Electrochemical catalytic cyclization reactions using environmentally friendly methodologies

The electrochemical intramolecular cyclisation of bromoalkoxylated derivatives 1 was carried out using Ni(II) complexes as the catalysts in ethanol solutions by constant-current electrolysis in one-compartment cell in the absence of sacrificial anodes as an environmentally friendly system. The reduction of the substrates proceeds via one-electron cleavage of the carbon–bromine bond to form radical-type intermediates that undergo cyclisation to afford cyclic ethers in moderate to good yields.Fundação para a Ciência e a Tecnologia (FCT

Electroreductive intramolecular cyclization of bromoalkoxylated derivatives catalyzed by nickel(I) tetramethylcyclam in "green" media

The (1,4,8,11-tetramethyl-1,4,8,11-tetraazacyclotetra-decane)nickel(I), [Ni(tmc)]+, electrogenerated at glassy carbon cathodes is shown to be an effective catalyst for the intramolecular radical-type cyclisation of bromoalkoxylated derivatives 1 in alcohol and / or alcohol/water mixtures as well as in microemulsions made with cationic and anionic surfactants. The results obtained indicate that the reaction proceeds via cleavage of the carbon–bromine bond to form a radicaltype intermediate that undergoes cyclisation on the unsaturated C-C bond to afford substituted tetrahydrofurans. The reactions are more selective and take place at higher current density than when carried out in conventional aprotic solvents

Electrochemical study of nickel(salen) and cobalt(salen) derivatives complexes in the presence of unsaturated halides

The electrochemical intramolecular cyclisation of allyl 2-bromophenyl ethers in N,N'-dimethylformamide at constant current in a diaphragmless cell has been developed using Ni(II) and Co(II) complexes as electron-transfer mediators. Cyclic compounds are obtained in good yields under appropriate experimental conditions

Gamma-Secretase-Dependent and -Independent Effects of Presenilin1 on β-Catenin·Tcf-4 Transcriptional Activity

Presenilin1 (PS1) is a component of the γ-secretase complex mutated in cases of Familial Alzheimer's disease (FAD). PS1 is synthesized as a 50 kDa peptide subsequently processed to two 29 and 20 kDa subunits that remain associated. Processing of PS1 is inhibited by several mutations detected in FAD patients. PS1 acts as negative modulator of β-catenin·Tcf-4 transcriptional activity. In this article we show that in murine embryonic fibroblasts (MEFs) the mechanisms of action of the processed and non-processed forms of PS1 on β-catenin·Tcf-4 transcription are different. Whereas non-processed PS1 inhibits β-catenin·Tcf-4 activity through a mechanism independent of γ-secretase and associated with the interaction of this protein with plakoglobin and Tcf-4, the effect of processed PS1 is prevented by γ-secretase inhibitors, and requires its interaction with E- or N-cadherin and the generation of cytosolic terminal fragments of these two cadherins, which in turn destabilize the β-catenin transcriptional cofactor CBP. Accordingly, the two forms of PS1 interact differently with E-cadherin or β-catenin and plakoglobin: whereas processed PS1 binds E-cadherin with high affinity and β-catenin or plakoglobin weakly, the non-processed form behaves inversely. Moreover, contrarily to processed PS1, that decreases the levels of c-fos RNA, non-processed PS1 inhibits the expression c-myc, a known target of β-catenin·Tcf-4, and does not block the activity of other transcriptional factors requiring CBP. These results indicate that prevention of PS1 processing in FAD affects the mechanism of repression of the transcriptional activity dependent on β-catenin

Synthesis of Heterocyclic Compounds by Radical Electrochemical Approach in Environmentally Friendly Media

Radical cyclisation is rapidly becoming an important method for the formation of cyclic systems. Hence, some electrochemical results obtained in the study of electroreductive intramolecular cyclisation of ethyl 2-bromo-3-(3 ,4 -methylenedioxophenyl)-3-(propargyloxy)propanoate (1a), [1-bromo-2-methoxy-2-(prop-2'-ynyloxy) ethyl] benzene (1b) and 1-[2-bromo-2-phenyl-1-(prop-2'-ynyloxy)ethyl]-4-methoxybenzene (1c) promoted by (1,4,8,11-tetramethyl-1,4,8,11-tetraazacyclotetra-decane) nickel(I), [Ni(tmc)] + , electrogenerated at glassy carbon cathodes in ethanol, ethanol / water and microemulsions made with cationic and anionic surfactants are presented. The results obtained indicate that the reaction proceeds via cleavage of the carbon-bromine bond to form a radical intermediate that undergoes cyclization on the unsaturated C-C bond to afford the substituted tetrahydrofurans

Nucleotide and Mg2+ dependency of the thermal denaturation of mitochondrial F1-ATPase.

The influence of adenine nucleotides and Mg2+ on the thermal denaturation of mitochondrial F1-ATPase (MF1) was analyzed. Differential scanning calorimetry in combination with ATPase activity experiments revealed the thermal unfolding of MF1 as an irreversible and kinetically controlled process. Three significant elements were analyzed during the thermal denaturation process: the endothermic calorimetric transition, the loss of ATP hydrolysis activity, and the release of tightly bound nucleotides. All three processes occur in the same temperature range, over a wide variety of conditions. The purified F1-ATPase, which contains three tightly bound nucleotides, denatures at a transition temperature (Tm) of 55 degrees C. The nucleotide and Mg2+ content of MF1 strongly influence the thermal denaturation process. First, further binding of nucleotides and/or Mg2+ to MF1 increases the thermal denaturation temperature, whereas the thermal stability of the enzyme is decreased upon removal of the endogenous nucleotides. Second, the stabilizing effect induced by nucleotides is smaller after hydrolysis of ATP (i.e., in the presence of ADP . Mg2+) than under nonhydrolytical conditions (i.e., absence of Mg2+ or using the nonhydrolyzable analog 5'-adenylyl-imidodiphosphate). Third, whereas the thermal denaturation of MF1 fully loaded with nucleotides follows an apparent two-state kinetic process, denaturation of MF1 with a low nucleotide content follows more complex kinetics. Nucleotide content is therefore an important factor in determining the thermal stability of the MF1 complex, probably by strengthening existing intersubunit interactions or by establishing new ones