Primary Brain Cultures Research Articles

Nicotine-induced alterations in the expression of nicotinic receptors in primary cultures from human prenatal brain

The nicotinic receptor proteins and gene transcripts for the different nicotinic receptor subunits exist in human prenatal brain already at 4–5 weeks of gestation. The early presence of nicotinic receptors suggests an important role for these receptors in modulating dendritic outgrowth, establishment of neuronal connections and synaptogenesis during development. When measurements of nicotinic receptors using [ 3H]epibatidine (labelling both the α3 and α4 subtype) and [ 3H]cytisine (labelling the α4 subtype) were performed in intact cells from the cortex, subcortical forebrain and mesencephalon (7.5–11 weeks of gestation), the highest specific binding for both ligands was detected in cells from mesencephalon, followed by subcortical forebrain and cortex. The effects of nicotine exposure were studied in primary cultures of prenatal brain (7.5–11 weeks of gestation). Treatment with nicotine (1–100 μM) for 3 days significantly increased the specific binding of [ 3H]epibatidine and [ 3H]cytisine in cortical cells but not in cells from subcortical forebrain and mesencephalon brain regions, indicating region-specific differences in the sensitivity to nicotine exposure. Relative quantification of mRNA showed that the expression of the nicotinic receptor subunits α3 and α7, but not α4, was increased in cortical cells after nicotine treatment. These findings support the assumption of a potential risk of disturbance in the functional role of nicotinic receptors during brain development as a consequence of maternal smoking during pregnancy.

Effects of estrogen and neurotransmitters on the primary cultures of tilapia brain from different ages

The effects of estrogen and neurotransmitters on the proliferation of brain cells were investigated in the primary cultures of tilapia brain from different ages. Treatment of brain cells that were cultured on day 1, 3, 5, 7, 10, 30, and 180 posthatching with serotonin (5-HT), resulted in a significant increase of the Brdu +-cell number. By contrast, norepinephrine (NE) resulted in a significant decrease and γ-aminobutyric acid (GABA) had no effect. 17β-Estradiol (E 2) significantly increased the Brdu +-cell number when the brain cells were cultured after 5 days of age, but had no effect when cultured on day 1 or 3 of age. These results indicate that the proliferation of brain cell is enhanced by 5-HT at each stage. This effect is mimicked by E 2 when given after 5 days of age. Conversely, NE has an effect to depress the proliferation of brain cells. Whereas, GABA has no effect.

Deferoxamine toxicity in hepatoma and primary rat cortical brain cultures.

Deferoxamine is commonly used for treatment of iron intoxication. Because the usual dose is unable to chelate sufficient iron before severe injury occurs, "high-dose" deferoxamine treatment has been proposed. However, several authors have reported severe toxicity after deferoxamine therapy. Although the hemodynamic effects are well described, the cellular toxicity of deferoxamine is unknown. Accordingly, we investigated the cellular toxicity of deferoxamine using in vitro techniques in two cell lines. Brain cells were harvested from fetal rats and cultured for 14-21 days before deferoxamine exposure. Using similar techniques, rat hepatoma cells were grown until confluent. Deferoxamine was added to the cultures to achieve final concentrations of 200-800 microg/ml, corresponding to in vivo infusion rates of 15-60 mg/kg/h. Deferoxamine was removed after 3 or 6 days by changing the medium. Subtoxic FeCl3 (500 mg/dl) was concurrently added to identical cultures to determine if deferoxamine potentiated iron toxicity. Cell viability was measured by a colorimetric assay. The addition of deferoxamine (0.2, 0.4, 0.8 mg/ml) significantly decreased cell viability in both cell groups. The effect of deferoxamine on primary cortical brain cultures was similar for the three concentrations used, and was similar when examined either 72 h or 6 days later. In contrast, hepatoma cell cultures evidenced a dose- dependent cell loss that increased with the length of exposure. The addition ofsubtoxic amounts of FeCl3 (500 microg/dl) in the presence of deferoxamine was protective in all cultures, and abolished deferoxamine-induced cell loss. Interestingly, the addition of serum albumin significantly reduced the amount of iron present in cells, suggesting its potential use to treat iron toxicity. These results suggest that deferoxamine, in the absence of iron, is toxic to cortical brain and hepatoma cells in vitro.

The effects of propofol on NMDA- or nitric oxide-mediated neurotoxicity in vitro.

Acute brain ischemia causes neurotoxic cascades including NMDA receptors and NO. Propofol, an i.v. anesthetic, is thought to have a neuroprotective effect. We investigated the influence of propofol on NMDA/NO neurotoxicity using Shibuta's established model of primary brain cultures. Cortical neurons prepared from E16 were used after 13-14 days in culture. The neurons were exposed to various concentrations of propofol with NMDA or NO-donor. The survival rates of neurons exposed to 30 microM NMDA with or without 300 microM propofol were 12.1 +/- 2.2% and 11.9 +/- 2.2%, respectively. The survival rates exposed to 30 microM NO-donor with or without 300 microM propofol were 11.2 +/- 4.2% and 14.0 +/- 3.9%, respectively. These results suggest that neuroprotective effect of propofol is limited and propofol does not offer advantages over thiopental against NMDA/NO-induced cytotoxicity.

Microtubule-associated protein 1 subunit expression in primary cultures of rat brain

Microtubule-associated protein 1A (MAP1A) and MAP1B are developmentally regulated proteins linked to axon formation. They each consist of a unique heavy chain and three common light chains. We used immunofluorescence microscopy to qualitatively assess the variability in MAP1 subunit expression between individual cells. The ratio of light chain 1 to MAP1 heavy chain varies greatly between cells with some cells expressing MAP1A heavy chain in the apparent absence of light chain 1. The results imply the existence of MAP1 molecules that differ in light chain composition. Transfection experiments indicate that the light chains differ in microtubule binding activity and subcellular targeting activity. This further suggests that the regulation of MAP1 light chain content can control MAP1 function.

Expression of multiple functional chemokine receptors and monocyte chemoattractant protein-1 in human neurons

Functional chemokine receptors and chemokines are expressed by glial cells within the CNS, though relatively little is known about the patterns of neuronal chemokine receptor expression and function. We developed monoclonal antibodies to the CCR1, CCR2, CCR3, CCR6, CXCR2, CXCR3 and CXCR4 chemokine receptors to study their expression in human fetal neurons cultured from brain tissue as well as the clonally derived NT2.N human neuronal cell line (NTera 2/cl.D1). Specific monoclonal antibody labeling demonstrated expression of CCR2, CXCR2, CXCR3 and CXCR4 on neurons from both sources. Co-labeling studies revealed strong expression of CXCR3 and CXCR4 on both dendritic and axonal processes, with a weaker expression of CXCR2 and CCR2. Reverse transcriptase–polymerase chain reaction analysis of pure NT2.N neurons confirmed RNA expression for CCR2, CXCR2, CXCR3 and CXCR4. No changes in the neuronal labeling pattern of chemokine receptor expression were noted when NT2.N neurons were grown on a supporting layer of astrocytes, again consistent with similar patterns seen in primary human fetal brain cultures. Analysis of single-cell calcium transients revealed a robust response to stromal derived factor-1α (CXCR4) and melanocyte growth-stimulating activity (CXCR2), and variable response to monocyte chemoattractant protein-1 (CCR2) or interferon-γ inducible protein-10 (CXCR3). Finally, we detected the release of monocyte chemoattractant protein-1 from pure cultures of NT2.N neurons, but not undifferentiated NT2 cells. These data indicate that individual neurons may not only co-express multiple functional chemokine receptors, but also that neurons themselves produce chemokines which may influence cellular function within the central nervous system.

Preferential infection of neuronal and astroglia cells by Akabane virus in primary cultures of fetal bovine brain

Akabane virus is a member of the genus Bunyavirus; it is pathogenic for ruminants and transmitted by arthropod vectors. Infection of adult cattle and sheep causes a transient viremia without obvious clinical signs, while infection of pregnant animals often causes fetal abnormalities including hydranencephaly, poliomyelitis and arthrogryposis. Infectious virus or viral antigens is present in the brain, spinal cord and skeletal muscle of infected fetuses. To understand the interaction between Akabane virus and bovine brain cells, we investigated the viral tropism using primary cultures of fetal bovine brain. The cultured neuronal cells, astroglia cells and microglia cells were distinguished by cell type specific antisera. Akabane virus was found to infect neuronal cells and astroglia cells, which led to degenerative death. No microglia cells were found infected. In some brain cultures, we observed different sensitivities of the cells to two Akabane virus strains: an attenuated strain infected and spread more readily than wild type virus. This difference was not observed in a hamster fibroblast cell line. Both viral and host determinants might be involved in the different susceptibility of brain cells to Akabane virus infection.

The influence of the timing of administration of thiopentone sodium on nitric oxide-mediated neurotoxicity in vitro.

Thiopentone sodium is a highly useful pharmacological agent that provides a neuroprotection against cerebral ischaemia. Since not all patients can receive thiopentone sodium before cerebral ischaemia occurs, we investigated the influence of timing of thiopentone sodium administration on the neurotoxicity induced by nitric oxide (NO) using Shibuta's established model of primary brain cultures. Cortical neurones prepared from 16-day gestational rat foetuses were used after 13-14 days in culture. The cells were exposed to an NO-donor, NOC-5 at 30 microM. Thiopentone sodium administered at 30 and 10 min before or 5, 10 and 15 min after exposure to NOC-5, but not thereafter, significantly attenuated NO-induced neurotoxicity compared with controls. The survival rate of the neurones in which thiopentone sodium was administered at 15 min after exposure to NOC-5 was 55.7+/-2.4%, compared to a 10.0+/-1.6% survival rate in neurones when thiopentone sodium was administered at 30 min after exposure to NOC-5. These findings demonstrate that thiopentone sodium, which protects cerebral cortical neurones against NO-mediated cytotoxicity, should be given as soon as possible in case ischaemic or hypoxic neuronal damage is predicted.

Co-localization of patched and activated sonic hedgehog to lysosomes in neurons.

We demonstrate co-localization of the Patched 1 (Ptc1) receptor and its ligand sonic hedgehog (Shh) in lysosomes suggests an intracellular sorting mechanism for this receptor and its ligand. Treatment of murine brain primary cultures and a human teratoma cell line with the N-terminal activated form of Shh (ShhNT), a Ptc1-Shh complex was observed in lysosomes. Consistent with this interaction, Western immunoblot analysis revealed intracellular localization of native Ptc1 and ShhNT. Examination of the topological model of the Ptc1 receptor revealed a number of Yxxphi lysosomal targeting sequences consistent with our observations for Ptc1 sorting.

Isozyme pattern of glycogen phosphorylase in the rat nervous system and rat astroglia-rich primary cultures: electrophoretic and polymerase chain reaction studies.

Of the three isozymes of glycogen phosphorylase (GP) known, the brain (B) and muscle (M) isoforms have been reported to occur in brain. We investigated the regional and cellular occurrence of the three isozymes in various parts of the rat nervous system, fetal brain and astroglia-rich primary cultures by means of electrophoresis of native proteins with subsequent activity stain and by reverse transcriptase polymerase chain reaction. In the cortex, cerebellum, olfactory bulb, brainstem, spinal cord and dorsal root ganglia, both mRNA and enzyme protein were found for the B and M isozymes. In addition, the liver (L) isoform mRNA was detected in fetal brain and cultured astrocytes. Our studies indicate that there is no regional difference in distribution pattern between brain regions, spinal cord and dorsal root ganglia. In immature brain and cultured glial cells, the additional presence of the L isozyme is possible. These results support the idea that astrocytes express two or even three GP isozymes simultaneously.

Effects of retinoic acid on N-glycosylation and mRNA stability of the liver/bone/kidney alkaline phosphatase in neuronal cells.

Alkaline phosphatase (ALP) is a glycoenzyme that is highly expressed during carcinogenesis and is induced by retinoic acid (RA) in various cells. We investigated the effects of RA on N-linked glycosylation of the tissue nonspecific liver/bone/kidney- type of ALP (L/B/K ALP), on ALP transcripts, and on total protein glycosylation in two neuronal cell lines, P19 and NG108CC15, and in primary cultures of neonatal rat brain. ALP activity was determined in cell extracts and found to be induced by RA. Tunicamycin was used at various concentrations to inhibit protein N-glycosylation. After treatment of cells with low concentrations (0.1 and 0.125 microgram/ml) of tunicamycin for 48 h, uninduced and RA-induced ALP activity declined while incubation with a protease inhibitor restored activity, indicating that the L/B/K ALP bear N-linked oligosaccharide chains important for maintaining enzymatic activity. Interestingly, ALP activity in RA-treated cultures was less inhibited by tunicamycin compared to untreated controls suggesting that RA may have an impact on ALP N-glycosylation. To investigate effects of RA on ALP glycosylation further, incorporation of [(14)C]mannose and [(35)S]methionine into ALP protein was determined in the presence or absence of RA. The ratio of mannosylation and biosynthesis demonstrate that incubation of cells with RA increased [(14)C]mannose incorporation into ALP molecules. Also, the release of free [(14)C]mannose from ALP molecules relative to the amount of protein by N-Glycanase was increased in RA-treated cultures. In addition, mannosylation of total protein was found to be induced in cells after exposure to RA. Analysis of biosynthesized ALP monomers revealed that RA increased glycosylation of the polypeptides. Furthermore, tunicamycin decreased the stability of ALP mRNA, an effect that was reduced by cotreatment with RA. Thus, the degree of N-glycosylation of the L/B/K ALP as well as mRNA and protein levels of this enzyme are affected by RA. The P19 cell line provides a useful model system to study the molecular mechanism(s) underlying the action of RA on glycosylation during neuronal differentiation further.

Catechol-O-methyltransferase activity in rat brain primary neuronal and glial cell cultures and its inhibitation by novel drugs

To analyze the intracellular catechol-O-methyltransferase (COMT) activity in cultured cells, a substrate (dihydroxybenzoic acid) was added to the tissue culture plates and the product (vanillic acid) was anlayzed with reversed-phase HPLC with coulometric detection. The cultures, prepared from various regions of the brain, were immunohistochemically characterized. Basal COMT activites were similar in all glial cultures while in some neuron-enriched cultures the enzyme activity was lower. Preincubation with nitrocatechol COMR inhibitors, entacapone or tolcapone (30-300 nM), decreased COMT activity in all culture types with slightly different potencies. An atypical inhibitor of O-methylation, CGP 28104, had no oeffect on COMT activity in any of these cultures. In conclusion: 1) this method enables straight-forward analysis of a large number of COMT activity samples in cultured cells, 2) COMT activity is almost equally distributed throughout the brain, and 3) tolcapone was a more potent COMT inhibitor than entacapone in cultures containing glial cells.

Antigen presentation function of brain-derived dendriform cells depends on astrocyte help.

In mouse brain primary culture, supplementation with granulocyte macrophage colony-stimulating factor (GM-CSF) induces development of dendriform cells emerging on the astroglia monolayer. As revealed by flow cytofluorimetric analysis, >70% of isolated cells are CD11c(+) and express the dendritic cell (DC) marker 33D1. Additional expression of F4/80 and CD11b suggests a myeloid origin of these cells. The lymphoid DC marker CD8alpha is lacking while DEC-205 has been detected on approximately 10% of the cells. When freshly isolated, such brain-derived DC-like cells are excellent antigen-presenting cells (APC) but their functional capability is lost during subculture with GM-CSF. In contrast, their antigen presentation function remains stable in the presence of GM-CSF plus astrocytes or astrocyte-conditioned medium. The responsible astrocytic activity co-fractionates with macrophage colony-stimulating factor (M-CSF). Neutralization of the activity with anti-M-CSF antibody and substitution with recombinant M-CSF provide evidence that, in addition to GM-CSF, M-CSF is required to preserve the functional capability of these brain-derived APC. Responsiveness of the isolated cells to M-CSF is substantiated by the expression of c-fms/M-CSF receptor gene. Consistently, GM-CSF proves stimulatory for astrocytes by up-regulating their secretion of M-CSF. Furthermore, depletion or blocking of endogenous M-CSF in primary brain cell culture prevents the development of functionally active APC regardless of exogenous GM-CSF. In sum, these findings ascribe an immature DC phenotype to GM-CSF-grown myeloid brain cells and indicate a role for astrocytic M-CSF in maintaining their antigen presentation function.

Regulation of metallothionein-3 mRNA by thyroid hormone in developing rat brain and primary cultures of rat astrocytes and neurons

Metallothionein-3 (MT-3) is a brain specific member of the MT family. Unlike other members of this family, MT-3 has been shown to act as a neuronal growth inhibitory factor. MT-3 mRNA abundance increases throughout the developmental period, reaching adult levels by postnatal day 21. The role of thyroid hormone in the developmental regulation of MT-3 mRNA was tested because thyroid hormone is known to regulate brain gene expression. Furthermore, gestational hypothyroidism results in developmental brain abnormalities. Hypothyroidism was induced in pregnant dams by the administration of PTU from gestational day 7, resulting in a 4- to 6-fold increase in pup MT-3 mRNA abundance on the day of birth (day 0) and on postnatal day 3. Normal pups did not reach this level of brain MT-3 mRNA until postnatal day 21. Administration of thyroxine (T 4, 2 μg/g) to pups on postnatal day 1 or day 20 resulted in a decrease in MT-3 mRNA abundance on postnatal day 21, regardless of when the injection was given. Furthermore, addition of T 4 to primary cultures of brain (olfactory bulb) astrocytes and neurons from 4-day-old rats resulted in a significant decrease in MT-3 mRNA in 24 h. Given the neuronal growth inhibitory function of MT-3, these data suggest that MT-3 may play a role in the CNS-related consequences of hypo- and hyperthyroidism during development.

The course of putrescine immunocytochemical appearance in neurons, astroglia and microglia in rat brain cultures

Putrescine, the diamine precursor for polyamine biosynthesis, is a ubiquitous molecule normally present at low concentration in quiescent cells. During development, or after traumatic stress, putrescine concentrations are greatly increased. Here we describe the localization of putrescine by fluorescence immunocytochemistry in primary cultures of embryonic rat brain using specific antibodies. Antibodies against putrescine conjugated to keyhole limpet hemocyanin (KLH) were produced in rabbits. The antisera were adsorbed on KLH affinity columns and the specificity of the antibodies was assessed by inhibition enzyme-linked immunoassays (ELISA). The cellular localization paralleled the temporal sequence of appearance and disappearance of the different cell types in these mixed cultures. During the first 3 days after plating the antibodies were localized mainly in neurons. As the neurons disappeared the localization was mainly in the growing astroglia, and then, as astroglia reached confluence between 10 and 14 days in vitro, labeled astroglia were diminished in numbers while the number of labeled microglia was greatly increased. The subcellular localization was prominent in the perinuclear region of the cytoplasm. The results indicate that antibodies to KLH-conjugated putrescine can be used for immunocytochemical studies of changes in putrescine concentrations during development and after traumatic injuries.

Brain Primary Cultures and Vibrodissociated Cells as Tools for the Study of Astroglial Properties and Functions

The glial cells, especially the astroglia constitute a prominent part of the brain cell volume. Astroglial properties are difficult to study in the intact nervous system. For that reason, different in vitro models have been developed. The development of cell and tissue cultivation conditions has been the prerequisite to our present knowledge of the biochemistry and pharmacology of glial cells and to some extent even neurons. It is, however, an advantage if results from tissue culture can be evaluated in more in vivo like systems. We here describe a method for acute isolation of freshly prepared neurons and glial cells.

Apoptosis induced by infection of primary brain cultures with diverse human immunodeficiency virus type 1 isolates: evidence for a role of the envelope.

Apoptosis of neurons and astrocytes is induced by human immunodeficiency type 1 (HIV-1) infection in vitro and has been demonstrated in brain tissue from patients with AIDS. We analyzed a panel of diverse HIV-1 primary isolates for the ability to replicate and induce neuronal and astrocyte apoptosis in primary human brain cultures. Apoptosis was induced three- to eightfold by infection with the blood-derived HIV-1 isolates 89.6, SG3, and ADA. In contrast, the brain-derived HIV-1 isolates YU2, JRFL, DS-br, RC-br, and KJ-br did not induce significant levels of apoptosis. The ability of HIV-1 isolates to induce apoptosis was independent of their replication capacity. Studies of recombinant chimeras between the SG3 and YU2 viruses showed that replacement of the YU2 Env with the SG3 Env was sufficient to confer the ability to induce apoptosis to the YU2 virus. Replacement of the Env V3 regions alone largely conferred the phenotypes of the parental clones. The SG3 Env used CXCR4 and CCR3 as coreceptors for virus entry, whereas YU2 used CCR5 and CCR3. The V3 regions of SG3 and YU2 conferred the ability to use CXCR4 and CCR5, respectively. In contrast, the 3' region of Env, particularly the C3V4 region, was required in conjunction with the V3 region for efficient use of CCR3. These results provide evidence that Env is a major determinant of neurodegenerative mechanisms associated with HIV-1 infection in vitro and raise the possibility that blood-derived viruses which emerge during the late stages of disease may affect disease progression in the central nervous system.

Cerebrospinal fluid from L-dopa-treated Parkinson's disease patients is dystrophic for various neural cell types ex vivo: effects of astroglia.

Cerebrospinal fluid from L-dopa-treated Parkinson's disease patients and subjects without neurodegenerative diseases (controls) was explored in its trophic properties as culture medium on a variety of cells from neural origin. Primary cultures of regional brain dissociates from rat and Cebus apella monkey fetuses, immature rat adrenal chromaffin cells, phaeochromocytoma (PC12), and neuroblastoma (NB69) cell lines as well as subcultured fetal rat astroglia were used as target cells for 24- to 48-h culture periods. Most cerebrospinal fluid samples from L-dopa-treated patients had a general dystrophic effect. This phenomenon was more apparent on striatum and ventral mesencephalon than on cerebral cortex cell dissociates. The deleterious effect of these samples was abolished by previous exposure to fetal astroglial cells. Neuroblastoma cells showed no differential response when exposed to samples from control and L-dopa-treated patients. Phaeochromocytoma cells did not grow processes under any of the samples assayed in the time interval explored, but neither showed evidence of dystrophy. The relevance of these findings to the transplantation of different cell types as one of the possible therapies for Parkinson's disease is discussed. The suggestion is made that CSF testing prior to transplantation may aid in anticipating its possible outcome. Cotransplantation of neuronal cells with subcultured astroglia may foster survival and growth of the former cells.

Properties of GABA A receptors in cultured rat oligodendrocyte progenitor cells

We have studied the properties of GABA responses in oligodendrocyte-type 2 astrocyte (O-2A) progenitor cells derived from primary cultures of the neonatal rat brain. In whole cell voltage clamp recordings, rapid application of 1–10 mM GABA elicited current responses in >85% of the cells examined. The dose-response relationship pooled from nine progenitor cells was best fit by a logistic function of EC 50=113 μM and Hill coefficient=0.9. In contrast to the rate of current deactivation, the rate of current activation exhibited marked concentration-dependence. Pharmacologically, GABA, muscimol and ZAPA ((Z)-3[(aminiiminomethyl)thio]prop-2-enoic acid sulphate) produced responses with ligand-specific kinetics, whereas glycine and the GABA C receptor agonist CACA were without effect; bicuculline methochloride acted as a competitive antagonist. Neither the amplitude nor the kinetics of currents produced by 100 μM GABA were affected by the benzodiazepine flunitrazepam (1 μM). Similarly the benzodiazepine receptor inverse agonist DMCM (1 μM) was also without effect. GABA-activated currents reversed polarity within 2 mV of the calculated Cl − equilibrium potential. With brief agonist pulses deactivation was monoexponential, however, unlike neurones the rate of deactivation was voltage-independent. Desensitisation of responses to 10 mM GABA was bi-exponential and accelerated at depolarised membrane potentials. Increasing the amount of GABA A receptor desensitisation (by increasing the duration of the agonist exposure) consistently produced a slowing of deactivation.

Amyloid β-peptides inhibit Na/K-ATPase: tissue slices versus primary cultures

Aβ 1-40 (20 μM) has been reported to selectively inhibit Na +/K +-ATPase activity in rat primary hippocampal cultures after 2–6 days of exposure [10]. We expanded these studies to include Aβ’s effects on Na +/K +-ATPase activity in rat primary cortical cultures and hippocampal slices, and we correlated these effects with estimates of cell survival in rat brain primary cultures. Using optimized assay conditions, a 5-day exposure to 50 μM Aβ 25-35, 20 μM Aβ 1-40, and 20 μM Aβ 1-42 decreased Na +/K +-ATPase activity in rat primary cortical cultures 66%, 60%, and 22%, respectively. Aβ 25-35 (50 μM) at 24 h was the only condition that caused inhibition of Na +/K +-ATPase activity in the absence of cell death, defined as an extracellular shift in the localization of the cytoplasmic enzyme lactate dehydrogenase (LDH). We also found that hippocampal slices were sensitive to Aβ, exhibiting a 40–60% reduction in membrane Na +/K +-ATPase activity when exposed to 1–30 nM of Aβ 1-40 for 60 min. This inhibition was not readily reversible, as it withstood homogenization and repeated dilution and centrifugation. Additionally, this inhibition occurred only after amyloid incubation with intact hippocampal slices, not with disrupted membranes. The inhibition of Na +/K +-ATPase in brain slices by physiological, low nM concentrations of Aβ 1-40 is consistent with effects on neurotransmitter release and intrasynaptosomal calcium responses [4,7].