Enhanced lipid peroxidation, perturbations in the activities of antioxidant enzymes accompanied with depletion of reduced glutathione levels in head region at high concentrations suggested induction of oxidative stress. Further, marked diminution in the activities of complexes I-Ill, Succinic dehydrogenase, with concomitant reduction in MTT suggested the propensity of ACR to impair mitochondrial function. Furthermore, ACR-induced
neurotoxic effects were discernible in terms of diminished ATPase activity, enhanced activity of acetylcholinesterase and dopamine depletion. In a satellite study, employing a co-exposure paradigm, we tested the propensity of spice actives namely eugenol (EU) and isoeugenol (LE) to ameliorate ACR-induced neurotoxicity. EU/IE enriched diet offered marked protection against ACR-induced mortality, PXD101 mouse locomotor dysfunctions and oxidative stress. Furthermore, the spice actives prevented the depletion of reduced GSH levels, maintained the activity of AChE enzyme and dopamine levels in head region. Collectively, these findings clearly demonstrate that ACR induced neurotoxicity in Drosophila may be mediated through oxidative stress mechanisms and the potential of spice actives to abrogate the
condition. These data suggest that SYN-117 price Drosophila may serve as a suitable model to understand the possible mechanism/s associated with ACR associated neuropathy. (C) 2012 Elsevier
Inc. All Succinyl-CoA rights reserved.”
“The Crc protein is a global translational regulator involved in catabolite repression of catabolic pathways for several non-preferred carbon sources in Pseudomonads when other preferred substrates are present. Using proteomic and transcriptomic approaches, we have analyzed the influence of Crc in cells growing in a complete medium, where amino acids are the main carbon source. Inactivation of the crc gene modified the expression of at least 134 genes. Most of them were involved in the transport and assimilation of amino acids or sugars. This allowed envisioning which amino acids are preferentially used. Crc did not inhibit the pathways for proline, alanine, glutamate, glutamine and histidine. These amino acids are good carbon sources for P. putida. In the case of arginine, lysine, aspartate and asparagine, which can be assimilated through several pathways, Crc favored one particular route, inhibiting other alternatives. Finally, Crc-inhibited genes needed to assimilate valine, isoleucine, leucine, tyrosine, phenylalanine, threonine, glycine and serine, amino acids that provide a less efficient growth. Crc has therefore a key role in coordinating metabolism, controlling the sequential assimilation of amino acids when cells grow in a complete medium. Inactivation of crc reduced growth rate, suggesting that Crc optimizes metabolism.