Selective damage in striatum and hippocampus with in vitro anoxia

An in vitro model of anoxia-induced brain damage was utilized to help elucidate the biochemical basis of cell damage due to reduced oxygen availability. Previous studies suggest that anoxia-induced damage may vary presynaptically, post-synaptically or in the cell body. Thus, the consequences of an anoxic treatment incubation were examined with hippocampal slices, which contain cholinergic nerve terminals but not cell bodies, and with slices from whole striatum or its subregions, which contain both cholinergic cell bodies and nerve terminals. Slices were preincubated with either oxygen or nitrogen (treatment incubation) and the persistent effects of this treatment on [¹⁴C]acetylcholine and¹⁴CO₂ production from [U-¹⁴C]glucose were assessed in a subsequent incubation under optimal conditions (test incubation). An anoxic treatment incubation reduced the subsequent test incubation production of CO₂ about 40% in the hippocampus and striatum, The anoxic treatment incubation diminished ACh production by 46% in the striatum, but only minimally affected that in the hippocampus. Anoxic treatment incubations of synaptosomes did not alter test-incubation ACh synthesis or CO₂ production. Omission of calcium from the anoxic treatment incubation increased striatal ACh synthesis by 88% and CO₂ production in both regions. These results suggest that anoxia produces persistent changes in postsynaptic processes or cell bodies (in this model cholinergic ones) that differ from those in nerve terminals and that calcium is important in the production of these deficits.     

Modulation of Na+-channels by neurotoxins produces different effects on [3H]ACh release with mobilization of distinct Ca2+-channels

1. Voltage-gated Na⁺ channels are responsible for initiation and conduction of action potentials. The arrival of an action potential at nerve terminal increases intracellular Na⁺ and Ca²⁺ concentrations. Calcium entry into neurons through voltage-dependent calcium channels is associated with a variety of intracellular processes. Scorpion neurotoxins have been used as tools to investigate mechanisms involved in neurotransmitter release. Tityustoxin (TsTX) is an -type toxin that delays Na⁺-channel inactivation. Toxin- (TiTX-) is a -type toxin that induces Na⁺-channel activation at resting potentials.2. In the present work, we describe the effects of both toxins on [³H]acetylcholine ([³H]ACh) release from rat cerebrocortical synaptosomes, in the presence or absence of the calcium channels blockers: -conotoxin-GVIA (-CgTx), 1 M; -agatoxin-IVA (-Aga), 30 nM; -conotoxin-MVIIC (-MVIIC), 1 M; or verapamil, 1M.3. TsTX evokes [³H]ACh release in a concentration-dependent manner with a gradual increase up to saturation at concentrations of 500 nM. However, release of ACh evoked by TiTX- was not linear regarding the toxin concentration. The [³H]-ACh release evoked by TsTX or TiTX- was partially inhibited by -CgTx or -Aga, and blocked with -MVIIC. Verapamil (1 M) had no effect. Tetrodotoxin blocked [³H]ACh release evoked by both toxins.4. These results show that different actions on Na⁺-channels produce different effects on [³H]ACh release with involvement of distinct presynaptic Ca²⁺-channels, which supports the idea that sodium channels may modulate neurotransmitter release.     

Regulation of Ca2+ homeostasis by glucose metabolism in rat brain

In a previous communication we reported that glucose deprivation from KHRB medium resulted in a marked stimulation of Ca²⁺ uptake by brain tissue, suggesting a relationship between glucose and Ca²⁺ homeostasis in brain tissue [17]. Experiments were carried out to investigate the significance of glucose in Ca²⁺ transport in brain cells. The replacement of glucose with either D-methylglucoside or 2-deoxyglucose, non-metabolizable analogues of glucose, resulted in stimulation of Ca²⁺ uptake just as by glucose deprivation. These data show that glucose metabolism rather than glucose transfer was necessary to stimulate Ca²⁺ uptake in brain tissue. Inhibition of glucose metabolism with either NaF, NaCN, or iodoacetate resulted in stimulation of Ca²⁺ uptake similar to that produced by glucose deprivation. These results lend further support for the concept that glucose metabolism is essential for Ca²⁺ homeostasis in brain. Anoxia promotes glucose metabolism through glycolytic pathway to keep up with the demand for ATP by cellular processes (the Pasteur effect). Incubation of brain slices under nitrogen gas did not alter Ca²⁺ uptake by brain tissue, as did glucose deprivation and the inhibitors of glucose metabolism. We conclude that glucose metabolism resulting in the synthesis of ATP is essential for Ca²⁺ homeostasis in brain. Verapamil and nifedipine which block voltage-gated Ca²⁺ channels, did not alter Ca²⁺ uptake stimulated by glucose deprivation, indicating that glucose deprivation-enhanced Ca²⁺ uptake was not mediated by Ca²⁺ channels. Tetrodotoxin which specifically blocks Na⁺ channels, abolished Ca²⁺ uptake enhanced by glucose deprivation, but had no effect on Ca²⁺ uptake in presence of glucose (controls). These results suggest that stimulation of Ca²⁺ uptake by glucose deprivation may be related to Na⁺ transfer via Na-Ca exchange in brain.     

Studies on oxygen and volume restrictions in cultured cardiac cells I. A model for ischemia and anoxia with a new approach

Summary A novel incubation unit is described that is highly suitable for thorough studies of oxygen deprivation states. Its application with cultured heart cells is experimentally demonstrated. The release of enzymes, taken as a marker for cell damage, has clearly shown that restriction of the volume of extracellular medium combined with oxygen plus glucose deprivation caused greatest cellular damage. It may be considered as an experimental ischemia-like state. Furthermore, the onset of cellular damage followed a time table very much like that occurring in vivo under similar conditions, more so than any other previously described studies. A time lag between the release of cytoplasmic enzymes and lysosomal enzymes and other observations made in the present study suggests a sequential order of events in which the release of cytoplasmic enzymes occurs at a stage of reversible damage due to oxygen deprivation, whereas the release of lysosomal enzymes may point at irrepairable damage. Supported by grants from The Chief Scientist, Ministry of Health, State of Israel; The Ministry of Education and Sciences, State of Niedersachsen (FRG); and The Foundation for Heart Research from Mr. and Mrs. D. Vidal-Madjar, Paris, France. This study was done as partial fulfilment of Vemuri's Ph.D. thesis in biochemistry.     

Neuroprotective Effects of Ischemic Preconditioning in Brain Mitochondria Following Cerebral Ischemia

Numerous studies support the hypothesis that reperfusion following cerebral ischemia contributes substantially to ischemic injury and that mitochondrial dysfunction plays a central role. Defining the mechanisms by which mitochondrial dysfunction occurs may be important for the development of new therapies against delayed neuronal cell death. Ischemic preconditioning (IP) increases an organ's resistance to ischemic injury. There are two windows for IPC, one that requires several hours to develop and another one with a rapid setting (rapid window). However, the rapid window only provides neuroprotection for few days. We have recently determined that this lack of chronic protection by the rapid window was due to lack of protection against mitochondrial dysfunction.     

Pharmacological analysis of heartbeat in Drosophila

Analysis of the mechanisms underlying cardiac excitability can be faciliated greatly by mutations that disrupt ion channels and receptors involved in this excitability. With an extensive repertoire of such mutations, Drosophila provides the best available genetic model for these studies. However, the use of Drosophila for this purpose has been severely handicapped by lack of a suitable preparation of heart and a complete lack of knowledge about the ionic currents that underlie its excitability. We describe a simple preparation to measure heartbeat in Drosophila. This preparation was used to ask if heartbeat in Drosophila is myogenic in origin, and to determine the types of ion channels involved in influencing the heart rate. Tetrodotoxin, even at a high concentration of 40 μM, did not affect heart rate, indicating that heartbeat may be myogenic in origin and that it may not be determined by Na⁺ channels. Heart rate was affected by PN200–110, verapamil, and diltiazem, which block vertebrate L-type Ca²⁺ channels. Thus, L-type channels, which contribute to the prolonged plateau of action potentials in vertebrate heart, may play a role in Drosophila cardiac excitability. It also suggests that Drosophila heart is subject to a similar intervention by organic Ca²⁺ channel blockers as the vertebrate heart. A role for K⁺ currents in the function of Drosophila heart was suggested by an effect of tetraethylammonium, which blocks all the four identified K⁺ currents in the larval body wall muscles, and quinidine, which blocks the delayed rectifier K⁺ current in these muscles. The preparation described here also provides an extremely simple method for identifying mutations that affect heart rate. Such mutations and pharmacological agents will be very useful for analyzing molecular components of cardiac excitability in Drosophila. © 1995 John Wiley & Sons, Inc.     

KB-2796, a calcium channel blocker,ameliorates ischemic spinal cord damage in rabbits

The effect of the calcium channel blocker (KB-2796) on metabolic and functional recovery in rabbit spinal cord after 20, 30, and 40 min ischemia and 4 days of recovery was investigated. The drug was given intraperitoneally in three different doses, 10, 20, or 50 mg/kg pre-or post-ischemia of 20, 30, or 40 min duration. Both higher doses 20 and 30 mg/kg completely recovered energy state and significantly improved neurological functions in the spinal cord following 20 and 30 min ischemia. Partial protection was observed even after 40 min ischemia. The protective effect of KB-2796 exceeds the effect of calcium blockers previously used in experimental spinal cord ischemia.     

Generation of a hypoxia‐sensing mouse model

Oxygen (O₂) homeostasis is essential to the metazoan life. O₂‐sensing or hypoxia‐regulated molecular pathways are intimately involved in a wide range of critical cellular functions and cell survival from embryogenesis to adulthood. In this report, we have designed an innovative hypoxia sensor (O₂CreER) based on the O₂‐dependent degradation domain of the hypoxia‐inducible factor‐1α and Cre recombinase. We have further generated a hypoxia‐sensing mouse model, R26‐O₂CreER, by targeted insertion of the O₂CreER‐coding cassette in the ROSA26 locus. Using the ROSA^mTmG mouse strain as a reporter, we have found that this novel hypoxia‐sensing mouse model can specifically identify hypoxic cells under the pathological condition of hind‐limb ischemia in adult mice. This model can also label embryonic cells including vibrissal follicle cells in E13.5–E15.5 embryos. This novel mouse model offers a valuable genetic tool for the study of hypoxia and O₂ sensing in mammalian systems under both physiological and pathological conditions.     

A combined analysis of regional energy metabolism and immunohistochemical ischemic damage in the gerbil brain

By combining immunohistochemical technique with microassay methods, we analyzed regional energy metabolism in vulnerable and tolerant areas of gerbil brains during evolution of neuronal damage after bilateral common carotid artery occlusion for 10 min with subsequent reperfusion. Four animals were used for each reperfusion period. Based on the information from the immunohistochemical examination, we dissected out vulnerable and tolerant subregions of the hippocampus, cerebral cortex, and thalamus from freeze-dried 20-microm-thick sections, and measured the levels of creatine phosphate (P-Cr), adenine nucleotides, guanine nucleotides, and purine bodies by HPLC, and the levels of glucose, glycogen, and lactate by an enzyme-immobilized column method. There were no significant differences in the levels of metabolites between vulnerable and tolerant subregions of control brains. After reperfusion, both vulnerable and tolerant subregions recovered preischemic metabolic profiles by 2 days. Although the regional differences between vulnerable and tolerant subregions were minimal at each reperfusion period, there were delays in the recovery of P-Cr, ATP, and/or total adenine nucleotides in all vulnerable subregions. A decline of P-Cr, ATP, and GTP levels without change in %ATP, AMP, or purine bodies occurred after reperfusion for 3 days, coinciding with the development of immunohistochemical damage by the immunoreaction for microtubule-associated protein 1A. The results supported the notion that subtle but sustained impairment of energy metabolism caused by mitochondrial dysfunction in the early reperfusion period might trigger delayed neuronal death in vulnerable subregions.     

Cerebral ischemia: Changes in brain choline,acetylcholine, and other monoamines as related to energy metabolism

The relationship of cerebral neurotransmitters acetylcholine (ACh), noradrenaline (NA), dopamine (DA), 5-hydroxytryptamine (5HT) to the energy state of the brain was examined in mice at various times following complete ischemia produced by decapitation, in gerbils submitted to transient global ischemia (10 min bilateral carotid artery occlusion, 5 or 30 min recirculation), and in rats 24 hr after irreversible microembolism. Ischemia caused significant reductions in brain monoamine concentrations. The alterations in NA, DA, and 5HT levels persisted during recirculation and were unrelated to energy restoration. They were accompanied by an increase in the concentrations of related metabolites, suggesting that synthesis was unable to compensate for the release of the transmitters at early post-ischemic time periods. As described for the catecholamines and 5HT, ischemia resulted in a significant decrease in ACh level, but recirculation was associated with a rapid increase in ACh concentration. Impaired synthesis and/or increased release of ACh can be responsible for the decrease in ACh concentration during ischemia. Early post-ischemic elevation of ACh may be related to the large increase in brain choline brought about by ischemia.     

ERK1/2通路在低氧上调大鼠PASMCs钙激活性氯离子通道表达的作用

目的：探讨钙激活性氯离子通道（CLCA2）在大鼠低氧性肺动脉平滑肌细胞（PASMCs）中mRNA和蛋白表达的变化及其与ERK1/2信号通路的关系。方法：PASMCs随机分为：常氧组（N组）,低氧组（H组）,DMSO对照组（D组）,U0126干预组（U组）,Staurosporine aglycone干预组（SA组）,采用免疫印迹法检测CLCA2蛋白的表达;选用半定量逆转录-聚合酶链反应（RT-PCR）技术测定CLCA2 mRNA水平的表达。结果：PASMCs中CLCA2 mRNA和蛋白的表达量,H组较N组明显上调（P<0.01）;U组较D组明显上调（P<0.01）;SA组较D组mRNA的表达显著下调（P<0.01）,蛋白的表达轻微下调。结论：低氧可上调CLCA2中mRNA和蛋白在PASMCs的表达;ERK1/2通路激活剂-Staurosporine aglycone能下调CLCA2在PASMCs中mRNA和蛋白的表达量;ERK1/2通路抑制剂-U0126可上调CLCA2在PASMCs中mRNA和蛋白的表达量。     

An assessment of the in vitro antimicrobial effects of two antiepileptic drugs--sodium valproate and phenytoin

An incidental observation led to the evaluation of the antimicrobial properties of valproate and phenytoin. In vitro inhibition of Mycobacterium smegmatis, Candida albicans, and other standard test organisms by these two antiepileptic drugs was assessed using the broth microdilution procedure. Fluorescence microscopy (Viability Stains, Molecular Probes Inc.) and cultural techniques were employed to distinguish between microbicidal and microbistatic effects. Phenytoin showed no inhibitory activity against the microbes tested. Sodium valproate, on the other hand, was selectively potent against the yeast strains in a dose-dependent manner (MIC = 10–20 μg ml⁻¹). In vitro activity against Mycobacterium smegmatis (70% growth inhibition by 81 μg ml⁻¹) was moderate to low while Staphylococcus aureus, Pseudomonas aeruginosa and Escherichia coli were not significantly affected. Viability data from fluorescent microscopy and plate cultures correlated well with absorbance (A_620nm) growth index, and showed that valproate was microbicidal against susceptible organisms. The mode of action may include blockage of calcium channels and perturbation of membrane potential. This report opens up yet another opportunity for further enquiry into the fundamental mechanisms of drug action and microbial resistance. This revised version was published online in June 2006 with corrections to the Cover Date.     

A computational model of cardiomyocyte metabolism predicts unique reperfusion protocols capable of reducing cell damage during ischemia/reperfusion

If a coronary blood vessel is occluded and the neighboring cardiomyocytes deprived of oxygen, subsequent reperfusion of the ischemic tissue can lead to oxidative damage due to excessive generation of reactive oxygen species. Cardiomyocytes and their mitochondria are the main energy producers and consumers of the heart, and their metabolic changes during ischemia seem to be a key driver of reperfusion injury. Here, we hypothesized that tracking changes in cardiomyocyte metabolism, such as oxygen and ATP concentrations, would help in identifying points of metabolic failure during ischemia and reperfusion. To track some of these changes continuously from the onset of ischemia through reperfusion, we developed a system of differential equations representing the chemical reactions involved in the production and consumption of 67 molecular species. This model was validated and used to identify conditions present during periods of critical transition in ischemia and reperfusion that could lead to oxidative damage. These simulations identified a range of oxygen concentrations that lead to reverse mitochondrial electron transport at complex I of the respiratory chain and a spike in mitochondrial membrane potential, which are key suspects in the generation of reactive oxygen species at the onset of reperfusion. Our model predicts that a short initial reperfusion treatment with reduced oxygen content (5% of physiological levels) could reduce the cellular damage from both of these mechanisms. This model should serve as an open-source platform to test ideas for treatment of the ischemia reperfusion process by following the temporal evolution of molecular concentrations in the cardiomyocyte.     

Blockade of L-type voltage-gated Ca channel inhibits ischemia-induced neurogenesis by down-regulating iNOS expression in adult mouse

Neurogenesis in the adult mammalian hippocampus may contribute to repairing the brain after injury. The signals that regulate neurogenesis in the dentate gyrus following ischemic stroke insult are not well known. We have previously reported that inducible nitric oxide synthase (iNOS) expression is necessary for ischemia-stimulated neurogenesis in the adult dentate gyrus. Here, we show that mice subjected to 90 min of middle cerebral artery occlusion (MCAO) significantly increased the number of new neurons and up-regulated iNOS expression in the dentate gyrus. Blockade of the L-type voltage-gated Ca(2+) channel (L-VGCC) prevented neurogenesis in the dentate gyrus and subventricular zone (SVZ), and down-regulated iNOS expression in the dentate gyrus after cerebral ischemia. This study suggests that Ca(2+) influx through L-VGCC is involved in ischemia-induced neurogenesis by up-regulating iNOS expression.     

Increased oxidative damage to DNA in a transgenic mouse model of Huntington's disease

Mitochondrial dysfunction and oxidative damage may play a role in the pathogenesis of Huntington's disease (HD). We examined concentrations of 8-hydroxy-2-deoxyguanosine (OH(8)dG), a well-established marker of oxidative damage to DNA, in a transgenic mouse model of HD (R6/2). Increased concentrations of OH(8)dG were found in the urine, plasma and striatal microdialysates of the HD mice. Increased concentrations were also observed in isolated brain DNA at 12 and 14 weeks of age. Immunocytochemistry showed increased OH(8)dG staining in late stages of the illness. These results suggest that oxidative damage may play a role in the pathogenesis of neuronal degeneration in the R6/2 transgenic mouse model of HD.     

An in vitro cell model to study microglia activation in diabetic retinopathy

Microglial activation has been studied extensively in diabetic retinopathy. We have previously detected activation and migration of microglia in 8-week-old diabetic rat retinas. It is widely acknowledged that microglia-mediated inflammation contributes to the progression of diabetic retinopathy. However, existing cell models do not explore the role of activated microglia in vitro. In this study, microglia were subject to various conditions mimicking diabetic retinopathy, including high glucose, glyoxal, and hypoxia. Under high glucose or glyoxal treatment, microglia demonstrated only partially functional changes, while under hypoxia, microglia became fully activated showing enlarged cell bodies, enhanced migration and phagocytosis as well as increased production of pro-inflammatory factors such as cyclooxygenase-2 (COX-2), interleukin-1β (IL-1β), and inducible nitric oxide synthase (iNOS). The data indicate that hypoxia-treated microglia is an optimal in vitro model for exploration of microglia activation in diabetic retinopathy.     

Neurochemical correlates of cyanide-induced hypoxic neuronal damage in vitro

Neuronal cortical cell cultures obtained from fetal mice were subjected to an hypoxic insult produced by sodium cyanide (1 mM) for 24 h. Neurochemical assays were performed 13–14 days after plating on intact cells in situ to determine if there was a specific pattern of cellular dysfunction in addition to morphologic change. Ro5-4864-displaceable benzodiazepine (BDZ) binding and high-affinity [³H]-alanine uptake were not reduced when compared to control values. However, specific and clonazepam-displaceable BDZ binding (81±4% and 50±9% of control values, respectively), high-affinity [³H]GABA uptake (75±2%), and choline acetyltransferase activity (82±2%) were significantly lower. When the data were expressed in terms of protein content, high-affinity [³H]-alanine uptake was significantlyincreased in cyanide-exposed and magnesium-treated cultures (123±5% and 117±3%, respectively) as was R05-4864-displaceable BDZ binding (152±14%), consistent with stimulation of nonneuronal BDZ binding and increased glial neurotransmitter uptake. Moreover, pretreatment of the cultures with magnesium effectively prevented both the morphologic and neurochemical evidence of hypoxic injury. These data lend further support to the notion that the release of excitatory neurotransmitters may mediate neurotoxicity in developing brain.