Diseases like obesity, diabetes or generalized lipodystrophy cause a chronic elevation of circulating fatty acids that can become cytotoxic, a condition known as lipotoxicity. Fatty acids cause oxidative stress and alterations in mitochondrial structure and function. The uncoupling of the oxidative phosphorylation is one of the most recognized deleterious fatty acid effects and several metabolite transporters are known to mediate in their action. The fatty acid interaction with the carriers leads to membrane depolarization and/or the conversion of the carrier into a pore. The result is the opening of the permeability transition pore and the initiation of apoptosis. Unlike the other members of the mitochondrial carrier superfamily, the eutherian uncoupling protein UCP1 has evolved to achieve its heat-generating capacity in the physiological context provided by the brown adipocyte and therefore it is activated by the low fatty acid concentrations generated by the noradrenaline-stimulated lipolysis.
β-sitostanol esters, used as dietary complement for decreasing cholesterol absorption, have been synthesized at 28°C via direct esterification or transesterification catalyzed by the versatile lipase/sterol esterase from the ascomycete fungus O. piceae. Direct esterification was conducted in biphasic isooctane: water systems containing 10mM β-sitostanol and lauric or oleic acid as acyl donors, reaching 90% esterification in 3h with the recombinant enzyme. The use of molar excesses of the free fatty acids did not improve direct esterification rate, and the enzyme did not convert one of the two fatty acids preferentially when both were simultaneously available. On the other hand, solvent-free transesterification was an extremely efficient mechanism to synthesize β-sitostanyl oleate, yielding virtually full conversion of up to 80mM β-sitostanol in 2h. This process may represent a promising green alternative to the current chemical synthesis of these esters of unquestionable nutraceutical value.
While metformin has been widely used to treat type 2 diabetes for the last fifty years, its mode of action remains unclear. Hence, we investigated the short-term alterations in energy metabolism caused by metformin administration in 3T3-L1 adipocytes. We found that metformin inhibited mitochondrial respiration, although ATP levels remained constant as the decrease in mitochondrial production was compensated by an increase in glycolysis. While AMP/ATP ratios were unaffected by metformin, phosphorylation of AMPK and its downstream target acetyl-CoA carboxylase augmented. The inhibition of respiration provoked a rapid and sustained increase in superoxide levels, despite the increase in UCP2 and superoxide dismutase activity. The inhibition of respiration was rapidly reversed by fatty acids and thus respiration was lower in treated cells in the presence of pyruvate and glucose while rates were identical to control cells when palmitate was the substrate. We conclude that metformin reversibly inhibits mitochondrial respiration, it rapidly activates AMPK without altering the energy charge, and it inhibits fatty acid synthesis. Mitochondrial β-oxidation is facilitated by reversing the inhibition of complex I and, presumably, by releasing the inhibition of carnitine palmitoyltransferase. This article is part of a Special Issue entitled: 17th European Bioenergetics Conference (EBEC 2012).
SummaryYeast Reb1 and its mammalian ortholog TTF1 are conserved Myb-type DNA-binding proteins that bind to specific sites near the 3Ј-end of rRNA genes (rDNA). Here, they participate in the termination of transcription driven by RNA polymerase I and block DNA replication forks approaching in the opposite direction. We found that Schizosaccharomyces pombe Reb1 also upregulates transcription of the ste9 + gene that is required for nitrogen-starvation-induced growth arrest with a G1 DNA content and sexual differentiation. Ste9 activates the anaphase-promoting complex or cyclosome ('APC/C') in G1, targeting B-cyclin for proteasomal degradation in response to nutritional stress. Reb1 binds in vivo and in vitro to a specific DNA sequence at the promoter of ste9 + , similar to the sequence recognized in the rDNA, and this binding is required for ste9 + transcriptional activation and G1 arrest. This suggests that Reb1 acts as a link between rDNA metabolism and cell cycle control in response to nutritional stress. In agreement with this new role for Reb1 in the regulation of the G1-S transition, reb1⌬ and wee1 ts mutations are synthetically lethal owing to the inability of these cells to lengthen G1 before entering S phase. Similarly, reb1⌬ cdc10 ts cells are unable to arrest in G1 and die at the semi-permissive temperature.
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