Activation and cleavage of the carbon-cobalt bond of adeninylethylcobalamin by diol dehydrase

Adeninylethylcobalamin (AdeEtCbl) underwent cleavage of the C-Co bond by interaction with apoprotein of diol dehydrase from Klebsiella pneumoniae ATCC 8724, although this analog was quite inactive as coenzyme. Spectroscopic observation indicates that AdeEtCbl was converted to the enzyme-bound hydroxocobalamin without intermediates. The conversion was stoichiometric (1:1) and obeyed the second-order reaction kinetics (k = 0.027 min-1 microM-1 at 37 degrees C) depending upon concentrations of apoprotein and AdeEtCbl. This suggests that the complex formation is the rate-determining step and that AdeEtCbl undergoes rapid C-Co bond cleavage once it binds to the apoenzyme. Substrates and oxygen did apparently not affect the rate of the C-Co bond cleavage. The experiments using [adenine-U-14C]AdeEtCbl and [1(3)-3H]glycerol demonstrated that 9-ethyladenine was the only product formed from the adeninylethyl group of AdeEtCbl during the conversion and that an additional hydrogen atom in the 9-ethyladenine is not derived from the substrate. 1H NMR measurement of the 9-ethyladenine formed enzymatically from AdeEtCbl and DL-1,2-[1,1,2-2H3]propanediol also led to the same conclusion. All of these results indicate that the C-Co bond of AdeEtCbl is activated by diol dehydrase and undergoes heterolysis forming Co(III) and a carbanion or a carbanion-like species, in clear contrast to the homolysis of the C-Co bond of adenosylcobalamin in the normal catalytic process. 9-Ethyladenine formed remained tightly associated with the enzyme. Longer chain homologs, i.e. adeninylpropylcobalamin, adeninylbutylcobalamin, and adeninylpentylcobalamin did not undergo such cleavage of the C-Co bond by diol dehydrase.     

Roles of β-d-ribofuranose ring and the functional groups of the d-ribose moiety of adenosylcobalamin in the diol dehydratase reaction

Four analogs of adenosylcobalamin (AdoCbl) modified in the d-ribose moiety of the Coβ ligand were synthesized, and their coenzyme properties were studied with diol dehydratase of Klebsiella pneumoniae ATCC 8724. 2′-Deoxyadenosylcobalamin (2′-dAdoCbl) and 3′-deoxyadenosylcobalamin (3′-dAdoCbl) were active as coenzyme. 2′,3′-Secoadenosylcobalamin (2′,3′-secoAdoCbl), an analog bearing the same functional groups as AdoCbl but nicked between the 2′ and 3′ in the ribose moiety, and its 2′,3′-dialdehyde derivative (2′,3′-secoAdoCbl dialdehyde) were totally inactive analogs of the coenzyme. It is therefore evident that the β-d-ribofuranose ring itself, possibly its rigid structure, is essential and much more important than the functional groups of the ribose moiety for coenzyme function (relative importance; β-d-ribofuranose ring ⪢ 3′-OH ⪢ 2′-OH ⪢ ether group). With 2′-dAloCbl and 3′-dAdoCbl as enzymes. an absorption peak at 478 nm appeared during enzymatic reaction, suggesting homolysis of the CCo bound to form cob(II)alamin as intermediate. In the absence of substrate, the complexes of the enzyme with these active analogs underwent rapid inactivation by oxygen. This suggests that their CCo bond is activated even in the absence of substrate by binding to the apoprotein. No significant spectral changes were observed with 2′,3′-secoAdoCbl upon binding to the apoenzyme. In contrast, spectroscopic observation indicates that 2′,3′-secoAdoCbl dialdehyde, another inactive analog, underwent gradual and irreversible cleavage of the CCo bond by interaction with the apodiol dehydratase, forming the enzyme-bound cob(II)alamin without intermediates.     

The interaction of adeninylalkylcobalamins with ribonucleotide reductase.

Several structural analogs of adenosylcobalamin, containing 2, 3, 4, 5 and 6 methylene carbons instead of the ribofuranose moiety, have been synthesized and their interaction with ribonucleotide reductase from Lactobacillus leichmannii has been investigated. Kinetic studies of the inhibition of the reductase by these analogs showed that the adeninylalkylcobalamins with 4, 5 and 6 carbons interposed between the adenine moiety and the cobalt atom are potent inhibitors of ribonucleotide reduction. The stronger interaction between adeninylpentylcobalamin and the enzyme than that between adenosylcobalamin and the enzyme suggests that the more flexible acyclic analog of adenosine requires fewer adjustments of the protein upon binding.     

Reaction of alkylcobalamins with thiols

Carbon-13 NMR spectroscopy and phosphorus-31 NMR spectroscopy have been used to study the reaction of several alkylcobalamins with 2-mercaptoethanol. At alkaline pH, when the thiol is deprotonated, the alkyl-transfer reactions involve a nucleophilic attack of the thiolate anion on the Co-methylene carbon of the cobalamins, yielding alkyl thioethers and cob(II)alamin. In these nucleophilic displacement reactions cob(I)alamin is presumably formed as an intermediate. The higher alkylcobalamins react more slowly than methylcobalamin. The lower reactivity of ethyl- and propylcobalamin is probably the basis of the inhibition of the corrinoid-dependent methyl-transfer systems by propyl iodide. The transfer of the upper nucleoside ligand of adenosylcobalamin to 2-mercaptoethanol is a very slow process; S-adenosyl-mercaptoethanol and cob(II)alamin are the final products of the reaction. The dealkylation of (carboxymethyl)cobalamin is a much more facile reaction. At alkaline pH S-(carboxymethyl)mercaptoethanol and cob(II)alamin are produced, while at pH values below 8 the carbon-cobalt bond is cleaved reductively to acetate and cob(II)alamin. The reductive cleavage of the carbon-cobalt bond of (carboxymethyl)cobalamin by 2-mercaptoethanol is extremely fast when the cobalamin is in the "base-off" form. Because we have been unable to detect trans coordination of 2-mercaptoethanol, we favor a mechanism that involves a hydride attack on the Co-methylene carbon of (carboxymethyl)cobalamin rather than a trans attack of the thiol on the cobalt atom.     

Stereochemistry of the acyl dihydroxyacetone phosphate acyl exchange reaction

The fatty acid of acyl dihydroxyacetone phosphate can be exchanged enzymatically for another fatty acid. It has been shown that this reaction proceeds by cleavage of the oxygen bound to C-1 of the dihydroxyacetone phosphate (DHAP) moiety rather than by the more common cleavage at the acyl to oxygen bond. In the present study, the stereochemistry of this reaction was defined further; using deuterated substrates and fast atom bombardment-mass spectrometry, it was shown that the fatty acid exchange involves the stereospecific labilization of the pro-R hydrogen at C-1 of the DHAP moiety of acyl DHAP. The mechanism of ether bond formation, in which acyl DHAP is converted to O-alkyl DHAP, also proceeds via labilization of the pro-R hydrogen and cleavage of the fatty acid at the C-1 to oxygen bond. In addition, other workers have provided evidence that the enzyme responsible for the exchange reaction is O-alkyl DHAP synthetase. Therefore, the present results support the hypothesis that the acyl exchange is the reverse reaction of the first step in O-alkyl DHAP synthesis; in both of these reactions the pro-R hydrogen of C-1 of the DHAP moiety of acyl DHAP and the fatty acid moiety are labilized with cleavage of the fatty acid at the DHAP C-1 to oxygen bond.     

The interaction of adeninylalkycobalamins with ribonucleotide reductase

Several structural analogs of adenosylcobalamin, containing 2, 3, 4, 5 and 6 methylene carbons instead of the ribofuranose moiety, have been synthesized and their interaction with ribonucleotide reductase from Lactobacillus leichmannii has been investigated. Kinetic studies of the inhibition of the reductase by these analogs showed that the adeninylalkylcobalamins with 4, 5 and 6 carbons interposed between the adenine moiety and the cobalt atom are potent inhibitors of ribonucleotide reduction. The stronger interaction between adeninylpentylcobalamin and the enzyme than that between adenosylcobalamin and the enzyme suggests that the more flexible acyclic analog of adenosine requires fewer adjustments of the protein upon binding.     

Stabilization of thermally labile alkylcobalamins by a haptocorrin from chicken serum

Binding of neopentylcobalamin and benzylcobalamin to the apoprotein of a haptocorrin from chicken serum has been demonstrated spectrophotometrically. The spectra of the protein-bound cobalamins strongly resemble those of base-on alkylcobalamins and show that when unbound these sterically hindered alkylcobalamins are only approximately 75% (benzyl) and 40% (neopentyl) base-on, at neutral pH and at 5 degrees C. The haptocorrin was found to stabilize the spontaneous thermal decomposition of the neutral species of benzylcobalamin and neopentylcobalamin by 470-fold (3.6 kcal) and 166-fold (3.0 kcal), respectively, relative to the protein-free species. After correction of the activation parameters for the thermal decomposition of the protein-free, neutral alkylcobalamins for the relative proportions of base-on and base-off species, the haptocorrin was found to stabilize the base-on species of both alkylcobalamins by 275- to 1400-fold (approximately 3.3 to 4.3 kcal). From the temperature dependence of the decomposition reactions, the enthalpies of activation are found to be essentially identical for the protein-free and protein-bound species of either cobalamin. Thus, stabilization of the thermal decomposition of these sterically hindered alkylcobalamins by haptocorrin is entirely due to entropic factors.     

Studies on the mechanism of the adenosylcobalamin-dependent diol dehydrase reaction by the use of analogs of the coenzyme.

A series of 16 analogs of 5'-deoxy-5'-adenosylcobalamin (adenosylcobalamin) were examined for their effects on the diol dehydrase system of Klebsiella pneumoniae (Aerobacter Aerogenes). Four analogs, ara-adenosyl-, aristeromycyl-, 3-isoadenosyl-, and nebularylcobalamin, were able to function as coenzymes in the diol dehydrase reaction, coenzyme activity decreasing in that order. Like the native holoenzyme, complexes of the enzyme with these four analogs show a cob(II)alamin-like absorption peak or shoulder in the presence of 1,2-propanediol. Analogs containing hypoxanthine, cytosine, or benzimidazole do not function as coenzymes, but are weak competitive inhibitors in the presence of adenosylcobalamin. Analogs in which the D-ribosyl moiety is replaced by L-ribose or by an alkyl chain of 2 to 6 carbons are inactive as coenzymes, but act as competitive inhibitors with extremely high affinity for the apoenzyme. Complexes with the inactive analogs showed visible spectra similar to those of the corresponding free cobalamins. Upon anaerobic photolysis and subsequent aeration, complexes with the first group of inactive analogs produced unusually stabilized cob(II)alamin, while complexes with the second group of inactive analogs were readily photolyzed to a hydroxocobalamin-enzyme complex. Complexes with adeninylpentyl- and L-adenosylcobalamin were stable to light under the same conditions. These findings suggest that both the ribose and the adenine moiety of the nucleoside participate in enzyme-coenzyme interaction, involving not only the binding to the apoenzyme but also the activation of the carbon-cobalt bond.     

The synthesis of adenine-modified analogs of adenosylcobalamin and their coenzymic function in the reaction catalyzed by diol dehydrase

Five analogs of adenosylcobalamin modified in the adenine moiety of the Co beta ligand were synthesized and tested for coenzymic function with diol dehydrase of Klebsiella pneumoniae ATCC 8724. 1-Deaza and 3-deaza analogs of adenosylcobalamin were active as coenzyme, whereas 7-deaza and N6,N6-dimethyl derivatives and guanosylcobalamin did not show detectable coenzymic activity. 7-Deaza and N6,N6-dimethyl analogs acted as strong competitive inhibitors with respect to adenosylcobalamin. The formation of cob(II)alamin as intermediate in the catalytic reaction was spectroscopically observed with catalytically active complexes of the enzyme with 1-deaza and 3-deaza analogs in the presence of 1,2-propanediol, but not with complexes with the inactive analogs. Oxygen sensitivity of the enzyme-analog complexes suggests that the carbon-cobalt bond of 1-deaza and 3-deaza analogs becomes activated by the enzyme even in the absence of substrate. These results indicate that the importance of the nitrogen atoms in the adenine moiety of the coenzyme for manifestation of catalytic function and for activation of the carbon-cobalt bond decreases in the following order: N-7 greater than 6-NH2 greater than N-3 greater than N-1. The dissociation constant for 5'-deoxyadenosine determined by equilibrium dialysis at 37 degrees C was about 23 microM.     

Crystal Structures of Ethanolamine Ammonia-lyase Complexed with Coenzyme B12 Analogs and Substrates

N-terminal truncation of the Escherichia coli ethanolamine ammonia-lyase β-subunit does not affect the catalytic properties of the enzyme (Akita, K., Hieda, N., Baba, N., Kawaguchi, S., Sakamoto, H., Nakanishi, Y., Yamanishi, M., Mori, K., and Toraya, T. (2010) J. Biochem. 147, 83–93). The binary complex of the truncated enzyme with cyanocobalamin and the ternary complex with cyanocobalamin or adeninylpentylcobalamin and substrates were crystallized, and their x-ray structures were analyzed. The enzyme exists as a trimer of the (αβ)₂ dimer. The active site is in the (β/α)₈ barrel of the α-subunit; the β-subunit covers the lower part of the cobalamin that is bound in the interface of the α- and β-subunits. The structure complexed with adeninylpentylcobalamin revealed the presence of an adenine ring-binding pocket in the enzyme that accommodates the adenine moiety through a hydrogen bond network. The substrate is bound by six hydrogen bonds with active-site residues. Argα¹⁶⁰ contributes to substrate binding most likely by hydrogen bonding with the O1 atom. The modeling study implies that marked angular strains and tensile forces induced by tight enzyme-coenzyme interactions are responsible for breaking the coenzyme Co–C bond. The coenzyme adenosyl radical in the productive conformation was modeled by superimposing its adenine ring on the adenine ring-binding site followed by ribosyl rotation around the N-glycosidic bond. A major structural change upon substrate binding was not observed with this particular enzyme. Gluα²⁸⁷, one of the substrate-binding residues, has a direct contact with the ribose group of the modeled adenosylcobalamin, which may contribute to the substrate-induced additional labilization of the Co–C bond.     

The synthesis and properties of four spin-labeled analogs of adenosylcobalamin

Four spin-labeled analogs of adenosylcobalamin have been synthesized to aid in the detection and identification of radical intermediates in the adenosylcobalamin-dependent enzymatic reactions and to serve as probes of the coenzyme, substrate, and effector binding sites of the protein. Three isomers of adenosylcobalamin, in which one of the propionamide side chains (b, d, or e) was hydrolyzed, and adenosylepicobalamin e-carboxylic acid were reacted with 4-amino-2,2,6,6-tetramethylpiperidine-N-oxyl in the presence of 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide to yield the spin-labeled adenosylcorrinoids. These spin-labeled derivatives of adenosylcobalamin function as coenzymes and/or inhibitors of dioldehydrase from Klebsiella pneumoniae and of ribonucleotide reductase from Corynebacterium nephridii. Electron spin resonance has been used to monitor the photolytic cleavage of the carbon-cobalt bond of these analogs.     

Emission M?ssbauer studies of some organocobalamins

Subtle changes in the M?ssbauer parameters are observed while going from methyl- to ethyl- to adenosylcobalamin, and also when the "base" is detached from the cobalt. The observation of these changes demonstrates that the Co-C bond, among others, remains intact after the Auger event, accompanying the electron-capture decay of the cobalt-57. The differences between ethylcobalamin and the other two organocobalamins in the magnitude of the quadrupole splittings have been interpreted on the basis of the sigma-donating tendency of the organic moiety and the Co-C bond length. The latter is presumably determined by the steric hindrance offered to the group in approaching the cobalt atom. The ethyl- and adenosylcobalamins in their "base-off" form exhibit a larger quadrupole splitting than the corresponding "base-on" form. In the "bas-off" form, the cobalt atom is perhaps raised above the mean plane of the four equatorial nitrogen atoms of the corrin ring, which may result in the diminution of the delocalization of the 3dpi electron density. The higher population of dpi orbitals and the enhanced metallic character of the dz2, resulting from shrinkage of the Co-C bond length, enhances the magnitude of the quadrupole splitting.     

Functions of the D-ribosyl moiety and the lower axial ligand of the nucleotide loop of coenzyme B(12) in diol dehydratase and ethanolamine ammonia-lyase reactions

The roles of the D-ribosyl moiety and the bulky axial ligand of the nucleotide loop of adenosylcobalamin in coenzymic function have been investigated using two series of coenzyme analogs bearing various artificial bases. The 2-methylbenzimidazolyl trimethylene analog that exists exclusively in the base-off form was a totally inactive coenzyme for diol dehydratase and served as a competitive inhibitor. The benzimidazolyl trimethylene analog and the benzimidazolylcobamide coenzyme were highly active for diol dehydratase and ethanolamine ammonia-lyase. The imidazolylcobamide coenzyme was 59 and 9% as active as the normal coenzyme for diol dehydratase and ethanolamine ammonia-lyase, respectively. The latter analog served as an effective suicide coenzyme for both enzymes, although the partition ratio (k(cat)/k(inact)) of 630 for ethanolamine ammonia-lyase is much lower than that for diol dehydratase. Suicide inactivation was accompanied by the accumulation of a cob(II)amide species, indicating irreversible cleavage of the coenzyme Co-C bond during the inactivation. It was thus concluded that the bulkiness of a Co-coordinating base of the nucleotide loop is essential for both the initial activity and continuous catalytic turnovers. Since the k(cat)/k(inact) value for the imidazolylcobamide in diol dehydratase was 27-times higher than that for the imidazolyl trimethylene analog, it is clear that the ribosyl moiety protects the reaction intermediates from suicide inactivation. Stopped-flow measurements indicated that the rate of Co-C bond homolysis is essentially unaffected by the bulkiness of the Co-coordinating base for diol dehydratase. Thus, it seems unlikely that the Co-C bond is labilized through a ground state mechanochemical triggering mechanism in diol dehydratase.     

Computational study on the difference between the Co–C bond dissociation energy in methylcobalamin and adenosylcobalamin

The bond dissociation energies of the Co–C bonds in the cobalamin cofactors methylcobalamin and adenosylcobalamin were calculated using the hybrid quantum mechanics/molecular mechanics method IMOMM (integrated molecular orbital and molecular mechanics). Calculations were performed on models of differing complexities as well as on the full systems. We investigated the origin of the different experimental values for the Co–C bond dissociation energies in methylcobalamin and adenosylcobalamin, and have provided an explanation for the difficulties encountered when we attempt to reproduce this difference in quantum chemistry. Additional calculations have been performed using the Miertus–Scrocco–Tomasi method in order to estimate the influence of solvent effects on the homolytic Co–C bond cleavage. Introduction of these solvation effects is shown to be necessary for the correct reproduction of experimental trends in bond dissociation energies in solution, which consequently have no direct correlation with dissociation processes in the enzyme.     

Relevance of weak flavin binding in human D‐amino acid oxidase

In the brain, the human flavoprotein D ‐amino acid oxidase (hDAAO) is involved in the degradation of the gliotransmitter D ‐serine, an important modulator of NMDA‐receptor‐mediated neurotransmission; an increase in hDAAO activity (that yields a decrease in D ‐serine concentration) was recently proposed to be among the molecular mechanisms leading to the onset of schizophrenia susceptibility. This human flavoenzyme is a stable homodimer (even in the apoprotein form) that distinguishes from known D ‐amino acid oxidases because it shows the weakest interaction with the flavin cofactor in the free form. Instead, cofactor binding is significantly tighter in the presence of an active site ligand. In order to understand how hDAAO activity is modulated, we investigated the FAD binding process to the apoprotein moiety and compared the folding and stability properties of the holoenzyme and the apoprotein forms. The apoprotein of hDAAO can be distinguished from the holoenzyme form by the more “open” tertiary structure, higher protein fluorescence, larger exposure of hydrophobic surfaces, and higher sensitivity to proteolysis. Interestingly, the FAD binding only slightly increases the stability of hDAAO to denaturation by urea or temperature. Taken together, these results indicate that the weak cofactor binding is not related to protein (de)stabilization or oligomerization (as instead observed for the homologous enzyme from yeast) but rather should represent a means of modulating the activity of hDAAO. We propose that the absence in vivo of an active site ligand/substrate weakens the cofactor binding, yielding the inactive apoprotein form and thus avoiding excessive D ‐serine degradation.     

The mechanism of adenosylcobalamin-dependent rearrangements

Adenosylcobalamin (AdoCbl)-dependent rearrangements are a group of reactions with no obvious precedents in organic chemistry. In every case, they are characterized by a mechanism in which a hydrogen atom on one carbon atom exchanges places with a group X on an adjacent carbon: (formula; see text) Much experimental work indicates that an AdoCbl rearrangement is initiated by homolysis of the C-Co bond of the cofactor. The migrating hydrogen is then abstracted from the substrate by the resulting 5'-deoxyadenosyl radical, or by a second radical that is generated elsewhere at the active site, and, after the migration of group X, is returned to the product in a similar reaction. In at least some of the rearrangements, group X migration may occur via a cation radical intermediate that formed by the departure of X with its electrons, a process assisted by the unpaired electron left behind on the adjacent carbon after the abstraction of the migrating hydrogen. Once C-Co bond cleavage has initiated the reaction by producing a free radical at the active site, the corrin ring plays no further role in the rearrangements.     

Distinction in the mode of receptor-mediated endocytosis between high density lipoprotein and acetylated high density lipoprotein: evidence for high density lipoprotein receptor-mediated cholesterol transfer

The interactions of high density lipoprotein (HDL) and acetylated high density lipoprotein (acetyl-HDL) with isolated rat sinusoidal liver cells have been investigated. Cellular binding of 125I-acetyl-HDL at 0 degrees C demonstrated the presence of a specific, saturable membrane-associated receptor. This receptor was affected neither by formaldehyde-treated albumin nor by low density lipoprotein modified either by acetylation or malondialdehyde, ligands known to undergo receptor-mediated endocytosis by the cells, indicating that the receptor for acetyl-HDL constitutes a distinct class among the scavenger receptors for chemically modified proteins. Parallel binding experiments using 125I-HDL also revealed the presence on these cells of a receptor for unmodified HDL. The ligand specificities of these two receptors were similar to each other except that the acetyl-HDL receptor was sensitive to polyanions such as dextran sulfate and fucoidin. Interaction of HDL with the cells at 37 degrees C was totally different from that of acetyl-HDL. Cellular binding of HDL was not accompanied by subsequent intracellular degradation of its apoprotein moiety, whereas its cholesterol moiety was significantly transferred to the cells. In contrast, acetyl-HDL was endocytosed and underwent lysosomal degradation as a holoparticle. This shift in receptor-recognition from the HDL receptor to the acetyl-HDL receptor was accomplished by acetylation of approximately 8% of the total lysine residues of HDL apoprotein. This unique difference in endocytic behavior between HDL and acetyl-HDL suggests a potential link of the HDL receptor to HDL-mediated cholesterol transfer in sinusoidal liver cells.     

In situ reactivation of glycerol-inactivated coenzyme B12-dependent enzymes, glycerol dehydratase and diol dehydratase.

The catalytic properties of coenzyme B12-dependent glycerol dehydratase and diol dehydratase were studied in situ with Klebsiella pneumoniae cells permeabilized by toluene treatment, since the in situ enzymes approximate the in vivo conditions of the enzymes more closely than enzymes in cell-free extracts or cell homogenates. Both dehydratases in situ underwent rapid "suicidal" inactivation by glycerol during catalysis, as they do in vitro. The inactivated dehydratases in situ, however, were rapidly and continually reactivated by adenosine 5'-triphosphate (ATP) and Mn2+ in the presence of free adenosylcobalamin, although in cell-free extracts or in cell homogenates they could not be reactivated at all under the same reaction conditions. ATP was partially replaced by cytidine 5'-triphosphate or guanosine 5'-triphosphate but not by the beta, gamma-methylene analog of ATP in the in situ reactivation. Mn2+ was fully replaced by Mg2+ but only partially by Co2+. Hydroxocoblamin could not replace adenosylcobalamin in reactivation mixtures. The ability to reactivate the glycerol-inactivated dehydratases in situ was only seen in cells grown anaerobically in glycerol-containing media. This suggests that some factor(s) required for in situ reactivation is subject to induction by glycerol. Of the two possible mechanisms of in situ reactivation, i.e., the regeneration of adenosylcobalamin by Co-adenosylation of the bound inactivated coenzyme moiety (B12-adenosylation mechanism) and the displacement of the bound inactivated coenzyme moiety by free adenosyl-cobalamin (B12-exchange mechanism), the former seems very unlikely from the experimental results.     

Recombination of human erythrocyte apoprotein and lipid. I. Interaction of apoprotein and lipid at the air-water interface

The formation and stabilization of a complex between total erythrocyte apoprotein and monolayers of total erythrocyte lipid as measured by changes of surface pressure (Δπ) and rate of change of surface pressure (dπ/dt) was studied as a function of pH, ionic strength, and lipid surface pressure. Penetration of apoprotein into lipid monolayers was favored by conditions in which lipid and apoprotein were oppositely charged. Once the interaction was completed, the resultant surface complex was resistant to large changes in subphase pH and ionic strength as shown by the insensitivity of Δπ to these parameters. The dπ/dt, however, showed strong dependence on pH and ionic strength, but not on lipid surface pressure. A sharp decrease in dπ/dt around pH 3.5–4.5 is associated with the change in apoprotein charge from (+) to (?). Comparison of complex formation between apoprotein and bovine serum albumin, cytochrome c, and human hemoglobin suggests that erythrocyte apoprotein was specialized in its interaction with erythrocyte lipids. The data show that formation of an apoprotein-lipid complex at the air-water interface has both electrostatic and hydrophobic components. This contradicts results from other laboratories studying erythrocyte membrane recombination by bulk methods.     

Studies on the composition of pig serum lipoproteins. Isolation and characterization of different apoproteins.

1. Different lipoprotein density fractions from pig serum were isolated by phosphotungstate precipitation followed by purification in the preparative ultra-centrifuge. 2. The protein part of very low density lipoproteins was composed of approximately 52 percent lipoprotein B apoprotein and the rest of lipoprotein C II apoprotein and other as yet unidentified peptides. 3. The protein moiety of low density lipoproteins consisted primarily of lipoprotein B apoprotein (over 95 percent); the amino acid compositions of lipoprotein B apoprotein of very low and low density lipoproteins were practically identical. 4. The predominant polypeptide of pig serum high density lipoproteins exhibited an amino acid composition and a molecular weight very similar to human liprotein A I apoprotein. In contrast to human lipoprotein A I apoprotein, the apoprotein from pigs was found to release leucine first followed by alanine, threonine, and lysine upon incubation with carboxypeptidase A. 5. In pig serum the major lipoprotein C apoprotein was found to be a polypeptide similar in amino acid composition to lipoprotein C II apoprotein from human serum. The molecular weight of this polypeptide is approximately 8000. Incubation experiments with carboxypeptidase A indicate serine to be the most likely C-terminal amino acid.