ESR parameters for cupric bleomycin in the mobilized state

The configuration of the copper complex of the glycopeptide bleomycin, CuBlm, is presumed to be pyramidal square planar from a previous X-ray structural determination of a fragment of cupric bleomycin. This study presents evidence for a difference in the ESR parameters for cupric bleomycin in the liquid as opposed to the solid state. A decrease in Aiso for CuBlm in the liquid state can be directly surmised from the low frequency S-band spectrum for which three of the four cupric hyperfine lines are partially resolved. Computer simulated spectra infer that the absolute value of All increases about 100 MHz and the value of Al may change sign for CuBlm in the liquid state. Simulations using a rotational correlation time of about 250 psec. indicate that CuBLM may not be spherical in the liquid phase. The fastest component for anisotropic motion could dominate and account for the well resolved cupric hyperfine structure. Furthermore, it is argued from an analysis of the cupric hyperfine coupling constants that the CuBlm structure opens up at room temperature and that the cupric ion is displaced from the square plane.     

Orientation of non-blue cupric complexes on DNA fibers.

Three different orientations of non-blue, type 2 cupric complexes on DNA fibers are obtained from EPR data. The cupric complex of bleomycin, CuBlm, binds as described previously (Shields, H., McGlumphy,C., and Hamrick, P., J., Jr. (1982) Biochim. Biophys. Acta 697, 113-120), except possibly with more restricted motion. The square plane of CuBlm makes an angle of about 65 degrees with the fiber axis. The tridentate complex 2-formylpyridine monothiosemicarbazonato Cu2+ binds with its planar structure perpendicular to the fiber axis. In contrast, other tridentate cupric complexes of tripeptides, CuGHK and CuGHG, bind with the square plane parallel to the fiber axis. The bound forms of Cu(GHK) and Cu(GHG) are determined mostly by the GH moiety in the complex; the contribution of lysine in defining the orientation of the copper moiety is minimal. Thus, the structure of the ligand determines the orientation of these complexes on DNA.     

NMR Studies of the Interaction of Bleomycin with (dC-dG)3

Abstract

The interaction of bleomycin A₂ and Zn(II)-bleomycin A₂ with the oligonucleotide (dC-dG)₃ has been monitored by nuclear magnetic resonance spectroscopy. Binding of the drug to the oligonucleotide is indicated by an upfield shift of the bithiazole proton resonances consistent with partial intercalation of this group between base pairs. The effect of temperature and ionic strength on the binding of both free bleomycin and the Zn(II) complex has been studied. Consistent with earlier studies on polynucleotides, the rate of exchange between the free drug and the drug-oligonucleotide complex is rapid on the ¹H NMR chemical shift time scale. Binding of the oligonucleotide induced changes in resonances assigned to protons in the metal-binding region of Zn(II)-bleomycin. Intermolecular nuclear Overhauser effect enhancements between bleomycin and the oligonucleotide have not been detected.     

The conformation and orientation of copper(II)-bleomycin intercalated with DNA

EPR data are used to describe the conformation and identity of the atoms coordinated to Cu(II) in Cu(II)-bleomycin bound to oriented DNA fibers. The fibers were slowly drawn from viscous solutions of Cu(II)-bleomycin-DNA containing one Cu(II)-bleomycin to 200 basepairs. EPR measurements were made at room temperature and 90 K for different orientations of the external magnetic field with respect to the helical axes of the fibers. The g-values ($\text{g}{}_{\mathrm{}}\text{=2.21}$, g_⊥ =2.04) and the hyperfine constant ($\text{A}{}_{\mathrm{}}\text{=175}\text{G}$) are consistent with values expected for Cu(II) chelated to a square planar array of ligands. In the oriented fibers, the square planar arrays do not all have the same orientations with respect to the fiber axes. At room temperature the chelated ions have rotational freedom in which the normal to the planar array has almost complete freedom of rotation about axes perpendicular to the DNA fiber axes. The normal maintains an angle of 75° with respect to the axis, in the plane of the basepair, about which it rotates. Nine superhyperfine peaks on the high field side of the EPR spectrum were partially resolved. The number and splitting (12 G) of these superhyperfine peaks indicate that four nitrogen atoms are chelated to Cu(II) in a square planar array. These data on Cu(II)-bleomycin bound to DNA give information on the orientation of the metal-containing portion of bleomycin which lies outside the double helix.     

On the role of a cuprous ion intermediate in the galactose oxidase reaction

The Cu⁺² electron spin resonance spectrum of galactose oxidase (galactose:O₂ oxidoreductase, E.C. 1.1.3.9) indicates that the metal is in a pseudo-square planar environment. The electron g values are: g_zz = 2.273, g_xx = 2.058 and g_yy = 2.048. The copper nuclear hyperfine constants are (in Gauss): A_zz = 176.5, A_xx = 28.8 and A_yy = 30.1. This spectrum is unaltered in either intensity or g or A values under conditions which cause the inhibition of galactose oxidase by superoxide dismutase. No combination of substrates (galactose and O₂) and oxidant traps (superoxide dismutase and catalase) results in the reduction of the cupric ion resonance. Thus, a Cu⁺¹-enzyme does not appear to be a stable intermediate along this enzyme's reaction path.     

The cationic plastoquinone radical of the chloroplast water splitting complex: Hyperfine splitting from a single methyl group determines the EPR spectral shape of Signal II

The proposal that EPR Signal II in spinach chloroplasts is due to a plastoquinone cation radical (O'Malley, P.J. and Babcock, G.T. (1983) Biophys. J. 41, 315a) has been investigated in further detail. The similarity in spectral shape between Signal II and the 2-methyl-5-isopropylhydroquinone cation radical is shown to arise from hyperfine coupling to one methyl group for both radicals. A well-resolved four line EPR spectrum of approximate relative intensity 1:3:3:1 for membrane orientation parallel and perpendicular to the applied magnetic field direction also indicates that the partially resolved structure of Signal II is due to hyperfine interaction with one methyl group, i.e., the 2-CH₃ group of the plastoquinone cation radical. The ENDOR band observed for this coupling is similar to that observed for methyl group bands of model quinone radicals. The principal hyperfine tensor values obtained for the methyl group interactions are A_⊥ = 27.2 MHz and $\text{A}{}_{\mathrm{}}\text{= 31.4}\text{MHz}$. The large isotropic coupling value (28.6 MHz) of the plastoquinone cation radical's 2-methyl group in vivo indicates that the antisymmetric orbital is the sole contributor to the spin-density distribution of Signal II. The orientation data also suggest that the plastoquinone cation radical is oriented such that the C-CH₃ bond direction, and hence the aromatic ring plane, lies perpendicular to the membrane plane.     

New cardiac expression of two adenosine-2A receptor isoforms in dysfunctioning minipigs

Purpose: Eight A_2AR variants are reported in humans while no A_2AR isoforms in pigs. The aim of this study was to evaluate potential isoforms presence in cardiac pig tissue to better define possible involvement of A_2AR in the cardiovascular pathophysiology.

Materials and methods: In adult male minipigs (n?=?4) left ventricular dysfunction (LVD) was induced by pacing at 200 bpm in the right ventricular (RV) apex. In these animals and in sham operated pigs (C-SHAM, n?=?4) cardiac tissue was collected from LV-septal wall (LV-SW)-close to pacing site-and from lateral (opposite) site (LV-OSW). A_2AR specific primers, derived from Sus scrofa AY772412 sequence, were used for Real-Time PCR. The DNA was sequenced using the Sanger method. Histological analysis was also performed.

Results: In LV-SW of LVD minipigs the A_2AR melting curves were characterized by a sharp peak between 87 and 91?°C (short isoform, 1–94?bp) on the right of the principal peak corresponding to a long A_2AR isoform (GenBank: JQ229674.1) 1–213?bp. As for C-SHAM only one peak was observed in LV-OSW region of LVD animals. The short isoform had an alternative promoter region and a specific translated protein. Histology showed in LVD-LV-SW prominent Purkinje cells compared to LV-OSW and C-SHAM. No difference in A_2AR expression was observed between LVD animals and C-SHAM although a slight decrease was observed in LVD-LV-OSW.

Conclusions: The presence of two different isoforms in the myocardium close to the insertion of pacing is suggestive of a differential state-specific expression of A_2AR in cardiac tissue.     

Synthesis,antioxidant and carbonic anhydrase I and II inhibitory activities of novel sulphonamide-substituted coumarylthiazole derivatives

New secondary benzenesulphonamide-substituted coumarylthiazole derivatives were synthesized and their inhibitory effects on purified carbonic anhydrase I and II were evaluated using CO₂ as a substrate. The result showed that all the synthesized compounds exhibited inhibitory activity on both hCA I and hCA II with N-(4-(2-oxo-2H-chromen-3-yl)thiazol-2-yl)naphthalene-2-sulphonamide (5f, IC₅₀ value of 5.63 and 8.48?µM, against hCA I and hCA II, respectively) as the strongest inhibitor revealed from this study. Structure–activity relationship revealed that the inhibitory activity of the synthesized compounds is related to the type of the halogen and bulky substituent on the phenyl ring. In addition, the cupric reducing antioxidant capacities (CUPRAC) and ABTS cation radical scavenging abilities of the synthesized compounds were assayed. 4-methoxy-N-(4-(2-oxo-2H-chromen-3-yl)thiazol-2-yl)benzenesulphonamide (5e) exhibited the strongest ABTS and CUPRAC activity with IC₅₀ value of 48.83?µM and A_0.50 value of 23.29?µM, respectively.     

Synthesis and Receptor Affinity of Polysubstituted Adenosines

Abstract

In a search for potent and selective adenosine agonists it has been found that 2-hexynyladenosine-5′-N-ethyluronamide (HENECA) displays high affinity at rat A_2A receptor combined with a good A_2A vs A₁ selectivity. The finding that HENECA shows good affinity also for A₃ receptors prompted us to investigate the effect of various substituents in different positions of this molecule.     

Studies on the chemical reactivity of copper bleomycin

The copper(II) complex of the clinically used antitumor agent bleomycin (Blm) has cytotoxic as well as antitumor properties. To understand the relationship of the bleomycin ligand, copper bleomycin, and other possible metal complexes of this agent, kinetic studies of the formation of Cu(II)Blm, ligand substitution reactions of CuBlm with ethylenediaminetetraaletic acid, and the redox reaction of CuBlm with thiols have been completed and interpreted along with previous studies of the thermodynamic stability of Cu2+ with bleomycin. Cu(II)Bm is found to be kinetically and thermodynamically stable in ligand substitution processes and is only slowly reduced and dissociated by sulfhydryl reagents. The rate constant of reduction of the complex by 2-mercaptoethanol (2-ME) at pH 7.4 and 25 degrees C is 9.5 X 10(-3) M-1 sec-1, explaining the inhibition of Fe2+-dependent strand scission of DNA by Cu2+ in the presence of 2-ME. CuBlm forms in preference to Fe(II)Blm and cannot be reduced and dissociated rapidly enough by thiols to liberate Blm and form the reactive iron complex. In agreement with the observed chemical stability of CuBlm, it is also shown that the complex is stable in human plasma and in the presence of Ehrlich cells suspended in ascites fluid. Interestingly, little CuBlm enters these cells to carry out cytotoxic reactions. Finally, it is shown that both Cu2+ and Zn2+, at equivalent concentrations to Fe2+, effectively inhibit the strand scission of DNA by Fe(II)Blm plus oxygen. However, at substoichiometric amounts of Cu2+, the ferroxidase activity of Blm enables the drug to remain effective in the strand-scission reaction, despite the lowered Cu-free Blm/Fe2+ ratio. These results are discussed in light of the proposed mechanism of action of bleomycin.     

A spectral investigation of the copper(II) complex of the antitumor compound bleomycin

A thorough spectral investigation of the copper(II) complex of the antitumor compound, bleomycin, has been carried out in solution employing optical, difference optical, electron spin resonance, and circular dichroism techniques. The optical spectrum of a pH = 7 solution of the 1:1 complex between copper(II) and bleomycin is characterized by a broad weak band in the visible region (λ_max = 610 nm) that cannot be resolved and intense ultraviolet bands at 317 (? = 2800), 327 (shoulder), 250 (? = 4700), and 257 nm (shoulder). The circular dichroism spectrum in the visible region shows the broad and weak visible absorption band contains at least three components (558, 675, and 880 nm) that are likely to be “d-d” in origin. The electron spin resonance spectrum is characteristic of a tetragonal d⁹ copper(II) system showing no rhombic distoritions at X-band frequencies (g_x = g_y ± 0.002). The spin Hamiltonian parameters for the pH = 7.0 solution corrected for second order effects are A_∥ = 177 × 10^?4 cm^?1, A_⊥ ? 15 × 10^?4 cm^?1, g_∥ = 2.214, g_⊥ = 2.039. Most interesting was the observation of extra hyperfine splitting due to endogenous nitrogen coordination in a 30% glycerol glass (A^N = 12.0 × 10^?4 cm^?1). That pattern is best interpreted as a seven-line sequence associated with three liganded nitrogens. A dramatic change in all spectral properties occurs when the pH of the copper(II)-bleomycin complex is lowered to 2.5. All these data taken together suggest a CuN₃O coordination complex in solution. Details and justifications as well as a discussion of the limitations of the interpretations are presented.     

Impediment to growth and yeast-to-hyphae transition in Candida albicans by copper oxide nanoparticles

Abstract

The effects of two prominent copper oxide nanoparticles (CuO-NP and Cu₂O-NP), with the oxidation state of Cu⁺⁺ (cupric) and Cu⁺ (cuprous), on Candida albicans were evaluated. CuO-NP and Cu₂O-NP were synthesized and characterized by XRD, FESEM, HR-TEM and Zeta potential. At sub-MIC (50?µg ml^?1), both cupric and cuprous oxide NPs prevented yeast-to-hyphae switching and wrinkling behaviour in C. albicans. The mechanism for the antifungal action of the two NPs differed; CuO-NP significantly elicited reactive oxygen species, whereas membrane damage was more pronounced with Cu₂O-NP. Real time PCR analysis revealed that CuO-NP suppressed the morphological switching of yeast-to-hyphae by down-regulating cph1, hst7 and ras1 and by up-regulation of the negative regulator tup1. In comparison, Cu₂O-NP resulted in down-regulation of ras1 and up-regulation of the negative regulators nrg1 and tup1. Between the two NPs, CuO exhibited increased antifungal activity due to its stable oxidation state (Cu⁺⁺) and its smaller dimensions compared with Cu₂O-NP.     

Effect of Endogenous Phospholipids on the [3H]R-Pia Binding to A1 Adenosine Receptors from PIG Cerebral Cortex

Abstract

The effect of phospholipases on the membrane-bound and solubilized A₁ adenosine receptor has been studied. The results indicate that phospholipids are essential for the functionality of the A₁ adenosine receptor and that there is a co-solubilization of receptor and phospholipids.     

Survey of Nonxanthine Derivatives as Adenosine Receptor Ligands

Abstract

The binding affinities at rat A₁, A_2a, and A₃ adenosine receptors of a wide range of heterocyclic derivatives have been determined. Mono-, bi-, tricyclic and macrocyclic compounds were screened in binding assays, using either [³H]PIA or [³H]CGS 21680 in rat brain membranes or [¹²⁵I]AB-MECA in CHO cells stably transfected with rat A₃ receptors. Several new classes of adenosine antagonists (e. g. 5- oxoimidazopyrimidines and a pyrazoloquinazoline) were identified. Various sulfonylpiperazines, 11- hydroxytetrahydrocarbazolenine, 4H-pyrido[1,2-a]pyrimidin-one, folic acid, and cytochalasin H and J bound to A₃ receptors selectively. Moreover, cytochalasin A, which bound to A₁ adenosine receptors with Ki value of 1.9 μM, inhibited adenylyl cyclase in rat adipocytes, but not via reversible A₁ receptor binding.

     

Characteristics of Adenosine-Mediated Inhibition of Tachykinin Release from Perifused Myenteric Plexus Synaptosomes

Abstract

Adenosine receptor agonists were shown to inhibit evoked release of the tachykinins Substance P and Neurokinin-A from perifused myenteric synaptosomes. The potencies of selective A₁ and A₂ agonists are consistent with activity at adenosine A₁ receptors located on the nerve endings.     

The Synthesis and Biological activity of a Highly Selective Adenosine A2a. Receptor Agonist

Abstract

Three novel nucleosides 1, 2, and 3 were prepared that contained side chains at the 2-position of adenosine. Compound 1 was shown to be the most selective A_2a receptor agonist reported to date having an A₁/A₂ ratio of 2400. In addition, compound 1 was shown to reduce blood pressure in rats and dogs with only minimal effects on heart rate.     

Comparison of the electron spin polarized spectrum found in plant photosystem I and in iron-depleted bacterial reaction centers with time-resolved K-band EPR; evidence that the photosystem I acceptor A1 is a quinone

The suggestion that the electron acceptor A₁ in plant photosystem I (PSI) is a quinone molecule is tested by comparisons with the bacterial photosystem. The electron spin polarized (ESP) EPR signal due to the oxidized donor and reduced quinone acceptor (P ₈₇₀ ⁺ Q^-) in iron-depleted bacterial reaction centers has similar spectral characteristics as the ESP EPR signal in PSI which is believed to be due to P ₇₀₀ ⁺ A ₁ ^- , the oxidized PSI donor and reduced A₁. This is also true for better resolved spectra obtained at K-band (24 GHz). These same spectral characteristics can be simulated using a powder spectrum based on the known g-anisotropy of reduced quinones and with the same parameter set for Q^- and A₁ ^-. The best resolution of the ESP EPR signal has been obtained for deuterated PSI particles at K-band. Simulation of the A₁ ^- contribution based on g-anisotropy yields the same parameters as for bacterial Q^- (except for an overall shift in the anisotropic g-factors, which have previously been determined for Q^-). These results provide evidence that A₁ is a quinone molecule. The electron spin polarized signal of P₇₀₀ ⁺ is part of the better resolved spectrum from the deuterated PSI particles. The nature of the P₇₀₀ ⁺ ESP is not clear; however, it appears that it does not exhibit the polarization pattern required by mechanisms which have been used so far to explain the ESP in PSI.Abbreviations hf hyperfine - A₀ A₀ acceptor of photosystem I - A₁ A₁ acceptor of photosystem I - Brij-58 polyoxyethylene 20 cetyl ether - CP1 photosystem I particles which lack ferridoxin acceptors - ESP electron spin polarized - EPR electron paramagnetic resonance - I intermediary electron acceptor, bacteriopheophytin - LDAO lauryldimethylamine - N-oxide, P₇₀₀ primary electron donor of photosystem I - PSI photosystem I - P₇₀₀ ^T triplet state of primary donor of photosystem I - P₈₇₀ primary donor in R. sphaeroides reaction center - Q quinore-acceptor in photosynthetic bacteria - RC reaction center     

Critical evaluation of electron transfer kinetics in P700–FA/FB, P700–FX, and P700–A1 Photosystem I core complexes in liquid and in trehalose glass

This work aims to fully elucidate the effects of a trehalose glassy matrix on electron transfer reactions in cyanobacterial Photosystem I (PS I). Forward and backward electron transfer rates from A_1A^? and A_1B^? to F_X, and charge recombination rates from A₀^?, A_1B^?, A_1A^?, F_X^?, and [F_A/F_B]^? to P₇₀₀⁺ were measured in P₇₀₀–F_A/F_B complexes, P₇₀₀–F_X cores, and P₇₀₀–A₁ cores, both in liquid and in a trehalose glassy matrix at 11% humidity. By comparing CONTIN-resolved kinetic events over 6 orders of time in increasingly simplified versions of PS I at 480?nm, a wavelength that reports primarily A_1A^?/A_1B^? oxidation, and over 9 orders of time at 830?nm, a wavelength that reports P₇₀₀⁺ reduction and A₀^? oxidation, assignments could be made for nearly all of the resolved kinetic phases. Trehalose-embedded PS I samples demonstrated partially arrested forward electron transfer. The fractions of complexes in which electron transfer did not proceed beyond A₀, A₁ and F_X were 53%, 16% and 22%, respectively, with only 10% of electrons reaching the terminal F_A/F_B clusters. The ~10?μs and ~150?μs components in both liquid and trehalose-embedded PS I were assigned to recombination between A_1B^? and P₇₀₀⁺ and between A_1A^? and P₇₀₀⁺, respectively. The kinetics and amplitudes of these resolved kinetic phases in liquid and trehalose-embedded PS I samples could be well-fitted by a kinetic model that allowed us to calculate the asymmetrical contribution of the A_1A^? and A_1B^? quinones to the electrochromic signal at 480?nm. Possible reasons for these effects are discussed.     

Metallobleomycins: electron spin resonance study on nitrosyl complex of iron(II)-Bleomycin

The ESR spectrum of the bleomycin-Fe(II)NO complex shows rhombic symmetry with a triplet hyperfine interaction in the g_z signal, and its ESR parameters have been compared with those of the ferrous-NO complexes of hemoproteins. The substitution of ₁₄NO by ₁₅NO gives the transition from a triplet to a doublet in the g_z absorption with a concomitant change in the nitrogen hyperfine constant. The addition of DNA to the ferrous-NO complex of bleomycin induces the greater separation of the g_x and g_y absorptions in comparison with the original ESR spectrum. The present three-line g_z signal for the bleomycin-Fe(II)-NO complex is indicative of weakened fifth axial nitrogen ligand-to-iron bonding with concomitantly stronger NO-to-iron bonding. On the other hand, the ESR feature of the bleomycin-Fe(III) complex is typical of the rhombic low-spin type, and no stable ferric-NO complex of bleomycin is formed.