Expression of Neuronal Proteins in Cells from Normal Adult Rat Brain Propagated in Serial Culture

Abstract: Cells have been cultured from the brains of 60-day-old rats and propagated through 12 passages. The cells contain the high and middle, but not low, molecular weight neurofilament subunits and neuron-specific enolase, demonstrated by immunoblotting and immunocyto-chemistry with redundant antibodies. The cells did not have the morphology of neurons when cultured in medium containing fetal calf serum and growth factors. In low serum medium containing the same growth factors with the addition of dibutyryl cyclic AMP, the cells became smaller and developed long processes. Three clonal lines derived from these cultures had the same properties. These observations are in agreement with recent observations using mouse and human brain tissue and demonstrate that proteins normally associated with neurons can be found in dividing cells cultured from the brains of young adult rats.     

Effects of arachidonic,linoleic, linolenic and oleic acid on experimental arrhythmias in cats,rabbits and guinea-pigs

Antiarrhythmic effects of the Prostaglandin (PG) precursors arachidonic and Linoleic acid were demonstrated on three models of experimental arrhythmias, whereas the fatty acids linolenic and oleic acid proved to be ineffective in these models. In ouabain-induced arrhythmias infusions of arachidonic acid (1,0 mg/kg/min) caused a strong antiarrhythmic effect in 80 percent of the animals. On the same model linoleic acid showed a maximum effect in 40 percent of the animals. BaCl₂-induced arrhythmias were abolished by arachidonic and linoleic acid in 60 percent and 66 percent of the rabbits, respectively. Pretreatment by indomethacin reduced the antiarrhythmic effect of linoleic acid from 40 percent to 9 percent on ouabain-induced arrhythmias in cats. The results suggest a participation of PG synthesis in the antiarrhythmic effect of PG precursors.     

Nile perch and the transformation of Lake Victoria

The transformation of Lake Victoria that began in 1980 followed the population explosion of Nile perch Lates niloticus, causing the apparent extirpation of 500+ endemic haplochromine species and dramatic physico-chemical changes. Officially introduced in 1962–1963, but present earlier, the reasons for the long delay before its population exploded are discussed. The hypothesis that it occurred only after the haplochromine decline is evaluated, but haplochromines declined only after the Nile perch expansion began. The sudden eutrophication of the lake was attributed to Nile perch, but evidence of eutrophication from 1950 onwards led some researchers to conclude that it was the result of climatic changes. We conclude that the haplochromine destruction disrupted the complex food webs that existed prior to the upsurge of Nile perch. The depletion of fish biomass by Nile perch may have been the source of extra phosphorus responsible for the eutrophication of the lake. After the Nile perch explosion in 1980 the fish population came to be dominated by only three species, but fisheries productivity increased at least 10-fold. Fishing has caused demographic changes in Nile perch, which may have allowed some haplochromine species to recover. The condition of the lake appears to have stabilised since 2000, partly because the fish biomass has risen to at least 2 × 10⁶ t, replacing the ‘lost’ biomass and restoring some ecosystem functioning.     

What Affects the Secondhand Value of Smartphones: Evidence from eBay

Reuse via secondhand markets can extend the use phase of products, thereby reducing environmental impacts. Analyzing 500,000 listings of used Apple and Samsung smartphones sold in 2015 and 2016 via eBay, we examine which product properties affect how long smartphones retain market value and facilitate market‐based reuse. Our results suggest that although repairability and large memory size are typically thought to be “life extending,” in practice they have limited impact on the current economic life span of smartphones and their market‐based reuse. In contrast, we show that brand, an intangible product property, can extend smartphones’ economic life span by 12.5 months. Because longer economic life spans imply extended use phases and longer life spans overall, these results illustrate the potential of harnessing the intangible properties of products to promote sustainable consumption.     

Inhibition of Brain Glycolysis by Aluminum

Abstract: Aluminum inhibited both the cytosolic and mitochondrial hexokinase activities in rat brain. The IC₅₀ values were between 4 and 9 μ M . Aluminum was effective at mildly acidic (pH 6.8) or slightly alkaline (pH 7.2–7.5) pH, in the presence of a physiological level of magnesium (0.5 m M ). However, saturating (8 m M ) magnesium antagonized the effect of aluminum on both forms of hexokinase activity. Other enzymes examined were considerably less sensitive to inhibition by aluminum. The IC₅₀ of aluminum for phosphofructokinase was 1.8 m M and for lactate dehydrogenase 0.4 m M . At 10–600 μ M , aluminum actually stimulated pyruvate kinase. Aluminum also inhibited lactate production by rat brain extracts: this effect was much more marked with glucose as substrate than with glucose-6-phosphate. However, the IC₅₀ for inhibiting lactate production using glucose as substrate was 280 μ M , higher than that required to inhibit hexokinase. This concentration of aluminum is comparable to those reportedly found in the brains of patients who had died with dialysis dementia and in the brains of some of the patients who had died with Alzheimer disease. Inhibition of carbohydrate utilization may be one of the mechanisms by which aluminum can act as a neurotoxin.     

Neurotoxic effects of copper: Inhibition of glycolysis and glycolytic enzymes

The effects of Cu²⁺ on glycolysis and several glycolytic enzymes were studied in rat brain extracts in vitro. At concentrations reportedly found in Wilson's disease, Cu²⁺ significantly inhibited lactate production from glucose or glucose-6-phosphate in rat brain postnuclear supernatant with an IC₅₀ of about 3 M. Cu²⁺ also inhibited several glycolytic enzymes. Amongst the latter, Cu²⁺ was most effective in inhibiting hexokinase (IC₅₀ for Cu²⁺=7 M), moderately effective in inhibiting pyruvate kinase (IC₅₀ for Cu²⁺=56 M), but least effective in inhibiting lactate dehydrogenase (IC₅₀ for Cu²⁺=300 M). These results suggest that inhibition of brain glycolysis may have pathophysiological importance in copper poisoning and in Wilson's disease.     

The subcellular localization of glutamate dehydrogenase (GDH): is GDH a marker for mitochondria in brain?

Glutamate dehydrogenase (GDH, EC 1.4.1.2) has long been used as a marker for mitochondria in brain and other tissues, despite reports indicating that GDH is also present in nuclei of liver and dorsal root ganglia. To examine whether GDH can be used as a marker to differentiate between mitochondria and nuclei in the brain, we have measured GDH by enzymatic activity and on immunoblots in rat brain mitochondria and nuclei which were highly enriched by density-gradient centrifugation methods. The activity of GDH was enriched in the nuclear fraction as well as in the mitochondrial faction, while the activities of other mitochondrial enzymes (fumarase, NAD-isocitrate dehydrogenase and pyruvate dehydrogenase complex) were enriched only in the mitochondrial fraction. Immunoblots using polyclonal antibodies against bovine liver GDH confirmed the presence of GDH in the rat brain nuclear and mitochondrial fractions. The GDH in these two subcellular fractions had a very similar molecular weight of 56,000 daltons. The mitochondrial and nuclear GDH differed, however, in their susceptibility to solubilization by detergents and salts. The mitochondrial GDH could be solubilized by extraction with low concentrations of detergents (0.1% Triton X-100 and 0.1% Lubrol PX), while the nuclear GDH could be solubizeded only by elevated concentrations of detergents (0.3% each) plus KCl (>150mM). Our results indicate that GDH is present in both nuclei and mitochondria in rat brain. The notion that GDH may serve as a marker for mitochondria needs to be re-evaluated.     

Effects of Postdecapitative Ischemia on Mitochondrial Respiration in Brain Tissue Homogenates

Mitochondria isolated from ischemic brain characteristically show changes in respiratory function. As conventional procedures for mitochondrial isolation yield a subpopulation of the total population and require extensive manipulation, it is unclear to what extent these changes are representative of mitochondria in the unfractionated tissue. We previously showed that the oxygen uptake by unfractionated forebrain homogenates, measured under two different sets of incubation conditions, provided information on some aspects of the respiratory activity of both the free and synaptosomal pools of mitochondria. Forebrain homogenates from animals subjected to 30 min of postdecapitative ischemia exhibited large reductions in oxygen uptake rates measured in a high K+ (mitochondrial) buffer in the presence of either ADP (44% of control values) or an uncoupling agent (45% of control values). These reductions in respiratory activity were comparable to alterations observed under the same conditions for mitochondria isolated from the ischemic brains. Similar alterations were seen in homogenates from three subregions: neocortex, hippocampus, and striatum. In a physiological buffer, in which oxygen uptake by homogenates largely resulted from activity of mitochondria within synaptosomes, there was little or no change in basal glucose-supported rates (79-96% of control values) and small reductions in maximal rates (63-81% of control values) measured in the presence of an uncoupling agent. These results suggest that alterations of respiratory function seen in isolated free mitochondria provide appropriate estimates of the dysfunction in the total free mitochondrial pool but that synaptosomal mitochondria may be less affected. Measurements of respiratory function of isolated synaptosomes from ischemic tissue provided further support for the relative preservation of synaptosomal mitochondria during ischemic insult.     

Expression of Classical Mitochondrial Respiratory Responses in Homogenates of Rat Forebrain

Respiratory studies of brain mitochondria have, in general, been limited to purified preparations. Conventional procedures for mitochondrial isolation yield relatively small and potentially selected subfractions of mitochondria. Examination of respiratory responses of homogenates of rat forebrain indicated that key respiratory properties of mitochondria are fully expressed in these preparations. In a high K+ buffer, comparable to those commonly used for purified mitochondria, forebrain homogenates exhibited many of the characteristics of oxygen uptake by "free" mitochondria: requirement for both pyruvate and malate for maximal respiration, stimulation (over threefold) by ADP, stimulation by uncoupling agent [carbonyl cyanide m-chlorophenylhydrazone (CCCP)], but little effect of digitonin. In a modified Krebs-Ringer phosphate buffer (a physiological buffer), respiratory responses were primarily due to mitochondria enclosed in synaptosomes: respiration with glucose was markedly stimulated by CCCP, further stimulated by pyruvate, and extensively inhibited by digitonin (which disrupts the cholesterol-rich synaptosomal membranes). Studies with purified mitochondria and synaptosomes supported the specificity of these responses. These data indicate that classical mitochondrial responses are expressed in whole brain homogenates and, under appropriate conditions, provide functional measures of the total pools of free and synaptosomal mitochondria.