Chemoselective Umpolung of Enals for Asymmetric Homoenolate Cross-Annulation of Enals and Aldehydes Catalyzed by N-Heterocyclic Carbene.

An asymmetric homoenolate cross-annulation of enals and aldehydes with high enantioselectivity is realized by NHC-catalyzed chemoselective umpolung of enals. The reaction proceeds in a highly chemoselective manner, selectively generating the conjugated Breslow intermediates from enals rather than aldehydes, enabling the homoenolate addition of enals to aldehydes in preference to competing acyl anion-mediated reactions. Enantioenriched substituted γ-butyrolactones are formed in good yields with high enantioselectivities.

Optimization of the alkyl side chain length of fluorine-18-labeled 7α-alkyl-fluoroestradiol.

INTRODUCTION: Several lines of evidence suggest that 7α-substituted estradiol derivatives bind to the estrogen receptor (ER). In line with this hypothesis, we designed and synthesized (18)F-labeled 7α-fluoroalkylestradiol (Cn-7α-[(18)F]FES) derivatives as molecular probes for visualizing ERs. Previously, we successfully synthesized 7α-(3-[(18)F]fluoropropyl)estradiol (C3-7α-[(18)F]FES) and showed promising results for quantification of ER density in vivo, although extensive metabolism was observed in rodents. Therefore, optimization of the alkyl side chain length is needed to obtain suitable radioligands based on Cn-7α-substituted estradiol pharmacophores. METHODS: We synthesized fluoromethyl (23; C1-7α-[(18)F]FES) to fluorohexyl (26; C6-7α-[(18)F]FES) derivatives, except fluoropropyl (C3-7α-[(18)F]FES) and fluoropentyl derivatives (C5-7α-[(18)F]FES), which have been previously synthesized. In vitro binding to the α-subtype (ERα) isoform of ERs and in vivo biodistribution studies in mature female mice were carried out. RESULTS: The in vitro IC50 value of Cn-7α-FES tended to gradually decrease depending on the alkyl side chain length. C1-7α-[(18)F]FES (23) showed the highest uptake in ER-rich tissues such as the uterus. Uterus uptake also gradually decreased depending on the alkyl side chain length. As a result, in vivo uterus uptake reflected the in vitro ERα affinity of each compound. Bone uptake, which indicates de-fluorination, was marked in 7α-(2-[(18)F]fluoroethyl)estradiol (C2-7α-[(18)F]FES) (24) and 7α-(4-[(18)F]fluorobutyl)estradiol (C4-7α-[(18)F]FES) (25) derivatives. However, C1-7α-[(18)F]FES (23) and C6-7α-[(18)F]FES (26) showed limited uptake in bone. As a result, in vivo bone uptake (de-fluorination) showed a bell-shaped pattern, depending on the alkyl side chain length. C1-7α-[(18)F]FES (23) showed the same levels of uptake in uterus and bone compared with those of 16α-[(18)F]fluoro-17ß-estradiol. CONCLUSIONS: The optimal alkyl side chain length of (18)F-labeled 7α-fluoroalkylestradiol was the shortest: C1-7α-[(18)F]FES. Our results indicate that shorter chain lengths within the 4-Å ligand binding cavities of ERα are suitable for 7α-fluoroalkylestradiol derivatives.

Synthesis and evaluation of 7α-(3-[(18)F]fluoropropyl) estradiol.

INTRODUCTION: Several lines of evidence suggest that C-7α-substituted estradiol derivatives are well tolerated by estrogen receptor (ER). In line with this hypothesis, we are interested in the design and synthesis of C-7α-substituted estrogens as molecular probes to visualize ER function. METHODS: We have synthesized 7α-(3-[(18)F]fluoropropyl) estradiol (C3-7α-[(18)F]FES) as a potential radiopharmaceutical for ER imaging by positron emission tomography (PET). In vitro receptor binding and in vivo biodistribution and blocking studies in mature female mice, and in vivo metabolite analysis were carried out. Furthermore, in vivo ER-selective uptake was confirmed using ER-positive T-47D and ER-negative MDA-MB-231 tumor-bearing mice. We also compared the in vivo biodistribution of C3-7α-[(18)F]FES with 16α-[(18)F]FES. RESULTS: C3-7α-[(18)F]FES was produced in moderate yields (30.7%±15.1%, decay corrected) with specific activity of 32.0±18.1GBq/µmol (EOS). The in vitro binding affinity of C3-7α-FES to the ERα isoform was sufficient and equivalent to that of estradiol. C3-7α-[(18)F]FES showed selective uptake in ER-rich tissues, such as the uterus (4.7%ID/g±1.2%ID/g at 15minutes) and ovary (4.0%ID/g±1.0%ID/g at 5minutes). The tissue time activity curves of these organs showed reversible kinetics, indicating suitability for quantitative analysis. The highest contrast was obtained at 120minutes after injection of C3-7α-[(18)F]FES in the uterus (uterus/blood=18, uterus/muscle=17.3) and ovary (ovary/blood=6.3, ovary/muscle=6.0). However, the level of selective uptake of C3-7α-[(18)F]FES was significantly lower than that of 16α-[(18)F]FES. Most radioactivity in the uterus was detected in unchanged form, although peripherally C3-7α-[(18)F]FES was rapidly degraded to hydrophilic metabolites. In accordance with this peripheral metabolism, gradual increases in bone radioactivity were observed, indicating defluorination. Coinjection with estradiol dose-dependently inhibited C3-7α-[(18)F]FES uptake in the uterus and ovary. The in vivo IC50 values of estradiol in the uterus and ovary were 34.4 and 38.5nmol/kg, respectively. Furthermore, in vivo tumor uptake of C3-7α-[(18)F]FES was significantly higher (unpaired t test with Welch's correction; p=0.015) in ER-positive T-47D tumors (2.3%ID/g±0.4%ID/g) than ER-negative MDA-MB-231 tumors (0.9%ID/g±0.1%ID/g). CONCLUSIONS: Although extensive metabolism was observed in rodents, C3-7α-[(18)F]FES showed promising results for quantitative analysis of ER density in vivo. However, the selective uptake of C3-7α-[(18)F]FES was lower than that of 16α-[(18)F]FES. Further optimizations and structure-activity relationship studies of the C-7α-substituted estradiol are needed.

Theoretical study of the excited states of the photosynthetic reaction center in photosystem II: electronic structure, interactions, and their origin.

The excited states of the chlorophyll 6-mer in the photosystem II (PSII) reaction center (RC) were investigated theoretically using ab initio quantum chemical calculations, and the results are compared with those of the bacterial reaction center (bRC). A significant difference in the peak at the lowest energy in the absorption spectra arises from the structural asymmetry of the special pair (SP). The origin can be traced back to the structural difference in the CD helix. The low-lying excited states are characterized as a linear combination of the excited states of the chlorophyll monomers, which verifies the applicability of exciton theory. Analysis of the molecular interactions clearly explains the cause of the constructive/destructive interferences in the state transition moment. The protein electrostatic potential (ESP) decreases the energy of the charge-transfer (Chl(D1)→Pheo(D1)) state. The ESP also localizes the HOMO distribution to the P(D1) moiety and increases the ionization potential.