Management of time by the cell and by the organism

Time-dependent regulations of cells and organisms can be analysed at different levels. One of these levels is the periodicity of cell functions such as cell division, metabolic processes (generation of ATP by glycolysis or oxidative mitochondrial processes) and the biosynthesis of cell constituents. Studies carried out on unicellular eukaryotes revealed the periodic, oscillatory nature of most of these processes. Time constants of these reactions vary from nanoseconds to hours-days, necessitating coupling mechanisms. Comparative studies revealed the coupling of the rapid processes (mitochondrial ATP generation) to the slower rhythms of the biosynthetic processes of macromolecules. Adenine nucleotides are involved in the coupling mechanisms between rapid and slow processes ("the slow dance of life to the music of time"). The mechanisms underlying these rhythmic processes involve either key allosteric regulatory enzymes (PFK for glycolysis) or "desensitization" of receptors by phosphorylation-dephosphorylation. At the organismic level the study of rhythmic processes is illustrated by the periodicity of heart beats, shown to exhibit multifractality, following apparently the formalism of deterministic chaos. Another example is the rhythmic oscillatory discharges of neuronal networks. The existence of subrhythmes mostly of epigenetic nature, facilitated probably the progressive adjustment of cells during evolution to the slow increase of day time since the separation of the moon from the earth. We analysed the mechanisms underlying the decline of these processes during aging. Loss of receptors or/and their uncoupling from their transmission pathway appear to be involved in most of these processes of decline. One conclusion of this review is the importance of epigenetic mechanisms both in the genesis and in the decline of these rythmic processes involved in time keeping by the cell.     

Induction of neurites by the regulatory domains of PKCdelta and epsilon is counteracted by PKC catalytic activity and by the RhoA pathway

We have shown that protein kinase C (PKC) epsilon, independently of its kinase activity, via its regulatory domain (RD), induces neurites in neuroblastoma cells. This study was designed to evaluate whether the same effect is obtained in nonmalignant neural cells and to dissect mechanisms mediating the effect. Overexpression of PKCepsilon resulted in neurite induction in two immortalised neural cell lines (HiB5 and RN33B). Phorbol ester potentiated neurite outgrowth from PKCepsilon-overexpressing cells and led to neurite induction in cells overexpressing PKCdelta. The effects were potentiated by blocking the PKC catalytic activity with GF109203X. Furthermore, kinase-inactive PKCdelta induced more neurites than the wild-type isoform. The isolated regulatory domains of novel PKC isoforms also induced neurites. Experiments with PKCdelta-overexpressing HiB5 cells demonstrated that phorbol ester, even in the presence of a PKC inhibitor, led to a decrease in stress fibres, indicating an inactivation of RhoA. Active RhoA blocked PKC-induced neurite outgrowth, and inhibition of the RhoA effector ROCK led to neurite outgrowth. This demonstrates that neurite induction by the regulatory domain of PKCdelta can be counteracted by PKCdelta kinase activity, that PKC-induced neurite outgrowth is accompanied by stress fibre dismantling indicating an inactivation of RhoA, and that the RhoA pathway suppresses PKC-mediated neurite outgrowth.     

Inhibition of the oxidation of acetaldehyde and formaldehyde by hepatocytes and mitochondria by crotonaldehyde

Crotonaldehyde was oxidized by disrupted rat liver mitochondrial fractions or by intact mitochondria at rates that were only 10 to 15% that of acetaldehyde. Although a poor substrate for oxidation, crotonaldehyde is an effective inhibitor of the oxidation of acetaldehyde by mitochondrial aldehyde dehydrogenase, by intact mitochondria, and by isolated hepatocytes. Inhibition by crotonaldehyde was competitive with respect to acetaldehyde, and the Ki for crotonaldehyde was about 5 to 20 microM. Crotonaldehyde had no effect on the oxidation of glutamate or succinate. Very low levels of acetaldehyde were detected during the metabolism of ethanol. Crotonaldehyde increased the accumulation of acetaldehyde more than 10-fold, indicating that crotonaldehyde, besides inhibiting the oxidation of added acetaldehyde, also inhibited the oxidation of acetaldehyde generated by the metabolism of ethanol. Formaldehyde was a substrate for the low-Km mitochondrial aldehyde dehydrogenase, as well as for a cytosolic, glutathione-dependent formaldehyde dehydrogenase. Crotonaldehyde was a potent inhibitor of mitochondrial oxidation of formaldehyde, but had no effect on the activity of formaldehyde dehydrogenase. In hepatocytes, crotonaldehyde produced about 30 to 40% inhibition of formaldehyde oxidation, which was similar to the inhibition produced by cyanamide. This suggested that part of the formaldehyde oxidation occurred via the mitochondrial aldehyde dehydrogenase, and part via formaldehyde dehydrogenase. The fact that inhibition by crotonaldehyde is competitive may be of value since other commonly used inhibitors of aldehyde dehydrogenase are irreversible inhibitors of the enzyme.     

Metabolism of N-nitrosomorpholine by the rat in vivo and by rat liver microsomes and its oxidation by the Fenton system

N-Nitrosomorpholine is converted into N-nitroso-2-hydroxymorpholine by rat liver microsomes and by the Fenton oxidation system. The hydroxy derivative was also synthesised by the oxidation of N-nitrosomorpholine with permanganate and characterized as the methoxime and the 2,4-dinitrophenylhydrazone. The Fenton system also afforded products believed to be N-nitroso-2-morpholone, and the 2-hydroperoxy- and 2-peroxy-derivatives ofN-nitrosomorpholine. The only urinary metabolite definitely identified was N-itrosodiethanolamine.

The significance of metabolic 2-hydroxylation in relation to the carcinogenic action of N-nitrosomorpholine is discussed.     

Stabilization of the colchicine-binding activity of tubulin by glutathione and by dietary selenium-deficiency

The lability of tubulin in supernatant fluids from rat brain was studied by measuring the loss of colchicine-binding activity. During incubation at 37 degrees C for 1 hr approximately 50% of the binding activity of rat brain supernatant fluids was lost. This loss was reduced by mercaptoethanol or reduced glutathione. Anaerobic conditions did not affect loss of binding, while oxygen markedly reduced it, especially in the presence of reduced glutathione. Supernatant fluids prepared from brains of animals deficient in selenium showed a lower loss of binding than those from selenium-supplemented controls.