The non-convalent binding of small molecules by ligandin. Interactions with steroids and their conjugates, fatty acids, bromosulphophthalein carcinogens, glutathione and realted compounds.

1. Equilibrium dialysis studies have been made of the binding of a number of small molecules by rat ligandin. Direct measurements of binding together with competition experiments indicated that bromosulphophthalein, oestrone sulphate and dehydroepiandrosterone sulphate each bind at the same single primary binding site with association constants of 1.1 X 10(7), 6.6 X 10(5) and 2.6 X 10(5) 1/mol respectively at pH 7.0,IO.16M,4 degrees C. As well as bromosulphophthalein and dehydroepiandrosterone sulphate, a number of strucurally similar organic anions including 2-hydroxyoestradiol-glutathione oestrone glycyronide, N-methyl-4-aminoazobenzene-glutathione and several bile acids, were able to displace oestrone sulphate from ligandin in a manner consistent with competition at a single binding site. From these experiments association constants for the competing ligands were derived; these were inthe range 1 X 10(4)-1 X 10(6) 1/mol. 2. Ligandin was found to bind a number of compounds for which, because of their low aqueous solubilities relative to their binding affinities complete binding isotherms could bot be obtained. These included several steroids (but not cortisol), 20-methylcholanthrene, diethylstilboestrol, oleate and palmitate. Oestrone sulphate was able to compete with these ligands for binding and the results of the competition experiments were interpretable in terms of 1:1 competition at a single binding site. 3. In general the conjugation of non-polar ligands with sulphate or glutathione resulted in increased affinities, but such increases were relatively small (approximately 15% in therms of free energy) implying that the main driving force for the binding of both the conjugated and unconjugated species was the hydrophobic effect. This conclusion is borne out by the observations that both oestrone and its sulphate showed slight increases in affinity with increase in ionic strength, as would be expected for hydrophobic interactions. 4. As well as non-polar compounds and organic anions, ligandin was also found to bind sulphate and glucuronate to a measurable degree, and to interact quite strongly with glutathione. For the latter compound a single binding site was found with an association constant of 1 X 10(5) 1/mol. Glutathione was able to cause the dissociation of the ligandin-oestrone sulphate complex, but this effect was not explicable in terms of simple 1:1 competition. 5. Both oestrone and oestrone sulphare were bound most strongly at pH 6-7, the affinity of the protein for these ligands falling off quite sharply on either side of this maximum. 6. The affinities of ligandin for bromosulphophthalein, steroids and their conjugates, diethylstilboestrol and N,N-dimethyl-4-aminoazobenzene are similar in magnitude to those of serum albumin and aminoazodye-binding protein A (B. Ketterer, E. Tipping, J.F. Hackney and D. Beale, 1976).     

Spectroscopic studies of the binding of bilirubin by ligandin and aminoazo-dye-binding protein A.

Ligandin and aminoazo-dye-binding protein A both bind bilirubin at a single site. Quantitative studies of the interactions using difference spectrophotometry show that at pH 7.0, protein A binds the tetrapyrrole with an association constant (K) greater than or equal to 2 X 10(7) litre/mol, whereas binding by ligandin is slightly weaker (K = 7 X 10(6) litre/mol) at this pH. The protein-bilirubin complexes give rise to absorption and fluorescence spectra quite different from those of unbound bilirubin and also to large Cotton effects. It appears that on binding to both proteins, the ligand is forced into a rigid twisted configuration in a hydrophobic environment. Ligandin and protein A resemble serum albumin in their interactions with bilirubin.     

Interactions of bilirubin and other ligands with ligandin.

Circular dichroism methods were used to study the structure of rat ligandin and the binding of organic anions to the protein. Ligandin has a highly ordered secondary structure with about 40%alpha helix, 15% beta structure, and 45% random coil. Bilirubin binding occurred primarily at a single high affinity site on the protein. The binding constant for bilirubin (5 X 10-7 Mminus 1) was the highest among the ligands studied. The bilirubin-ligandin complex exhibited a well-defined circular dichroic spectrum with two major overlapping ellipticity bands of opposite sign in the bilirubin absorption region. This spectrum was virtually a mirror image of that of human or rat serum albumin-bilirubin complexes. Studies on the direct transfer of bilirubin from ligandin to rat serum albumin showed that sasociation constants of bilirubin-ligandin complexes were approximately tenfold less than those of the bilirubin-albumin system. Ligandin exhibited a broad specificity with respect to the typeof ligand bond. A series of organic anions inclucing dyes used clinically for liver function tests, fatty acids, hormones, heme derivatives, bile acids, and other ligands that were considered likely to interact with ligandin, were examined. Most induced ellipticity changes consistent with competitive displacement of bilirubin from ligandin and relative affinities of these compounds for ligandin were determined based on their effectiveness in desplacing the bilirubin. Some substances such as glutathione, conjugated sulfobromophthaleins and lithocholic acid bound to ligandin but induced anomalous spectral shifts, when added to ligandin-bilirubin complexes. Other compounds, including some that act as substrates for the glutathione transferase activity exhibited by ligandin, revealed no apparent competitive effects with respect to the bilitubin binding site.     

Comparison of binding of thyroid hormone analogues to hepatic organic anion binding proteins

Dv protein and ligandin are two hepatic cytosolic proteins which bind organic anions, including endogenous thyroid hormones. Binding studies were performed using the ANS displacement technique to compare the binding of a variety of thyroid hormone analogues to purified organic anion binder and ligandin. Inhibition of ANS binding by these compounds was competitive. Both proteins bound L- and D-thyroxine with comparable affinity (Kd 30-45 microM), whereas ligandin bound 3',3',5-triiodo-L-thyronine, 3',3',5-triiodo-L-thyronine and most analogues with greater affinity. Nevertheless, the order of ligand affinities for both binders was highly correlated, suggesting that the nature of the binding site on both proteins is similar. The binding affinities of these organic anion binders are 2-3 orders of magnitude lower than an hepatic cytosolic thyroid binder reported by others, suggesting that ligandin and organic anion binder may not be important in intracellular thyroid hormone transfer.     

Interactions of small molecules with phospholipid bilayers. Binding to egg phosphatidylcholine of some organic anions (bromosulphophthalein, oestrone sulphate, haem and bilirubin) that bind to ligandin and aminoazo-dye-binding protein A.

1. To assess the possible involvement of ligandin and aminoazo-dye-binding protein A in intracellular transport it is necessary to know how their ligands, most of which are molecules with hydrophobic moieties, interact with cellular membranes. To obtain such information we examined the interactions of bromosulphophthalein, oestrone sulphate, haem and bilirubin with aqueous dispersions of egg phosphatidylcholine and egg phosphatidylchone/cholesterol (1:1, molar ratio) by equilibrium dialysis and spectrophotometry. 2. In all four cases, saturation effects were observed. Values of Vmax (v = mol of compound bound/mol of lipid phosphorus) at 25 degrees C were: for bromosulphophthalein, approximately 0.1; for oestrone sulphate, approximately 0.25; for haem, approximately 0.25 (all at pH 7.4); and for bilirubin 0.1--0.2 (at pH 8.2). 3. Limiting values of v/c (c = unbound concentration) as v leads to 0 at 25 degrees C and pH 7.4 are: for bromosulphophthalein, 6.25 x 10(4) litre-mol-1; for oestrone sulphate, 7.8 x 10(2) litre-mol-1; for haem, 4.5 x 10(5) litre-mol-1; and for bilirubin, approximately 1.2 x 10(4) litre-mol-1. For haem the result depends on the assumption that only the monomeric form binds to the lipid. 4. The binding of each compound was decreased by cholesterol; bromosulphophthalein and oestrone sulphate were affected more than haem and bilirubin. 5. Bromosulphophthalein at saturating concentration decreased the limiting values of v/c of the other three compounds by approximately one order of magnitude. 6. By assuming that the interactions with egg phosphatidylcholine resemble those with the phospholipid components of mammalian intracellular membranes the binding data for phosphyatidylcholine, together with data for binding to the intracellular proteins ligandin and aminoazo-dye-binding protein A, enable the subcellular distributions of the four compounds to be estimated. For the rat hepatocyte up to 92, 51, 98 and 47% of the total bromosulphophthalein, oestrone sulphate, haem and bilirubin respectively may be membrane-bound.     

Circular dichroism analysis of the secondary structure of Z protein and its complexes with bilirubin and other organic anions.

Circular dichroism (CD) methods were employed to study the conformation of Z protein and characterize its complexes with bilirubin and other organic anions. Z protein-bilirubin complexes exhibited a spectrum with overlapping ellipticity bands of opposite sign in the bilirubin absorption region. These results were compared with those obtained with ligandin, the other major organic anion binding protein of liver. Secondary structural differences between the two proteins were easily demonstrated since ligandin is predominantly an alpha-helical protein and Z features mainly beta-structure. Furthermore, the optical activity pattern generated by bilirubin binding to Z was virtually a mirror image of that of the ligandin bilirubin system. CD experiments were designed to study the direct transfer of bilirubin between Z protein and ligandin, and it was shown that both proteins have almost equal affinities for bilirubin. The bilirubin on Z was readily displaced by oleic acid and displaced to a lesser extent by sulfobromophthalein,     

Spectral and other studies on the intestinal haem receptor of the pig

We recently demonstrated the presence of a Triton-solubilized high-affinity haem binder on the pig duodenal brush border membrane. The association of haem to the binding factor was determined using radioactive haem and is now studied by a spectrophotometric technique. The binding alters the Soret absorption band of haem from 395 nm to 413 nm. The dissociation constant for the binding of haem to the solubilized binding factor was estimated to be about 10(-9) M by difference spectroscopy. Human serum albumin could not prevent the solubilized binding factor from binding haem. Trypsin digestion destroyed the binder.     

A protein with multiple heme-binding sites from rabbit serum

A 93,000 molecular weight protein (HBP.93) which binds hemin and protoporphyrin IX with high affinity has been isolated from rabbit serum using affinity chromatography on hemin-conjugated agarose. The amino acid composition of this protein is unique in that the proline and histidine contents are remarkably high (16.6 and 9.9 mol %, respectively). A large increase in the absorbance of the Soret region arises from the heme-protein interaction. The spectrophotometric titration showed that the protein can bind 25-35 mol of hemin/mol of protein. The apparent dissociation constant was estimated to be 1-4 X 10(-7) M for hemin at pH 7.4 and approximately 10(-6) M for protoporphyrin IX at pH 9.2. The similarity of the difference spectrum of heme-HBP.93 complex to that of heme-hemopexin complex suggests that a bisimidazol-type coordination of heme iron is involved in the binding. The extremely high capacity of HBP.93 to bind heme is also demonstrated by a large increase in the sedimentation velocity of the protein upon heme binding. The native heme-protein complex migrates faster than the heme-free protein in a polyacrylamide gel at pH 8.8; the increased mobility appears to be due to the charge on the carboxyl groups of the bound heme. Although the use of a hemin-agarose column has failed to reveal a protein of similar size and heme affinity in the sera of a number of other species, including man, the heme-binding properties and high histidine level of the human alpha 2-histidine-rich glycoprotein raise the possibility that the two proteins are related.     

Separate identities of ligandin and the h-protein,a major protein to which carcinogenic hydrocarbons are covalently bound

There is a protein moiety in the C3H mouse liver cytosol which gives a line of identity with rat liver ligandin one of three azo dye binding proteins of the liver using anti-rat ligandin. This mouse liver protein has been termed mouse ligandin and is not the $\text{h}$-protein, the major target protein in the mouse liver of methylcholanthrene and its metabolites. Mouse ligandin is identical to a minor methylcholanthrene binding protein species that was found previously to consist of basic proteins II and III. Both mouse ligandin and mouse $\text{h}$-protein contain glutathione S-transferase activity with different substrate specificitles.     

Haemophore functions revisited

Haem is the major iron source for bacteria that develop in higher organisms. In these hosts, bacteria have to cope with nutritional immunity imposed by the host, since haem and iron are tightly bound to carrier and storage proteins. Siderophores were the first recognized fighters in the battle for iron between bacteria and host. They are non-proteinaceus organic molecules having an extremely high affinity for Fe(3+) and able to extract it from host proteins. Haemophores, that display functional analogy with siderophores, were more recently discovered. They are a class of secreted proteins with a high affinity for haem; they are able to extract haem from host haemoproteins and deliver it to specific receptors that internalize haem. In the past few years, a wealth of data has accumulated on haem acquisition systems that are dependent on surface exposed/secreted bacterial proteins. They promote haem transfer from its initial source (in most cases, a eukaryotic haem binding protein) to the transporter that carries out the membrane crossing step. Here we review recent discoveries in this field, with particular emphasis on similar and dissimilar mechanisms in haemophores and siderophores, from the initial host source to the binding protein/receptor at the cell surface.     

Protein structural requirements and properties of membrane binding by gamma-carboxyglutamic acid-containing plasma proteins and peptides

The membrane-binding characteristics of a number of modified vitamin K-dependent proteins and peptides showed a general pattern of structural requirements. The amino-terminal peptides from human prothrombin (residues 1-41 and 1-44, 60:40) bovine factor X (residues 1-44), and bovine factor IX (residues 1-42), showed a general requirement for a free amino-terminal group, an intact disulfide, and the tyrosine homologous to Tyr44 of factor X for membrane binding. Consequently, the peptide from factor IX did not bind to membranes. Any of several modifications of the amino terminus, except reaction with trinitrobenzenesulfonic acid, abolished membrane binding by the factor X and prothrombin peptides. Calcium, but not magnesium, protected the amino terminus from chemical modification. The requirement for a free amino terminus was also shown to be true for intact prothrombin fragment 1, factor X, and factor IX. Although aggregation of the peptide-vesicle complexes greatly complicated accurate estimation of equilibrium binding constants, results with the factor X peptide indicated an affinity that was not greatly different from that of the parent protein. The most striking difference shown by the peptides was a requirement for about 10 times as much calcium as the parent proteins. In a manner similar to the parent proteins, the prothrombin and factor X peptides showed a large calcium-dependent quenching of tryptophan fluorescence. This fluorescence quenching in the peptides also required about 10 times the calcium needed by the parent proteins. Thus, the 1-45 region of the vitamin K-dependent proteins contained most of the membrane-binding structure but lacked component(s) needed for high affinity calcium binding. Protein S that was modified by thrombin cleavage at Arg52 and Arg70 showed approximately the same behavior as the amino-terminal 45-residue peptides. That is, it bound to membranes with overall affinity that was similar to native protein S but required high calcium concentrations. These results suggested that the second disulfide loop of protein S (Cys47-Cys72) and prothrombin (Cys48-Cys61) were involved in high affinity calcium binding. Since factor X lacks a homologous disulfide loop, an alternative structure must serve a similar function. A striking property of protein S was dissociation from membranes by high calcium. While this property was shared by all the vitamin K-dependent proteins, protein S showed this most dramatically and supported protein-membrane binding by calcium bridging.     

Binding of Escherichia coli protein synthesis initiation factor IF1 to 30S ribosomal subunits measured by fluorescence polarization

The interaction of initiation factor IF1 with 30S ribosomal subunits was measured quantitatively by fluorescence polarization. Purified IF1 was treated with 2-iminothiolane and N-[[(iodoacetyl)-amino]ethyl]-5-naphthylamine-1-sulfonic acid in order to prepare a covalent fluorescent derivative without eliminating positive charges on the protein required for biochemical activity. The fluorescent-labeled IF1 binds to 30S subunits and promotes the formation of N-formylmethionyl-tRNA complexes with 70S ribosomes. Analyses of mixtures of fluorescent-labeled IF1 and 30S ribosomal subunits with an SLM 4800 spectrofluorometer showed little change in fluorescence spectra or lifetimes upon binding, but a difference in polarization between free and bound forms is measurable. Bound to free ratios were calculated from polarization data and used in Scatchard plots to determine equilibrium binding constants and number of binding sites per ribosomal subunit. Competition between derivatized and nonderivatized forms of IF1 was quantified, and association constants for the native factor were determined: (5 +/- 1) X 10(5) M-1 with IF1 alone; (3.6 +/- 0.4) X 10(7) M-1 with IF3; (1.1 +/- 0.2) X 10(8) M-1 with IF2; (2.5 +/- 0.5) X 10(8) M-1 with both IF2 and IF3. In all cases, 0.9-1.1 binding sites per 30S subunit were detected. Divalent cations have little effect on affinities, whereas increasing monovalent cations inhibit binding. On the basis of the association constants, we predict that greater than 90% of native 30S subunits are complexed with all three initiation factors in intact bacterial cells.     

The effect of the iron saturation of transferrin on its binding and uptake by rabbit reticulocytes.

Polyacrylamide-gel electrophoresis in urea was used to prepare the four molecular species of transferrin:diferric transferrin, apotransferrin and the two monoferric transferrins with either the C-terminal or the N-terminal metal-binding site occupied. The interaction of these 125I-labelled proteins with rabbit reticulocytes was investigated. At 4 degrees C the average value for the association constant for the binding of transferrin to reticulocytes was found to increase with increasing iron content of the protein. The association constant for apotransferrin binding was 4.6 X 10(6)M-1, for monoferric (C-terminal iron) 2.5 X 10(7)M-1, for monoferric (N-terminal iron) 2.8 X 10(7)M-1 and for diferric transferrin, 1.1 X 10(8)M-1. These differences in the association constants did not affect the processing of the transferrin species by the cells at 37 degrees C. Accessibility of the proteins to extracellular proteinase indicated that the transferrin was internalized by the cells regardless of the iron content of the protein, since in each case 70% was inaccessible. Cycling of the cellular receptors may also occur in the absence of bound transferrin.     

Comparative interactions of factor IX and factor IXa with human platelets

Both factor IX and factor IXa were bound to gel filtered platelets in the presence of CaCl2 (2-20 mM) and human alpha-thrombin (0.06-0.2 units/ml) with maximal binding occurring in 10-20 min at 37 degrees C, and rapid reversibility was observed when unlabeled ligands were added in 100-fold molar excess. Competition studies with various coagulation proteins revealed that neither factor XI nor high molecular weight kininogen, at 300-fold molar excess, could compete with 125I-labeled factor IXa for binding sites on thrombin-activated platelets, whereas prothrombin and factor X, in 450-fold molar excess, could displace approximately 15 and 35%, respectively, of bound factor IXa in the absence of added factor VIII. Analysis of saturation binding data in the presence of CaCl2 and thrombin without factors VIII and X indicated the presence of 306 (+/- 57) binding sites per platelet for factor IX (Kd(app) = 2.68 +/- 0.25 nM) and 515 (+/- 39) sites per platelet for factor IXa (Kd = 2.57 +/- 0.14 nM). In the presence of thrombin-activated factor VIII (1-5 units/ml) and factor X (0.15-1.5 microM), the number of sites for factor IX was 316 (+/- 50) with Kd = 2.44 (+/- 0.30) nM and for factor IXa 551 (+/- 48) sites per platelet (Kd = 0.56 +/- 0.05 nM). Studies of competition for bound factor IXa by excess unlabeled factor IX or factor IXa, and direct 125I-labeled factor IXa binding studies in the presence of large molar excesses of factor IX, confirmed the conclusion from these studies that factor IX and factor IXa share approximately 300 low-affinity binding sites per thrombin-activated platelet in the presence of Ca2+ and in the absence of factor VIII and factor X, with an additional 200-250 sites for factor IXa with Kd(app) similar to that for factor IX. The presence of factor VIII and factor X increases by 5-fold the affinity of receptors on thrombin-activated platelets for factor IXa that participate in factor X activation.     

Immunoglobulin M possesses two binding sites for complement subcomponent C1q, and soluble 1:1 and 2:1 complexes are formed in solution at reduced ionic strength

Soluble complexes were formed between C1q, a subunit of the first component of human complement, and four different Waldenstr?m IgM proteins at reduced ionic strengths. The equilibria between these complexes and the free proteins were studied in the ultracentrifuge. Complex formation was found to be a very sensitive function of the salt concentration, and at physiological ionic strength complex formation was negligible. The complexes were cross-linked with a water-soluble carbodiimide and separated by sucrose gradient centrifugation. Both 22 S 1:1 and 26 S 2:1 C1q X IgM complexes were formed; stoichiometry was established by cross-linking 125I-C1q with 131I-IgM and determining the ratios of the specific activities of the gradient-purified materials. The association process was studied as a function of protein concentration and was analyzed by Scatchard and Hill plots to yield stoichiometry, association constant, and degree of cooperativity. The results indicated that IgM has two identical and independent binding sites for C1q. The intrinsic association constant was found to vary between 10(6) M-1 at 0.084 M ionic strength to 10(4) M-1 at physiological ionic strength; the slope of the log-log plot gave a value of -6.0. The cross-linked complexes were examined by electron microscopy, and the C1q appeared to be attached to the IgM through the C1q heads, implying that the biologically significant binding sites were involved in this interaction. For the 2:1 complexes, the two C1q appeared to attach to opposite surfaces of the IgM, suggesting the presence of a pseudo-2-fold axis lying in the plane of the IgM disk.     

Conformational changes in an epitope localized to the NH2-terminal region of protein C. Evidence for interaction of protein C domains

Murine monoclonal antibodies, developed following immunization with human protein C, were characterized for their ability to bind antigen in the presence of either CaCl2 or excess EDTA. Three stable clones were obtained which produced antibodies that bound to protein C only in the presence of EDTA. All three antibodies bound to the light chain of protein C on immunoblots and also bound to the homologous proteins factor X and prothrombin in solid-phase radioimmunoassays. One antibody, 7D7B10 was purified and studied further. The binding of 7D7B10 to human protein C was characterized by a KD of 1.4 nM. In competition studies, it was found that the relative affinity of the antibody for protein C was 20-40-fold higher than for prothrombin, fragment 1 of prothrombin, or factor X. In contrast, 7D7B10 was unable to bind to factor IX or bovine protein C. The effect of varying Ca2+ concentration on the interaction of the antibody with protein C was complex. Low concentrations of Ca2+ enhanced the formation of the protein C-antibody complex with half-maximal effect occurring at approximately 60 microM metal ion. However, higher concentrations of Ca2+ completely inhibited 7D7B10 binding to protein C with a K0.5 of 1.1 mM. Furthermore, millimolar concentrations of Mn2+, Ba2+, or Mg2+ also completely abolished antibody binding to protein C. The location of the epitope was delineated by immunoblotting and peptide studies and found to be present in the NH2-terminal 15 residues of protein C. Although residues corresponding to positions 10-13 of human protein C were necessary for maximal binding of the antibody, they were not sufficient. No evidence could be found for involvement of the epitope in metal binding per se. Therefore, the effect of Ca2+ on antibody binding is thought to be due to metal-dependent conformational changes in protein C. It seems likely that Ca2+ occupation of a high affinity site, shown by others to be located in the epidermal growth factor-like domain, causes a conformational change in the NH2-terminal region of protein C which is favorable for antibody interaction, whereas Ca2+ binding to the low affinity site(s), known to be present in the gamma-carboxyglutamic acid domain, causes an unfavorable conformational change.     

Kinetics of Congo-red binding by haemin-limited and haemin-excess cells of Porphyromonas gingivalis W50

The binding of Congo red to P. gingivalis W50 grown in a chemostat under haemin-limitation and haemin-excess was quantified. Congo red bound to both haemin-excess and haemin-limited cells with similar capacity and affinity. Binding of Congo red was greater than for ferri- (haemin) or ferroprotoporphyrin IX (haem), and was not influenced by redox potential at low added ligand concentrations. Both haemin-limited and haemin-excess cells showed positive co-operativity towards Congo red binding. Pre-exposure of haemin-limited and haemin-excess cells to sub-saturating concentrations of ferriprotoporphyrin IX did not affect Congo red binding, whereas pre-exposure of haemin-excess cells to ferroprotoporphyrin IX increased binding. Iron protoporphyrin IX binding was enhanced after exposure of both haemin-excess and haemin-limited cells to Congo red, especially under reducing conditions. These results confirm that Congo red binding cannot be used as an indirect measure of haemin binding, nor can Congo red be used to inhibit haemin binding to P. gingivalis.     

Metabolic activation of acetylenes. Covalent binding of [1,2-14C]octyne to protein, DNA and haem in vitro and the protective effects of certain thiol compounds

[1,2-14C]Oct-l-yne was used to investigate metabolic activation of the ethynyl substituent in vitro. Activation of octyne by liver microsomal cytochrome P-450-dependent enzymes gave intermediate(s) that bound covalently to protein, DNA and to haem. The time course and extent of covalent binding of octyne to haem and to protein were similar. However, two different activating mechanisms are probably involved. Whereas covalent binding to protein or to DNA was inhibited by nucleophiles such as N-acetylcysteine, that to haem was little affected. When N-acetylcysteine was included in the reaction mixtures, two major octyne-N-acetylcysteine adducts were isolated and purified by high-pressure liquid chromatography. G.l.c.-mass spectrometry and n.m.r. suggest that these are the cis-trans isomers of S-3-oxo-oct-1-enyl-N-acetylcysteine. Oct-1-yn-3-one reacted non-enzymically with N-acetylcysteine at pH 7.4 and 37 degrees C with a t1/2 of about 6 s also to yield S-3-oxo-oct-l-enyl-N-acetylcysteine. The same product was formed when microsomal fractions were incubated with oct-1-yn-3-ol, N-acetylcysteine and NAD(P)+. Octyn-3-one did not appear to react with haem or protoporphyrin IX. 5. A mechanism for the metabolic activation of oct-1-yne is proposed, consisting in (a) microsomal hydroxylation of the carbon atom alpha to the acetylenic bond and (b) oxidation to yield octyn-3-one as the reactive species.     

Kinetics of haem binding to human albumin and haemopexin: nonspecific interactions of haem with proteins

The kinetics of haem binding to human serum albumin and haemopexin were studied by means of the stopped flow technique. The reaction could be divided into three kinetically clearly distinguished steps: (1) extremely fast reaction of haem with nonspecific binding sites on the surface of the apoprotein molecule; this type of haem binding site seems to exist in proteins in general; (2) by meaas of equilibrium with its monomer, haem is transferred to the specific binding site; this second order reaction takes about 1–2 s, the reaction rate constant amounts to ≈10⁶ l mol^?1 s^?1 both for albumin and haemopexin: (3) conformational changes of haemoprotein molecule, accompanied by changes of absorption spectra in the Soret region; this series of slow monomolecular reactions takes about 20 min. These results are discussed in connection with the mechanism of haem transport from blood to liver cells.     

Complexes of bilirubin with proteins

Complexes of bilirubin with chymotrypsin, lysozyme and apomyoglobin in neutral aqueous solution are characterized by circular dichroism spectra in the visible region. These are analogous to previously investigated bilirubin-serum albumin complexes. Ferriprotoporphyrin IX displaces bilirubin from its apomyoglobin complex.