Stable Singlet Biradicals of Rare-Earth-Fused Diporphyrin-Triple-Decker Complexes with Low Energy Gaps and Multi-Redox States.

Dinuclear rare-earth (TbIII , YIII ) triple-decker complexes with a fused diporphyrin (FP) and two tetraphenylporphyrin (TPP) ligands were synthesized in neutral, dianionic, and diprotonated forms. The neutral forms have large open shell biradical character, as determined from the temperature dependency of the magnetic susceptibility measurements and theoretical calculations. The coupling value (J=-1.4 kcal mol-1 , -487 cm-1 ) of the radical centers in the neutral form of the YIII complex indicates weak pairing interactions. Theoretical calculations on the neutral form reveal a significant biradical character (y=68 %). Furthermore, the TbIII complex exhibits multi-redox states, having more than eight clear peaks in the voltammetry curves. The optical (3700 nm, 0.33 eV) and electrochemical measurements (3400 nm, 0.36 eV) indicate that the neutral form has very small HOMO-LUMO energy gap. Despite the large biradical character, the neutral complexes are thermally stable and do not decompose on heating at 120 °C. These complexes with unique characteristics are promising candidates for use in molecular electronics, optics, and spintronics.

Redox-Driven Symmetry Change for Terbium(III) Bis(porphyrinato) Double-Decker Complexes by the Azimuthal Rotation of the Porphyrin Macrocycles.

Molecular structures for three oxidation forms (anion, radical, and cation) of terbium(III) bis(porphyrinato) double-decker complexes have been systematically studied. We found that the redox state controls the azimuthal rotation angle (φ) between the two porphyrin macrocycles. For [TbIII (tpp)2 ]n (tpp: tetraphenylporphyrinato, n=-1, 0, and +1), φ decreases at each stage of the oxidation process. The decrease in φ is due to the higher steric repulsion between the phenyl rings on the porphyrin macrocycle and the ß hydrogen atoms on the other porphyrin macrocycle, which results from the shorter interfacial distance between the two porphyrin macrocycles. Conversely, φ=45° for both [TbIII (oep)2 ]-1 and [TbIII (oep)2 ]0 (oep: octaethylporphyrinato), but φ=36° for [TbIII (oep)2 ]+1 . Theoretical calculations suggest that the smaller azimuthal rotation angle of the cation form is due to the electronic interaction in the doubly oxidized ligand system.

Systematic Structural Elucidation for the Protonated Form of Rare Earth Bis(porphyrinato) Double-Decker Complexes: Direct Structural Evidence of the Location of the Attached Proton.

Direct structural evidence of the presence and location of the attached proton in the protonated form of rare earth bis(porphyrinato) double-decker complexes is obtained from an X-ray diffraction study of single crystals for a series of protonated forms of bis(tetraphenylporphyrinato) complexes [M(III)(tpp)(tppH)] (M = Tb, Y, Sm, Nd, and La). When CHCl3 is used as a solvent for crystallization of the complexes, their nondisordered molecular structures are obtained and the attached proton is identified on one of the eight nitrogen atoms. Use of other solvents affords another type of crystal, in which the position of the proton is disordered and thus the molecular structure is averaged. La complex also affords the disordered average structure even when CHCl3 is used for crystallization. A variable-temperature diffraction study for the Tb complex reveals that the dynamics of the proton in the nondisordered crystal is restricted.

Preservation of mechanical and energetic function after adenoviral gene transfer in normal rat hearts.

1. The aim of the present study was to examine the acute and chronic effects of adenoviral gene transfer on cardiac function in terms of left ventricular (LV) mechanoenergetic function. Recombinant adenoviral vector carrying beta-galactosidase and green fluorescent protein genes (Ad.betagal-GFP) was used. Cardiac function was examined in cross-circulated rat heart preparations, where end-systolic/diastolic pressure-volume relationships (ESPVR/EDPVR), systolic pressure-volume area (PVA), LV relaxation rate, equivalent maximal elastance at mid-range LV volume (eE(max) at mLVV), coronary blood flow, coronary vascular resistance and myocardial oxygen consumption (VO(2)) were also measured. 2. To examine the ex vivo acute effects of the adenoviral vector, data were obtained before and 30-90 min after intracoronary infusion of Ad.betagal-GFP in the excised, cross-circulated hearts that underwent serotonin pretreatment. To examine the in vivo chronic effects of adenoviral gene transfer, normal rat hearts received Ad.betagal-GFP or saline by a catheter-based technique and data were obtained 3 days after the injection of Ad.betagal-GFP or saline. 3. The ESPVR, EDPVR, LV relaxation rate, eE(max) at mLVV, coronary blood flow and coronary vascular resistance remained unchanged in Ad.betagal-GFP-transfected hearts in both ex vivo acute and in vivo chronic experiments. Moreover, the ex vivo and in vivo transfection caused no change in the slope and VO(2) intercept of the VO(2)-PVA relationship, VO(2) for basal metabolism and for Ca(2+) handling in excitation-contraction coupling and O(2) costs of LV contractility. 4. These results indicate that adenoviral gene transfer has neither acute nor chronic toxic effects on LV mechanical and energetic function. A special combination of in vivo adenoviral gene transfer and a cross-circulation experimental system may provide a useful novel strategy to explore the functional and mechanoenergetic role of specifically targeted genes in the diseased heart.

Restoration of mechanical and energetic function in failing aortic-banded rat hearts by gene transfer of calcium cycling proteins.

The aim of this study was to examine whether short- and long-term gene transfer of Ca(2+) handling proteins restore left ventricular (LV) mechanoenergetics in aortic banding-induced failing hearts. Aortic-banded rats received recombinant adenoviruses carrying sarcoplasmic reticulum Ca(2+)-ATPase (SERCA2a) (Banding+SERCA), parvalbumin (Banding+Parv) or beta-galactosidase (Banding+betagal), or an adeno-associated virus carrying SERCA2a (Banding+AAV.SERCA) by a catheter-based technique. LV mechanoenergetic function was measured in cross-circulated hearts. "Banding", "Banding+betagal" and "Banding+saline" groups showed lower end-systolic pressure at 0.1 ml intraballoon water (ESP(0.1)), higher end-diastolic pressure at 0.1 ml intraballoon water (EDP(0.1)) and slower LV relaxation rate, compared with "Normal" and "Sham". However, "Banding+SERCA" and "Banding+Parv" showed high ESP(0.1), low EDP(0.1) and fast LV relaxation rate. In "Banding", "Banding+betagal" and "Banding+saline", slope of relation between cardiac oxygen consumption and systolic pressure-volume area, O(2) cost of total mechanical energy, was twice higher than normal value, whereas slope in "Baning+SERCA" and "Banding+Parv" was similar to normal value. Furthermore, O(2) cost of LV contractility in the 3 control banding groups was approximately 3 times higher than normal value, whereas O(2) cost of contractility in "Banding+SERCA", "Banding+AAV.SERCA" and "Banding+Parv" was as low as normal value. Thus, high O(2) costs of total mechanical energy and of LV contractility in failing hearts indicate energy wasting both in chemomechanical energy transduction and in calcium handling. Improved calcium handling by both short- and long-term overexpression of SERCA2a and parvalbumin transforms the inefficient energy utilization into a more efficient state. Therefore enhancement of calcium handling either by resequestration into the SR or by intracellular buffering improves not only mechanical but energetic function in failing hearts.

Targeted gene transfer increases contractility and decreases oxygen cost of contractility in normal rat hearts.

The aim of this study was to examine how global cardiac gene transfer of sarcoplasmic reticulum Ca(2+)-ATPase (SERCA2a) can influence left ventricular (LV) mechanical and energetic function, especially in terms of O(2) cost of LV contractility, in normal rats. Normal rats were randomized to receive an adenovirus carrying the SERCA2a (SERCA) or beta-galactosidase (beta-Gal) gene or saline by a catheter-based technique. LV mechanical and energetic function was measured in cross-circulated heart preparations 2-3 days after the infection. The end-systolic pressure-volume relation was shifted upward, end-systolic pressure at 0.1 ml of intraballoon water volume was higher, and equivalent maximal elastance, i.e., enhanced LV contractility, was higher in the SERCA group than in the normal, beta-Gal, and saline groups. Moreover, the LV relaxation rate was faster in the SERCA group. There was no significant difference in myocardial O(2) consumption per beat-systolic pressure-volume area relation among the groups. Finally, O(2) cost of LV contractility was decreased to subnormal levels in the SERCA group but remained unchanged in the beta-Gal and saline groups. This lowered O(2) cost of LV contractility in SERCA hearts indicates energy saving in Ca(2+) handling during excitation-contraction coupling. Thus overexpression of SERCA2a transformed the normal energy utilization to a more efficient state in Ca(2+) handling and superinduced the supranormal contraction/relaxation due to enhanced Ca(2+) handling.

Transcoronary gene transfer of SERCA2a increases coronary blood flow and decreases cardiomyocyte size in a type 2 diabetic rat model.

The Otsuka Long-Evans Tokushima fatty rat is an animal model of Type 2 diabetes mellitus (DM), which is characterized by diastolic dysfunction associated with decreased sarcoplasmic reticulum Ca(2+)-ATPase (SERCA2a). The aim of this study was to examine whether gene transfer of SERCA2a can influence coronary blood flow and cardiomyocyte diameter in this model. DM rats were injected with adenovirus carrying SERCA2a (DM+SERCA) or beta-galactosidase gene (DM+betaGal). Coronary blood flow was measured in cross-circulated excised hearts 3 days after infection. Although in all groups coronary blood flow remained unchanged even if left ventricular (LV) volume or intracoronary Ca(2+) infusion was increased, the DM+SERCA group showed a sustained increase in coronary blood flow compared with the other groups. This result suggests that the sustained high coronary blood flow is a specific response in SERCA2a-overexpressed hearts. Although the LV weight-to-body weight ratio (LV/BW) and cardiomyocyte diameter were higher in the DM and DM+betaGal groups than in the non-DM group, in the DM+SERCA group, these measurements were restored to non-DM size. The percentages of collagen area in the three DM groups was significantly higher than results shown in non-DM rats, and there were no significant differences in collagen area percentage among the three DM groups. These results suggest that a lowered LV/BW by SERCA2a overexpression is due mainly to reduced size of cardiomyocytes without any changes in collagen area percentage. In conclusion, in DM failing hearts, SERCA2a gene transfer can increase coronary blood flow and reduce cardiomyocyte size without reduction in collagen production.

Mechanical and metabolic rescue in a type II diabetes model of cardiomyopathy by targeted gene transfer.

The Otsuka-Long-Evans Tokushima Fatty rat represents a model for spontaneous non-insulin-dependent type II diabetes mellitus (DM), characterized by diastolic dysfunction and associated with abnormal calcium handling and decrease in sarcoplasmic reticulum Ca2+ -ATPase (SERCA2a) expression. The aim of this study was to examine whether SERCA2a gene transfer can restore the energetic deficiency and left ventricular (LV) function in this model. DM rats were randomized to receive adenovirus carrying either the SERCA2a gene (DM + Ad.SERCA2a) or the beta-galactosidase gene (DM + Ad.betaGal) or saline (DM + saline). LV mechanoenergetic function was measured in cross-circulated heart preparations 3 days after infection. In DM, end-systolic pressure at 0.1 ml intraballoon water (ESP0.1) was low and end-diastolic pressure at 0.1 ml intraballoon water (EDP0.1) was high (22 mm Hg), compared with non-DM (EDP0.1 12 mm Hg). In DM + Ad.SERCA2a, however, ESP0.1 was increased over 200 mm Hg and EDP(0.1) was decreased to 7 mm Hg. LV relaxation rate was fast in DM + Ad.SERCA2a, but slow in the other DM groups. There was no difference in relation between cardiac oxygen consumption per beat and systolic pressure-volume area among all groups. Finally, the oxygen cost of LV contractility in DM was about three times as high as that of normal. In DM + Ad.SERCA2a, the oxygen cost decreased to control levels, but in DM + Ad.betaGal/DM + saline it remained high. In DM failing hearts, the high oxygen cost indicates energy wasting, which contributes to the contractile dysfunction observed in diabetic cardiomyopathy. SERCA2a gene transfer transforms this inefficient energy utilization into a more efficient state and restores systolic and diastolic function to normal.