The excited state of 4a-hydroxy-4a,5-dihydroFMN has been postulated to be the emitter in the bacterial bioluminescence reaction. However, while the bioluminescence quantum yield of the luciferase emitter is about 0.16, chemiluminescence and fluorescence quantum yields of earlier flavin models mimicking the luciferase emitter were no more than 10(-5). To further examine the proposed chemical identity of the luciferase emitter, 5-decyl-4a-hydroxy-4a,5-dihydroFMN was prepared as a new flavin model. Both the wild-type Vibrio harveyi luciferase and a catalytically active alphaC106A mutant formed complexes with the flavin model at a 1:1 molar ratio with K(d) values at 2.4 and 1.2 microM, respectively. This flavin model inhibited the activity of both luciferases, suggesting that it was bound to the enzyme active center. While the free flavin model was itself only very weakly fluorescent, its binding to either luciferase species resulted in markedly enhanced fluorescence, peaking at 440 nm. The fluorescence quantum yields of 5-decyl-4a-hydroxy-4a,5-dihydroFMN bound to wild-type and alphaC106A luciferases were 0.08 and 0.05, respectively, which are about 50% of the respective emitter bioluminescence quantum yields of these two luciferases. The present findings clearly demonstrated that the luciferase active site was suitable for marked enhancement of fluorescence of 4a-hydroxyflavin and, hence, provides a strong support to the proposed identity of 4a-hydroxy-4a,5-dihydroFMN, in its exited state, as the luciferase emitter.
Marine organisms are a rich source for natural products. Pyrrolo[4,3,2-de]quinolines and pyrido[4,3,2-mn]acridines are of major interest as metabolites in sponges and ascidians. Many of these compounds have generated interest both as challenging problems for structure elucidation and synthesis as well as for their cytotoxicities. The isolation, structure proof, biological activities, chemical properties and synthesis have attracted the attention of chemists, biologists and pharmacists. The principal structural feature of these alkaloids is the core of a planar iminoquinone moiety which can intercalate into DNA and cleave the DNA double helix or inhibit the action of topoisomerase II. Of the makaluvamines, rhakaluvamine F and A are the most cytotoxic to the HCT 116 cell line. The enhanced toxicity of the makaluvamines towards xrs-6 cells shows that all of the makaluvamines, except makaluvamine B, act like m-AMSA and etoposide in inhibiting topoisomerases via cleavable complex formation, or via the direct induction of DNA double-strand breaks. They are also amongst the most potent inhibitors of topoisomerase II. Both makaluvamine A and C can decrease tumor size in a solid human tumor model. Discorhabdin A and C in contrast are of high cytotoxicity, but they exhibit no inhibition of topoisomerase II. As representatives of the derivatives of pyrido[4,3,2-mn]acridine, cystodytins, kuanoniamines and diplamine are the most potent to inhibit HCT replication. Eilatin, as a 1,10-phenanthroline derivative, can form complexes with metal ions. It has been shown that these metal complexes can bind to DNA by intercalation. The new members of the pyrrolo[4,3,2-de]quinolines and pyrido[4,3,2- mn]acridines, such as veiutamine, discorhabdin G, tsitsikammamines, epinartins, arnoamines as well as sagitol are reviewed. Some successful syntheses of pyrrolo[4,3,2- de]quinoline ring system and pyrido[4,3,2-mn]acridine ring system are also reviewed in this article.
The gas-phase, carbon-catalyzed, microwave-promoted conversion of methane to ethylene, ethane, acetylene, and hydrogen is reported. A selection of C1−C4 hydrocarbons, hexadecane, and a cyclic hydrocarbon, cyclodecane, were also subjected to microwave conversion, resulting primarily in α-olefins, ethylene, and hydrogen. For methane conversion, the products are reminiscent of those found in methane pyrolysis. Microwave-induced cleavage of the liquid hydrocarbons provides conditions for the stabilization, by rapid thermal quenching in ambient-temperature liquid reagent, of products such as terminal olefins that would be labile under conventional (thermal bath) pyrolysis reaction conditions. The reactions of long chain acyclic and cyclic hydrocarbons involve high temperatures in the region of the spark leading to a cascade of unimolecular scission reactions from initially formed biradicals from cycloalkanes or radical pairs from linear alkanes, largely to the exclusion of intermolecular radical−radical and radical−molecule reactions. The observed products are discussed in terms of the thermochemistry and dynamics of high-temperature unimolecular biradical and radical decomposition reactions, and mechanisms involving reactive surface metal sites. The reaction rates of alkanes were found to increase with the molecular weight of the reactants. Mechanistic pathways consistent with these results are discussed.
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