles containing acidic phospholipids and trace amounts of the photoactivatable phospholipid. Proteolytic cleavage of photolabeled synapsin I localized the label to the head domain of the molecule.(ABSTRACT TRUNCATED AT 400 WORDS)     

Analysis of the nuclear estrogen receptor from MCF-7 cells by limited proteolysis

The proteolytic fragments of the nuclear estrogen receptor in the MCF-7 cell line were characterized following limited digestion with chymotrypsin and trypsin. Nuclei were isolated from cells previously exposed to 10 nM [3H]estradiol. The proteolytic digestion was performed either on the micrococcal nuclease hydrolysate or on intact nuclei. The molecular weights (Mr) were calculated from the sedimentation coefficients determined on a sucrose gradient and from the Stokes radii estimated by gel filtration. Digestion of the nuclei with micrococcal nuclease solubilized a receptor form of Mr = 151,000. This receptor form was degraded by chymotrypsin to a receptor of Mr = 33,000 and by trypsin to a receptor of Mr = 60,000. Digestion of intact nuclei with chymotrypsin solubilized a receptor form of Mr = 62,000 which dissociated in 0.4 M KCl to a receptor of Mr = 32,000. Digestion of intact nuclei with trypsin followed by micrococcal nuclease solubilized a receptor form of Mr = 75,000 which was further dissociated by 0.4 M KCl to a receptor form of Mr = 60,000. The ability of the receptor forms to bind DNA was tested using DNA-cellulose column chromatography. About 40% of the micrococcal nuclease solubilized receptor form, compared to about 7% of the chymotrypsin degraded receptor and to about 13% of the trypsin degraded receptor forms, all bound to the column and could be eluted by high salt concentrated buffer. We conclude that the nuclear estrogen receptor in the MCF-7 cell line can be partially degraded either in the micrococcal nuclease hydrolysate or in intact nuclei by chymotrypsin or trypsin generating protein moieties, probably receptor fragments of Mr = 33,000 and 60,000 respectively. Both fragments retain their estradiol binding domain and it may be hypothesized that the heavier fragment retains its chromatin binding domain.     

Posttranslational processing of an Epstein-Barr virus-encoded membrane protein expressed in cells transformed by Epstein-Barr virus.

The BamHI Nhet fragment of the B958 strain of Epstein-Barr virus (EBV) encodes a membrane protein (BNLF-1) that is present in cells transformed by EBV. We made a hybrid protein in which a polypeptide sequence from the carboxyl-terminal part of BNLF-1 is fused to Escherichia coli beta-galactosidase. This hybrid protein was used to immunize rabbits, and the resulting antiserum was purified by immunoaffinity chromatography. The antiserum was able to immunoprecipitate BNLF-1 from cell lysates. We found that BNLF-1 is phosphorylated at serines in EBV genome-positive B-cell lines. Pulse-chase analyses with [35S]methionine indicated that BNLF-1 is turned over in lymphoblasts with a half-life of approximately 5 h. Protein immunoblots of EBV genome-positive B-cell lines revealed both a 62,000-molecular-mass band corresponding to BNLF-1 and a myriad of lower-molecular-mass bands. We postulate that these lower-molecular-mass bands are degradation products resulting from the turnover of BNLF-1 in cells. The BNLF-1 gene was expressed in COS cells, and the protein was both phosphorylated and turned over in these cells.     

Purification of the Epstein-Barr virus-determined nuclear antigen from Epstein-Barr virus-transformed human lymphoid cell lines.

The Epstein-Barr virus-determined nuclear antigen (EBNA) was purified from extracts of the human lymphoid cell lines Raji, Namalwa, and B95-8/MLD by two different methods. In the first approach, the apparently native antigen was purified 1,200-fold by a four-step procedure involving DNA-cellulose chromatography, blue dexptran-agarose chromatography, hydroxyapatite chromatography, and gel filtration, employing complement fixation as the assay procedure. Such EBNA preparations specifically inhibited the anticomplement immunofluorescence test for EBNA and bound to methanol/acetic acid-fixed metaphase chromosomes. The purified antigen, which has a molecular weight of 170,000 to 200,000, yielded a single protein band of molecular weight about 48,000 by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. These data indicate that native EBNA has a tetrameric structure. In the second purification method, EBNA-containing cell extracts containing radioactively labeled proteins were incubated with anti-EBNA-positive sera, and antigen-antibody complexes were adsorbed to matrix-bound staphylococcal protein A. The bound proteins were then released with an SDS-containing buffer, and denatured EBNA was separated from antibody chains by SDS-polyacrylamide gel electrophoresis and visualized by fluorography. The denatured EBNA obtained in radiochemically pure form by this procedure has a molecular weight of about 48,000, so both methods yield an EBNA monomer of the same size.