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Start Over Author "Margoliash, E." Publisher elsevier inc. on behalf of american society for biochemistry and molecular biology
53 results on '"Margoliash, E."'

1. Determinants of cytochrome c pro-apoptotic activity. The role of lysine 72 trimethylation.

Author

Kluck RM, Ellerby LM, Ellerby HM, Naiem S, Yaffe MP, Margoliash E, Bredesen D, Mauk AG, Sherman F, and Newmeyer DD

Subjects
Amino Acid Sequence, Animals, Horses, Lysine analogs & derivatives, Lysine metabolism, Methylation, Mitochondria metabolism, Models, Molecular, Molecular Sequence Data, Oocytes, Peptide Hydrolases metabolism, Protein Isoforms, Sequence Homology, Amino Acid, Xenopus, Apoptosis, Cytochrome c Group metabolism, Cytochromes c, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins
Abstract

Cytochrome c released from vertebrate mitochondria engages apoptosis by triggering caspase activation. We previously reported that, whereas cytochromes c from higher eukaryotes can activate caspases in Xenopus egg and mammalian cytosols, iso-1 and iso-2 cytochromes c from the yeast Saccharomyces cerevisiae cannot. Here we examine whether the inactivity of the yeast isoforms is related to a post-translational modification of lysine 72, N-epsilon-trimethylation. This modification was found to abrogate pro-apoptotic activity of metazoan cytochrome c expressed in yeast. However, iso-1 cytochrome c lacking the trimethylation modification also was devoid of pro-apoptotic activity. Thus, both lysine 72 trimethylation and other features of the iso-1 sequence preclude pro-apoptotic activity. Competition studies suggest that the lack of pro-apoptotic activity was associated with a low affinity for Apaf-1. As cytochromes c that lack apoptotic function still support respiration, different mechanisms appear to be involved in the two activities.

Published
2000
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2. Cytochrome c heme lyase activity of yeast mitochondria.

Author

Tong J and Margoliash E

Subjects
Animals, Apoproteins genetics, Apoproteins metabolism, Cytochrome c Group genetics, Cytochrome c Group metabolism, Cytochromes c, Enzyme Inhibitors pharmacology, Hemin metabolism, Kinetics, Lyases antagonists & inhibitors, Mutagenesis, Site-Directed, Oxidation-Reduction, Protein Binding genetics, Reducing Agents pharmacology, Cytochrome c Group biosynthesis, Drosophila melanogaster chemistry, Lyases metabolism, Mitochondria enzymology, Saccharomyces cerevisiae enzymology
Abstract

A highly efficient in vitro system was established for measuring by high performance liquid chromatography the formation of holocytochrome c by yeast mitochondria. Holocytochrome c formation required reducing agents, of which dithiothreitol was the most effective. With biosynthetically made, pure Drosophila melanogaster apocytochrome c and Saccharomyces cerevisiae mitochondria, the activity of cytochrome c heme lyase amounted to about 800 fmol min-1 mg-1 mitochondrial protein. The kinetics were typical Michaelis-Menten (Km approximately 1 nM), as were those of mitoplasts with broken outer membranes (Km approximately 3 nM). As tested with mitoplasts, holocytochromes c from a range of species were found to be competitive inhibitors of heme lyase at physiological concentrations, providing a mechanism for controlling this concentration in vivo. Apocytochrome c associated with yeast mitochondria in two phases of Kd approximately 2 x 10(-10) and 10(-8) M, respectively, whereas mitoplasts had lost the high affinity binding. A site-directed mutant of apocytochrome c (lysines 5, 7, and 8 replaced by glutamine, glutamic acid, and asparagine) was found to be converted to holocytochrome c (Km approximately 3.3 nM; maximal activity unchanged), even though the mutations completely eliminated the high affinity binding. Thus, the high affinity binding of apocytochrome c to mitochondria is not directly related to holocytochrome c formation.

Published
1998
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3. Crystallization of tuna ferricytochrome c at low ionic strength.

Author

Walter MH, Westbrook EM, Tykodi S, Uhm AM, and Margoliash E

Subjects
Animals, Crystallization, Hydrogen-Ion Concentration, Osmolar Concentration, Polyethylene Glycols, X-Ray Diffraction, Cytochrome c Group, Fishes metabolism, Tuna metabolism
Abstract

Previous crystallographic studies of tuna ferricytochrome c have employed crystals grown from solutions of ammonium sulfate, corresponding to an ionic strength of 9.5 M (Takano, T., and Dickerson, R. E. (1981) J. Mol. Biol. 153, 95-115). To obtain a structure at a lower ionic strength, the ferric tuna protein was crystallized at neutral pH with polyethylene glycol at an ionic strength of 45 mM, These crystals (space group P2(1), a = 37.11 A, b = 107.66 A, c = 55.75 A, beta = 105.3 degrees) contain four molecules/asymmetric unit and grow to dimensions of 0.2 X 0.4 X 1.0 mm in 2-4 weeks. They diffract to beyond 1.8 A and are stable in the x-ray beam. We have recorded 28,198 unique Bragg reflections (83% of those possible) to a resolution of 1.89 A from a native crystal. We are undertaking a solution of this structure by the molecular replacement method.

Published
1990

4. Electron paramagnetic and electron nuclear double resonance of the hydrogen peroxide compound of cytochrome c peroxidase.

Author

Hoffman BM, Roberts JE, Kang CH, and Margoliash E

Subjects
Binding Sites, Electron Spin Resonance Spectroscopy, Magnetic Resonance Spectroscopy, Mathematics, Protein Binding, Protein Conformation, Saccharomyces cerevisiae enzymology, Cytochrome-c Peroxidase, Hydrogen Peroxide, Peroxidases
Abstract

We have collected electron paramagnetic resonance (EPR) and electron nuclear double resonance (ENDOR) spectra from the hydrogen peroxide compound of yeast cytochrome c peroxidase, termed ES, employing EPR microwave frequencies of 9.6 and 11.6 GHz. We have measured and analyzed the temperature dependence of the spin-lattice relaxation rate (1/T1) of the paramagnetic center of ES over the temperature range 1.9 to 4 K. In addition, an upper bound to exchange coupling between the ferryl heme and EPR-visible centers of ES has been calculated and expressions for the dipolar interaction between a ferryl heme and a free radical have been derived. These results all confirm that the EPR signal of ES is not associated with an aromatic amino acid radical, and in particular not with a tryptophanyl radical. This conclusion has led us to consider an explanation of the EPR signal in terms of a nucleophilically stabilized methionyl radical.

Published
1981

5. Multiple low spin forms of the cytochrome c ferrihemochrome. EPR spectra of various eukaryotic and prokaryotic cytochromes c.

Author

Brautigan DL, Feinberg BA, Hoffman BM, Margoliash E, Preisach J, and Blumberg WE

Subjects
Animals, Azides, Binding Sites, Cyanides, Electron Spin Resonance Spectroscopy, Euglena enzymology, Horses, Hydrogen-Ion Concentration, Imidazoles, Ligands, Myocardium enzymology, Paracoccus denitrificans enzymology, Protein Binding, Protein Conformation, Rhodospirillum rubrum enzymology, Species Specificity, Spectrophotometry, Tuna, Cytochrome c Group
Abstract

1. Despite the same methionine-sulfur:heme-iron:imidazole-nitrogen hemochrome structure observed by x-ray crystallography in four of the seven c-type eukaryotic and prokaryotic cytochromes examined, and the occurrence of the characteristic 695 nm absorption band correlated with the presence of a methionine-sulfur:heme-iron axial ligand in all seven proteins, they fall into two distinct classes on the basis of their EPR and optical spectra. The horse, tuna, and bakers' yeast iso-1 cytochromes c have a predominant neutral pH EPR form with g1=3.06, g2=2.26, and g3=1.25, while the bakers' yeast iso-2 and Euglena cytochromes c, the Rhodospirillum rubrum cytochrome c2, and the Paracoccus denitrificans cytochrome c550 all have a predominant neutral pH EPR form with g1=3.2, g2=2.05, and g3=1.39. The ferricytochromes with g1=3.06 have a B-Q splitting that is approximately 150 cm-1 larger than the ferricytochromes with g1=3.2. 2. Each of the cytochromes displays up to four low spin EPR forms that are in pH-dependent equilibrium and can all be observed at near neutral pH. As the pH is raised the predominant neutral pH form is converted into two forms with g1=3.4 and g1=3.6, identified by comparsion with model compounds and other heme proteins as epsilon-amino:heme-iron:imidazole and bis-epsilon-amino:heme-iron ferrihemochromes, respectively. 3. The pK for the conversion of the predominant neutral pH EPR form into the alkaline pH forms is the same as the pK for the disappearance of the 695 nm absorption band for the cytochromes, even though these pK values range over 2 pH units. This confirms that the g1=3.06 and g1=3.2 forms contain the methionine-sulfur:heme-iron axial ligand while the g1=3.4 and the g1=3.6 forms do not. 4. At extremes of pH, the horse and bakers' yeast iso-1 proteins display several high and low spin forms that are identified, showing that a variety of protein-derived ligands will coordinate to the heme iron including methionine and cysteine sulfur, histidine imidazole, and lysine epsilon-amine. 5. The spectrum of horse cytochrome c with added azide, cyanide, hydroxide, or imidazole as axial ligands has also been examined. 6. From a comparison of the EPR and optical spectral characteristics of these groups of cytochromes with model compounds, it is suggested that the difference between them is due to a change in the hydrogen bonding or perhaps even in the protonation of N-1 of the heme iron-bound histidine imidazole.

Published
1977

6. Conformational stability of ferrocytochrome c. Electrostatic aspects of the oxidation by tris(1,10-phenanthroline)cobalt(III) at low ionic strength.

Author

Rush JD, Koppenol WH, Garber EA, and Margoliash E

Subjects
Algorithms, Animals, Horses, Osmolar Concentration, Oxidation-Reduction, Protein Conformation, Cytochrome c Group, Organometallic Compounds, Phenanthrolines
Abstract

At ionic strengths below 0.1 M the oxidation of horse ferrocytochrome c by tris(1,10-phenanthroline)cobalt (III) and tris(2,2'-bipyridine)cobalt(III) proceeds by a pathway which is independent of the transition metal complex concentration. Formation of an activated form of the protein appears to be rate limiting. The rate of oxidation decreases as the ionic strength increases. This dependence of the reaction rate on inert electrolyte concentration indicates that electrostatic association of anions under physiological ionic strength confers stability to the protein. The activated form of the protein, which reacts at least 10(4) times as fast as the predominant form, is thought to be a conformation of the reduced protein with an open heme crevice. Binding of the open form of ferrocytochrome c with the redox-inactive cationic transition metal complexes hexamminecobalt(III) and tris(1,10-phenanthroline)chromium(III) inhibits the oxidation by tris(1,10-phenanthroline)cobalt(III). Reactions of tris(1,10-phenanthroline)cobalt(III) with 4-carboxy-2,5-dinitrophenyllysine 13 and 72 ferrocytochromes c show no dependence on ionic strength. NMR studies at pH 7 demonstrate that ferricytochrome c is partly (15%) in the open conformation at low ionic strength. Furthermore, the interaction of redox-inert tris (1,10-phenanthroline)chromium(III) with ferricytochrome c under conditions identical to those of the kinetic studies demonstrates that the transition metal complex binds only to the open form of the protein. Titration with increasing amounts of tris(1,10-phenanthroline) chromium(III) shows changes in the NMR spectrum that are inconsistent with a single binding site.

Published
1988

7. Definitaion of cytochrome c binding domains by chemical modification. Reaction of carboxydinitrophenyl- and trinitrophenyl-cytochromes c with baker's yeast cytochrome c peroxidase.

Author

Kang CH, Brautigan DL, Osheroff N, and Margoliash E

Subjects
Binding Sites, Cytochrome c Group metabolism, Kinetics, Lysine analogs & derivatives, Models, Molecular, Nitrobenzoates, Osmolar Concentration, Saccharomyces cerevisiae enzymology, Trinitrobenzenes, Cytochrome c Group analogs & derivatives, Cytochrome-c Peroxidase metabolism, Peroxidases metabolism
Published
1978

8. Amino acid sequence of Paracoccus denitrificans cytochrome c550.

Author

Timkovich R, Dickerson RE, and Margoliash E

Subjects
Amino Acid Sequence, Models, Molecular, Peptide Fragments analysis, Species Specificity, Trypsin, Cytochrome c Group, Paracoccus denitrificans metabolism
Abstract

The amino acid sequence of Paracoccus (formerly Micrococcus) denitrificans cytochrome c550 has been established by a combination of standard chemical techniques and interpretation of a 2.5 A resolution x-ray electron density map. Peptides derived from a trypsin digest were chemically sequenced, and then ordered by fitting them to the density map. The amino acid compositions of chymotryptic peptides confirmed the x-ray map ordering the tryptic peptides. The amino acid sequence of this respiratory, prokaryotic cytochrome with 134 residues is discussed in relation to those of eukaryotic respiratory cytochrome c (103 to 113 amino acids), and prokaryotic, photosynthetic c2 (103 to 124 amino acids). At the primary structure level, c and c550 differ no more from cytochromes c2 than the various cytochromes c2 do from one another. It is suggested that the respiratory electron transport chain in prokaryotes and eukaryotes is a relatively late evolutionary offshoot of the photosynthetic electron transport chain in purple non-sulfur bacteria.

Published
1976

11. Preferred sites for electron transfer between cytochrome c and iron and cobalt complexes.

Author

Butler J, Chapman SK, Davies DM, Sykes AG, Speck SH, Osheroff N, and Margoliash E

Subjects
Chemical Phenomena, Chemistry, Cytochrome c Group analogs & derivatives, Electrochemistry, Electron Transport, Kinetics, Structure-Activity Relationship, Cobalt metabolism, Cytochrome c Group metabolism, Cytochromes c, Ferricyanides metabolism, Lysine analogs & derivatives, Organometallic Compounds, Phenanthrolines metabolism
Abstract

The kinetics of oxidation of eight different singly substituted 4-carboxy-2,6-dinitrophenyl (CDNP) horse ferrocytochromes c, modified at lysine 7, 13, 25, 27, 60, 72, 86, or 87, and of one trinitrophenyl horse ferrocytochrome c, modified at lysine 13, by the 3- and 3+ inorganic complexes hexacyanoferrate(III) (Fe(CN)6(3-) ) and tris(1,10-phenanthroline)cobalt(III) (Co(phen)3(3+) ) have been characterized. The influence of the modified residues on the bimolecular rate constants for these reactions define the protein molecular surface involved. The site of electron exchange for both oxidants appears to be the solvent accessible edge of the heme prosthetic group or a closely related structure on the "front" surface of the molecule. The reaction with Fe(CN)6(3-) is most strongly influenced by modification of lysine 72, a residue to the left of the exposed heme edge. (CDNP lysine 72 cytochrome c yields a 3.6-fold decrease in the bimolecular rate constant, as compared to that for the native protein.) However, it is the region around lysine 27, to the right of the heme edge, that is most influential in the reaction with Co(phen)3(3+). (CDNP-lysine 27 cytochrome c exhibits a 7.3-fold increase in the rate constant, as compared to that for the native protein.) The kinetics of reaction of the CDNP-lysine 13, 60, 72, and 87 modified cytochromes c with Fe(CN)5(4-aminopyridine)2- as oxidant and Fe(CN)5(4-aminopyridine)3- and Fe(CN)5-(imidazole)3- as reductants have also been determined and further illustrate the influence of electrostatics on the kinetics of such protein-small molecule electron exchanges.

Published
1983

12. Correlation of the kinetics of electron transfer activity of various eukaryotic cytochromes c with binding to mitochondrial cytochrome c oxidase.

Author

Ferguson-Miller S, Brautigan DL, and Margoliash E

Subjects
Animals, Binding Sites, Cattle, Electron Transport, Euglena enzymology, Horses, Hydrogen-Ion Concentration, Kinetics, Mitochondria, Muscle enzymology, Myocardium, Phospholipids analysis, Protein Binding, Saccharomyces cerevisiae enzymology, Species Specificity, Cytochrome c Group metabolism, Electron Transport Complex IV metabolism, Mitochondria enzymology
Abstract

1. A detailed study of cytochrome c oxidase activity with Keilin-Hartree particles and purified beef heart enzyme, at low ionic strength and low cytochrome c concentrations, showed biphasic kinetics with apparent Km1 = 5 x 10(-8) M, and apparent Km2 = 0.35 to 1.0 x 10(-6) M. Direct binding studies with purified oxidase, phospholipid-containing as well as phospholiptaining aid-depleted, demonstrated two sites of interaction of cytochrome c with the enzyme, with KD1 less than or equal to 10(-7) M, and KD2 = 10(-6) M. 2. The maximal velocities as low ionic strength increased with pH and were highest above ph 7.5. 3. The presence and properties of the low apparent Km phase of the kinetics were strongly dependent on the nature and concentration of the anions in the medium. The multivalent anions, phosphate, ADP, and ATP, greatly decreased the proportion of this phase and similarly decreased the amount of high affinity cytochrome c-cytochrome oxidase complex formed. The order of effectiveness was ATP greater than ADP greater than P1 and since phosphate binds to cytochrome c more strongly than the nucleotides, it is concluded that the inhibition resulted from anion interaction with the oxidase. 4mat low concentrations bakers' yeast iso-1, bakers' yeast iso-1, horse, and Euglena cytochromes c at high concentrations all attained the same maximal velocity. The different proportions of low apparent Km phase in the kinetic patterns of these cytochromes c correlated with the amounts of high affinity complex formed with purified cytochrome c oxidase. 5. The apparent Km for cytochrome c activity in the succinate-cytochrome c reductase system of Keilin-Hartree particles was identical with that obtained with the oxidase (5 x 10(-8) M), suggesting the same site serves both reactions. 6. It is concluded that the observed kinetics result from two catalytically active sites on the cytochrome c oxidase protein of different affinities for cytochrome c. The high affinity binding of cytochrome c to the mitochondrial membrane is provided by the oxidase and at this site cytochrome c can be reduced by cytochrome c1. Physiological concentrations of ATP decrease the affinity of this binding to the point that interaction of cytochrome c with numerous mitochondrial pholpholipid sites can competitively remove cytochrome c from the oxidase. It is suggested that this effect of ATP represents a possible mechanism for the control of electron flow to the oxidase.

Published
1976

13. Control of the transfer of oxidizing equivalents between heme iron and free radical site in yeast cytochrome c peroxidase.

Author

Ho PS, Hoffman BM, Kang CH, and Margoliash E

Subjects
Dithionite pharmacology, Electron Spin Resonance Spectroscopy, Free Radicals, Iron metabolism, Kinetics, Oxygen Consumption, Protein Binding, Spectrophotometry, Cytochrome-c Peroxidase metabolism, Heme metabolism, Peroxidases metabolism, Saccharomyces cerevisiae enzymology
Abstract

A procedure has been developed for obtaining yeast cytochrome c peroxidase with the heme iron in the Fe(IV) state, without the concomitant formation of the protein free radical that occurs in the ES compound resulting from the oxidation of ferric peroxidase with hydrogen peroxide. In this procedure, ferrous peroxidase, prepared either by photochemical reduction or by trapping the dithionite-reduced enzyme with carbon monoxide, is oxidized with a stoichiometric amount of hydrogen peroxide. The resulting Fe(IV) enzyme oxidizes ferrocyanide monophasically, with a rate constant of 4 x 10(3) M-1 S-1. The optical spectrum of the free radical was obtained as the difference between the spectra of the ES and Fe(IV) compounds. EPR spectra of ES compound prepared with [16O]-and [17O]hydrogen peroxide are identical, demonstrating that no fragment of the oxidant is associated with the free radical. The heme in the Fe(IV) enzyme is stable and does not oxidize the free radical site either intra- or intermolecularly. On the other hand, previous results from the presteady state kinetics of reduction and reductive titrations of the ES compound with ferrocyanide imply that the heme and free radical sites exchange oxidizing equivalents, in particular that the radical site once reduced can be reoxidized, either intra- or intermolecularly, by the ferryl heme. To resolve these contradictions, we propose a catalytic mechanism for cytochrome c peroxidase in which the radical site can exist in two conformations having very different reduction potentials and in which a significant flow of oxidizing equivalents between heme and free radical sites occurs only (i) during the hydrogen peroxide oxidation of the resting Fe(III) enzyme to form compound ES and (ii) within the initial transient intermediate formed upon the one-electron reduction of this oxidized product.

Published
1983

15. Site-specific anti-cytochrome c antibodies. Inhibition of the reactions between cytochrome c and its respiratory chain electron exchange partners.

Author

Osheroff N, Jemmerson R, Speck SH, Ferguson-Miller S, and Margoliash E

Subjects
Animals, Antigen-Antibody Complex, Cytochrome c Group immunology, Electron Transport, Horses, Immunoglobulin Fab Fragments, Kinetics, Models, Molecular, Protein Conformation, Rabbits immunology, Antibodies, Binding Sites, Antibody, Cytochrome c Group metabolism, Epitopes
Published
1979

16. Heterogeneity of amino acid sequence in hippopotamus cytochrome c.

Author

Thompson RB, Borden D, Tarr GE, and Margoliash E

Subjects
Amino Acid Sequence, Animals, Chymotrypsin, Peptide Fragments analysis, Species Specificity, Swine, Trypsin, Artiodactyla, Cytochrome c Group
Abstract

The amino acid sequences of chymotryptic and tryptic peptides of Hippopotamus amphibius cytochrome c were determined by a recent modification of the manual Edman sequential degradation procedure. They were ordered by comparison with the structure of the hog protein. The hippopotamus protein differs in three positions: serine, alanine, and glutamine replace alanine, glutamic acid, and lysine in positions 43, 92, and 100, respectively. Since the artiodactyl suborders diverged in the mid-Eocene some 50 million years ago, the fact that representatives of some of them show no differences in their cytochromes c (cow, sheep, and hog), while another exhibits as many as three such differences, verifies that even in relatively closely related lines of descent the rate at which cytochrome c changes in the course of evolution is not constant. Furthermore, 10.6% of the hippopotamus cytochrome c preparation was shown to contain isoleucine instead of valine at position 3, indicating that one of the four animals from which the protein was obtained was heterozygous in the cytochrome c gene. Such heterogeneity is a necessary condition of evolutionary variation and has not been previously observed in the cytochrome c of a wild mammalian population.

Published
1978

17. Comparison of yeast and beef cytochrome c oxidases. Kinetics and binding of horse, fungal, and Euglena cytochromes c.

Author

Dethmers JK, Ferguson-Miller S, and Margoliash E

Subjects
Amino Acid Sequence, Animals, Candida, Cattle, Euglena, Horses, Kinetics, Models, Molecular, Neurospora crassa, Protein Binding, Protein Conformation, Species Specificity, Tuna, Cytochrome c Group, Electron Transport Complex IV metabolism, Mitochondria enzymology, Mitochondria, Heart enzymology, Saccharomyces cerevisiae enzymology
Published
1979

18. Identification of missense mutants by amino acid replacements in iso-1-cytochrome c from yeast.

Author

Putterman GJ, Margoliash E, and Sherman F

Subjects
Amino Acid Sequence, Binding Sites, Chromatography, Gel, Chromatography, Ion Exchange, Chromatography, Thin Layer, Chymotrypsin, Electrophoresis, Heme analysis, Hydrolysis, Isoleucine, Peptides analysis, Proline, RNA, Messenger, Saccharomyces cerevisiae, Serine, Threonine, Ultraviolet Rays, Cytochrome c Group analysis, Genes, Mutation
Published
1974

19. Definition of cytochrome c binding domains by chemical modification. Interaction of horse cytochrome c with beef sulfite oxidase and analysis of steady state kinetics.

Author

Speck SH, Koppenol WH, Dethmers JK, Osheroff N, Margoliash E, and Rajagopalan KV

Subjects
Animals, Binding Sites, Cattle, Horses, Kinetics, Models, Molecular, Osmolar Concentration, Protein Binding, Protein Conformation, Affinity Labels pharmacology, Cytochrome c Group metabolism, Liver enzymology, Oxidoreductases metabolism, Oxidoreductases Acting on Sulfur Group Donors metabolism
Published
1981

20. Topographic antigenic determinants on cytochrome c. Immunoadsorbent separation of the rabbit antibody populations directed against horse cytochrome.

Author

Jemmerson R and Margoliash E

Subjects
Animals, Antigen-Antibody Complex, Binding, Competitive, Columbidae, Horses, Humans, Immunoglobulin Fab Fragments, Kinetics, Mice, Myocardium, Rabbits immunology, Species Specificity, Spectrometry, Fluorescence, Antibodies isolation & purification, Cytochrome c Group immunology, Epitopes
Abstract

Seven populations of site-specific antibodies were isolated from each of three sera of rabbits immunized against glutaraldehyde-polymerized horse cytochrome c. The antibodies were separated using an immunoadsorption scheme which employed the following cytochromes c: horse, beef, guanaco, rabbit, mouse testicular, pigeon, and the cyanogen-bromide cleaved fragment of the rabbit protein containing residues 1 to 65. The monovalent, antigen-binding fragments of the antibodies (Fab') gave 1:1 stoichiometries with native horse cytochrome c in fluorescence quenching assays. Cross-reactivities with heterologous cytochromes c using fluorescence quenching and a modified Farr assay demonstrated that the antigenic determinants are situated around residues 44, 60, and 89/92, four of the six amino acid sequence positions where horse and rabbit cytochromes c differ. The remaining two differences occur at residues 47 and 62. The apparent lack of immunogenicity of these two substitutions may result from the presence of the more immunogenic residues 44 and 60 nearby. Of the seven antibody populations isolated, four were shown to bind in the region of residues 89 and 92. Since several cytochromes c have amino acid sequence differences from the horse protein at either of these two residue positions, it was possible to fractionate the antibodies directed against this complex site on the basis of subtle specificity differences between them. Two antibody populations bind in the region of residue 44. One of these is specific for proline at that position, while the other antibody population also binds to cytochrome c containing glutamic acid at position 44. The remaining antibody population binds in the region of the lysine residue at position 60. Each of the seven site-specific antibody populations binds effectively to any cytochrome c having a suitable amino acid sequence in the antigenic determinant regardless of any residue differences from the immunogen outside of that area. It was also demonstrated that these seven antibody populations represent the totality of the antibodies elicited in rabbits against horse cytochrome c, since the immunoadsorbants bound all the antibodies specific for the native protein. Furthermore, the rabbit antisera contained no other antibody population that could bind to the conformationally disturbed, cyanogen bromide-cleaved fragment of horse cytochrome c containing residues 1 to 65, making it appear that there were no antibodies elicited against a "processed" form of cytochrome c.

Published
1979

21. Definition of cytochrome c binding domains by chemical modification. II. Identification and properties of singly substituted carboxydinitrophenyl cytochromes c at lysines 8, 13, 22, 27, 39, 60, 72, 87, and 99.

Author

Brautigan DL, Ferguson-Miller S, Tarr GE, and Margoliash E

Subjects
Binding Sites, Chemical Phenomena, Chemistry, Chlorobenzoates, Indicators and Reagents, Peptide Fragments analysis, Protein Conformation, Cytochrome c Group analogs & derivatives, Lysine
Abstract

Sensitive thin layer peptide mapping is employed to establish the identity and the homogeneity of eight singly substituted 4-carboxy-2,6-dinitrophenyl derivatives of horse cytochrome c. Seven of the components, all of greater than 95% homogeneity, are modified at lysyl residues 13, 72, 87, 8, 27, 39, and 60. The eighth component is a mixture of derivatives at lysines 22 and 99. The positions of the modified residues were confirmed by the amino acid analysis and Edman sequential degradation of the CDNP-peptides. Physiochemical properties characteristic of cytochrome c are unchanged in the chemically modified products examined. These properties, that include the proton NMR spectrum, are sensitive probes of the polypeptide organization surrounding the heme prosthetic group. The lack of any discernable changes indicates that modification of the epsilon-amino groups on the surface of cytochrome c does not perturb the overall structure of the protein. The widespread distribution of the modifications on the surface of the molecule, together with the homogeneity and native conformation of the CDNP-derivatives make them well suited for assessing the effects of changes in the charge topography on the electron transfer activity of cytochrome c.

Published
1978

23. The asymmetric distribution of charges on the surface of horse cytochrome c. Functional implications.

Author

Koppenol WH and Margoliash E

Subjects
Amino Acid Sequence, Animals, Cytochrome Reductases metabolism, Cytochrome-c Peroxidase metabolism, Electron Transport Complex IV metabolism, Horses, Kinetics, Mathematics, Models, Molecular, Oxidoreductases Acting on Sulfur Group Donors metabolism, Potentiometry, Protein Conformation, Cytochrome c Group metabolism
Abstract

The electric potential field around native horse cytochrome c and 12 singly modified 4-carboxy-2,4-dinitrophenyl- (CDNP) lysine cytochromes c is asymmetric, mainly because of the inhomogeneous distribution of negative charges. Dipole moments of 325 and 308 debye, (1.08.10(-27) and 1.03.10(-27) coulomb.meter), respectively, were calculated for horse ferri- and ferrocytochrome c. The angle between the heme plane and the dipole vector of horse ferricytochrome c is 33 degrees and increases 1 degree upon reduction to the ferrous form. Dipole moments of the CDNP-lysine cytochromes c differ from that of native cytochrome c by as much as 140 debye in magnitude and 45 degrees in direction. It is proposed that its dipole moment causes cytochrome c to orient itself in the electric fields of its redox partners, and that the CDNP-lysine cytochromes c, which have different dipole moments, do not form a productive complex. Reorientation to the correct position for electron transfer increases the activation energy and lowers the rate of reaction. This model describes quantitatively the relative activities of those CDNP-lysine cytochromes c which are modified outside of the interaction domain and it allows correction of the activities of those modified inside the domain, on the front surface of the molecule, for the change in dipole moment. The interaction domain for the reaction with cytochrome c reductase includes in decreasing order of involvement lysines 13, 72, 86, 27, and 87. That for the reaction with cytochrome c oxidase is slightly smaller, with lysines 13, 72, 86, and 27. The cytochrome c peroxidase domain is the largest of all and is defined by lysines 72, 86, 13, 87, 27,, and 73. All refined interaction domains encompass the exposed heme edge and are to a large extent overlapping, indicating that electron transfer takes place at or close to this prosthetic group and that cytochrome c must move on the outer surface of the inner mitochondrial membrane during electron transport between reductase and oxidase. For a quantitative description of the electrostatic interaction of cytochrome c with other molecules, it is essential to take into account the totality of its charge configuration.

Published
1982

24. Definition of enzymic interaction domains on cytochrome c. Purification and activity of singly substituted carboxydinitrophenyl-lysine 7, 25, 73, 86, and 99 cytochromes c.

Author

Osheroff N, Brautigan DL, and Margoliash E

Subjects
Animals, Cattle, Electron Transport Complex IV metabolism, Horses, Kinetics, Lysine analysis, Magnetic Resonance Spectroscopy, Mitochondria, Heart enzymology, Models, Molecular, Oxidation-Reduction, Potentiometry, Protein Binding, Protein Conformation, Submitochondrial Particles enzymology, Cytochrome c Group, Dinitrophenols analysis, Lysine analogs & derivatives
Published
1980

25. Electrostatic interactions in cytochrome c. The role of interactions between residues 13 and 90 and residues 79 and 47 in stabilizing the heme crevice structure.

Author

Osheroff N, Borden D, Koppenol WH, and Margoliash E

Subjects
Animals, Computers, Dinitrophenols, Drug Stability, Haplorhini, Horses, Humans, Hydrogen-Ion Concentration, Lysine, Models, Molecular, Myocardium analysis, Protein Binding, Protein Conformation, Species Specificity, Spectrophotometry, Trinitrobenzenes, Cytochrome c Group, Heme
Published
1980

26. Lactoperoxidase-catalyzed iodination of horse cytochrome c:monoiodotyrosyl 74 cytochrome c.

Author

Osheroff N, Feinberg BA, Margoliash E, and Morrison M

Subjects
Animals, Circular Dichroism, Electron Transport, Horses, Myocardium enzymology, Peptide Fragments analysis, Protein Conformation, Spectrophotometry, Ultraviolet, Tyrosine, Cytochrome c Group metabolism, Lactoperoxidase, Monoiodotyrosine, Peroxidases
Abstract

Iodination of horse cytochrome c with the lactoperoxidase-hydrogen peroxide-iodide system results initially in the formation of the monoiodotyrosyl 74 derivative. This singly modified protein was obtained in pure form by ion exchange chromatography and preparative column electrophoresis. It shows an intact 695 nm absorption band, the midpoint potential of the native protein, a nuclear magnetic resonance spectrum which indicates an undisturbed heme crevice structure, a normal reaction with antibodies directed against native horse cytochrome c, and circular dichroic spectra in which the only changes from those of the native protein can be ascribed to the spectral properties of iodotyrosine itself. This conformationally intact derivative reacts with the succinate-cytochrome c reductase and the cytochrome c oxidase systems of beef mitochondrial particle preparations indistinguishably from the unmodified protein, showing that the region including tyrosine 74 is not involved in these enzymic electron transfer functions of the protein. The circular dichroic spectra of this derivative indicate that the minima observed at 288 and 282 nm in the spectrum of native ferricytochrome c originate from tyrosyl residue 74.

Published
1977

27. Interaction of cytochrome c with the blue copper proteins, plastocyanin and azurin.

Author

Augustin MA, Chapman SK, Davies DM, Sykes AG, Speck SH, and Margoliash E

Subjects
Cytochrome c Group analogs & derivatives, Electrochemistry, Kinetics, Lysine analogs & derivatives, Structure-Activity Relationship, Azurin metabolism, Bacterial Proteins metabolism, Cytochrome c Group metabolism, Cytochromes c, Plant Proteins metabolism, Plastocyanin metabolism
Abstract

Bimolecular rate constants have been determined for the reactions of native horse cytochrome c, eight 4-carboxy-2,6-dinitrophenyl (CDNP-) cytochromes c singly modified at lysines 7, 13, 25, 27, 60, 72, 86, or 87 and one 2,3,6-trinitrophenyl cytochrome c singly modified at lysine 13, with the blue copper proteins, plastocyanin (from parsley leaves) and azurin (from Pseudomonas aeruginosa). Plastocyanin, a protein having a negative charge of about -7, yields a bimolecular rate constant with native ferrocytochrome c of 1.5 x 10(6) M-1 S-1, which decreases with the modified cytochromes c to a minimum of 7.5 x 10(5) M-1 S-1 for the CDNP-lysine 13 derivative. Conversely azurin, a protein with an overall negative charge of only about -1 to -2, exhibits bimolecular rate constants with native ferrocytochrome c of 6.6 x 10(3) M-1 S-1 at pH 6.1 and 4.0 x 10(3) M-1 S-1 at pH 8.6, which increase upon modification of the cytochrome c to a maximum of 4.1 x 10(4) M-1 S-1 at pH 6.1 and 2.7 x 10(4) M-1 S-1 at pH 8.6, for the CDNP-cytochrome c modified at lysine 72. This behavior indicates that: 1) the reaction of cytochrome c occurs at a negatively charged site on plastocyanin, whereas azurin behaves as a positively charged reactant, the electrostatics governing to a large extent the relative reactivities of the modified cytochromes c; 2) in both cases the interaction domain on cytochrome c is located on the "front" surface of the protein and encompasses the solvent accessible edge of the heme prosthetic group, as is the case for all the reactions of cytochrome c with its mitochondrial protein redox partners, as well as for small inorganic redox complexes; and 3) the bimolecular rate constants for plastocyanin and azurin are orders of magnitude slower and the effects of lysine modifications far smaller than for the reactions with physiological systems, indicating that: (a) the electric fields generated by the reactants do not align them, prior to electron transfer, as effectively as for the physiological reaction partners of cytochrome c; and (b) there is an absence of a precise molecular fit between cytochrome c and the nonphysiological redox partners.

Published
1983

28. Transmission of the cytochrome c structural gene in horse-donkey crosses.

Author

Walasek OF and Margoliash E

Subjects
Amino Acid Sequence, Amino Acids analysis, Animals, Crosses, Genetic, Dipeptides analysis, Horses, Humans, Male, Peptide Fragments analysis, Perissodactyla, Species Specificity, Cytochrome c Group biosynthesis, Genes
Abstract

Donkey cytochrome c was shown to differ from horse cytochrome c by having a serine in position 47 rather than a threonine. The rest of the amino acid sequences are identical. Mules and hinnies, both males and females, carry equal amounts of horse and donkey cytochromes c. The same ratio is found in hinnies in preparations from heart tissue and from skeletal muscle. These results demonstrate that cytochrome c is transmitted in horse-donkey crosses as a simple Mendelian character which is neither sex-linked nor shows dominance. The cytochrome c gene is therefore located in the nuclear genome, as earlier shown to be the case for Saccharomyces iso-1-cytochrome c.

Published
1977

29. Steady state kinetics and binding of eukaryotic cytochromes c with yeast cytochrome c peroxidase.

Author

Kang CH, Ferguson-Miller S, and Margoliash E

Subjects
Animals, Binding Sites, Grasshoppers, Horses, Hydrogen-Ion Concentration, Isoenzymes metabolism, Kinetics, Osmolar Concentration, Protein Binding, Species Specificity, Tuna, Cytochrome c Group metabolism, Cytochrome-c Peroxidase metabolism, Peroxidases metabolism, Saccharomyces cerevisiae enzymology
Abstract

1. The steady state kinetics for the oxidation of ferrocytochrome c by yeast cytochrome c peroxidase are biphasic under most conditions. The same biphasic kinetics were observed for yeast iso-1, yeast iso-2, horse, tuna, and cicada cytochromes c. On changing ionic strength, buffer anions, and pH, the apparent Km values for the initial phase (Km1) varied relatively little while the corresponding apparent maximal velocities varied over a much larger range. 2. The highest apparent Vmax1 for horse cytochrome c is attained at relatively low pH (congruent to 6.0) and low ionic strength (congruent to 0.05), while maximal activity for the yeast protein is at higher pH (congruent to 7.0) and higher ionic strength (congruent to 0.2), with some variations depending on the nature of the buffering ions. 3. Direct binding studies showed that cytochrome c binds to two sites on the peroxidase, under conditions that give biphasic kinetics. Under those ionic conditions that yield monophasic kinetics, binding occurred at only one site. At the optimal buffer concentrations for both yeast and horse cytochromes c, the KD1 and KD2 values approximate the Km1 and Km2 values. At ionic strengths below optimal, binding becomes too strong and above optimal, too weak. 4. Under ionic conditions that are optimal and give monophasic kinetics with horse cytochrome c but are suboptimal for the yeast protein, yeast cytochrome c strongly inhibits the reaction of horse cytochrome c with peroxidase, uncompetitively at one site and competitively at a second site. The appearance of the second site under monophasic conditions is interpreted as an allosteric effect of the inhibitor binding to the first site. 5. The simplest model accounting for these observations postulates two kinetically active sites on each molecule of peroxidase, a high affinity and a low affinity site, that may correspond to the free radical and the heme iron (IV) of the oxidized enzyme, respectively. Both oxidizing equivalents may be discharged at either site. Furthermore, the enzyme appears to exist as an equilibrium mixture of a high ionic strength form, EH and a low ionic strength form, EL, the former reacting optimally with yeast cytochrome c, and the latter with horse cytochrome c.

Published
1977

30. Characterization of the interaction of cytochrome c and mitochondrial ubiquinol-cytochrome c reductase.

Author

Speck SH and Margoliash E

Subjects
Animals, Electron Transport Complex III, Horses, Hydrogen-Ion Concentration, Kinetics, Osmolar Concentration, Cytochrome c Group metabolism, Mitochondria enzymology, Models, Chemical, Multienzyme Complexes metabolism, NADH, NADPH Oxidoreductases metabolism, Quinone Reductases metabolism
Abstract

Characterization of the steady state kinetics of reduction of horse ferricytochrome c by purified beef ubiquinol-cytochrome c reductase, employing 2,3-dimethoxy-5-methyl-6-decylbenzoquinol as reductant, has shown that: 1) the dependence of the reaction on quinol and on ferricytochrome c concentration is consistent with a ping-pong mechanism; 2) the pH optimum of the reaction is near 8.0; 3) the effect of ionic strength on the apparent Km and the TNmax of the reaction for the native cytochrome c is small, and at higher cytochrome c concentrations substrate inhibition is observed; 4) the effect of ionic strength on the kinetic parameters for the reaction of 4-carboxy-2,6-dinitrophenyllysine 27 horse cytochrome c is much larger than for the native protein; and 5) competitive product inhibition is also observed with a Ki consistent with the binding affinity of ferrocytochrome c for Complex III, as determined by gel filtration. In addition, direct binding measurements demonstrated that ferricytochrome c binds more tightly than the reduced protein to Complex III under low ionic strength conditions and that under these conditions more than one molecule of cytochrome c is bound per molecule of Complex III. Exchange of Complex III into a nonionic detergent decreases this excess nonspecific binding. Measurement of the rates of dissociation of the oxidized and reduced 1:1 complexes of cytochrome c and Complex III by stopped flow was consistent with the disparity of binding affinities, the dissociation rate constant for ferrocytochrome c being about 5-fold higher than that for the ferric protein. A model which accounts for the properties of this system is described, assuming that cytochrome c bound to noncatalytic sites on the respiratory complex decreases the catalytic site binding constant for the substrate.

Published
1984

31. Kinetics and mechanism of the reduction of ferricytochrome c by the superoxide anion.

Author

Butler J, Koppenol WH, and Margoliash E

Subjects
Animals, Horses, Hydrogen-Ion Concentration, Kinetics, Myocardium, Oxidation-Reduction, Temperature, Cytochrome c Group metabolism, Oxygen metabolism, Superoxides metabolism
Abstract

The temperature and pH dependence of the reaction of the superoxide radical anion with ferricytochrome c have been measured using the pulse-radiolysis technique. The temperature dependence of the reaction at low ionic strength yields an activation energy of 31 +/- 5 kJ/mol as compared to 14 +/- 3 kJ/mol for the reaction of CO2.(-) under the same conditions. The pH dependence fits the single pK'a of ferricytochrome c of 9.1. The bimolecular rate constant for the reaction of the superoxide anion with ferricytochrome c at pH 7.8, 21 +/- 2 degrees C, in the presence of 50 mM phosphate and 0.1 mM EDTA is (2.6 +/- 0.1) X 10(5) M-1 s-1. Using this value, 1 unit of superoxide dismutase activity (McCord, J. M., and Fridovich, I. (1969) J. Biol. Chem. 244, 6049-6055) is calculated to be 3.6 +/- 0.3 pmol of enzyme if the assay is performed in a total volume of 3.0 ml. Copper ions reduce the yield of the reaction of ferricytochrome c with CO2.(-). The reactivities of native and singly modified 4-carboxy-2,4-dinitrophenyllysine cytochromes c towards the superoxide anion radical are in the order native greater than 4-carboxy-2,4-dinitrophenyllysine 60 greater than lysine 13 greater than lysine 87 greater than lysine 27 greater than lysine 86 greater than lysine 72, indicating that electron transfer takes place at or close to the solvent accessible heme edge. The mechanism of the reaction is discussed in terms of the approach of superoxide anion radicals to the heme edge and the available molecular orbitals of both heme and free radicals.

Published
1982

32. Separate oxidase and reductase reaction sites on cytochrome c demonstrated with purified site-specific antibodies.

Author

Smith L, Davies HC, Reichlin M, and Margoliash E

Subjects
Animals, Antigen-Antibody Reactions, Binding Sites, Cytochrome Reductases antagonists & inhibitors, Electron Transport Complex IV antagonists & inhibitors, Fluorescence, Goats immunology, Haplorhini, Humans, Immunoglobulin Fab Fragments, Kinetics, Macaca, Myocardium enzymology, Oxidation-Reduction, Rabbits immunology, Spectrophotometry, Succinates, Antibody Specificity, Cytochrome c Group
Published
1973

34. The mutational alteration of the primary structure of yeast iso-1-cytochrome c.

Author

Sherman F, Stewart JW, Parker JH, Inhaber E, Shipman NA, Putterman GJ, Gardisky RL, and Margoliash E

Subjects
Acridines pharmacology, Amino Acids analysis, Autoanalysis, Culture Media, Electrophoresis, Genes, Genotype, Haploidy, Imidazoles pharmacology, Lactates, Mutagens pharmacology, Nitrites pharmacology, Nitroso Compounds pharmacology, Peptides analysis, Radiation Genetics, Spectrophotometry, Staining and Labeling, Ultraviolet Rays, Cytochromes analysis, Genetics, Microbial, Mutation, Saccharomyces drug effects, Saccharomyces growth & development, Saccharomyces radiation effects
Published
1968

37. Immunological activity of cytochrome c. II. Localization of a major antigenic determinant of human cytochrome c.

Author

Nisonoff A, Reichlin M, and Margoliash E

Subjects
Amino Acid Sequence, Amino Acids analysis, Animals, Antibody Formation, Antigen-Antibody Reactions, Antigens, Binding Sites, Biological Evolution, Chemical Phenomena, Chemistry, Complement Fixation Tests, Cross Reactions, Haplorhini, Humans, Immune Sera, Iodine Isotopes, Marsupialia, Rabbits, Threonine, Cytochromes analysis, Isoleucine analysis
Published
1970

38. Rabbit heart cytochrome c.

Author

Needleman SB and Margoliash E

Subjects
Amino Acid Sequence, Animals, Chemical Phenomena, Chemistry, Chromatography, Ion Exchange, Chymotrypsin, In Vitro Techniques, Rabbits, Trypsin, Cytochromes, Myocardium
Published
1966

40. Antibodies against cytochromes c from vertebrates.

Author

Reichlin M, Fogel S, Nisonoff A, and Margoliash E

Subjects
Animals, Complement System Proteins, Fishes, Horses, Immunochemistry, In Vitro Techniques, Precipitin Tests, gamma-Globulins, Antibodies, Cytochromes
Published
1966

41. The structure of bovine proinsulin.

Author

Nolan C, Margoliash E, Peterson JD, and Steiner DF

Subjects
Alanine, Amino Acid Sequence, Amino Acids analysis, Animals, Carboxypeptidases, Cattle, Chemical Phenomena, Chemistry, Chromatography, DEAE-Cellulose, Chromatography, Gel, Chromatography, Ion Exchange, Chymotrypsin, Cysteine, Electrophoresis, Islets of Langerhans cytology, Islets of Langerhans metabolism, Pepsin A, Peptides, Polymers, Species Specificity, Sulfides analysis, Swine, Trypsin, Insulin biosynthesis
Published
1971

46. Immunological activity of cytochrome c. I. Precipitating antibodies to monomeric vertebrate cytochromes c.

Author

Margoliash E, Nisonoff A, and Reichlin M

Subjects
Amino Acid Sequence, Animals, Antibody Formation, Binding Sites, Cattle, Chromatography, Gel, Complement Fixation Tests, Cross Reactions, Fishes, Freund's Adjuvant, Haplorhini, Haptens analysis, Horses, Humans, Immunochemistry, Immunodiffusion, Immunoelectrophoresis, Iodine Isotopes, Marsupialia, Precipitin Tests, Proteins, Rabbits, Species Specificity, Spectrophotometry, Turkeys, Ultraviolet Rays, gamma-Globulins, Antigen-Antibody Reactions, Cytochromes analysis, Immune Sera
Published
1970

47. Primary structure of alfalfa ferredoxin.

Author

Keresztes-Nagy S, Perini F, and Margoliash E

Subjects
Amino Acids analysis, Bacterial Proteins, Carboxypeptidases, Chromatography, Gel, Chromatography, Ion Exchange, Chymotrypsin, Clostridium, Mutation, Trypsin, Amino Acid Sequence, Ferredoxins analysis, Medicago sativa, Peptides analysis, Plant Proteins analysis
Published
1969

48. Electrophoretic behavior of mammalian-type cytochromes c.

Author

Barlow GH and Margoliash E

Subjects
Animals, Artiodactyla, Biological Evolution, Chemical Phenomena, Chemistry, Electrophoresis, Fishes, Horses, In Vitro Techniques, Insecta, Mutation, Myocardium, Poultry, Swine, Cytochromes
Published
1966

50. Amino acid composition of horse heart cytochrome c.

Author

MARGOLIASH E, KIMMEL JR, HILL RL, and SCHMIDT WR

Subjects
Animals, Horses, Amino Acids, Antifibrinolytic Agents, Cytochromes chemistry, Cytochromes c, Heart, Myocardium chemistry
Published
1962

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