An approach towards artificial quinone pools by use of photo- and redox-active dendritic molecules

Molecules with one porphyrin and multiple quinone groups are described. The molecules are based on dendritic frameworks, with the quinone groups attached at the “internal” positions and the porphyrin attached at the focal point, leading to a characteristic layer architecture. When irradiated with visible light in the presence of 4-tert-butylthiophenol, the quinones were converted to quinols. Such a behavior mimics the function of quinone pools in photosynthesis.     

Bioconjugatable porphyrins bearing a compact swallowtail motif for water solubility

A broad range of applications requires access to water-soluble, bioconjugatable porphyrins. Branched alkyl groups attached at the branching site to the porphyrin meso position are known to impart high organic solubility. Such "swallowtail" motifs bearing a polar group (hydroxy, dihydroxyphosphoryl, dihydroxyphosphoryloxy) at the terminus of each branch have now been incorporated at a meso site in trans-AB-porphyrins. The incorporation of the swallowtail motif relies on rational synthetic methods whereby a 1,9-bis(N-propylimino)dipyrromethane (bearing a bioconjugatable tether at the 5-position) is condensed with a dipyrromethane (bearing a protected 1,5-dihydroxypent-3-yl unit at the 5-position). The two hydroxy groups in the swallowtail motif of each of the resulting zinc porphyrins can be transformed to the corresponding diphosphate or diphosphonate product. A 4-(carboxymethyloxy)phenyl group provides the bioconjugatable tether. The six such porphyrins reported here are highly water-soluble (> or =20 mM at room temperature in water at pH 7) as determined by visual inspection, UV-vis absorption spectroscopy, or 1H NMR spectroscopy. Covalent attachment was carried out in aqueous solution with the unprotected porphyrin diphosphonate and a monoclonal antibody against the T-cell receptor CD3epsilon. The resulting conjugate performed comparably to a commercially available fluorescein isothiocyanate-labeled antibody with Jurkat cells in flow cytometry and fluorescence microscopy assays. Taken together, this work enables preparation of useful quantities of water-soluble, bioconjugatable porphyrins in a compact architecture for applications in the life sciences.     

Vibrational modes of ubiquinone in cytochrome bo(3) from Escherichia coli identified by Fourier transform infrared difference spectroscopy and specific (13)C labeling.

In this study we present the infrared spectroscopic characterization of the bound ubiquinone in cytochrome bo(3) from Escherichia coli. Electrochemically induced Fourier transform infrared (FTIR) difference spectra of DeltaUbiA (an oxidase devoid of bound ubiquinone) and DeltaUbiA reconstituted with ubiquinone 2 and with isotopically labeled ubiquinone 2, where (13)C was introduced either at the 1- or at the 4-position of the ring (C=O groups), have been obtained. The vibrational modes of the quinone bound to the discussed high-affinity binding site (Q(H)) are compared to those from the synthetic quinones in solution, leading to the assignment of the C=O modes to a split signal at 1658/1668 cm(-)(1), with both carbonyls similarly contributing. The FTIR spectra of DeltaUbiA reconstituted with the labeled quinones indicate an essentially symmetrical and weak hydrogen bonding of the two C=O groups from the neutral quinone with the protein and distinct conformations of the 2- and 3-methoxy groups. Perturbations of the vibrational modes of the 5-methyl side groups are discussed for a signal at 1452 cm(-)(1). Only negligible shifts of the aromatic ring modes can be reported for the reduced and the protonated form of the quinone. Alterations of the protein upon quinone binding are reflected in the electrochemically induced FTIR difference spectra. In particular, difference signals at 1640-1633 cm(-)(1) and 1700-1670 cm(-)(1) indicate variations of beta-sheet secondary structure elements and loops, bands at 1706 and 1678 cm(-)(1) are tentatively attributed to individual amino acids, and a difference signal a 1540 cm(-)(1) is discussed to reflect an influence on C=C modes of the porphyrin ring or on deprotonated propionate groups of the hemes. Further tentative assignments are presented and discussed. The (13)C labeling experiments allow the assignment of the vibrational modes of a bound ubiquinone 8 in the electrochemically induced FTIR difference spectra of wild-type bo(3).     

The Synthesis of New Porphyrin–Quinone Dyad Systems

New porphyrin–quinone dyad systems containing spacer groups of various lengths and structures and sterically hindered 5,10,15,20-tetrakis(3,5-di-tert-butylphenyl)porphyrin as an electron donor were synthesized. These compounds seem to be promising models for studying the photoinduced electron transfer.     

A thiolate ligand on a cytochrome P-450 mimic permits the use of simple environmentally benign oxidants for biomimetic steroid hydroxylation in water

Manganese porphyrin systems carrying cyclodextrin binding groups can regioselectively and stereoselectively hydroxylate bound steroid substrates, using iodosobenzene as oxidant, but hydrogen peroxide and other simple oxidants such as sodium hypochlorite are not effective in water. Thiol ligands were then added to the catalyst, both covalently attached and hydrophobically bound, and with these ligands hydrogen peroxide was now an effective oxidant.     

Cytotoxicity of quinone drugs on highly proliferative human leukemia T cells: reactive oxygen species generation and inactive shortened SOD1 isoform implications

Drugs containing the quinone group were tested on hyperproliferative leukemia T cells (HLTC: Jhp and Jws) and parental Jurkat cells. Doxorubicin, menadione and adaphostin produced different effects on these cell lines. Rapid doxorubicin-induced cell death in Jurkat cells was mediated by caspase activation. Doxorubicin-induced cell death of HLTCs was delayed due to the absence of caspase-3 and -8 expression. Delayed HLTC cell death was mediated and triggered by the generation of reactive oxygen species (ROS). Other drugs containing quinone groups, such as menadione and adaphostin, were also tested on HLTC and both were toxic by a caspase-independent mechanism. The toxicity of these drugs correlated with the generation of the superoxide anion, which increased and was more effective in HLTCs than in parental Jurkat cells. Accordingly, SOD1 activity was much lower in HLTCs than in Jurkat cells. This lower SOD1 activity in HLTCs was associated not only with the absence of the wild-type (16 kDa) SOD1 monomer but also with the presence of a shortened (14 kDa) SOD1 monomer isoform. Moreover, the cytotoxicity of drugs containing the quinone group was prevented by incubation with manganese(III) tetrakis (4-benzoic acid) porphyrin (MnTBAP), a cell-permeable superoxide dismutase mimetic and a potent inhibitor of oxidation. These findings could explain the sensitivity of HLTCs to drugs containing the quinone group using a mechanism dependent on oxidative stress. These observations can also be useful to target hyperproliferative leukemias that are resistant to the classical caspase-dependent apoptotic pathway.     

Synthesis,DNA-Binding,and Photocleavage Properties of a Serious of Porphyrin-Daunomycin Hybrids

It is widely accepted that the pharmacological activities of anthracyclines antitumor agents express when the quinone-containing chromophore intercalates into base pairs of the duplex DNA. We have successfully synthesized and investigated the DNA-interactions of hybrids composed with quinone chromophore and cationic porphyrin. Herein, a clinic anticancer drug, daunomycin, is introduced to the porphyrin hybrids through different lengths of amide alkyl linkages, and their interactions and cleavage to DNA were studied compared with the previous porphyrin-quinone hybrids. Spectral results and the determined binding affinity constants (K_b) show that the attachment of daunomycin to porphyrin could improve the DNA-binding and photocleaving abilities. The porphyrin-daunomycin hybrids may find useful employment in investigating the ligand-DNA interaction.     

Conjugation of a hairpin pyrrole-imidazole polyamide to a quinone methide for control of DNA cross-linking

A series of quinone methide precursors designed for DNA cross-linking were prepared and conjugated to a pyrrole-imidazole polyamide for selective association to the minor groove. Although reaction was only observed for DNA containing the predicted recognition sequence, yields of strand alkylation were low. Interstrand cross-linking was more efficient than alkylation but still quite modest and equivalent to that generated by a comparable conjugate containing the N-mustard chlorambucil. Varying the length of the linker connecting the polyamide and quinone methide derivative did not greatly affect the yield of DNA cross-linking. Instead, intramolecular trapping of the quinone methide intermediate by nucleophiles of the attached polyamide appears to be the major determinant that limits its reaction with DNA. Self-adducts of the quinone methide conjugate form readily and irreversibly as detected by a combination of chromatography and mass spectroscopy. This result is unlike comparable self-adducts observed for oligonucleotide conjugates that form more slowly and remain reversible. Equivalent intramolecular alkylation of a polyamide by its attached chlorambucil mustard was not observed under similar condition. The presence of DNA, however, did facilitate hydrolysis of this mustard conjugate.     

Role of heme in structural organization of cytochrome c probed by semisynthesis

The heme prosthetic group of cytochrome c is covalently attached to the protein through thioether bonds to two cysteine side chains. The role of covalent heme attachment to cytochrome c is not understood, and most heme proteins bind the prosthetic group by iron ion ligation and tertiary interactions only. A two-armed attachment seems redundant if the role of covalent connection is to limit heme group orientation or to decouple heme affinity from redox potential. These considerations suggested that one role for covalent attachment of the rigid planar heme might be in organizing the cytochrome c protein structure. Indeed, porphyrin cytochrome c (in which the heme iron ion has been removed) is substantially more ordered than apocytochrome c, having characteristics consistent with a molten globule state. To assess the importance of planar rigidity in ordering this protein, semisynthesis was used to substitute porphyrin by two hydrophobic surrogates, one based on biphenyl and the other on phenanthrene, which have different degrees of planarity and rigidity. The expected two-armed covalent attachment of each surrogate was confirmed in the protein products by a variety of methods including mass spectrometry and NMR. Despite being only about half the size of the porphyrin macrocycle, and lacking any possibility for ligation or polar group interactions with the surrounding protein, the two surrogates confer helix contents that are comparable to that of the molten globule formed by porphyrin cytochrome c under similar solution conditions. The pH titrations of the derivatives monitored by circular dichroism exhibit reversible, bell-shaped folding and unfolding transitions, implying that charge group interactions in the protein are involved in stabilizing the helical structures formed. The thermal transitions of the two derivatives at neutral pH are cooperative, with similar midpoints. The similarity of helical content and structural stability in the two derivatives indicates that the increase in conformational freedom by the biphenyl surrogate does not substantially reduce protein structural stability. The similarity of the two derivatives to porphyrin cytochrome c suggests that the common feature among the three covalently attached groups-their hydrophobicity-is by far the dominant factor in organizing stable structures in the protein.     

Calcium-ion induced color changes of a porphyrin solution

Interactions between the porphyrin-bearing multidentate ligands and group II metal ions in aqueous solution were studied. Changes in the visible spectra of 5 × 10⁻⁵ M solution of the porphyrin in 0.01 M 2-[4-(2-hydroxyethyl)-1-piperazinyl] ethanesulfonic acid (pH 7.4) containing 0.1 M KCl were observed upon titration of Ca²⁺ at 25 °C. From the analyses of NMR and visible spectral data, we proposed that the spectral changes are due to the formation of an associate between the porphyrin and Ca²⁺ via the following three interactions: (i) formation of a complex between the attached NTA groups and Ca²⁺; (ii) hydrophobic interaction among porphyrin rings; and (iii) interaction between the pyrrole nitrogens and Ca²⁺.     

Valence-tautomerism in high-valent iron and manganese porphyrins

Iron and manganese hemes are "high-valent" when the valence state of the metal exceeds III. Redox chemistry of the high valent metal complexes involves redistribution of holes and electrons over the metal ion and the porphyrin and axial ligands, defined as valence tautomerism. Thus, catalytic pathways of heme-containing biomolecules such as peroxidases, catalases and cytochromes P450 involve valence tautomerism, as do pathways of biomimetic oxygen transfer catalysis by manganese porphyrins, robust catalysts with potential commercial value. Determinants of the site of electron abstraction are key to understanding valence tautomerism. In model systems, metal-centered oxidation is supported by hard anionic axial ligands that are also strongly pi-donating, such as oxo, aryl, bix-methoxy and bis-fluoro groups. Manganese(IV) is more stable than iron(IV) and metal-centered one-electron oxidations occur with weaker pi-donating axial ligands such as bisazido, -isocyanato, -hypochlorito and bis chloro groups. Virtually all known high-valent iron porphyrin complexes oxidized by two-electrons above the ferric state are coordinated by the strongly pi-donating oxo or nitrido ligands. In all well-characterized oxo complexes, iron is in the ferryl state and the second oxidizing equivalent resides on the porphyrin. Complexes with iron(V) have not been definitively characterized. One-electron oxidation of oxomanganese(IV) porphyrin complexes gives the oxomanganese(IV) porphyrin pi-cation redicals. In aqueous solution, oxidation of Mn(III) complexes of tetra cationic N-methylpyridiniumylporphyrin isomers by monooxygen donors yields a transient oxomanganese(V) species.     

Characteristics of the interaction of adrenal lipoamide dehydrogenase with physiological and quinone electron acceptors

Lipoamide dehydrogenase (EC 1.6.4.3) from the ketoglutarate dehydrogenase complex of adrenals catalyzes the oxidation of NADH by lipoamide and quinone compounds according to the "ping-pong" scheme. The catalytic constants of these reactions are equal to 220 and 24 s-1, respectively (pH 7.0). The maximal quinone reductase activity is observed at pH 5.6, whereas the lipoamide reductase activity changes insignificantly at pH 7.5-5.5. The maximal dihydrolipoamide-NAD+ reductase activity is observed at pH 7.8. The oxidative constants of quinone electron acceptors vary from 6 X 10(6) to 4 X 10(2) M-1 s-1 and increase with their redox potential. The patterns of NAD+ inhibition in the quinone reductase reaction differ from that of lipoamide reductase reaction. The quinones are reduced by lipoamide dehydrogenase in the one-electron mechanism.     

Magnetic resonance studies of the binding of 13C-labeled carbon monoxide to myoglobins and hemoglobins containing modified hemes.

The effects of changes in the groups attached to the periphery of the porphyrin ring of the heme of various hemoglobin and myoglobins on the environment experienced by the ligand, carbon monoxide, have been studied by observation of the chemical shift of the bound 13CO. The results indicate that the major interaction between bound ligands and substituents around the porphyrin is that transmitted electronically from substituent to ligand. The nature of the protein environment around the ligand and the interaction between the proximal histidine (F8) and the ligand (through the iron atom) impose differences between subunits of hemoglobin and between myoglobins and hemoglobins which are largely, but not entirely, independent of these substituent effects. To assess the influence of protein structure on the chemical shifts of bound ligand, the shifts of 13CO bound to myoglobin and hemoglobins from a wide range of species have also been measured.     

Hormonal effects on the regulation of hepatic heme biosynthesis

Summary Drug-induced porphyrin accumulation occurs in chick embryo liver cells maintained in serum-free Waymouth MD 705/1 medium. Addition of insulin and thyroxine to the medium results in a marked enhancement of porphyrin accumulation. The addition of hydrocortisone results in a further enhancement of porphyrin accumulation.Several agents which are reported to increase intracellular adensosine 3:5-monophosphate (cAMP) levels, viz. glucagon, sodium fluoride, cAMP or its dibutyryl derivative, 3-isobutyl-1-methylxanthine and papaverine enhanced drug-induced porphyrin biosynthesis. On the other hand, agents which are reported to decrease intra-cellular cAMP levels, viz. alloxan and imidazole, diminished drug-induced porphyrin accumulation. cAMP appears to enhance, but not to function as a second messenger in drug-induced porphyrin biosynthesis.Drug-induced porphyrin accumulation in chick embryo liver cells depend upon the insulin to glucagon ratio. A low level of porphyrin accumulation occurs at insulin to glucagon ratios similar to those found following glucose administration in vivo, suggesting a possible explanation for the therapeutic effect of glucose in hepatic porphyria.The 5H(A:B trans) and 5H(A:B cis) steroids are equipotent in inducing -aminolevulinic acid synthetase and porphyrin accumulation in chick embryo liver cells maintained in serum-free culture medium. Thus, there is no specific steric requirement for porphyrin-inducing activity in steroids.This work was supported by the Medical Research Council of Canada.     

Transverse motion of chlorophyll derivatives in phospholipid bilayers

Chlorophyll derivatives were synthesized with spin labels attached to the porphyrin ring. These labels were incorporated into egg phosphatidylcholine vesicles in order to estimate the transbilayer motion (flip-flop) of this class of photosynthetic pigments. Using the ascorbate reduction method, the upper limit to the spin label half-life is tau 1/2 approximately 4 min at 0 degrees C. The flip-flop rate is rapid compared to that of a phospholipid spin label under the same conditions. The presence or absence of magnesium in the center of the porphyrin ring had no measurable effect on the flip-flop rate.     

Self-aggregation of free base porphyrins in aqueous solution and in DMPC vesicles

Free base porphyrin (PPhe), derivatized with aminosulfonyl groups linked to the aromatic amino acid phenylalanine at the meso-positions, was mixed with DMPC vesicles. The resulting interaction was studied by absorption, steady-state and transient state fluorescence, at different pHs. At pH=2 to pH=9, the aforementioned porphyrin predominates as an aggregated species, with a co-facial arrangement of the molecules taking into account the blue shift of the Soret band (414 nm for the monomer and 401 nm for the aggregate). Upon interaction with DMPC vesicles, the competing hydrophobic interactions with the bilayer destabilize the aggregated species in favor of monomer incorporation. Fluorescence lifetimes also show that the long component assigned to the monomer contributes only 30% to the overall decay in solution (e.g. pH=7.0) whereas in DMPC vesicles this contribution increases up to 85% independent of the solution pH, which confirms a location of the probe in an environment "protected" from free water. The picture changes completely in the case of TSPP, an anionic porphyrin which does not incorporate in DMPC vesicles. Remarkably, at pH=2.5 all the experimental findings point to the self-assembling of the porphyrin units in J-aggregates induced at the surface of the DMPC vesicle. In fact, upon removal of the aqueous solvent, we could define by fluorescence lifetime imaging microscopy (FLIM) regions where the fluorescence lifetime is that characteristic of the J-aggregate ( 0.11 ns).     

Protein influences on porphyrin structure in cytochrome c: evidence from Raman difference spectroscopy

To probe the details of protein heme interactions, we have developed a Raman difference spectroscopic technique, which allows reliable detection of very small, approximately equal to 0.01 cm-1, frequency differences. When this technique is applied to heme proteins, structural differences in the protein which perturb the porphyrin macrocycle may be examined by obtaining Raman difference data on the porphyrin vibrational modes which are strongly enhanced in the Raman spectrum produced with visible laser excitation. We report here Raman difference spectroscopic data on cytochromes c from 24 species. The differences in the Raman spectrum of the porphyrin between the cytochromes c of any two species are small, confirming that all of the cytochromes we have examined have the same "cytochrome fold". However, many small (0.02-2 cm-1) but systematic differences were detected which indicate structural differences among these proteins. These differences could be classified into three different groups and interpreted in terms of different types of structural variations resulting from specific differences in the amino acid sequences. First, direct interactions between near-heme residues and the porphyrin influence the electron density in the pi orbitals of the porphyrin macrocycle. Second, variation in the residue at position 92, far removed from the heme, affects the frequency of the core-size marker line at 1584 cm-1. Third, the conformation near cysteine 14 affects the shape of the Raman mode which is sensitive to the pyrrole ring substituents (approximately 1313 cm-1). From these data we conclude that there are several ways in which the protein amino acid sequence may regulate the oxidation-reduction potential and several ways in which the sequence can modify the binding site between cytochrome c and its redox partners.     

Porphyrin conjugated to DNA by a 2'-amido-2'-deoxyuridine linkage

A porphyrin that contains a single carboxylic acid group was synthesized and coupled to 2'-amino-2'-deoxyuridine. The resultant product contained a free 3' hydroxyl group and a 4,4'-dimethoxytrityl (DMT) protecting group on the 5' hydroxyl of the uridine, making it suitable for use in oligonucleotide synthesis. The 3' H-phosphonate derivative of this molecule was synthesized and used to form a conjugate with a 19 nucleotide sequence of DNA (5'-CCTCCAGTGGAAATCAAGG-3'). This was carried out with the DNA attached at the 3' end to a control pore glass (CPG) substrate, allowing for rapid purification. After removal of the DMT group, an additional three nucleotides were added, leaving the porphyrin as an internal modification. This is the first report of porphyrin attached internally to an oligonucleotide using a hydrogen-bonding nucleoside analog. This allows oligonucleotides to be used as a scaffold for precise positioning of multiple porphyrins within biomimetic arrays.     

Metal binding by melanins: studies of colloidal dihydroxyindole-melanin, and its complexation by Cu(II) and Zn(II) ions

Melanins are colloidal pigments known to have a high affinity for metal ions. In this work, the nature of the metal-binding sites are determined and the binding affinities are quantified. Initial potentiometric titrations have been performed on synthetic dihydroxyindole (DHI) melanin solutions to determine the chemical speciation of quinole/quinone subunits. Two types of acidic functionalities are assignable: catechol groups, with pK(a) between 9 and 13, and quinone imines (QI), with pK(a) of 6.3. The presence of the quinone-imine tautomer has, to our knowledge, never been assessed in polymeric melanins. Melanin solutions obtained from N-methylated DHI lack the pK(a) 6.3 buffer, consistent with its inability to form the quinone-imine tautomer. EPR spectroscopy of the DHI-melanin samples demonstrates that the semiquinone radical is in too low a concentration to contribute to the bulk binding of metals. Changes in the titration curves after addition of Cu(II) and Zn(II) ions were analyzed to obtain the binding constants and stoichiometry of the metal-melanin complexes, using the BEST7 program. UV-Vis spectra at neutral and high pH are used to identify absorbances due to Cu-bound quinone imine and catechol groups. The derived binding constants were used to determine speciation of the Cu(II) and Zn(II) ions coordinated to the quinone imine and catechol groups at various pH. The mixed complexes, Zn(QI)(Cat)(-) and Cu(QI)(Cat)(-) are shown to dominate at physiological pH.