pH-dependent changes of intrinsic fluorescence of chemically modified liver alcohol dehydrogenases.

Horse liver alcohol dehydrogenase specifically carboxymethylated on cysteine-46 (a ligand to the zinc in the active site) or acetimidylated on 25 of the 30 lysine residues per subunit (including residue 228) was studied. The tryptophan fluorescence of these enzymes decreased by 35% as pH was increased, with an apparent pKa of 9.8 +/- 0.2, identical with that of native enzyme. Native enzyme in the presence of 30mM-imidazole, which displaces a water molecule ligated to the zinc, also had a pKa of 9.8. The ionoizable group is thus neither the water molecule nor one of the modified groups. Binding of NAD+ shifted the pKa for the fluorescence transition to 7.6 with native enzyme and to 9.0 with acetimidylated enzyme, but did not shift the pKa of carboxymethylated enzyme. Binding of NAD+ and trifluoroethanol, an unreactive alcohol, gave maximal fluorescence quenching at pH7 with all three enzymes. The acetimidylated enzyme--NAD+--trifluoroethanol complex had an apparent pKa of 5.0, but the pK of the native enzyme complex was experimentally inaccessible. The results are interpreted in terms of coupled equilibria between two different conformational states. On binding of NAD+, the modified enzymes apparently change conformation less readily than does native enzyme, but binding of alcohol can drive the change to completion.     

Studies on the role of methionine in porcine pancreatic phospholipase A2.

The unique methionine-15 residue located at the N-terminal site of iso- or beta-phospholipase A2 from porcine pancrease has been specifically carboxymethylated with iodoacetic acid. The modification results in a complete inactivation of the enzymatic activity toward micellar and monomeric substrates. Spectroscopic measurements reveled that the carboxymethylated protein still binds Ca2+ and monomeric substrates with comparable affinities as the native enzyeme. The active site histidine-54 residue in the modified enzyme shows a reactivity toward the active site-directed irreversible inhibitor p-bromophenacylbromide which is identical to that of the native enzyme. The alkylated protein, however, has lost its ability to bind to lipid-water interfaces. Although circular dichroic spectra of the carboxymethylated enzyme display some changes in the tertiary structure as compared with the native enzyme, the alpha-helix content remains rather constant. It is concluded that carboxymethylation of methionine-15 destroys the interface recognition site but has only limited influence on the active site of the molecule. Therefore, it seems that methionine-15 is not involved in the catalytic events but that this residue is part of the interface recognition site which embraces the N-terminal hydrophobic part of the enzyme: Ala-Leu-Trp-Gln-Phe-Arg-Ser-Met.     

Structure of the Molybdoferredoxin Complex from Clostridium pasteurianum and Isolation of Its Subunits

Highly purified molybdoferredoxin, with a specific activity of 2.6 mumoles of acetylene reduced per min per mg of protein, was obtained from Clostridium pasteurianum. The protein at concentrations above 5 mg/ml exists in solution as a tetrameric complex with two subunits each of about 60,000 and 50,000 daltons. Two atoms of molybdenum are present per protein molecule of 220,000 daltons. The S(0) (20, w) was found to be 10.5. The tetramer dissociates into a dimer as demonstrated by a decreasing sedimentation coefficient with decreasing protein concentration. At low pH and ionic strength, further dissociation into the monomers is achieved. A method for the isolation of the protein subunits is described.     

Stoichiometry and specificity of binding of Rauscher oncovirus 10,000-dalton (p10) structural protein to nucleic acids.

A structural protein of Rauscher oncovirus of about 8,000 to 10,000 daltons (p10), encoded by the gag gene, has been purified in high yield to apparent homogeneity by a simple three-step procedure. The purified protein was highly basic, with an isoelectric point of more than 9.0, and its immunological antigenicity was chiefly group specific. A distinctive property of the protein was the binding to nucleic acids. The stoichiometry of p10 binding to Rauscher virus RNA was analyzed using both 125I-labeled p10 and 3H-labeled RNA. The protein-RNA complex, cross-linked by formaldehyde, was separated from free RNA and free protein by velocity sedimentation and density gradient centrifugation. A maximum of about 140 mol of p10 was bound per mol of 35S RNA, or about one molecule of p10 per 70 nucleotides. This protein-RNA complex banded at a density of about 1.55 g/ml. The number of nucleic acid sites bound and the affinity of p10 binding differed significantly among the other polynucleotides tested. The protein bound to both RNA and DNA with a preference for single-stranded molecules. Rauscher virus RNA and single-stranded phage fd DNA contained the highest number of binding sites. Binding to fd DNA was saturated with about 30 mol of p10 per mol of fd DNA, an average of about one p10 molecule per 180 nucleotides. The apparent binding constant was 7.3 X 10(7) M(-1). The properties of the p10 place it in a category with other nucleic acid binding proteins that achieve a greater binding density on single-stranded than on double-stranded molecules and appear to act by facilitating changes in polynucleotide conformation.     

Purification and Characterization of a Human Brain Galectin-1 Ligand

Abstract: Our previous studies have characterized an endogenous lectin from human brain identified as galectin-1. A soluble ligand of galectin-1 was purified from human brain by affinity chromatography and preparative electrophoresis. The purified ligand (termed HBGp82, for human brain galectin-1-binding polypeptide of 82,000 daltons) has an apparent molecular mass of 82 kDa and is glycosylated by N -linked biantennary complex structures. HBGp82 was partially characterized by microsequencing of peptide fragments. Similar peptides were found in a heat shock of protein of 90,000 daltons, hsp90. However, comparison of apparent molecular weights and matrix-assisted laser desorption mass spectrometry clearly showed that HBGp82 differs to some degree from hsp90.     

Zein of maize grain. Preparation and characterization]

A laboratory procedure for isolation and purification of zein from grains of 4 varieties of Maize was described. The preparations were characterized by their physicochemical properties. Upon polyacrylamide gel electrophoresis in sodium dodecyl sulphate (SDS), native zein (from INRA 260 hybrid) was resolved into 2 major classes with average molecular weights of 45,000 and 22,000. After reduction with mercaptoethanol zein contained only two subunits of 22,000 and 24,000 daltons. Upon starch gel electrophoresis in 6 M urea at pH 3.5, native zein exhibited five major or medium intensity bands and several minor ones. The latter, under reducing conditions, disappeared to reinforce the major bands or to yield some new minor bands. Amino acid analysis revealed a very low content of lysine. The NH2-terminal amino acids were determined to be threonine and phenylalanine with a preponderance of the former. Zeins isolated from the varieties studied appeared tohave the same NH2-terminal residues and similar amino acid compositions with an arginine/histidine ratio ranging from 1.1 to 1.2. They differed in relative importance of components, detected by electrophoresis in the presence of SDS or urea. Changes in zein characteristics with the grain genotype allow one to conclude that the components of molecular weights of 22,000 and 24,000 consist of several subunits differing in charge and amino acid content.     

The isolation of human beta-interferon receptor by wheat germ lectin affinity and immunosorbent column chromatographies

Radioiodinated human beta-interferon-Ser 17 (Betaseron) was reversibly cross-linked to Daudi cells by dithiobis(succinimidylpropionate). The radioactive ligand was cross-linked to three macromolecules forming labeled complexes of apparent Mr values of 130,000, 220,000, and 320,000. Betaseron, human alpha-interferon, human interleukin 2 but not recombinant human gamma-interferon competed with the labeled ligand for binding to these putative receptor(s). Human leukocyte-produced gamma-interferon competed weakly with 125I-Betaseron for binding to Daudi cells. The Betaseron-receptor complex(es) was purified by passage through a wheat germ lectin column followed by chromatography on an anti-interferon immunosorbent column and semipreparative gel electrophoresis. The cross-linked ligand-receptor complex was shown to be highly purified by sodium dodecyl sulfate and acetic acid:urea:Triton X-100 polyacrylamide gel electrophoresis. It can be dissociated into the labeled Betaseron (Mr = 17,000) ligand and a receptor moiety which has an apparent molecular weight of 110,000. The chromatographic behavior of the ligand-receptor complex on wheat germ lectin column suggests that the receptor is a glycoprotein. The described procedure yielded about 1 microgram of Betaseron receptor from 10(10) Daudi cells, estimated to contain a maximum of about 15 micrograms of the receptor.     

Physicochemical properties of Planorbis corneus erythrocruorin.

The erythrocruorin from the snail Planorbis corneus had a sedimentation coefficient, so/20,w, of 33.5 +/- 0.31 S, and a molecular weight of 1.65 x 10(6) +/- 0.04 x 10(6) by high-speed sedimentation-equilibrium ultracentrifugation. The amino acid composition and absorption spectrum of the protein are reported. A very low number of half-cystine residues was found, corresponding to 0.4 residue per haem group. The haem content was 2.76 +/- 0.22%, corresponding to a protein molecular weight of about 22300. Under both acid and alkaline conditions partial dissociation took place to yield mixtures of products that could not be identified. A subunit corresponding to that containing one haem group was not obtained under any of the dossociating conditions tried. Electron microscopy revealed a ring-shaped molecule about 12.2 +/- 0.5 nm in diameter. The native erythrocruorin bound O2 co-operatively, the intermediate value of h in Hill plots having values between 1.7 and 3.4 depending on the conditions.     

Proton NMR spectroscopy of Alcaligenes cytochrome c556

A high molecular-weight c-type cytochrome was purified from Alcaligenes faecalis ATCC 8750. Its weight was 40,000 daltons by sodium dodecyl sulfate-gel electrophoresis. Heme content was determined to be one heme per 40,000 daltons. Proton nuclear magnetic resonance-NMR-spectroscopy determined that the ferrous form is low spin. The detection of a methyl resonance at -3 ppm in the ferrous form indicated that methionine is a heme ligand in this state. The NMR spectrum of the ferric form at pH 7.2 revealed hyperfine shifted methyl resonances at 67.79, 63.17, 57.71, and 50.46 ppm. The large downfield shifts observed are indicative of high spin character. The ferric spectrum was pH-sensitive, indicating two pH-linked structural transitions with estimated pKs at 6.0 and 10.5. The first is interpreted as due to the ionization of a heme propionate. The second is interpreted as the acquisition of a strong field ligand and the subsequent conversion to a low spin ferric form. The ferricytochrome did not form complexes with cyanide, azide, or fluoride at pH 5.2 or 7.9.     

The galactose-binding sites of the cytotoxic lectin ricin can be chemically blocked in high yield with reactive ligands prepared by chemical modification of glycopeptides containing triantennary N-linked oligosaccharides.

A glycopeptide containing a triantennary N-linked oligosaccharide from fetuin was modified by a series of chemical and enzymic reactions to afford a reagent that contained a terminal residue of 6-(N-methylamino)-6-deoxy-D-galactose on one branch of the triantennary structure and terminal galactose residues on the other two branches. Binding assays and gel filtration experiments showed that this modified glycopeptide could bind to the sugar-binding sites of ricin. The ligand was activated at the 6-(N-methylamino)-6-deoxy-D-galactose residue by reaction with cyanuric chloride. The resulting dichlorotriazine derivative of the ligand reacts with ricin, forming a stable covalent linkage. The reaction was confined to the B-chain and was inhibited by lactose. Bovine serum albumin and ovalbumin were not modified by the activated ligand under similar conditions, and we conclude, therefore, that the reaction of the ligand with ricin B-chain was dependent upon specific binding to sugar-binding sites. Ricin that had its galactose-binding sites blocked by the covalent reaction with the activated ligand was purified by affinity chromatography. The major species in this fraction was found to contain 2 covalently linked ligands per ricin B-chain, while a minor species contained 3 ligands per B-chain. The cytotoxicity of blocked ricin was at least 1000-fold less than that of native ricin for cultured cells in vitro, even though the activity of the A-chain in a cell-free system was equal to that from native ricin. Modified ricin that contained only 1 covalently linked ligand was also purified. This fraction retained an ability to bind to galactose affinity columns, although with a lower affinity than ricin, and was only 5- to 20-fold less cytotoxic than native ricin.     

Spinach leaf ribulose-5-phosphate kinase: examination of sulfhydryls by chemical modification and spin-labeling

Methodology has been developed for complete or selective modification of the cysteinyl sulfhydryls of ribulose-5-phosphate (Ru5P) kinase. Using native enzyme, iodoacetate modifies four sulfhydryls with varying levels of completeness. The most reactive sulfhydryl in the native enzyme can be selectively titrated with iodoacetate; complete loss of activity occurs. Composition and N-terminal analyses of the peptide bearing this essential sulfhydryl indicate that the alkylated residue (Cys-16) is identical to the site modified by other modification reagents (M. A. Porter and F. C. Hartman (1986) Biochemistry 25, 7314-7318). In the presence of ATP, a nonessential sulfhydryl of the native enzyme is carboxymethylated. The peptide bearing this modified cysteine has been isolated and its composition and N-terminal sequence determined. Enzyme that is carboxymethylated in the presence of ATP retains activity and can be oxidatively inactivated in a reversible fashion. This suggests that the cysteine targeted by iodoacetate in the presence of ATP is not a residue that participates in regulation of enzyme activity. Using a spin-labeled analog of iodoacetate, both essential and nonessential cysteines have been selectively modified. ESR measurements suggest that the environment of these cysteines is not highly constrained. Modest effects on spin-label mobility are observed upon occupancy of Ru5P or ATP sites on the modified enzyme. These effects are dependent on the presence of divalent cations, suggesting that a binary enzyme-cation complex must form prior to productive enzyme-substrate interactions.     

Fractionation of the proteins of plant microbodies

1. Oxidized (polymerized) histidine ammonia-lyase from Pseudomonas testosteroni was activated with dithiothreitol and the reduced disulphide-linked cysteine residues of the native enzyme were carboxymethylated with iodo[(14)C]acetate. 2. The activity of the carboxymethylated enzyme was similar to that of the polymerized form and approx. 15% of that of the fully reduced form. 3. A tryptic digest of the [(14)C]carboxymethylated enzyme contained only one radioactive peptide. 4. The amino acid sequence of this peptide was shown to be Gly-Leu-Leu-Asp-Gly-Ser-Ala-Ile-Asn-Pro-Ser-His-Pro-Asn-Cys- (CH(2)CO(2)H)-Gly-Arg. 5. These findings show that, during polymerization, the disulphide bonds are formed between identical regions of the enzyme, and that the cysteine residue involved is also the one required in the reduced state for full activity of the enzyme.     

Trypsin activation of enterotoxin from Clostridium perfringens type A: fragmentation and some physicochemical properties

Clostridium perfringens type A enterotoxin was activated about 3-fold by treatment with trypsin, without an observed change in molecular weight. On denaturation in 8 M urea, the trypsinated enterotoxin lost a small peptide of about 4000 daltons. The single cysteine residue of enterotoxin was in the small peptide together with seven out of nine residues of proline. Trypsin activation, without removal of the small peptide, increased the 'outside' number of amino groups from eight to eleven. The trypsin treatment of the enterotoxin did not change the antigenic properties of the protein. Glycine was the C-terminal residue of the native enterotoxin while the dansyl alpha-amino acid of the N-terminal could not be identified.     

Selective carboxymethylation of cysteine-174 of the beta 2 beta 2 and beta 1 beta 1 human liver alcohol dehydrogenase isoenzymes by iodoacetate

The beta 1 beta 1 and beta 2 beta 2 human liver alcohol dehydrogenase isoenzymes differ by only one residue at the coenzyme-binding site; Arg-47 in beta 1 is replaced by His in the beta 2 subunit. Since Arg-47 is thought to facilitate the carboxymethylation of Cys-46 in horse liver alcohol dehydrogenase by binding halo acids in a Michaelis-Menten complex prior to inactivation, the specificity and kinetics of modification of the two human liver beta beta isoenzymes with iodoacetate were compared. Both of the beta beta isoenzymes were inactivated by treatment with iodo[14C]acetate, and one Cys per subunit was carboxymethylated. Cys-174, which is a ligand to the active-site zinc atom in horse liver alcohol dehydrogenase, was selectively carboxymethylated in each of the human beta beta isoenzymes; less than 15% of the iodo[14C]acetate incorporated into the enzyme appeared in Cys-46. Therefore, the three-dimensional structure of the basic amino acids in the anion-binding site of the human beta beta isoenzymes appears to be different from that of horse liver alcohol dehydrogenase. The kinetics of alkylation are consistent with the formation of a Michaelis-Menten complex before inactivation of the isoenzymes. The average Ki values for iodoacetate were 10 and 16 mM for beta 1 beta 1 and beta 2 beta 2, respectively, and maximal rate constants for inactivation were 0.22 and 0.17 min-1, respectively. From these data, it can be concluded that there is a relatively minor effect of the substitution of His for Arg at position 47 on the kinetics of inactivation.     

Single-crystal EPR study of novel azide complex of cyanogen bromide-modified myoglobin. Influence of specific modification of the heme distal histidyl residue on the ligand-binding structure

Stable azide complex of cyanogen bromide-modified met-myoglobin (metMb) was prepared and crystallized. The principal values and eigen vectors of g-tensor were determined by single-crystal EPR spectroscopy at 77 K: gxx = 1.50, gyy = 2.32, and gzz = 2.91. These g values were similar to those of tetrazole derivative rather than azide derivative of native metMbs, suggesting that tetrazole derivative might be formed from N-cyanoimidazole of distal histidyl residue via nucleophilic attack of azide ion by 1,3-dipolar cycloaddition reaction. The orientation of the maximal g value (gzz) of the novel product was found to deviate about 13 degrees from the heme normal of native aquometMb. Thus, the orientation of the heme plane might be altered in passing from native metMb to cyanogen bromide-mediated metmyoglobin. The present EPR results demonstrated that the modification of the histidyl residue at the heme distal side causes the changes in the stereochemical and electronic natures of the ligand binding to the heme.     

A lysyl residue at the NADP binding site of ferredoxin-NADP reductase.

Dansyl chloride, at low molar ratio, inactivates ferredoxin-NADP reductase (NADPH:ferredoxin oxidoreductase, EC 1.6.7.1). The complete protection afforded either by NADP or NADPH suggests a direct involvement of the active site. Experiments with [Me-14C] dansyl chloride showed that about 1.5 residues per flavin were dansylated: by differential labelling experiments using NADP, it has been proved that enzyme inactivation is due to dansylation of one residue. The group modified has been identified as the epsilon-amino group of a lysine. The pH-inactivation profile indicates that this essential group has an apparent pKa of 8.7. The dansylated flavoprotein seems to maintain its native conformation; it shows a fluorescent chromophore with a peak at 335 nm. The modified enzyme has lost the capacity to form a complex with NADP, nevertheless it interacts normally with ferredoxin. It is concluded that the loss of catalytic activity which parallels the dansylation of a lysyl residue occurs because this residue is essential for the binding of the pyridine nucleotide substrate. Protection experiments with a series of coenzyme analogs further indicate that this lysyl residue interacts, most likely, with the 2'-phosphate moiety of NADP(H).     

Carboxymethyl horse-liver alcohol dehydrogenase. Ligand-binding and kinetic properties of the cysteine-46-modified enzyme.

Horse-liver alcohol dehydrogenase was carboxymethylated with iodoacetate, which is known to selectively alkylate cysteine-46 in the polypeptide sequence. Carboxymethyl and native enzyme had the same electrophoretic mobility on starch or polyacrylamide gel, but some separation was achieved when isobutyramide and a low concentration of NADH were present (under these conditions NADH was bound by native enzyme but not by Carboxymethyl enzyme).The Carboxymethyl enzyme formed ternary complexes with NAD⁺ and pyrazole or decanoate. The fluorescence emission of NADH was enhanced 7- to 8-fold (at 410 nm), and a dissociation-constant of 1.7 μM was calculated at pH 7.4; but, in contrast to native enzyme, neither the affinity nor fluorescence were increased by amides (acetamide or isobutyramide).Carboxymethyl alcohol dehydrogenase possesses catalytic activity. Higher alcohols gave maximum velocities up to 7-fold higher than ethanol (reaching nearly 20% of the activity of native enzyme) while [²H]ethanol showed an isotope-rate effect of 3.3. Although the affinity for aldehydes was considerably increased, the maximum velocity of aldehyde-reduction was always at least 20% of that shown by native enzyme, and at pH 9.9 it was almost 2-fold greater than with native enzyme. The rate-limiting step in alcohol-oxidation is likely to be the interconversion of ternary complexes (possibly the hydride-transfer step), while in aldehyde-reduction it could still be the dissociation of the enzyme/NAD⁺ complex. This is also indicated by inhibition experiments with decanoate, pyrazole, and isobutyramide.These results suggest that a major effect of carboxymethylation is upon ternary complexes of enzyme and NADH, which become much more reluctant to form, either by combination of NADH and ligand with the modified enzyme, or by catalytic conversion of the enzyme/NAD ⁺/alcohol complex.     

Secreted amylolytic enzymes from Schwanniomyces occidentalis: purification by fast protein liquid chromatography (FPLC) and preliminary characterization

Amylolytic enzyme preparations are used extensively for the liquefaction and saccharification of starch in the production of ethanol and SCP (single cell protein). We report the first purification of two amylolytic enzymes from the yeast Schwanniomyces occidentalis using fast protein liquid chromatography (FPLC) in a two step process: size exclusion (Superose 12) followed by anion exchange (Mono Q). The procedure is amenable to direct scale up processes. The enzymes glucoamylase (E.C. 3.2.1.2) and alpha-amylase (E.C. 3.2.1.1) were found in the cell free supernatant of S. occidentalis when grown on a variety of carbon sources. The enzymes are substrate induced and catabolite repressed. Both amylolytic enzymes were purified from three separate culture broths containing either starch, maltose or cellobiose and their physical properties compared. Native molecular masses of glucoamylase and alpha-amylase were determined to be 122,000 +/- 28,000 daltons and 47,000 +/- 11,000 daltons, respectively, while subunit size was approximated at 143,000 +/- 2,000 daltons and 54,500 +/- 1,000 daltons, respectively. Both proteins are N-glycosylated with carbohydrate representing 10-15% of the total mass. The correlation of native mass and denatured subunit structure, while not identical due to slight aberrant behavior on gels and columns as a result of glycosylation, suggest that both proteins exist as monomeric polypeptides. Isoelectric points for both proteins under native conditions could not be determined since alpha-amylase failed to enter native polyacrylamide gels. However, a pI for glucoamylase of 6.2 +/- 0.2 (native) and a pI for alpha-amylase of 6.3 +/- 0.3 (in 6M urea) were determined. Glucoamylase and alpha-amylase specific activities (for the homogeneous proteins) were determined to be 48-67 x 10(3) units/mg and 214-457 x 10(3) units/mg respectively. We could find no apparent differences in either glucoamylase or alpha-amylase proteins obtained from three separate cultures which had been grown on different carbon sources. The purification method we have utilized is easily scaled up to larger protein concentrations, and provides a rapid procedure for analyzing and purifying these amylolytic enzymes.     

Ferric iron uptake in Erwinia chrysanthemi mediated by chrysobactin and related catechol-type compounds.

Erwinia chrysanthemi 3937 possesses a saturable, high-affinity transport system for the ferric complex of its native siderophore chrysobactin, [N-alpha-(2,3-dihydroxybenzoyl)-D-lysyl-L-serine]. Uptake of 55Fe-labeled chrysobactin was completely inhibited by respiratory poison or low temperature and was significantly reduced in rich medium. The kinetics of chrysobactin-mediated iron transport were determined to have apparent Km and Vmax values of about 30 nM and of 90 pmol/mg.min, respectively. Isomers of chrysobactin and analogs with progressively shorter side chains mediated ferric iron transport as efficiently as the native siderophore, which indicates that the chrysobactin receptor primarily recognizes the catechol-iron center. Free ligand in excess only moderately reduced the accumulation of 55Fe. Chrysobactin may therefore be regarded as a true siderophore for E. chrysanthemi.     

Means for the assessment of radioligand quality and its importance in receptor-binding studies. Observations with radiolabelled formylmethionyl-leucyl-phenylalanine.

Various methods for testing the quality of radioligands were applied to two different radiolabelled forms of formylmethionyl-leucyl-phenylalanine (fMet-Leu-Phe). The purpose of the study was both to examine the value of these methods for assessing radioligand quality and to determine the suitability of these particular radioligands for studying the chemotactic formylpeptide receptors on the rabbit neutrophil. It is useful in this context to distinguish two different aspects of radioligand quality: these are purity and equivalence to the native ligand. The two methods described for measuring receptor-reactivity (or 'bindability'), by measuring binding to an increasing excess of receptors and by a re-incubation procedure, provide a reliable measure of purity that should readily be applicable to other radioligands. Equivalence to the native ligand is more difficult to establish, and any uncertainty about the specific radioactivity of the radioligand can pose serious problems with this assessment. Commercial preparations of both tritiated and 35S-labelled fMet-Leu-Phe were found to be inadequately pure for detailed receptor studies. Repurification by t.l.c., however, consistently yielded radioligand preparations of high purity and close equivalence to the native ligand. Other radioligands may often also require a suitable repurification step before use for detailed receptor studies; this is especially important whenever a complex receptor-binding pattern is envisaged.