Surface modification of CdS quantum dots using thiols-structural and photophysical studies.

This study is aimed at identifying a suitable organic thiol for CdS by studying its structural, thermal and photophysical characteristics. Quantum dots of the II-VI semiconductor CdS, in the size regime of 2.0-3.3 nm, were prepared in the cubic phase by a wet chemical method. Five organic thiols were used for capping: (i) 1,4-dithiothreitol (DTT), (ii) 2-mercaptoethanol (ME), (iii) cysteine (Cys), (iv) methionine (Meth), and (v) glutathione (GSH). Structural studies were carried out by x-ray diffraction (XRD) and transmission electron microscopy (TEM), which revealed the cubic phase of CdS. Optical properties were studied by FT-IR, UV-visible and fluorescence spectroscopic techniques, and a comparison was made between uncapped and capped CdS. FT-IR studies suggested two different bonding mechanisms of the capping agents with the CdS. GSH and DTT capped CdS showed significant decrease in absorption wavelengths. An increase in band gap was observed in two cases: when (i) capped and (ii) decreased in size. The band gap was increased from 2.50 eV for the uncapped to 2.77 eV for the DTT capped CdS. DTT was found to be the best capping agent for CdS among these five organic thiols in two aspects: (i) yielding lower grain size in cubic phase, and (ii) good fluorescence properties with efficient quenching of the surface traps.

Studies on heme release from normal and metal ion reconstituted hemoglobin mediated through ionic surfactant.

The interaction of metal-substituted hemoglobin (MHb), where M = Ni and Cu (T-state with no O2 and CO binding capability) and Fe (R-state when CO is bound), with cationic cityl trimethyl ammonium bromide (CTAB) and anionic (sodium dodecyl sulfate-SDS) surfactants has been studied using spectroscopic techniques-UV-visible, electron paramagnetic resonance (EPR), and Fourier transform-Raman-with additional supportive evidence coming from conductivity measurements. We observed the loss of 5-coordination in all three hemoglobins below the critical micelle concentration (CMC) of surfactant, with noticeable differences, suggesting differing mechanisms involved in this process. In addition, above the CMC, Ni- and Cu-hemes were found to leave their proteins more easily than Fe-heme, presumably due to weaker or no bond with the proximal histidine in the former. The released heme is stabilized by micellar media through a hydrophobic interaction process. Of the two surfactants, CTAB seems to be capable of releasing the heme better than SDS and it is attributed to the greater hydrophobicity of CTAB though the charge of the surfactant plays an important role.

Conformational changes monitored by fluorescence study on reconstituted hemoglobins.

Intrinsic steady state fluorescence measurements were performed on a series of reconstituted metal ion and hybrid hemoglobins (Hbs). At 296 nm excitation, the spectrum exhibits a broad and asymmetric feature in the case of copper and nickel reconstituted hemoglobins. Deconvolution of the fluorescence bands clearly reveals the existence of two definite peaks. A similar trend was also observed for hybrid hemoglobins (CuNi, NiCu, CuFe-CO, and NiFe-CO). A guassian fit of the fluorescence bands in these proteins again yields two prominent peaks, which are assigned as due to two different tryptophan (Trp) environments. A relative ratio of the amplitudes of these peaks indicates the percentage of T-character in these molecules. This is in support to our previous findings by other spectroscopic studies on the same molecules. These studies therefore, suggest the presence of two different environments of a tryptophan thereby revealing structural heterogeneity among the subunits.

Redox reactions of hemoglobin.

Redox reactions of hemoglobin have gained importance because of the general interest of the role of oxidative stress in diseases and the possible role of red blood cells in oxidative stress. Although electron paramagnetic resonance (EPR) is extremely valuable in studying hemoglobin redox reactions it has not been adequately used. We have focused in this review on the important contributions of EPR to our understanding of hemoglobin redox reactions. We have limited our discussion to the redox reactions thought to occur under physiological conditions. This includes autoxidation as well as the reactions of hydrogen peroxide generated by superoxide dismutation. We have also discussed redox reactions associated with nitric oxide produced in the circulation. We have pinpointed the value of using EPR to detect and study the paramagnetic species and free radicals formed during these reactions. We have shown how EPR not only identifies the paramagnetic species formed but can also be used to provide insights into the mechanism involved in the redox reactions.

Resonance Raman spectroscopic studies in copper reconstituted and hybrid hemoglobins: probe into subunit heterogeneity.

Copper reconstituted hemoglobin (CuHb), copper containing T-state hybrid hemoglobins like alpha2(Ni)beta2(Cu), and alpha2(Cu)beta2(Ni), and intermediate R-state hybrids like alpha2(CO-Fe)beta2(Cu) and alpha2(Cu)beta2(Fe-CO) are studied using resonance Raman (RR) spectroscopy at two different excitation wavelengths. The high frequency RR region in CuHb indicates the presence of both 4- and 5-coordinate forms of Cu(II). In hybrid Hbs, the presence of two distinct metal ion environments within one particular subunit is evident. This is also consistent with previous findings using EPR spectroscopy and sulfydryl reactivity studies on these hybrid Hbs. The low frequency RR region on these copper derivatives of HbA further suggests the existence of two different heme moieties within the subunit.

Copper(II) azide complexes of aliphatic and aromatic amine based tridentate ligands: novel structure, spectroscopy, and magnetic properties.

Copper(II) azide complexes of three tridentate ligands namely 2,6-(3,5-dimethylpyrazol-1-ylmethyl)pyridine (L), 2,6-(pyrazol-1-ylmethyl)pyridine (L'), and dipropylenetriamine (dpt) yield three kinds of complexes with different azide-binding modes. The ligand L forms two end-on-end (mu-1,3) diazido-bridged binuclear complexes, [CuL(mu-N(3))](2)(ClO(4))(2) (1) and [CuL(mu-N(3))(ClO(4))](2).2CH(3)CN (2), and L' forms a perchlorato-bridged quasi-one-dimensional chain complex, [CuL'(N(3))(ClO(4))](n)() (3) with monodentate azide coordination. The ligation of dipropylenetriamine (dpt) gives a end-on (mu-1,1) diazido-bridged binuclear copper complex [Cu(dpt)(mu-N(3))](2)(ClO(4))(2) (4). The crystal and molecular structures of these complexes have been solved. Variable-temperature EPR results of 1 and 2 are identical and indicate the presence of both ferromagnetic and antiferromagnetic interactions within the dimer, the former dominating at low temperatures and the latter at high temperatures. The unusual temperature-dependent magnetic moment and EPR spectra of this dimer reveal the presence of temperature-dependent population of two triplet states, one being caused by antiferromagnetic and the other by ferromagnetic interaction, the former transforming to the latter on cooling. While the interaction of ground spin doublets of the two metal centers gives rise to a ferromagnetic coupling of J(g) = 90.73 cm(-1), the other coupling of J(e) = -185.64 cm(-1) is suggested to be caused by the interaction between an electron in one metal center and an electron from the azide of the other monomer by excitation of a d-electron to the empty ligand orbital. The ferromagnetic state is energetically favored by 104.39 cm(-1). Compound 3 exhibits axial spectra at room temperature and 77 K, and variable-temperature magnetic susceptibility data indicate that the copper centers form a weakly antiferromagnetic one-dimensional chain with J = -0.11 cm(-1). In the case of 4, the unique presence of two nonidentical dimeric units with different bond lengths and bond angles within the unit cell as inferred by crystal structure is proved by single-crystal EPR spectroscopy.

Lattice-dictated conformers in bis(pyrazolyl)pyridine-based iron(II) complexes: Mössbauer, NMR, and magnetic studies.

Iron(II) complexes [FeL(2)](ClO(4))(2).CH(3)CN, [FeL(2)](BPh(4))(2).2CH(3)CN, and [FeL(2)](PF(6))(2) with an FeN(6) chromophore of the same ligand L (2,6-bis(3,5-dimethylpyrazol-1-ylmethyl)pyridine) and differing counterions have been made and their crystal and molecular structures determined. The first two crystallized in triclinic space group P(-)1, and the third, with PF(6)(-) anion in Ibca space group. The FeL(2) complex ions in all lattices have similarly distorted octahedral geometry. Variable-temperature Mössbauer spectra of [FeL(2)](ClO(4))(2).CH(3)CN and [FeL(2)](PF(6))(2) measured in the temperature range 1.7-300 K reveal temperature-dependent populations of two different spin states with increased amount of low-spin form at high temperatures, a phenomenon unlike the normal spin crossover behavior; this abnormal behavior is interpreted here as due to the presence of two different conformations. It is very interesting to note that the two different compounds have similar spectra, Mössbauer parameters, and temperature dependence. But the variable-temperature Mössbauer spectra of [FeL(2)](BPh(4))(2).2CH(3)CN in the range 20-300 K do not show the presence of such different species but exhibit a clear phase transition at approximately 200 K. This phase transition is further supported by SQUID measurements. The results of variable-temperature (1)H NMR in CD(3)CN and the solution susceptibility measurement of all complexes also support the presence of high-spin and low-spin forms in solution. Hence, the complex ion [FeL(2)](2+) exhibits a thermally driven interconversion between low-spin and a high-spin structural forms-a phenomenon observed in the solid and solution states due to ligand dynamics. This is not due to the well-known spin crossover phenomenon. These results are compared with the case of normal spin crossover seen in [FeL'(2)](ClO(4))(2) (L' = 2,6-(bis(pyrazol-1-ylmethyl)pyridine)).

Hyperfine interaction in K2Ba[Fe(NO2)6].

Magnetic hyperfine splitting observed in the low temperature Mössbauer spectrum of potassium barium hexanitro ferrate(II), in the absence of any external field, is attributed to the 5T2g state of the central metal atom further split into a ground 5Eg state and a first excited 5B2g state under a distorted octahedral symmetry in contrast to the earlier prediction of 1A1g ground state on the basis of room temperature Mössbauer spectral and other properties. The central iron atom is coordinated to six nitrito groups (NO2-), having an oxidation state of +2. The temperature dependence of Mössbauer spectra is explained on the basis of electronic relaxation among the spin-orbit coupled levels of the 5Eg ground state. Various kinds of electronic relaxation mechanisms have been compared to explain the proposed mechanism. The observed temperature dependent spectra with varying internal magnetic field and line width can be explained by simple spin lattice relaxation.

Fourier transform Raman approach to structural correlation in hemoglobin derivatives.

In order to obtain information on the structural aspects of hemoglobin (Hb), Fourier transform Raman (FT-R) measurements on various ferrous, ferric derivatives and nickel reconstituted Hb (NiHb) has been made. FT-R spectra for these derivatives were obtained by laser excitation in the near infrared region (NIR) (1064 nm) whereby the wave-number region (600-1700 cm-1) related to both porphyrin ring modes and some globin modes were monitored. Comparison of various modes was made based on previous resonance Raman (RR) results. The wave-number shifts with respect to changes in oxidation state and spin state are very similar to those observed by RR. Additional bands at 1654, 1459, and 1003 cm-1 for deoxyHb and at 1656, 1454, and 1004 cm-1 for oxy Hb can be correlated to globin modes. The shift in the position of these bands for the binding of oxygen can be related to changes in conformation during the transformation. The presence of two distinct sites in NiHb could be monitored by the use of FT-R technique.

Superoxide produced in the heme pocket of the beta-chain of hemoglobin reacts with the beta-93 cysteine to produce a thiyl radical.

The role of the beta-93 cysteine residue in the hemoglobin autoxidation process has been delineated by electron paramagnetic resonance. At low temperatures (8 K) after incubation at 235 K, free radical signals were detected. An analysis of the free radical spectrum produced implies that, besides the superoxide radical expected to be formed during autoxidation, an isotropic free radical is produced with a giso of 2.0133. This g value is consistent with that expected for a sulfur radical. Blocking the beta-93 sulfhydryl group with N-ethylmaleimide was found to eliminate the formation of the isotropic radical, but not the superoxide. This finding confirms the assignment of the isotropic radical as a thiyl radical originating from the oxidation of the cysteine SH group. A kinetic analysis of the time course for the formation of both the superoxide and thiyl radicals is consistent with a reversible electron transfer process between superoxide in the heme pocket of the beta-chains and the cysteine residue. This reaction is expected to produce both a thiyl radical and a peroxide. Direct evidence for peroxide production comes from the detection of a transient Fe(III) heme peroxide complex. The significance of the electron transfer process producing a thiyl radical is discussed. It is shown that the formation of the thiyl radical decreases the rate of autoxidation for the beta-chain and reduces heme degradation attributed to the reaction of superoxide with the heme. The insights gained from these low-temperature studies are believed to be relevant to room-temperature autoxidation.

Surface active peptide-mediated porphyrin aggregation.

Surface active pentapeptide [2(HCOO-). Lys-Ala-Ala-Lys(Z)-Tyr-OCH3] has been synthesized and its micelle formation investigated using conductometric, pH metric, and UV spectroscopic techniques. The double head double tail peptide molecules are shown to interact with water soluble meso-tetrakis (4-sulfonatophenyl)-porphyrin [TPPS]H2 to form characteristic H-type aggregate at low concentrations, as evidenced by UV-Vis and fluorescence spectroscopic techniques. Spectroscopic analysis reveals that the aggregate contains 1:2 porphyrin-peptide combination. The equilibrium constant for the formation of peptide-porphyrin complex has been obtained by using absorption spectral data. The present studies provide new insight into the peptide-porphyrin interaction.

Production of superoxide from hemoglobin-bound oxygen under hypoxic conditions.

By low temperature electron paramagnetic resonance we have detected the formation of a free radical signal during incubation of partially oxygenated hemoglobin at 235 K. The observed signal has g parallel = 2.0565 and g perpendicular = 2.0043, consistent with the previously reported values for superoxide. The presence of additional EPR signals for oxygen-17 bound hemoglobin, with (017-017)A perpendicular = 63 G and (017-016)A perpendicular = 94 G under identical conditions, confirms the presence of a radical containing two nonequivalent oxygens as required for a superoxide in magnetically inequivalent environments. The superoxide radical has not previously been directly detected during hemoglobin autoxidation because of its rapid dismutation. Our ability to follow the formation of superoxide for more than 15 min is attributed to its production in the hydrophobic heme pocket where dismutation is slow. The enhanced production of this free radical at intermediate oxygen pressures is shown to coincide with enhanced rates of hemoglobin autoxidation for partially oxygenated intermediates. The formation of superoxide in the heme pocket under these conditions is attributed to enhanced heme pocket flexibility. Greater flexibility facilitates distal histidine interactions which destabilize the iron-oxygen bond resulting in the release of superoxide radical into the heme pocket.

Biradicals as ESR probes of conformations in model beta-turn peptides.

Electron spin-spin exchange interaction in biradicals has been examined for its potential usefulness in the conformational analysis of peptides in solution. Three peptides with high propensity to adopt beta-turn conformations in solution, Boc-Cys-Pro-Xxx-Cys-NHMe (Xxx = Leu, 1; Xxx = Aib, 2; Xxx = Tyr, 3), have been modified into biradicals by spin labeling the thiols groups. Analysis of electron spin resonance spectra of these peptides in a variety of solvents and at different temperatures suggests that the population of folded conformations follows the order 2 > 1 > 3.

The hypoxic stress on erythrocytes associated with superoxide formation.

Superoxide is produced during the autoxidation of hemoglobin. Autoxidation of hemoglobin is, however, facilitated under hypoxic conditions where hemoglobin is only partially oxygenated. We have recently found that the erythrocyte superoxide dismutase does not fully react with the additional superoxide produced under hypoxic conditions. A leakage of superoxide from the erythrocyte is thus detected, resulting in a potential source for oxyradical damage to tissues. Detailed studies on intact erythrocytes as a function of oxygen pressure have now been performed. These studies further delineate the hypoxic stress on erythrocytes and the mechanism for the leakage of superoxide. By centrifugation of samples under various oxygen pressures it was possible to show an enhanced rate of lysis at reduced oxygen pressures with a maximum rate in the region of 25 mm Hg. At much lower pressures where the hemoglobin is mostly deoxygenated the rate of lysis was dramatically decreased with almost no lysis detected even after three days. Lysis is shown to be associated with superoxide membrane damage. The formation of superoxide which does not react with endogenous SOD reaches a maximum value at much lower pressures where most of the hemoglobin is deoxygenated. It is suggested that the leakage at low pressure is associated with the formation of superoxide by oxidation of hemoglobin associated with the membrane.

Spin label probes of the environment of cysteine beta-93 in hemoglobin.

The environment of cysteine beta-93 is altered during the oxygenation of hemoglobin. Electron spin resonance was used to probe the hemoglobin conformation in this crucial region on the proximal side of the heme. Spin-labeled hemoglobins in both the R-liganded state [methemoglobin and oxyhemoglobin] and the T-unliganded state [deoxyhemoglobin as well as Ni(II) and Cu(II) substituted hemoglobins] were investigated. Included in this study are iodoacetamide and maleimide labels with different constraints at the point of reaction with the SH-group, as well as a series of pyrrolidinyloxyl maleimide labels of different chain length. From differences in the correlation time of the spin labels it was possible to identify two distinct strongly immobilized configurations in addition to the relatively mobile configuration with the label on the surface of the protein. By dipolar interactions between the spin labels and paramagnetic Cu(II) at the heme center, the relative position of the three orientations for the spin label are defined. Differences are observed between the two hemoglobin conformations with respect to the relative population of the various orientations and with respect to the potential barrier associated with the reorientation of the spin labels.

Interaction of copper(II) with hemoglobins in the unliganded conformation.

The interaction of exogenous Cu(II) with stable T-state Ni(II)- and Cu(II)-reconstituted hemoglobins has been studied. The relative binding affinities for the two human hemoglobin Cu(II) binding sites are found to be reversed in these hemoglobins relative to native iron(II) hemoglobin A. Nickel hemoglobin, modified by N-ethylmaleimide (NEM), iodoacetamide, and carboxypeptidase A, is used to establish that the observed differences can be attributed to the protein quaternary conformation and not to the metal substitution. Magnetic interactions between the Cu(II) responsible for oxidation and the metal-heme center suggest that the Cu(II) is closer to the heme in T-state hemoglobin than R-state hemoglobin. This finding suggests a pathway for T-state heme oxidation which does not require the beta-93 sulfhydryl group, consistent with rapid Cu(II) oxidation for NEM-reacted deoxyhemoglobin.

Mössbauer, EPR and NMR studies of the acid-induced reduction and changes in spin state of ferric bleomycin.

Iron-57 Mössbauer, electron paramagnetic resonance (EPR) and H-1 nuclear magnetic resonance (NMR) studies of iron-bleomycin complexes in the pH range from 1.0 to 6.0 are reported. Sequential protonation of the ligands produces a variety of high-spin and low-spin complexes of the metal. Of particular interest is the reversible equilibrium between Fe(III)- and oxygen-stable Fe(II)-bleomycin. Below pH 3.5 Fe(II) complexes form, with maximal reduction occurring at approximately pH 2. At still lower pH, Fe(III) complexes unassociated with bleomycin become dominant. The observed reduction in the absence of exogenous reducing agents suggests the possible involvement of intramolecular autoreduction in bleomycin-mediated DNA degradation.

Interaction between bound cupric ion and spin-labeled cysteine beta-93 in human and horse hemoglobins.

The location of the various copper binding sites for horse and human hemoglobin was probed using spin labels attached to the beta-93 cysteine residue. Dipole-dipole interactions between the spin label and bound copper produce a decrease in the amplitude of the spin label spectrum which was used to estimate the Cu(II) spin label distance. By comparing the results with horse and human hemoglobin at 298 and 77 K four different Cu(II) binding sites were identified. The low affinity horse hemoglobin site with the sulfhydryl blocked (site 1) was found to be located 10-13 A from the sulfhydryl spin label on the surface of the molecule. Only with a free sulfhydryl is the site (site 2) in the pocket between the F and H helices closer to the SH-group and the iron populated. It is site 2 which is responsible for the oxidation. In frozen solutions a Cu-nitroxide distance of about 17 A was determined with human hemoglobin. This distance is consistent with the previously postulated location of the "high affinity" human hemoglobin site near the amino terminus of the beta-chain. At 298 K a much shorter Cu-nitroxide distance of about 7 A was calculated for human hemoglobin. This shorter distance at higher temperature also correlated with a slightly smaller value of g11 and A11 for the Cu(II) ESR spectrum. It is postulated that in solution cross-linking between nitrogenous ligands in the region of the amino terminus of one beta-chain and the carboxyl terminus of the other beta-chain can explain this shorter distance. This cross-link could involve histidine beta-143, which is one of the ligands thought to be also involved in site 1. Binding to the "high-affinity" site in solution thus stabilizes the "low-affinity" site 2 relative to site 1 explaining the reported interaction between the "high-affinity" and "low-affinity" sites.