THE MECHANISM OF ACTION OF COLCHICINE : Colchicine Binding to Sea Urchin Eggs and the Mitotic Apparatus

Colchicine forms a complex in vivo with a protein present in fertilized or unfertilized sea urchin eggs; similar binding was obtained in vitro with the soluble fraction from egg homogenates. Kinetic parameters and binding equilibrium constant were essentially the same in vivo and in vitro. The binding site protein was shown to have a sedimentation constant of 6S by zone centrifugation. The protein was present in extracts of the isolated mitotic apparatus at a concentration which was several times higher than in whole-egg homogenates. It was extracted from the mitotic apparatus at low ionic strength under conditions which lead to the disappearance of microtubules. No binding could be detected to the 27S protein, previously described by Kane, which is a major protein component of the isolated mitotic apparatus. The properties of the colchicine-bindinG protein, (binding constant, sedimentation constant, Sephadex elution volume) are similar to those obtained with the protein from mammalian cells, sea-urchin sperm tails, and brain tissue, and thus support the conclusion that the protein is a subunit of microtubules.     

A cellular 3,3',5-triiodo-L-thyronine binding protein from a human carcinoma cell line. Purification and characterization

A cellular binding protein for 3,3',5-triiodo-L-thyronine (T3) was solubilized with 3-[(3-cholamidopropyl) dimethylammonio]-1-propanesulfonate (CHAPS) from A431 human epidermoid carcinoma cells. The binding activity is T3 specific. Analysis of the equilibrium binding data indicated that the binding protein has one class of binding sites for T3 with a Kd of (17 +/- 3) nM and Bmax of (1.8 +/- 0.6) pmol/50 micrograms of protein. The pH optimum for binding is 6.8. The T3 binding protein elutes from Sephadex G-200 in an included peak which has a Stokes radius of 40 A and sediments on glycerol gradients at 3.7 S. By affinity labeling with [3,5-125I]thyroxine a protein with a molecular weight of 58,000 was specifically labeled. Its isoelectric point was determined to be 7.1, which is different from the reported pIs of other thyroid hormone binding proteins. p58 was successively purified to apparent homogeneity by chromatography on Sephadex G-200, QAE-Sephadex, SP-Sephadex, and hydroxylapatite. Approximately 50 micrograms of purified protein was obtained from 2.5 X 10(9) cells with a yield of 1.1%. The purified protein retains its binding activity. The specific binding activity is enriched by approximately 1000-fold. With the availability of a purified protein with T3 binding activity, it becomes possible to study its cellular function.     

Actin affinity chromatography in the purification of human, avian and other mammalian plasma proteins binding vitamin D and its metabolites (Gc globulins).

The human plasma protein binding vitamin D and its metabolites (Gc globulin; group-specific component) has been isolated from human plasma by column affinity chromatography on gels to which monomeric actin was covalently attached. Rabbit skeletal-muscle G-actin was covalently coupled to amino-agarose gels before the application of human plasma. At actin/protein molar ratios of 4-8:1, excellent recovery (approximately 58%) of purified binding protein was achieved. After 0.75 M-NaCl washes, the binding protein was eluted from the columns in 3 M-guanidinium chloride, dialysed and analysed. These eluates contained the binding protein as 34-100% of the total protein, reflecting a 130-fold average purification in this single step. In the presence of Ca2+, gelsolin (another plasma protein that binds actin) was apparently retained by the affinity column, but this was prevented by chelation of plasma Ca2+. The actin affinity step also was effective in the isolation of the binding protein from rat, rabbit and chicken plasma, as indicated by autoradiographs of purified fractions analysed by gel electrophoresis after incubation with 25-hydroxy[26,27-3H]cholecalciferol. Further isolation by hydroxyapatite chromatography yielded a purified binding protein which displayed characteristic binding activity toward vitamin D metabolites and G-actin, and retained its physicochemical features. This brief purification sequence is relatively simple and efficient, and should prove to be useful to investigators studying this interesting plasma protein.     

Differential binding of folates by rat renal cortex brush border and basolateral membrane preparations

The binding of radioactive 5-methyltetrahydrofolate and folic acid was found to be greater in brush border than in basolateral membrane preparations of rat renal cortex. This appeared to be due to an increased amount of a specific folate binding protein in the brush border membrane preparations as compared to those of the basolateral membrane. The binding was saturable and inhibited by nonradioactive folic acid and, therefore, a specific, rather than nonspecific process. The Km's for folic acid binding in brush border and basolateral membrane preparations were similar and involved a single high-affinity binding site. In contrast, methotrexate was found to bind equally well to both brush border and basolateral membrane preparations. Moreover, folic acid binding was not inhibited by an equimolar amount of methotrexate. A folate binding protein could be extracted from either membrane preparation with 1% Triton X-100 and, to a lesser extent, with 0.6 M NaCl. These different extraction procedures resulted in different apparent molecular weights for folate binding protein (greater than 160,000 for Triton X-100-extracted samples and 40,000 for NaCl-extracted samples). The membrane preparation pellets remaining after NaCl extraction were able to rebind tritiated folic acid and also the 40,000-Da folate binding protein. On the other hand, membrane preparations extracted with Triton X-100 lost the ability to bind folic acid or the 40,000-Da folate binding protein. These differences in molecular weight and rebinding capacity may be explained by the existence of a receptor for folate binding protein which was extracted by Triton X-100, but not by NaCl. The greater concentration of folate binding protein in the renal tubule cell brush border membrane preparations as compared to those from basolateral membranes ascribes, for the first time, a functional role for folate binding protein in the renal reabsorption of folates which is required to prevent loss of folate in the urine and perhaps in the membrane transport of folates in general.     

Generation of epitope-specific antibodies to rat GHBP in the sheep using an interspecies switching strategy involving site-directed mutagenesis of ovine GHBP.

Site-directed antibodies to the growth hormone receptor could be potentially useful as growth hormone mimics but, in previous attempts, we found that antisera generated using peptides derived from growth hormone receptor sequences failed to recognize the intact protein. As an alternative approach to this problem, we have now adopted a strategy of epitope-switching between rat and ovine growth hormone receptors to produce rat epitopes in the correct structural context. Using site-directed mutagenesis, we altered the two dominant linear epitopes in the ovine growth hormone binding protein to the analogous sequences in rat growth hormone binding protein. Site A, between Thr28 and Leu34, is equivalent to epitope 1 in ovine growth hormone binding protein and site B, between Ser121 and Asp124, corresponds to epitope 5. The wild-type ovine growth hormone binding protein and the two mutant proteins were bacterially expressed, refolded and, following purification by metal-chelate affinity chromatography, used to raise antisera in sheep. We showed using RIA, in which wild-type ovine growth hormone binding protein acted as a competitor for the binding of rat growth hormone binding protein, that only the site A mutant protein elicited a specific anti-rat growth hormone binding protein response. This was confirmed in subsequent RIA studies using the antiserum to the site A mutant protein in which only peptides corresponding to the site A sequences in mutant ovine growth hormone binding protein and rat growth hormone binding protein, but not that in wild-type ovine growth hormone binding protein, were able to act as competitors for rat growth hormone binding protein. Antibodies specific for rat growth hormone binding protein could be separated from the antiserum to the site A mutant protein by means of affinity chromatography using immobilized wild-type ovine growth hormone binding protein to remove antibodies which cross-reacted with the ovine protein. The work lays the foundations for further studies in which the biological effects of these antibody fractions will be investigated and demonstrates an approach with general applicability in the production of antibodies directed towards specific epitopes on protein molecules.     

Characterization and identification of the hyaluronate binding site from membranes of SV-3T3 cells

Previous research has shown that binding sites for hyaluronate are present on the surfaces of a number of different cell types. To further characterize these binding sites, membranes were prepared from SV-3T3 cells and dissolved in a solution of sodium deoxycholate. Hyaluronate binding activity was detected by mixing the sodium deoxycholate extract with [3H]hyaluronate and then adding an equal volume of saturated (NH4)2SO4, which precipitated the binding protein and any [3H]hyaluronate associated with it, but left free [3H]hyaluronate in solution. Following partial purification by hydroxylapatite chromatography, the binding site was examined by molecular sieve chromatography and by rate-zonal centrifugation, which revealed that it has a Stokes radius of 6.5 nm and a sedimentation coefficient of 4.8 S. From these values, it was possible to calculate that the sodium deoxycholate-solubilized binding site has a frictional coefficient of 1.87 and a molecular weight of 132,000. Since this latter value applies to the complex of both detergent and protein, the binding protein by itself must have a molecular weight lower than 132,000. To determine the molecular weight of the hyaluronate binding site itself, the protein was purified by the sequential application of hydroxylapatite chromatography, molecular sieve chromatography, rate-zonal centrifugation, and finally lectin-affinity chromatography on concanavalin A-agarose. Analysis of the purified material by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed an 85,000 Mr protein which has been identified as the binding site. This protein was also detected on nitrocellulose blots which had been specifically stained for concanavalin A binding material, suggesting that the binding site is a glycoprotein.     

The solution behavior of the bovine myelin basic protein in the presence of anionic ligands. Binding behavior with the red component of trypan blue and sodium dodecyl sulfate.

The interaction of the azo dye (2,3'-dimethyldiphenyl-7-azo-8-amino-1-napthol 3,6-disulfonic acid (TBR) and sodium dodecyl sulfate with the bovine myelin basic protein has been studied using absorbance, circular dichroism and 220 MHz PMR spectroscopy. Additional analyses of the binding reaction were carried out using light scattering, ultracentrifugal and electrophoretic techniques. A procedure for preparing pure TBR was developed. A modified structure for this synthesized TBR has been suggested. The mechanism of TBR binding to the myelin basic protein was found to be metachromatic. In addition, the interaction of TBR with the basic protein which gives rise to aggregation of the dye bound species was found to be analogous to the model proposed by Schwarz, G. and Seelig-L?ffler, A. ((1975) Biochim. Biophys. Acta 379, 125-138) to explain the binding of acridine orange with poly (alpha-L-glutamic acid). PMR spectral analyses suggested that arginine residues provide the majority of primary sites of attachment on the basic protein for TBR. The effect of sodium dodecyl sulfate binding with the bovine myelin basic protein was found to induce a minimal change in the conformation of the protein. The induction of only about 20% alpha helial structure could be demonstrated and the binding was reversed by raising the solution temperature to 73 degrees C. The difference in the observed behavior of basic protein arising from TBR binding as opposed to the binding of sodium dodecyl sulfate is viewed as resulting from two different binding mechanisms. The binding behavior of TBR is primarily a consequence of charge-charge interaction while the binding effects of sodium dodecyl sulfate are a consequence of hydrophobic interaction. The sodium dodecyl sulfate binding acts as a shield which limits charge-charge interaction in the basic protein molecule thus preventing aggregate formation while TBR imposes no such restraints.     

Ligand binding characteristics of two molecular forms,one equipped with a hydrophobic glycosyl phosphatidylinositol tail,of the folate binding protein purified from human milk

Two molecular forms of the folate binding protein were isolated and purified from human milk by a combination of cation exchange- and affinity chromatography. One protein (27 kDa) was a cleavage product of the other 100 kDa protein as evidenced by N-terminal amino acid sequence homology and a reduction in the molecular size of the latter protein to 27 kDa after cleavage of its hydrophobic glycosylphosphatidylinositol tail by phosphatidylinositol-specific phospholipase C. High-affinity binding of [³H]folate was characterized by upward convex Scatchard plots and increasing ligand binding affinity with decreasing concentrations of both proteins. Downward convex Scatchard plots and binding affinities showing no dependence on the protein concentration were, however, observed in highly diluted solutions of both proteins. Radioligand binding was inhibited by folate analogs, and dissociation of radioligand was slow at pH 7.4 but rapid and complete at pH 5.0 and 3.5. Ligand binding quenched the tryptophan fluorescence of the 27 kDa protein suggesting that tryptophan is present at the binding site and/or ligand binding induces a conformation change that affects tryptophan environment in the protein. The 27 kDa protein representing soluble folate binding protein exhibited a greater affinity for ligand binding than the 100 kDa protein which possesses a hydrophobic tail identical to the one that anchors the folate receptor to the cell membrane.     

鼠伤寒沙门氏菌c-di-GMP结合蛋白YcgR的表达、纯化及活性鉴定

【背景】在鼠伤寒沙门氏菌中,c-di-GMP结合蛋白YcgR通过与鞭毛运动蛋白的相互作用,抑制鞭毛运动速度,使细菌由浮游生长向生物膜产生及侵染宿主的静止状态转变。然而,目前关于该蛋白的结构、功能以及与c-di-GMP结合后调控细菌运动状态的分子机制还不清楚。【目的】通过原核表达,获得高纯度的YcgR蛋白,并对其二级结构稳定性以及c-di-GMP结合活性进行表征,为进一步确定YcgR的结构以及阐明c-di-GMP如何通过结合YcgR而减缓细菌运动速度的分子机制奠定基础。【方法】通过构建重组大肠肝菌对YcgR进行原核表达;通过Ni-NTA镍离子亲和层析柱和体积排阻色谱两步纯化获得高纯度的YcgR蛋白;预测YcgR蛋白质结构,利用圆二色光谱仪(CD)测定其二级结构;通过等温滴定量热法(ITC)和热转移技术(Protein thermal shift)研究YcgR与c-di-GMP的结合活性。【结果】菌落PCR和质粒测序结果表明,表达YcgR的重组大肠杆菌构建成功;SDS-PAGE和体积排阻色谱显示YcgR的分子量大约为28 kD,在溶液中以二聚体的形式存在;通过预测和对比,发现YcgR的结构与同源蛋白PP4396高度相似,都有一个响应c-di-GMP的PilZ结构域,且CD结果显示YcgR具有稳定的二级结构;ITC和Thermal Shift结果表明,YcgR与c-di-GMP有较强的结合活性,其Kd值为50 nmol/L。【结论】首次实现了鼠伤寒沙门氏菌YcgR蛋白的原核表达及纯化,表征了其c-di-GMP结合活性,为进一步研究YcgR蛋白与细菌信号分子c-di-GMP调控鞭毛运动的分子机制奠定基础,并为鼠伤寒沙门氏菌抗感染药物的研发和治疗提供新的策略。     

Binding of [3H]forskolin to solubilized preparations of adenylate cyclase

The binding of [3H]forskolin to proteins solubilized from bovine brain membranes was studied by precipitating proteins with polyethylene glycol and separating [3H]forskolin bound to protein from free [3H]forskolin by rapid filtration. The Kd for [3H]forskolin binding to solubilized proteins was 14 nM which was similar to that for [3H]forskolin binding sites in membranes from rat brain and human platelets. Forskolin analogs competed for [3H]forskolin binding sites with the same rank potency in both brain membranes and in proteins solubilized from brain membranes. [3H]forskolin bound to proteins solubilized from membranes with a Bmax of 38 fmol/mg protein which increased to 94 fmol/mg protein when GppNHp was included in the binding assay. In contrast, GppNHp had no effect on [3H]forskolin binding to proteins solubilized from membranes preactivated with GppNHp. Solubilized adenylate cyclase from non-preactivated membranes had a basal activity of 130 pmol/mg/min which was increased 7-fold by GppNHp. In contrast, adenylate cyclase from preactivated membranes had a basal activity of 850 pmol/mg/min which was not stimulated by GppNHp or forskolin. Thus, the number of high affinity binding sites for [3H]forskolin in solubilized preparations correlated with the activation of adenylate cyclase by GppNHp via the guanine nucleotide binding protein (GS).     

Characterization of the DNA binding protein encoded by the N-specific filamentous Escherichia coli phage IKe. Binding properties of the protein and nucleotide sequence of the gene

A DNA binding protein encoded by the filamentous single-stranded DNA phage IKe has been isolated from IKe-infected Escherichia coli cells. Fluorescence and in vitro binding studies have shown that the protein binds co-operatively and with a high specificity to single-stranded but not to double-stranded DNA. From titration of the protein to poly(dA) it has been calculated that approximately four bases of the DNA are covered by one monomer of protein. These binding characteristics closely resemble those of gene V protein encoded by the F-specific filamentous phages M13 and fd. The nucleotide sequence of the gene specifying the IKe DNA binding protein has been established. When compared to the nucleotide sequence of gene V of phage M13 it shows an homology of 58%, indicating that these two phages are evolutionarily related. The IKe DNA binding protein is 88 amino acids long which is one amino acid residue larger than the gene V protein sequence. When the IKe DNA binding protein sequence is compared with that of gene V protein it was found that 39 amino acid residues have identical positions in both proteins. The positions of all five tyrosine residues, a number of which are known to be involved in DNA binding, are conserved. Secondary structure predictions indicate that the two proteins contain similar structural domains. It is proposed that the tyrosine residues which are involved in DNA binding are the ones in or next to a beta-turn, at positions 26, 41 and 56 in gene V protein and at positions 27, 42 and 57 in the IKe DNA binding protein.     

Binding of acyl-CoA to liver fatty acid binding protein: effect on acyl-CoA synthesis

The ability of purified rat liver and heart fatty acid binding proteins to bind oleoyl-CoA and modulate acyl-CoA synthesis by microsomal membranes was investigated. Using binding assays employing either Lipidex 1000 or multilamellar liposomes to sequester unbound ligand, rat liver but not rat heart fatty acid binding protein was shown to bind radiolabeled acyl CoA. Binding studies suggest that liver fatty acid binding protein has a single binding site acyl-CoA which is separate from the two binding sites for fatty acids. Experiments were then performed to determine how binding may influence acyl-CoA metabolism by liver microsomes or heart sarcoplasmic reticulum. Using liposomes as fatty acid donors, liver fatty acid binding protein stimulated acyl-CoA production, whereas that from heart did not stimulate production over control values. 14C-labeled fatty acid-fatty acid binding protein complexes were prepared, incubated with membranes, and acyl-CoA synthetase activity was determined. Up to 70% of the fatty acid could be converted to acyl-CoA in the presence of liver fatty acid binding protein but in the presence of heart fatty acid binding protein, only 45% of the fatty acid was converted. Liver but not heart fatty acid binding protein bound the acyl-CoA formed and removed it from the membranes. The amount of product formed was not changed by additional membrane, enzyme cofactors, or incubation time. Additional liver fatty acid binding protein was the only factor found that stimulated product formation. Acyl-CoA hydrolase activity was also shown in the absence of ATP and CoA. These studies suggest that liver fatty acid binding protein can increase the amount of acyl-CoA by binding this ligand, thereby removing it from the membrane and possibly aiding transport within the cell.     

Inactivation of rice bran thiamine-binding protein by N,N'-dicyclohexylcarbodiimide

The addition of a carboxyl-modifying reagent N,N'-dicyclohexylcarbodiimide (DCCD) to thiamine-binding protein isolated from rice bran resulted in a remarkable loss of its binding activity with [14C]thiamine. Thiamine and chloroethylthiamine substantially protected the protein against inactivation by DCCD, whereas thiamine phosphates did not. Another carboxyl reagent N-ethoxycarbonyl-2-ethoxy-1,2-dihydroquinoline (EEDQ) also inactivated rice bran thiamine-binding protein. Inactivation of the thiamine-binding protein was accompanied by covalent binding of DCCD to the protein as shown by the use of [14C]DCCD. The binding of [14C]DCCD to the thiamine-binding protein was specific, and significantly inhibited by the addition of thiamine. The loss of thiamine-binding activity was proportional to the specific binding of [14C]DCCD. For complete inactivation of the thiamine-binding activity, the binding of 2.46 mol of [14C]DCCD per mol of thiamine-binding protein was required. Furthermore, limited proteolysis of the binding protein by trypsin yielded two polypeptides with molecular weights of 35,000 (large polypeptide) and 12,500 (small polypeptide) which were separated by SDS-polyacrylamide gel electrophoresis. The binding sites of [14C]DCCD were found to be located on the large polypeptide. These results suggest that a specific carboxyl residue in the large polypeptide releasable from rice bran thiamine-binding protein by trypsin digestion when modified by DCCD is involved in the binding of thiamine.     

Interaction of R17 coat protein with its RNA binding site for translational repression

The interaction between bacteriophage R17 coat protein and its RNA binding site for translational repression was studied as an example of a sequence-specific RNA-protein interaction. A nitrocellulose filter retention assay is used to demonstrate equimolar binding between the coat protein and a synthetic 21 nucleotide RNA fragment. The Kd at 2 degrees C in a buffer containing 0.19 M salt is about 1 nM. The relatively weak ionic strength dependence of Ka and a delta H = -19 kcal/mole indicates that most of the binding free energy is due to non-electrostatic interactions. Since a variety of RNAs failed to compete with the 21 nucleotide fragment for coat protein binding, the interaction appears highly sequence specific. We have synthesized more than 30 different variants of the binding site sequence in order to identify the portions of the RNA molecule which are important for protein binding. Out of the five single stranded residues examined, four were essential for protein binding whereas the fifth could be replaced by any nucleotide. One variant was found to bind better than the wild type sequence. Substitution of nucleotides which disrupted the secondary structure of the binding fragment resulted in very poor binding to the protein. These data indicated that there are several points of contact between the RNA and the protein and the correct hairpin secondary structure of the RNA is essential for protein binding.     

Gonadotropin-releasing hormone receptor binding in bovine anterior pituitary

Synthetic gonadotropin-releasing hormone (GnRH) was monoiodinated at a high specific radioactivity with 125I. The iodinated hormone retained full biological activity as assessed by the release of luteinizing hormone in vitro from bovine anterior pituitary tissue slices. Specific binding of 125I-labeled gonadotropin-releasing hormone of high affinity and low capacity was obtained using dispersed bovine anterior pituitary cells. The binding had sigmoid characteristics, compatible with the presence of more than one binding site. The subcellular fraction responsible for binding was identified with the plasma membranes. However, significant binding also occurred in the secretory granules fraction. The plasma membranes were solubilized with sodium dodecyl sulfate. Using gonadotropin-releasing hormone covalently coupled to a solid phase, a protein was purified by an affinity technique from the solubilized plasma membrane preparation which possessed similar binding propperties as plasma membranes, both intact and solubilized. The protein migrated as a single component on polyacrylamide gel in sodium dodecyl sulfate and the estimated molecular weight was 60 000. The character of the gonadotropin-releasing hormone concentration dependence binding as well as association kinetics were multiphasic and suggested the presence of more than one binding site. When analyzed by the Hill plot, the Hill coefficient of all binding curves was always greater than one which is compatible with positive cooperativity. This was further supported by the dissociation studies where the dissociation rate was inversely proportionate to both the gonadotropin-releasing hormone concentration and the time interval during which the gonadotropin-releasing hormone-gonadotropin-releasing hormone receptor protein complex was formed. Using difference chromatography, aggregation of the purified gonadotropin-releasing hormone receptor protein was demonstrated to occur upon its exposure to gonadotropin-releasing hormone. The formed macromolecular complexes bound preferentially 125I-labeled gonadotropin-releasing hormone. It is concluded that a single receptor protein is responsible for gonadotropin-releasing hormone binding in the bovine anterior pituitary. It is a part of the plasma membranes. Its interaction with gonadotropin-releasing hormone provokes transitions of the protein into different allosteric forms and this may be related to the biological effect of gonadotropin-releasing hormone on gonadotropin secretion.     

Calmodulin binding to the intestinal brush-border membrane: comparison to other calcium-binding proteins

The intestinal brush-border membrane contains a high concentration of calmodulin bound to a 105,000 dalton (105 kDa) protein. Binding of radioiodinated calmodulin to this protein does not require calcium but is inhibited by trifluoperazine and excess unlabelled calmodulin. Recent evidence suggests that the 105 kDa protein in conjunction with calmodulin may be involved in the regulation of calcium transport across the brush-border membrane. In this report, we evaluated the binding of the 105 kDa protein to other radioiodinated calcium-binding proteins including the vitamin D-dependent intestinal calcium-binding protein. We observed that troponin C and S100 beta protein both bound strongly to the 105 kDa protein. The binding of S100 beta was inhibited by EGTA, but was little affected by trifluoperazine and excess unlabelled S100 beta, whereas that of troponin C was inhibited by trifluoperazine and excess unlabelled troponin C, but was little affected by EGTA. Both troponin C and S100 beta bound to a large number of proteins to which calmodulin did not bind. The vitamin D-dependent calcium-binding protein (calbindin) from chick intestine and rat kidney also bound to the 105 kDa protein, albeit more weakly than troponin C, S100 beta and calmodulin. The binding of the calbindins was increased by EGTA and was little affected by trifluoperazine and excess unlabelled calbindin. Parvalbumin, rat osteocalcin, and alpha-lactalbumin showed little binding to any brush-border membrane protein. Our results indicate that the 105 kDa calmodulin-binding protein of the intestinal brush border can bind to a variety of calcium-binding proteins all of which contain homologous regions thought to be the calcium-binding sites. Only the binding of troponin C resembles the binding of calmodulin, however, in being inhibited by trifluoperazine and excess unlabelled ligand. The functional significance of these observations in terms of regulating calcium transport across the brush-border membrane remains to be established.     

Cooperative binding of the E2 protein of bovine papillomavirus to adjacent E2-responsive sequences.

The DNA-binding properties of purified full-length E2 protein from bovine papillomavirus type 1 have been investigated by utilizing a quantitative gel shift analysis. By using a recombinant baculovirus which express the E2 open reading frame from the polyhedrin promoter, the full-length E2 protein was synthesized in insect cells and purified to homogeneity by using an E2 binding site (ACCGN4CGGT)-specific oligonucleotide column. The Kd of E2 binding to a 41-bp oligonucleotide containing a single binding site was found to be 2 x 10(-11) M. When two binding sites were included on an oligonucleotide, cooperative binding to these sites by the E2 protein was observed. A cooperativity parameter of 8.5 was determined for E2 binding to two sites. An 86-amino-acid peptide encompassing the C terminus of the protein retains the ability to bind E2 binding sites with a Kd of 4 x 10(-10) M but exhibits slight cooperativity of binding to two adjacent sites. A major determinant for cooperative binding of the full-length E2 protein is thus encoded by the N-terminal amino acids outside the minimal DNA binding domain.     

Purification and characterization of 55-kDa protein with 3,5,3'-triiodo-L-thyronine-binding activity and protein disulfide-isomerase activity from beef liver membrane

Beef liver membranes were shown to have different kinds of 3,5,3'-triiodo-L-thyronine binding proteins including the 55-kDa protein which had been reported to have this activity in many cells by affinity labelling with N-bromoacetyl-3,5,3'-[125I]triiodo-L-thyronine. In order to characterize the molecular features of these binding proteins, the 55-kDa protein was purified from a beef liver membrane fraction abundant in the plasma membrane. The protein was solubilized with 0.5% Chaps and purified by chromatography on gel filtration, hydroxyapatite, and Mono Q anion-exchange columns. The purity was confirmed with reversed-phase HPLC and SDS/PAGE. Consequently, 0.4% of the total proteins in the membrane fraction was recovered as the 55-kDa protein. One fourth of the amino acid composition of this protein was Glx (14.6%) plus Asx (11.7%) and the pI of this protein was 4.5. The purified protein has triiodothyronine-binding activity with a Kd of 57 nM which is similar to the high-affinity binding site of the membranes. The anti-(55-kDa protein) sera specifically recognized the 55-kDa protein of beef, rat and human cells. The immunoglobulin G fraction of the anti-(55-kDa protein) sera inhibited triiodothyronine binding to the beef liver membrane fraction. The purified protein also showed the activity of protein disulfide-isomerase (EC 5.3.4.1) as determined by reactivating scrambled ribonuclease. These data strongly suggested that the multi-functional 55-kDa protein which has triiodothyronine-binding activity and the activity of protein disulfide-isomerase, which is also reported to be the beta subunit of prolyl-4-hydroxylase, glycosylation-site-binding protein of oligosaccharyl transferase and iodothyronine 5'-monodeionidase, could be significant in the action of triiodothyronine towards the target cells.     

Cartilage link protein interacts with neurocan, which shows hyaluronan binding characteristics different from CD44 and TSG-6

The interaction of neurocan with hyaluronan was qualitatively characterized with alkaline phosphatase fusion proteins secreted by mammalian cells. The wild type neurocan hyaluronan binding domain fused to alkaline phosphatase bound to immobilized hyaluronan under physiological as well as moderately hypertonic conditions, whereas its ability to bind to immobilized chondroitin sulfate dropped rapidly with increasing salt concentration. Strong hyaluronan binding ability was still evident when in both link modules within the hyaluronan binding domain a basic amino acid was mutated, which is well conserved among link modules of hyaluronan binding proteins. A strong enhancement of the binding of neurocan to immobilized hyaluronan was observed after preincubation of the immobilized hyaluronan with cartilage link protein. Moreover, this preincubation mediated also the binding of a fusion protein representing only the immunoglobulin module of neurocan linked to alkaline phosphatase, which showed no binding to immobilized hyaluronan alone. The interaction of the neurocan immunoglobulin module with link protein could also be shown by overlay blot analysis. These observations suggest that the hyaluronan binding characteristics of paired link modules are different from those of single link modules, and that the reported temporal co-expression of cartilage link protein and of neurocan in developing brain implicates the possibility of a cooperative function of these molecules.