The effect of membrane potential on the redox state of cytochromeb 561 in antimycin-inhibited submitochondrial particles

The oxidation of cytochromeb ₅₆₁ by ATP was measured in submitochondrial particles inhibited by antimycin. The redox potential of the bulk (M phase) was controlled by the ratio of fumarate:succinate, and the oxidation of cytochromeb was calculated and expressed as a change in redox potential (E _h) measured in millivolts. The oxidation of cytochromeb ₅₆₁ is an energy-driven reaction affected only by the component of the proton motive force. The oxidation (measured in millivolts) is a function of the phosphate potential, reaching a maximal value of 40 mV at G_ATP<–12 kcal/mole. The maximal measured value of ATP-dependent was 100 mV. Thus only a fraction of the membrane potential effects the redox state of cytochromeb ₅₆₁. In contrast to the ATP-induced oxidation of cytochromeb ₅₆₁, cytochromeb ₅₆₆ is in redox equilibrium with fumarate succinate either in the presence or in the absence of ATP. The selective oxidation ofb ₅₆₁ is explained within the term of theQ cycle as a reflection of on the electron electrochemical potential. The positive electric potential of theC phase causes cytochromeb ₅₆₆ to act as oxidant with respect to cytochromeb ₅₆₁. In the presence of antimycin cytochromeb ₅₆₁ cannot equilibrate with the quinone and undergoes oxidation, while cytochromeb ₅₆₆ reequilibrates with the quinone and thus regains redox equilibrium with the fumarate succinate redox buffer.Abbreviations used: ETP_H, phosphorylating submitochondrial particles; TMPD,N ₁ N ₁ NN-tetramethyl-p-phenylenediamine; FCCP, carbonylcyanidep-trifluoromethoxyphenylhydrazone; Mes, 2-(N-morpholino) ethanesulfonic acid.     

Inhibition of the methylcoenzyme M methylreductase system by NAD+ and NADP+ in cell-extracts of Methanosarcina barkeri

In cell extracts of Methanosarcina barkeri, the methylcoenzyme M methylreductase system with H2 as the electron donor was inhibited by NAD+ and NADP+, but NADH and NADPH had no effect on enzyme activity. NAD+ (4 and 8 mM) shifted the saturation curve for methylcoenzyme M from hyperbolic (Hill coefficient [nH] = 1.0; concentration of substrate giving half maximal velocity [Km] = 0.21 mM) to sigmoidal (nH = 1.5 and 2.0), increased Km (Km = 0.25 and 0.34 mM), and slightly decreased Vmax. Similarly NADP+ at 4m and 8 mM increased nH to 1.6 and 1.85 respectively, but the Km values (0.3 and 0.56 mM) indicated that NADP+ was a more efficient inhibitor than NAD+.     

Interactions of beta and gamma ENaC with Nedd4 can be facilitated by an ERK-mediated phosphorylation.

Phosphorylation of the epithelial Na(+) channel (ENaC) has been suggested to play a role in its regulation. Here we demonstrate that phosphorylating the carboxyl termini of the beta and gamma subunits facilitates their interactions with the ubiquitin ligase Nedd4 and inhibits channel activity. Three protein kinases, which phosphorylate the carboxyl termini of beta and gammaENaC, have been identified by an in vitro assay. One of these phosphorylates betaThr-613 and gammaThr-623, well-conserved C-tail threonines in the immediate vicinity of the PY motifs. Phosphorylation of gammaThr-623 has also been demonstrated in vivo in channels expressed in Xenopus oocytes, and mutating betaThr-613 and gammaThr-623 into alanine increased the channel activity by 3.5-fold. Effects of the above phosphorylations on interactions between ENaC and Nedd4 have been studied using surface plasmon resonance. Peptides having phospho-threonine at positions beta613 or gamma623 bind the WW domains of Nedd4 two to three times better than the non-phosphorylated analogues, due to higher association rate constants. Using a number of different approaches it was demonstrated that the protein kinase acting on betaThr-613 and gammaThr-623 is the extracellular regulated kinase (ERK). It is suggested that an ERK-mediated phosphorylation of betaThr-613 and gammaThr-623 down-regulates the channel by facilitating its interaction with Nedd4.     

Frequency-Dependent Capacitance of Hydrophobic Membranes Containing Fixed Negative Charges

Filters containing fixed negative charges were saturated with hydrophobic solvent and interposed between aqueous solutions. The capacitance of such membranes was measured in the frequency range of 0.05-30 kc. The capacitance increased with decrease in frequency. The frequency dependence of the capacitance was sensitive to nature of the cation present and to salt concentration in the aqueous solution. It is suggested that variation of membrane resistivity in the space charge region of the membrane is responsible for this phenomenon. Possible effects of the potential and counterion concentration profiles at the membrane-water interface are discussed.     

The organotellurium compound ammonium trichloro(dioxoethylene-o,o')tellurate reacts with homocysteine to form homocystine and decreases homocysteine levels in hyperhomocysteinemic mice

Ammonium trichloro(dioxoethylene-o,o')tellurate (AS101) is an organotellurium compound with pleiotropic functions that has been associated with antitumoral, immunomodulatory and antineurodegenerative activities. Tellurium compounds with a +4 oxidation state, such as AS101, react uniquely with thiols, forming disulfide molecules. In light of this, we tested whether AS101 can react with the amino acid homocysteine both in vitro and in vivo. AS101 conferred protection against homocysteine-induced apoptosis of HL-60 cells. The protective mechanism of AS101 against homocysteine toxicity was directly mediated by its chemical reactivity, whereby AS101 reacted with homocysteine to form homocystine, the less toxic disulfide form of homocysteine. Moreover, AS101 was shown here to reduce the levels of total homocysteine in an in vivo model of hyperhomocysteinemia. As a result, AS101 also prevented sperm cells from undergoing homocysteine-induced DNA fragmentation. Taken together, our results suggest that the organotellurium compound AS101 may be of clinical value in reducing total circulatory homocysteine levels.     

Reproductive Mode and the Evolution of Genome Size and Structure in Caenorhabditis Nematodes

The self-fertile nematode worms Caenorhabditis elegans, C. briggsae, and C. tropicalis evolved independently from outcrossing male-female ancestors and have genomes 20-40% smaller than closely related outcrossing relatives. This pattern of smaller genomes for selfing species and larger genomes for closely related outcrossing species is also seen in plants. We use comparative genomics, including the first high quality genome assembly for an outcrossing member of the genus (C. remanei) to test several hypotheses for the evolution of genome reduction under a change in mating system. Unlike plants, it does not appear that reductions in the number of repetitive elements, such as transposable elements, are an important contributor to the change in genome size. Instead, all functional genomic categories are lost in approximately equal proportions. Theory predicts that self-fertilization should equalize the effective population size, as well as the resulting effects of genetic drift, between the X chromosome and autosomes. Contrary to this, we find that the self-fertile C. briggsae and C. elegans have larger intergenic spaces and larger protein-coding genes on the X chromosome when compared to autosomes, while C. remanei actually has smaller introns on the X chromosome than either self-reproducing species. Rather than being driven by mutational biases and/or genetic drift caused by a reduction in effective population size under self reproduction, changes in genome size in this group of nematodes appear to be caused by genome-wide patterns of gene loss, most likely generated by genomic adaptation to self reproduction per se.