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The proto-oncogenes bcl-2 and bcl-x-long have been shown to suppress apoptotic cell death in a variety of in vitro systems and cell lines, including neurons. An alternatively spliced form of bcl-x, bcl-x-short, is a promoter of apoptotic death. Whether these genes are induced after ischemia or play any role in determining the fate of ischemic neurons is unknown. To begin to address this issue, we studied the expression of bcl-2, and bcl-x mRNA and protein after global ischemia in the rat. Ischemia was induced in isoflurane-anesthetized rats by the four-vessel occlusion method. mRNA expression was studied by Northern blot analysis at 24 h after ischemia and by in situ hybridization at 2, 4, 8, 24, and 72 h after 15 min of global ischemia. Protein expression was studied using both immunocytochemistry at 4, 8, 16, 24, and 72 h after ischemia and Western blot analysis from tissue harvested at 16, 24, and 72 h after ischemia. Western blots showed that bcl-x-long is the predominant form of bcl-x protein expressed in both normal and ischemic brain. Both bcl-2 and bcl-x-long mRNA were expressed in CA1, CA3, and the molecular layer of the dentate after ischemia. However, bcl-2 and bcl-x protein were expressed only in CA3 and dentate. Thus, while bcl-2 and bcl-x-long mRNA were expressed in both surviving and dying neurons, their proteins were expressed in neurons destined to survive. These results support potential roles for these two apoptosis suppressor proteins in promoting survival after cerebral ischemia.
Recent investigations have been suggesting that some neuronal subpopulations may die via programmed cell death after focal ischemic injury. To clarify the possible roles of the genes involved in the cell-death program, this study examined the expression of three members of the interleukin-1β converting enzyme (
The intravenous infusion of rat adrenomedullin, at concentrations ranging from 0.1 to 1.0 μg/kg/min, for 60 min increased the regional cerebral blood flow (rCBF) in a dose-dependent manner in rats. rCBF was measured using a laser Doppler flowmetry device placed on the surface of the parietal cortex. The increase in rCBF induced by 1.0 μg/kg/min of adrenomedullin was up to 145 ± 10.8% of controls at 60 min (n = 5,
Reactive astrocytes influence not only the severity of brain injury, but also the capacity of brain to reshape itself with learning. Mechanisms responsible for astrogliosis remain unknown but might be best studied in vitro, where improved access and visualization permit application of modern molecular and cellular techniques. We have begun to explore whether gliosis might be studied in hippocampal organotypic cultures (HOTCs), where potential cell-to-cell interactions are preserved and the advantages of an in vitro preparation are still realized. Following HOTC exposure to
Hyperammonemia causes glutamine accumulation and astrocyte swelling. Inhibition of glutamine synthesis reduces ammonia-induced edema formation and watery swelling in astrocyte processes. Ordinarily, astrocytes tightly control extracellular K+ activity [K+]e. We tested the hypothesis that acute hyperammonemia interferes with this tight regulation such that [K+]e increases and that inhibition of glutamine synthetase reduces this increase in [K+]e. Ion-sensitive microelectrodes were used to measure [K+]e in parietal cortex continuously over a 6-h period in anesthetized rats. After i.v. sodium acetate infusion in eight control rats, plasma ammonia concentration was 33 ± 26 μmol/L (± SD) and [K+]e remained stable at 4.3 ± 1.6 mmol/L. During ammonium acetate infusion in nine rats, plasma ammonia increased to 594 ± 124 μmol/L at 2 h and to 628 ± 135 μmol/L at 6 h. There was a gradual increase in [K+]e from 3.9 ± 0.7 to 6.8 ± 2.7 mmol/L at 2 h and 11.8 ± 6.7 mmol/L at 6 h. In eight rats, L-methionine-D,L-sulfoximine (150 mg/kg) was infused 3 h before ammonium acetate infusion to inhibit glutamine synthetase. At 2 and 6 h of ammonium acetate infusion, plasma ammonia concentration was 727 ± 228 and 845 ± 326 μmol/L, and [K+]e was 4.5 ± 1.9 and 6.1 ± 3.8 mmol/L, respectively. The [K+]e value at 6 h was significantly less than that obtained with ammonium acetate infusion alone but was not different from that obtained with sodium acetate infusion. We conclude that acute hyperammonemia impairs astrocytic control of [K+]e and that this impairment is linked to glutamine accumulation rather than ammonium ions per se.
Effects of blood glucose concentration on biochemical and neurologic outcome following lateral fluid percussion-induced traumatic injury of moderate severity (2.8 atm) in rats were studied using radioactive phosphorus (31P) magnetic resonance spectroscopy (MRS) and a battery of tests designed to evaluate posttraumatic neurologic motor function. Prior to injury, male Sprague-Dawley rats (n = 18) were randomly assigned to receive either dextrose, 2 ml 50% (wt/vol), zinc insulin (10 IU/kg) or no treatment, thus dividing the animals into hyperglycemic, hypoglycemic, and normoglycemic groups, respectively. Animals were then injured, monitored for 4 h by 31P MRS before being allowed to recover, and assessed for posttraumatic motor function. Following brain injury, there was no difference in brain intracellular pH between groups over the 4-h posttraumatic MRS monitoring period. Similarly, intracellular free magnesium, cytosolic phosphorylation potential, and neurologic outcome posttrauma were not significantly different between groups. We conclude that, unlike models of ischemia, blood glucose concentration may not be a significant factor affecting outcome in traumatic brain injury.
Cerebral blood flow (CBF) rises when the glucose supply to the brain is limited by hypoglycemia or glucose metabolism is inhibited by pharmacological doses of 2-deoxyglucose (DG). The present studies in unanesthetized rats with insulin-induced hypoglycemia show that the increases in CBF, measured with the [14C]iodoantipyrine method, are relatively small until arterial plasma glucose levels fall to 2.5 to 3.0 m
A general mathematical model for the delivery of O2 to the brain is presented, based on the assumptions that all of the brain capillaries are perfused at rest and that all of the oxygen extracted from the capillaries is metabolized. The model predicts that disproportionately large changes in blood flow are required in order to support small changes in the O2 metabolic rate. Interpreted in terms of this model, previous positron emission tomography (PET) studies of the human brain during neural stimulation demonstrating that cerebral blood flow (CBF) increases much more than the oxygen metabolic rate are consistent with tight coupling of flow and oxidative metabolism. The model provides a basis for the quantitative interpretation of functional magnetic resonance imaging (fMRI) studies in terms of changes in local CBF.
When used to measure blood flow, water leaves a residue in the vascular bed, which may contribute to the calculation of increased blood flow during functional activation of brain tissue. To assess the magnitude of this contribution with the two-compartment positron emission tomography (PET) method, we mapped the water clearance (
We present a simple way of assessing dynamic or time-dependent changes in displacement during single-subject radioligand positron emission tomography (PET) activation studies. The approach is designed to facilitate dynamic activation studies using selective radioligands. These studies are, in principle, capable of characterising functional neurochemistry by analogy with the study of functional neuroanatomy using rCBF activation studies. The proposed approach combines time-dependent compartmental models of tracer kinetics and the general linear model used in statistical parametric mapping. This provides for a comprehensive, voxel-based and data-led assessment of regionally specific effects. The statistical model proposed in this paper is predicated on a single-compartment model extended to allow for time-dependent changes in kinetics. We have addressed the sensitivity and specificity of the analysis, as it would be used operationally, by applying the analysis to 11C-Flumazenil dynamic displacement studies. The activation used in this demonstration study was a pharmacological (i.v. midazolam) challenge, 30 min after administration of the tracer. We were able to demonstrate, and make statistical inferences about, regional increases in
In a previous study, we reported that the sustained increase in CBF concomitant with seizures induced by kainate is mainly due to the potent vasodilator nitric oxide (NO). However, the production site of NO acting at cerebral vessels was undetermined. In the present study, we investigated whether NO responsible for the cerebral vasodilation is of either neuronal or endothelial origin. We used a putative selective inhibitor of neuronal NO synthase, 7-nitro indazole (7-NI). CBF was measured continuously in parietal cortex by means of laser Doppler flowmetry in awake rats. Systemic variables and electroencephalograms were monitored. Kainate (10 mg/kg i.p.) was given to rats previously treated with saline (n = 8) or 7-NI (25 mg/kg i.p., n = 8) or L-arginine (300 mg/kg i.p., n = 8) followed 30 min later by 7-NI (25 mg/kg i.p.). Under basal conditions, 7-NI decreased CBF by 27% without modifying the mean arterial blood pressure. Under kainate, 7-NI prevented significant increases in CBF throughout the seizures despite sustained paroxysmal electrical activity. L-arginine, the substrate in the production of NO, prevented any decrease in CBF under 7-NI in basal conditions and partially, but nonsignificantly, reversed the cerebrovascular influence of 7-NI during seizures. In a separate group of rats (n = 6), inhibition of cortical NO synthase activity by 7-NI was assayed at 73%. The present results show that neurons are the source of NO responsible for the cerebrovascular response to seizure activity after kainate systemic injection.
Previously, it had been observed that nitric oxide (NO) contributes to hypoxia-induced pial artery dilation in the newborn pig. Additionally, it was also noted that activation of ATP-sensitive K+ channels (KATP) contribute to cGMP-mediated as well as to hypoxia-induced pial dilation. Although somewhat controversial, adenosine is also thought to contribute to hypoxic cerebrovasodilation. The present study was designed to investigate the role of NO, cyclic nucleotides, and activation of KATP channels in the elicitation of adenosine's vascular response and relate these mechanisms to the contribution of adenosine to hypoxia-induced pial artery dilation. The closed cranial window technique was used to measure pial diameter in newborn pigs. Hypoxia-induced artery dilation was attenuated during moderate (PaO2 ≈ 35 mm Hg) and severe hypoxia (PaO2 ≈ 25 mm Hg) by the adenosine receptor antagonist 8-phenyltheophylline (8-PT) (10–5
Nitric oxide synthase (NOS) participates in the regulation of cerebral blood flow and neurotransmitter release and as a second messenger of glutamatergic and cholinergic systems. Developmental differences in NOS activity have been described in the rat, but not in a species with longer gestation and a larger, lobulated brain at birth. We assayed NOS activity by conversion of [14C]L-arginine to [14C]L-citrulline in 50-mg tissue samples from eight brain regions in sheep at 70, 92, 110, and 135 days gestation (term = 145 days); newborns (<7 days); and adults to test the hypothesis that NOS activity in the brain is developmentally regulated from midgestation through adulthood and matures along the neuroaxis in parallel with the known development of cerebral blood flow and neuronal activity. Three patterns of maturation of NOS activity were evident: increasing to or exceeding adult levels before 70 days gestation in the thalamus, cerebellum, and medulla; increasing to adult levels between 70 and 92 days in the hippocampus; and increasing to adult levels after 92 days in the cortex and caudate. Additionally, there were regional differences in cortical NOS activity: at 70 and 92 days of gestation, frontal cortex NOS activity was greater than parietal or occipital activity, and at 135 days gestation and in the newborn and adult, cortical and caudate activity exceeded that in most of the more caudal regions. The up to fourfold increase in regional cortical NOS activity between 92 and 135 days gestation was associated with twofold increases in cerebral blood flow and oxygen consumption during this period. Inhibition of NOS activity with administration of 60 mg/kg of
To examine the reliability of quantitative positron emission tomography studies in the rat (Rat–PET), we assessed the influence of radioactivity accumulated in the Harderian glands on PET CMRglc determination. We measured CMRglc by PET and ex vivo dissection methods by using 2-[18F]fluoro-2-deoxy-D-glucose in rats with and without focal brain ischemia. The CMRglc values obtained by PET, after correcting with recovery coefficients, were higher than those measured by the ex vivo method at rostral slices, and reduction of the CMRglc in the ischemic brain was not demonstrated by PET in the frontal cortex. The radioactivity accumulated in the Harderian glands prevents the quantitative determination of CMRglc using Rat–PET.
