beta-Bungarotoxin. Separation of two discrete proteins with different synaptic actions.

beta-Bungarotoxin, a specific presynaptic blocking agent, was prepared in two stages from the crude venom of Bungarus multicinctus by ion-exchange chromatography on the weakly acidic ion exchanger, CM-Sephadex, and on the strongly acidic ion exchanger, sulphopropyl-Sephadex. By these procedures it was purified to a single protein, which was shown by reduction to contain two polypeptide chains with mol.wts. of less than 15000. During purification of beta-bungarotoxin three other proteins were isolated. Two of these proteins have similar molecular weights, subunit structure and physiological properties to the major protein component. This latter is referred to as beta-bungarotoxin, since it has the same physiological properties as those described for unpurified beta-bungarotoxin by other workers. The first protein has very different physiological effects and biochemical properties from beta-bungarotoxin. This protein has a single class of polypeptide chains with an apparent molecular weight that is lower than the main beta-bungarotoxin protein, and appears to block synaptic transmission by a predominantly postsynaptic effect. It has been suggested [Oberg & Kelly (1976) J. Neurobiol. 7, 129-141] that the action of beta-bungarotoxin depends on its phospholipase A activity; however, in this preparation of the toxin less than 50 muunits of phospholipase A activity were detected (1 unit of activity is the amount of enzyme forming 1 mumol of L-alpha-phosphatidylcholine/min per mg of protein).     

Purification and biochemical characterization of an 11 000-dalton beta-bungarotoxin

The chromatographic separation and biochemical characterization of a beta-bungarotoxin is described. This toxin is isolated as the most basic eluting protein of Bungarus multicinctus venom when separated by column chromatography on CM-Sephadex C-25. The protein migrated as a single band on pH 4.3 and sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. The molecular weight of this toxin was estimated to be 10 000 +/- 1000 by analytical sedimentation analysis. This value was consistent with the electrophoretic mobility of the toxin in SDS-polyacrylamide gels. The amino acid composition of this 11 000-dalton beta-bungarotoxin was similar to that of the 22 000-dalton beta-bungarotoxin previously reported (Lee et al. (1972) J. Chromatogr. 72, 71--82; Kelly, R.B. and Brown, III, F.R. (1974) J. Neurobiol. 5, 135--150; Kondo et al. (1978) J. Biochem. Tokyo 83, 91--99), suggesting that the 11 000-dalton toxin may be one of the polypeptide chains of the larger toxin. The 11 000-dalton beta-bungarotoxin was toxic to mice when injected intravenously. Animals that received lethal doses exhibited hyperexcitability followed by ataxia, convulsions, and death. The minimum lethal dose was 0.12 microgram/g body weight. This beta-bungarotoxin exhibited Ca2+-dependent phospholipase A activity comparable to that of the 22 000-dalton beta-bungarotoxin. The enzyme exhibited phospholipid substrate specificity in the rank order of phosphatidyl-choline, phosphatidylserine, phosphatidylethanolamine, and phosphatidyl-inositol. The enzyme activity was destroyed by boiling for 3 min at pH 8.6. In addition, an enzymatically inactive quantity of the 11 000-dalton toxin, equivalent to five times the minimum lethal dose of enzymatically active toxin, was not lethal when injected into mice. To test whether phospholipase A activity is responsible for lethality, bee venom phospholipase A2 was injected into mice at similar and greater concentrations with no toxic effect. Thus, while phospholipase A activity may be required for the lethal effect of the 11 000-dalton beta-bungarotoxin, the specificity of action of the toxin is not determined by its enzyme activity.     

Separation and purification of a potent bactericidal/permeability-increasing protein and a closely associated phospholipase A2 from rabbit polymorphonuclear leukocytes. Observations on their relationship.

Two antibacterial proteins from rabbit polymorphonuclear leukocytes, a potent bactericidal cationic protein that increases the envelope permeability of susceptible gram-negative bacteria and a phospholipase A2, have been purified to near homogeneity by ion exchange, gel filtration, and hydrophobic interaction chromatography. The apparently noncatalytic bactericidal/permeability-increasing protein has an approximate molecular weight of 50,000 and is isoelectric at pH 9.5 to 10.0. The molecular properties, including amino acid composition, and the antibacterial potency and specificity of this rabbit leukocyte protein and of the bactericidal/permeability-increasing protein from human granulocytes that we have recently purified (J. Biol. Chem. 253, 2664-2672, 1978) are closely similar. Both proteins kill several strains of Escherichia coli and Salmonella typhimurium. Rough strains are more sensitive than smooth strains. All gram-positive bacterial species tested are insensitive to high concentrations of either rabbit or human protein. The phospholipase A2, purified by hydrophobic interaction chromatography on phenyl-Sepharose, ran as a single band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis with an apparent molecular weight of 14,000 and had a specific enzymatic activity comparable to that of purified phospholipases A2 from other sources. Separation of the phospholipase A2 from the bactericidal/permeability-increasing protein has no noticeable effect on the bactericidal and permeability-increasing activities of the purified bactericidal protein, but removes the ability of the phospholipase A2 to hydrolyze the phospholipids of intact Escherichia coli. Upon recombination of the phospholipase A2 with the bactericidal/permeability-increasing protein, the phospholipase A2 regains its activity toward the phospholipids of intact E. coli suggesting that these two antibacterial leukocyte proteins act in concert.     

A proenzyme form of human urokinase

A culture of the human epidermoid carcinoma HEp 3 produces a plasminogen activator of Mr = 53,000 which we have purified to apparent homogeneity from serum-free conditioned medium by the combination of immunoaffinity chromatography and preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The highly purified protein has the following properties: 1) It is indistinguishable from urinary urokinase in electrophoretic mobility, in immunodiffusion, and in autoradiographically visualized tryptic peptide maps obtained from the 125I-labeled proteins. 2) The HEp 3 protein differs from urinary urokinase in the following respects: (a) although the apparent molecular weights of the two are identical (Mr = 53,000), the urinary enzyme consists of two polypeptide chains, whereas the HEp 3 protein is a single chain form. (b) Urinary urokinase can be labeled easily by incubation with radioactive diisopropylfluorophosphate but the HEp 3 protein cannot. (c) When assayed by the hydrolysis of a synthetic chromogenic peptide substrate, the HEp 3 enzyme has less than 1% of the catalytic activity of urinary urokinase. 3) On controlled exposure to plasmin, the HEp 3 protein is converted to an active enzyme that is identical with urinary urokinase in molecular weight, polypeptide chain composition, diisopropylfluorophosphate labeling, and specific catalytic activity. We conclude that the HEp 3 protein is a proenzyme that can be converted to active two-chain urokinase by plasmin, probably by a single proteolytic nick in the polypeptide chain.     

Characterization of an 11,000-dalton beta-bungarotoxin: binding and enzyme activity on rat brain synaptosomal membranes

The binding and phospholipase A2 activity of an 11,000-dalton beta-bungarotoxin, isolated from Bungarus multicincutus venom, have been characterized using rat brain subcellular fractions as substrates. 125I-labeled beta-bungarotoxin binds rapidly (k = 0.14 min-1 and 0.11 min-1), saturably (Vmax = 130.1 +/- 5.0 fmoles/mg and 128.2 +/- 7.1) fmoles/mg), and with high affinity (apparent Kd = 0.8 +/- 0.1 nM and 0.7 +/- 0.1 nM) to rat brain mitochondria and synaptosomal membranes, respectively, but not to myelin. The binding to synaptosomal membranes is inhibited by divalent cations and by pretreatment with trypsin. The binding results suggest that the toxin binds to specific protein receptor sites on presynpatic membranes. The 11,000-dalton toxin rapidly hydrolyzes synaptosomal membrane phospholipids to lysophosphatides and manifests relative substrate specificity in the order phosphatidyl ethanolamine greater than phosphatidyl choline greater than phosphatidyl serine. These results indicate that the 11,000-dalton beta-bungarotoxin is a phospholipase A2 and can use presynaptic membrane phospholipids as substrates. The binding, phospholipase activity and other biological properties of the 11,000-dalton toxin are contrasted with those of the beta-bungarotoxin found in highest concentration in the venom (the 22,000-dalton beta-bungarotoxin), and the two toxins are shown to have qualitatively similar properties. Finally the results are shown to support the hypothesis that beta-bungarotoxins act in a two-step fashion to inhibit transmitter release: first, by binding to a protein receptor site on the presynatic membrane associated with Ca2+ entry, and second, by perturbing through enzymatic hydrolyses the phospholipid matrix of the membrane and thereby causing an increase in passive Ca2+ permeability.     

Purification and properties of a virion protein kinase.

The protein kinase associated with virions of frog virus 3 was purified to apparent homogeneity by ion exchange chromatography and gel filtration. The enzyme protein appeared as a single polypeptide of molecular weight 50,000 to 55,000 as determined by gel filtration, glycerol gradient sedimentation, and sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and comprised approximately 0.4% of the total virion protein. The activity was classified as a cyclic nucleotide-independent protein kinase as it was not effected by cyclic adenosine 3':5'-monophosphate, cyclic guanosine 3':5'-monophosphate, or inhibited by a cyclic nucleotide-dependent protein kinase inhibitor protein, and utilized GTP as well as ATP as a phosphate donor. The greatest rates of phosphorylation were obtained with acidic phosphoprotein substrates such as casein or phosvitin, although potential physiological substrates for this activity included specific virion polypeptides of frog virus.     

Fractionation of two protein kinases from avian myeloblastosis virus and characterization of the protein kinase activity preferring basic phosphoacceptor proteins.

Two protein kinase activities were fractionated from purified virions of avian myeloblastosis virus. Distinguishing characteristics of these two protein kinases included: (i) their binding properties during purification by ion-exchange chromatography; (ii) their estimated molecular weights; and (iii) their phosphoacceptor protein specificities. The protein kinase that bound to the anion exchanger DEAE-cellulose (pH 7.2) had an estimated molecular weight of 60,000 to 64,000 and preferred basic phosphoacceptor proteins. The protein kinase that bound to the cation exchanger phosphocellulose (pH 7.2) had an estimated molecular weight of 42,000 to 46,000 and preferred acidic phosphoacceptor proteins. The protein kinase preferring basic phosphoacceptor proteins was further purified and characterized. Optimal transfer of phosphate catalyzed by this enzyme required a divalent metal ion, a sulfhydryl-reducing agent, and ATP as phosphate donor. GTP was not an effective phosphate donor at concentrations comparable to ATP; and the cyclic nucleotides cyclic AMP and cyclic GMP neither stimulated nor inhibited protein phosphorylation by the protein kinase. The specificity of the protein kinase for basic phosphoacceptor proteins extended to proteins from avian myeloblastosis virus, in that the neutral to basic virion proteins p12, p19, and p27 served as phosphate acceptors. In addition, the protein kinase also appeared to phosphorylate itself. The role(s) of this virion-associated protein kinase is discussed.     

Ribosomal proteins of pea seeds behaving like anions at pH 8.6]

A group of proteins migrating to the anode at pH 8.6 under polyacrylamide gel electrophoresis was revealed in the total protein of non-dissociated KCl-washed pea seed ribosomes. No proteins with an isoelectric point below pH 4.2 Were found. The presence of acidic proteins in 80 S ribosomes is due to the presence of a specific set of relatively acidic proteins in the total protein of large (5 major and 10 minor components) and small (2 major and 4 minor components) subunits. The mostly acidic proteins are located in the large subunit. The acidic proteins of 60S and 40S subunits are represented by the polypeptide chains with molecular weights from 48 000 to 13 000. The acidic proteins are present in the ribosomes studied in considerably less number than the basic proteins, and the former produce a very weak staining under electrophoretic analysis as compared with the latter. The data obtained suggest that 80S ribosomes of higher plants differ from animal ribosomes by a higher content of relatively acidic proteins.     

Characterization of monoclonal antibodies against beta-bungarotoxin and their use as structural probes for related phospholipase A2 enzymes and presynaptic phospholipase neurotoxins

Hybridoma lines secreting monoclonal antibodies against a phospholipase-inactive derivative of the presynaptic neurotoxin, beta-bungarotoxin, have been established. These antibodies, either of the IgG1 or IgG2b isotype with affinities in the range 1-2 X 10(8) 1/mol, recognized a single immunodominant region of native beta-bungarotoxin, most probably located on the A (phospholipase homologue) chain of the toxin. Using plate-adsorbed radioimmunoassay procedures, antibodies reacted with native beta-bungarotoxin and other beta-bungarotoxin isotoxins as well as with the non-toxic phospholipase A also present in Bungarus multicinctus venom. Other phospholipase A enzymes and presynaptic phospholipase neurotoxins did not show any competition with beta-bungarotoxin in the radioimmunoassay. Globulin fractions of monoclonal antibodies partially inhibited the phospholipase activity of beta-bungarotoxin.     

Selective extraction of desmosomal proteins by low ionic strength media.

Desmosomes, isolated using an acidic buffer, have been subjected to extraction at low ionic strength. This treatment removes more than 35% of their protein in the form of two polypeptide chains of molecular weight 210 000 and 230 000, but the desmosomes show only subtle changes in ultrastructure. It is concluded that the use of low ionic strength media for desmosome isolation yields residual structures specifically depleted in high molecular weight proteins.     

Bioenergetic actions of beta-bungarotoxin, dendrotoxin and bee-venom phospholipase A2 on guinea-pig synaptosomes.

Low concentrations of beta-bungarotoxin or bee-venom phospholipase A2 cause a progressive Ca2+-dependent increase in the proton permeability of the mitochondria within the synaptosomal cytosol, manifested as an increase in oligomycin-insensitive respiration and a partial depolarization of the mitochondrial membrane potential. This uncoupling appears to be a consequence of fatty acids liberated by phospholipase A2 activity at the plasma membrane, since it can be mimicked by the addition of oleate-albumin complexes, in which case there is no requirement for external Ca2+. Dendrotoxin does not affect the mitochondrial proton permeability in situ, but protects partially against the uncoupling action of beta-bungarotoxin. In contrast, this effect of bee-venom phospholipase A2 is unaffected by dendrotoxin. beta-Bungarotoxin, but not bee-venom phospholipase A2, induces a slow progressive depolarization of the plasma membrane. The action of beta-bungarotoxin at the plasma membrane appears not to be related to fatty acid production, since it is augmented rather than inhibited by raising albumin concentrations in the medium. It is concluded that beta-bungarotoxin has at least two actions on intact synaptosomes, both of which may involve interaction at the plasma membrane with a site common to dendrotoxin: first, a mitochondrial uncoupling mediated by fatty acids and, secondly, a depolarization at the plasma membrane.     

Antibodies to beta-bungarotoxin and its phospholipase inactive derivative

Antisera were raised against the presynaptic neurotoxin beta-bungarotoxin and against its phospholipase-inactive derivative, modified by reaction with p-bromophenacyl bromide. The cross-reactivity of the antisera to other phospholipase A2 enzymes and polypeptide neurotoxins was examined. The antisera inhibited both the neurotoxic effects of beta-bungarotoxin at the frog motor endplate and the enzymatic activity of the toxin on model phospholipid membranes, although it is unlikely that the catalytic active centre is the locus of any major determinant.     

The interaction between the presynaptic phospholipase neurotoxins beta-bungarotoxin and crotoxin and mixed detergent-phosphatidylcholine micelles. A comparison with non-neurotoxic snake venom phospholipases A2

Certain phospholipase A2 enzymes (E.C.3.1.1.4) selectively inhibit neurotransmitter release from cholinergic nerve terminals. Both specific acceptor proteins and the physical state of nerve terminal phospholipids have been implicated in studies of the mechanism of phospholipase neurotoxin action. Here we have examined the effects of charge on a micellar phospholipid substrate by comparing the enzyme activity and binding of two neurotoxic phospholipases (beta-bungarotoxin and crotoxin) with other non-neurotoxic phospholipases. This has been achieved by altering either the phospholipid or the ionic charge of the detergent in the mixed phospholipid micelle. The neurotoxic phospholipases were only active on negatively charged micelles, whereas the non-neurotoxic enzymes were equally active in hydrolyzing neutral micelles. This distinction was also reflected in binding studies; the non-neurotoxic phospholipases bound to both types of substrate, whereas beta-bungarotoxin and crotoxin selectively bound to negatively charged micellar structures. These experiments suggest that, in addition to the existence of any specific acceptor proteins, neurotoxin binding is also governed by the charge on the lipid phase of the nerve terminal membrane.     

Cytoplasmic DNA-binding phosphoproteins of Physarum polycephalum.

The cytoplasmic DNA-binding proteins of Physarum polycephalum were recovered by chromatography of cytosol extracts on sequential columns of native and denatured calf thymus DNA-cellulose. 5.4% of the total cytosol protein was bound to native DNA-cellulose, while 4.4% was bound to denatured DNA-cellulose. Stepwise salt gradient elution of the columns separated the DNA-binding proteins into 9 fractions which were analysed by acrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. Several hundred discrete polypeptide bands were identified, with many more high molecular weight polypeptides (greater than 100 000 D) binding to native than to denatured DNA. Continuous in vivo labelling of microplasmodia in KH₂[³²P]O₄ and [³H]leucine was used to determine which of the DNA-binding proteins were phosphorylated, and to approximate their phosphorus content. About 30–40 phosphoproteins were resolved among the DNA-binding proteins. Most phosphoproteins contained less than 3 phosphates per polypeptide, but a small number of low molecular weight phosphoproteins (less than 50 000 D) contained from 5 to 10 phosphates per polypeptide. The majority of high molecular weight DNA-binding phosphoproteins bound to native DNA and were eluted with 0.25 M NaCl. As a group, the DNA-binding proteins were enriched in protein-bound phosphorus when compared with the cytosol proteins which did not bind to DNA. The phosphorus content of the cytoplasmic DNA-binding proteins was similar to that of the acidic nuclear proteins.     

Purification and properties of Paracoccus denitrificans azurin

The isolation of an azurin type Cu protein from Paracoccus denitrificans (ATCC 13543) is described and some properties are reported. The purified protein has a molecular weight of 13,790 in a single polypeptide chain and contains one Cu atom per molecule. Its spectrum is typical of Type I, “blue” Cu proteins in showing an intense band at 595 nm; but it also shows a weaker absorption band at 448 nm. Its standard reduction potential has been measured to be +230 mV, which is the lowest potential observed to date for azurins isolated from bacterial sources. The purified protein shows fivefold greater electron transport activity with membrane fragments than with the soluble nitrite reductase of Paracoccus. This argues against the latter as the primary physiological oxidase system for azurin.     

Purification and properties of a phosphorylase (phosphoprotein) phosphatase associated with an alkaline phosphatase of Mr 35000 from bovine adrenal cortex.

A metal-ion-independent, nonspecific phosphoprotein phosphatase (Mr = 35000) which represents the major phosphorylase phosphatase activity in bovine adrenal cortex has been purified to apparent homogeneity. An alkaline phosphatase activity (p-nitrophenyl phosphate as a substrate) of the same molecular weight, which requires both a metal ion (Mg2+ greater than Mn2+ greater than Co2+) and a sulfhydryl compound for activity, has been found to co-purify with the phosphoprotein phosphatase throughout the purification procedures. Characterization of the phosphoprotein and the alkaline phosphatase activities with respect to their catalytic properties, substrate and metal ion specificities, relationship with large molecular forms of the enzymes and responses to various effectors has been carried out. The results indicate that the phosphoprotein phosphatase can be converted by pyrophosphoryl compounds (e.g. PPi and ATP) to a metal-ion-dependent form which, subsequently, can be reactivated by Co2+ greater than Mn2+ but not by Mg2+ or Zn2+. The results also indicate that, although the phosphoprotein and the alkaline phosphatase activities are closely associated, they exhibit distinct physical and catalytic properties. Discussions concerning whether these two activities represent two different forms of the same protein or two different yet very similar polypeptide chains have been presented.     

Vitelline coat of Unio elongatulus: II. Biochemical properties of the 220- and 180-kD components

In a previous study we found that two glycoproteins with apparent molecular weights of 220 kD and 180 kD account for 80–90% of the material dissolved from the vitelline coat of the egg of the bivalve mollusk, Unio elongatulus (Focarelli and Rosati, 1993: Mol Reprod Dev 35:44–51). In this study we isolated and purified these glycoproteins by electroelution. The two proteins differ in many respects: the 180-kD molecule is acidic in nature and highly heterogeneous, whereas the 220-kD protein is neutral and less heterogeneous. Both seem to have O- and N-linked oligosaccharide chains. The 180-kD protein contains 13–16% carbohydrate, whereas the 220-kD molecular contains only 7–8%. Amino acid analysis and peptide mapping also show that each protein represents a unique polypeptide chain. © 1995 Wiley-Liss, Inc.     

The subunit structure of thymus leukemia antigens.

EDTA-containing buffer solubilizes thymus leukemia antigens (TLa) from crude thymocyte membrane fractions. The TL antigens consist mainly of molecules of a size similar to immunoglobulin G when gel chromatography analyses were performed under physiological conditions. A single component of TLa was apparent on sucrose density gradient ultracentrifugation of solubilized thymocyte membrane macromolecules as monitored by indirect immunoprecipitation. The sedimentation constant for the TL antigens (5.8 S) was considerably less than that for immunoglobulin G. The gel chromatography and ultracentrifugation data suggest an apparent molecular weight for TLa of about 120000. TLa isolated by indirect immunoprecipitation is composed of two types of polypeptide chains. The smaller subunit was identified as beta2-microglobulin. The larger polypeptide chain carried the alloantigenic determinants and displayed a molecular weight of about 50000 after reduction and alkylation. TLa subjected to molecular weight determination under denaturing conditions was composed of two components. The smaller component was beta2-microglobulin which evidently is linked to the larger polypeptide chain by noncovalent interactions only. The larger component had a size greater than reduced and alkylated immunoglobulin G heavy chains. Upon reduction and alkylation of the latter component its size was reduced and it appeared to have a molecular weight of about 50000. Consequently, TLa is composed of two disulfide linked heavy polypeptide chains and two beta2-microglobulin molecules. TLa solubilized by papain digestion comprises two polypeptide chains, one of which is beta2-microglobulin. The larger 37000-dalton subunit is a fragment of the heavy polypeptide chain. This was demonstrated by digesting solubilized 120000-dalton TLa with papain. The proteolytic fragments obtained were indistinguishable from those directly released from the cell surface by proteolysis. The papain-derived TLa fragment exhibited most if not all the alloantigenic determinants.     

Structural analysis of bovine pancreatic thread protein

Pancreatic thread protein (PTP) forms double helical threads in the neutralpH range after purification, undergoing freely reversible,pH-dependent globule-fibril transformation. The purified bovine PTP consists on SDS gels of two carbohydrate-free polypeptide chains (Grosset al., 1985). Plasma desorption mass spectrometry and amino acid sequence analysis now confirm that bovine PTP contains two disulfide-bonded polypeptides, an A chain of 101 amino acid residues with a molecular weight of 11,073 and a B chain of 35 residues with a molecular weight of 3970. The intact protein exhibits a molecular weight of 15,036, agreeing >99.9% with the molecular weight calculated from the sequence. The B chain sequence was determined by gas-phase Edman degradation of the intact polypeptide. The A chain sequence was determined from overlapping peptides generated by cleavage at lysyl, tryptophanyl, and aspartyl-prolyl residues. Based upon the bovine PTP cDNA structure, the two chains of the protein result from cleavage of a single polypeptide with removal of a dipeptide between the NH₂-terminal A chain and COOH-terminal B chain. Comparison of bovine PTP with other proteins reveals significant structural relatedness with the single-chain homologues from human and rat pancreas and with the motif associated with Ca²⁺-dependent carbohydrate recognition domains. The physiological role of PTP has not yet been resolved. The protein is present in very high concentration in pancreatic secretion and it has been detected in brain lesions in Alzheimer's disease and Down syndrome and in regenerating rat pancreatic islets. The present results provide a firm protein base for ongoing molecular, physical-chemical, and structure-function studies of this unusual protein.