A novel approach for vital visualization and studying of neurons containing Ca2+ -permeable AMPA receptors.

Calcium-permeable AMPA receptors (CP-AMPARs) play a pivotal role in brain functioning in health and disease. They are involved in synaptic plasticity, synaptogenesis, and neuronal circuits development. However, the functions of neurons expressing CP-AMPARs and their role in the modulation of network activity remain elusive since reliable and accurate visualization methods are absent. Here we developed an approach allowing the vital identification of neurons containing CP-AMPARs. The proposed method relies on evaluating Ca2+ influx in neurons during activation of AMPARs in the presence of NMDAR and KAR antagonists, and blockers of voltage-gated Ca2+ channels. Using this method, we studied the properties of CP-AMPARs-containing neurons. We showed that the overwhelming majority of neurons containing CP-AMPARs are GABAergic, and they are distinguished by higher amplitudes of the calcium responses to applications of the agonists. Furthermore, about 30% of CP-AMPARs-containing neurons demonstrate the presence of GluK1-containing KARs. Although CP-AMPARs-containing neurons are characterized by more significant Ca2+ influx during the activation of AMPARs than other neurons, AMPAR-mediated Na+ influx is similar in these two groups. We revealed that neurons containing CP-AMPARs demonstrate weak GABA(A)R-mediated inhibition because of the low percentage of GABAergic synapses on the soma of these cells. However, our data show that weak GABA(A)R-mediated inhibition is inherent to all GABAergic neurons in the culture and cannot be considered a unique feature of CP-AMPARs-containing neurons. We believe that the suggested approach will help to understand the role of CP-AMPARs in the mammalian nervous system in more detail.

CEPO (carbamylated erythropoietin)-Fc protects hippocampal cells in culture against beta amyloid-induced apoptosis: considering Akt/GSK-3ß and ERK signaling pathways.

The tissue-protective properties of erythropoietin (EPO) have been described in several neurodegenerative diseases models, but erythrocytosis following EPO treatment may lead to deleterious effects. Carbamylated erythropoietin, an EPO derivative lacking hematopoietic side effects, has shown protective properties in some studies. However, it is not known if CEPO protects primary hippocampal cells against Aß25-35 toxicity. The present study aimed to investigate the effect of CEPO-Fc on biochemical alterations in Akt, GSK-3ß, and ERK signaling and cell death induced by Aß25-35 in isolated hippocampal cell culture. The embryonic hippocampal cells were obtained from 18-19 day rat embryos. The cells were exposed with Aß25-35 (20 µM) in the absence or presence of CEPO-Fc (1 or 5 IU) and PI3k and ERK inhibitors. CEPO-Fc at the dose of 5 IU significantly prevented the cell loss and caspase-3 cleavage caused by Aß25-35. Additionally, CEPO-Fc noticeably reversed Aß mediated decrement of Akt and GSK-3ß phosphorylation. With exposure to LY294002, PI3 kinase inhibitor, Akt phosphorylation diminished and CEPO-Fc protective effects disappeared. Furthermore, while CEPO-Fc nullified Aß-induced increment of phospho-ERK, inhibition of ERK activity by PD98059, had no effect on Aß25-35-mediated caspase-3 cleavage and cell toxicity. These results imply that protective effects of CEPO-Fc seem to be mainly exerted through the PI3K/Akt pathway rather than ERK signaling. This study suggested that CEPO-Fc prevents Aß-induced cell toxicity as well as Akt/GSK-3ß and ERK alterations in isolated hippocampal cells. These findings might provide a new perspective on CEPO-Fc protective properties as a prospective remedial factor for neurodegenerative diseases like AD.

The neuroprotective effect of agmatine against amyloid ß-induced apoptosis in primary cultured hippocampal cells involving ERK, Akt/GSK-3ß, and TNF-α.

ß-Amyloid peptide (Aß), the major element of senile plaques in Alzheimer's disease (AD), has been found to accumulate in brain regions critical for memory and cognition. Deposits of Aß trigger neurotoxic events which lead to neural apoptotic death. The present study examined whether agmatine, an endogenous polyamine formed by the decarboxylation of L-arginine, possesses a neuroprotective effect against Aß-induced toxicity. Primary rat hippocampal cells extracted from the brains of 18-19-day-old embryos were exposed to 10 µM of Aß (25-35) in the absence or presence of agmatine at 150 or 250 µM. Additionally, the involvement of Akt (Protein Kinae B), GSK-3ß (glycogen synthase kinase 3-ß), ERK (Extracellular Signal-Regulated Kinase) and TNF-α (Tumor necrosis factor-α) in the agmatine protection against Aß-induced neurotoxicity was investigated. Agmatine significantly prevented the effect of Aß exposure on cell viability and caspase-3 assays. Furthermore, agmatine considerably restored Aß-induced decline of phospho-Akt and phospho-GSK and blocked Aß-induced increase of phospho-ERK and TNF-alpha. Taken together, these findings might shed light on the protective effect of agmatine as a potential therapeutic agent for AD.

Cytokine IL-10, activators of PI3-kinase, agonists of α-2 adrenoreceptor and antioxidants prevent ischemia-induced cell death in rat hippocampal cultures.

In the present work we compared the protective effect of anti-inflammatory cytokine IL-10 with the action of a PI3-kinase selective activator 740 Y-P, selective agonists of alpha-2 adrenoreceptor, guanfacine and UK-14,304, and compounds having antioxidant effect: recombinant human peroxiredoxin 6 and B27, in hippocampal cell culture during OGD (ischemia-like conditions). It has been shown that the response of cells to OGD in the control includes two phases. The first phase was accompanied by an increase in the frequency of spontaneous synchronous Ca2+-oscillations (SSCO) in neurons and Ca2+-pulse in astrocytes. Spontaneous Ca2+ events in astrocytes during ischemia in control experiments disappeared. The second phase started after a few minutes of OGD and looked like a sharp/avalanche, global synchronic (within 20 s) increase in [Ca2+]i in many cells. Within 1 h after OGD, a mass death of cells, primarily astrocytes, was observed. To study the protective action of the compounds, cells were incubated in the presence of the neuroprotective agents for 10-40 min or 24 h before ischemia. All the neuroprotective agents delayed a global [Ca2+]i increase during OGD or completely inhibited this process and increased cell survival.

Ultrasound neuromodulation of cultured hippocampal neurons.

Ultrasound is becoming an emerging and promising method for neuromodulation due to its advantage of noninvasiveness and its high spatial resolution. However, the underlying principles of ultrasound neuromodulation have not yet been elucidated. We have herein developed a new in vitro setup to study the ultrasonic neuromodulation, and examined various parameters of ultrasound to verify the effective conditions to evoke the neural activity. Neurons were stimulated with 0.5 MHz center frequency ultrasound, and the action potentials were recorded from rat hippocampal neural cells cultured on microelectrode arrays. As the intensity of ultrasound increased, the neuronal activity also increased. There was a notable and significant increase in both the spike rate and the number of bursts at 50% duty cycle, 1 kHz pulse repetition frequency, and the acoustic intensities of 7.6 W/cm2 and 3.8 W/cm2 in terms of spatial-peak pulse-average intensity and spatial-peak temporal-average intensity, respectively. In addition, the impact of ultrasonic neuromodulation was assessed in the presence of a gamma-aminobutyric acid A (GABAA) receptor antagonist to exclude the effect of activated inhibitory neurons. Interestingly, it is noteworthy that the predominant neuromodulatory effects of ultrasound disappeared when the GABAA blocker was introduced, suggesting the potential of ultrasonic stimulation specifically targeting inhibitory neurons. The experimental setup proposed herein could serve as a useful tool for the clarification of the mechanisms underlying the electrophysiological effects of ultrasound.

Methods to Study the Roles of Rho GTPases in Dendritic Tree Complexity.

Most neurons elaborate a characteristic dendritic arbor which is physiologically important for receiving and processing of synaptic inputs. Pathologically, disturbances in the regulation of dendritic tree complexity are often associated with mental retardation and other neurological deficits. Rho GTPases are major players in the regulation of dendritic tree complexity. They are involved in many signal transduction cascades, activated at the neuronal plasma membrane, and relayed to intracellular proteins that directly rearrange the cytoskeleton. The use of siRNA technology combined with morphometric and imaging techniques allows the roles of individual Rho GTPases, such as Rac1, in dendritic branching to be examined. In this chapter we describe the establishment, transfection, and processing of a primary hippocampal cell culture. Methods to assess the complexity of dendritic arbors like the Sholl analysis, and techniques to investigate Rac1 activity in hippocampal cells, and specifically in neuronal dendrites, such as fluorescence resonance energy transfer (FRET) imaging are presented.

Functional Nanoscale Imaging of Synaptic Vesicle Cycling with Superfast Fixation.

Functional imaging is the measurement of structural changes during an ongoing physiological process over time. In many cases, functional imaging has been implemented by tracking a fluorescent signal in live imaging sessions. Electron microscopy, however, excludes live imaging which has hampered functional imaging approaches on the ultrastructural level. This barrier was broken with the introduction of superfast fixation. Superfast fixation is capable of stopping and fixing membrane traffic at sufficient speed to capture a physiological process at a distinct functional state. Applying superfast fixation at sequential time points allows tracking of membrane traffic in a step-by-step fashion.This technique has been applied to track labeled endocytic vesicles at central synapses as they pass through the synaptic vesicle cycle. At synapses, neurotransmitter is released from synaptic vesicles (SVs) via fast activity-dependent exocytosis. Exocytosis is coupled to fast endocytosis that retrieves SVs components from the plasma membrane shortly after release. Fluorescent FM dyes that bind to the outer leaflet of the plasma membrane enter the endocytic vesicle during membrane retrieval and remain trapped in endocytic vesicles have been widely used to study SV exo-endocytic cycling in live imaging sessions. FM dyes can also be photoconverted into an electron-dense diaminobenzidine polymer which allows the investigation of SV cycling in the electron microscope. The combination of FM labeling with superfast fixation made it possible to track the fine structure of endocytic vesicles at 1 s intervals. Because this combination is not specialized to SV cycling, many other cellular processes can be studied. Furthermore, the technique is easy to set up and cost effective.This chapter describes activity-dependent FM dye labeling of SVs in cultured hippocampal neurons, superfast microwave-assisted fixation, photoconversion of the fluorescent endocytic vesicles, and the analysis of individual synapses after serial section 3D reconstruction of individual synapses from electron micrographs.

The Interplay of Akt and ERK in Aß Toxicity and Insulin-Mediated Protection in Primary Hippocampal Cell Culture.

It is not known if insulin prevents Aß-induced cell death, MAPK, and Akt activity in isolated hippocampal cell culture. This study was aimed to explore the effect of insulin on Aß-induced cell death and ERK and Akt signaling alteration in isolated hippocampal cell culture. Additionally, it was desirable to assess if there is any interaction between these two pathways. The hippocampal cells were derived from fetuses at the embryonic day 18-19. The cells were treated with different drugs, and MTT assay, morphological assessments, and Western blot were done. Insulin prevented Aß-induced cell death and caspase-3 cleavage. Aß-induced toxicity was aligned with decrement of the phosphorylated Akt (pAkt) which was prevented by insulin. The PI3 kinase inhibitor, LY294002, decreased pAkt and abolished the protective effect of insulin. Aß exposure increased phosphorylated ERK (pERK) in parallel with cell death and apoptosis. Insulin-inhibited ERK activation (phosphorylation) induced by Aß and PD98059 (as ERK inhibitor) did not affect the protective effect of insulin. One of the interesting finding of this study was the interplay of Akt and ERK in Aß toxicity and insulin-mediated protection; meaning that there is an inverse relation between pERK and pAkt, in a way that PI3-Akt pathway inhibition leads to pERK increment while ERK inhibition causes Akt phosphorylation (activation). This study showed, for the first time, that insulin protects against Aß toxicity in isolated hippocampal cell culture via modulating Akt and ERK phosphorylation and also revealed an interaction between those signals in Aß toxicity and insulin-mediated protection.

Neurotoxicity of coral snake phospholipases A2 in cultured rat hippocampal neurons.

The neurotoxicity of two secreted Phospholipases A2 from Brazilian coral snake venom in rat primary hippocampal cell culture was investigated. Following exposure to Mlx-8 or Mlx-9 toxins, an increase in free cytosolic Ca(2+) and a reduction in mitochondrial transmembrane potential (ΔΨm) became evident and occurred prior to the morphological changes and cytotoxicity. Exposure of hippocampal neurons to Mlx-8 or Mlx-9 caused a decrease in the cell viability as assessed by MTT and LDH assays. Inspection using fluorescent images and ultrastructural analysis by scanning and transmission electron microscopy showed that multiphase injury is characterized by overlapping cell death phenotypes. Shrinkage, membrane blebbing, chromatin condensation, nucleosomal DNA fragmentation and the formation of apoptotic bodies were observed. The most striking alteration observed in the electron microscopy was the fragmentation and rarefaction of the neuron processes network. Degenerated terminal synapses, cell debris and apoptotic bodies were observed among the fragmented fibers. Numerous large vacuoles as well as swollen mitochondria and dilated Golgi were noted. Necrotic signs such as a large amount of cellular debris and membrane fragmentation were observed mainly when the cells were exposed to highest concentration of the PLA2-neurotoxins. PLA2s exposed cultures showed cytoplasmic vacuoles filled with cell debris, clusters of mitochondria presented mitophagy-like structures that are in accordance to patterns of programmed cell death by autophagy. Finally, we demonstrated that the sPLA2s, Mlx-8 and Mlx-9, isolated from the Micrurus lemniscatus snake venom induce a hybrid cell death with apoptotic, autophagic and necrotic features. Furthermore, this study suggests that the augment in free cytosolic Ca(2+) and mitochondrial dysfunction are involved in the neurotoxicity of Elapid coral snake venom sPLA2s.

Caracterização da via de ativação de neurotoxicidade induzida pela Anidroegconina Metil Éster (AEME) in vitro / Activation pathways characterization related to the Anhydroegconin Methyl Ester (AEME)-induced neurotoxicity in vitro

O consumo mundial de cocaína vem crescendo e no Brasil já são estimados mais de 2 milhões de usuários, destes 370 mil usam regularmente o crack. A cocaína, em suas diversas formas, é um psicoestimulante com alto potencial de abuso e a forma fumada causa à seus usuários mais complicações de saúde do que as demais formas. Muitas dessas complicações estão relacionadas às funções cognitivas, como comprometimento da atenção e memória. O usuário de crack, no ato de fumar, está sujeito tanto à ação da cocaína volatilizada quanto a dos seus produtos de pirólise, principalmente da anidroecgnonina metil éster (AEME). Considerando que pouco se conhece a respeito da AEME, ou de sua associação com cocaína, que os distúrbios cognitivos podem estar relacionados à morte neuronal e que o hipocampo é uma das principais estruturas encefálicas relacionada com cognição e memória, este trabalho visou investigar as vias de ativação de morte celular decorrente das exposições à 1 mM de AEME, 2 mM de cocaína, bem como da associação de ambas (C + A), por 3, 6 e 12 h. Para tanto, utilizamos neurônios hipocampais de embriões de rato no 18º dia embrionário (E18) que foram mantidos em cultura por até 7 dias (DIV7), quando foram feitas as exposições. Nossos resultados mostraram que em 3 h a cocaína e a AEME promoveram aumento de atividade enzimática (pelo teste de MTT) que se reverteu ao longo de 12 h. Além disso, AEME aumentou na permeabilidade da membrana plasmática em 6 h que se manteve em 12 h. Embora essas alterações tenham ocorrido em 3 h e 6 h, caspase-8 se ativou apenas em 12 h, ativando também a sinalização apoptótica com a externalização de FS. A cocaína ativou o processo autofágico a partir de 3 h aumentando a quantificação de LC3 II, mas apresentou redução de células com vesículas ácidas em 6 h e 12 h, sugerindo que esta promova morte neuronal por causar falha no fluxo autofágico. A AEME apresentou somente aumento de células com vesículas ácidas em 3 h, revertendo-se já em 6 h, indicando que o processo autofágico só se fez presente no primeiro horário, dando vez à programação de apoptose celular, por ativação da via extrínseca. A associação dessas substâncias apresentou-se mais neurotóxica do que as substâncias isoladas, com redução de células íntegras a partir de 3 h de exposição, ativação de caspase-8 e externalização de FS em 6 h, sem envolver o sistema autofágico. Além disso, as características morfológicas observadas em 6 h, como o aumento do tamanho do núcleo e do corpo celular que se tornaram picnóticos em 12 h, podem sugerir que a neurotoxicidade induzida por C + A seja por necroptose, onde a ativação de caspases resulta em um processo tipo necrótico. Assim, concluímos que, embora a literatura mostre morte neuronal por apoptose a partir de 24 h de exposição para cocaína e para AEME, as respostas celulares que levam à este fim iniciam-se já em 12 h, por ativação da via extrínseca e a associação destas substâncias é ainda mais neurotóxica, iniciando a sinalização de morte já em 6 h e induzindo uma morfologia tipo necrótica

Cocaine market is increasing all around the world. In Brazil it is estimated that almost 2 million people make usage of this substance which 370 thousand people use the crack form. Cocaine is a psychostimulant with large potential for abuse and the smokable form produces more health problems than the other routes of use, mainly in the cognitive field related to compromising attention, memory and decision take. The crack users are exposed to both volatized cocaine and their pyrolysis products, which the main product is the anhydroecgonine methyl ester (AEME). Considering that the cognitive disturbs could be related to neurons death, the memory functions are also related to the hippocampal functions, and little is known about the AEME neurotoxicity or even the combination of cocaine and AEME in cell fate, our study aims to characterize the time and pathways related to the hippocampal neurotoxicity induced by 2 mM of cocaine, 1 mM of AEME and the association (C + A) of both substances during 3 h, 6 h and 12 h of exposure. Our results showed that cocaine and AEME increased enzymatic activity (MTT test) in 3 h but it reversed during 12 h of exposure. Moreover, AEME increased cell permeability in 6 h keeping it until 12 h. Although theses early alterations, both substances activated caspase -8 after 12 h when early apoptosis was also observed by the FS externalization. Cocaine activated the autophagic process at 3 h increasing the LC3 II quantification, but decreased the number of cell with acid vesicle at 6 h and 12 h, suggesting neuronal death due to failure in the autophagic flux. AEME showed increased in cell number with acid vesicle only in 3 h which returned after 6 h suggesting that the autophagic process gave place to the apoptotic program starting from the extrinsic pathway. The association of cocaine and AEME was shown more neurotoxic than them alone, decreasing the number of integral cells after 3 h, activating caspase -8 and promoting FS externalization after 6 h without involving the autophagy. In addition, taking the C + A morphology in 6 h, where it was observed increasing of nucleus and soma size that became pyknotic at 12 h, we suggest that the neuronal death could occur by necroptosis because this composition activated caspase -8 and resulted in necrotic like morphology. Thus, we conclude that cocaine- and AEME-induced apoptosis neuronal death starts in 12 h of exposure by the extrinsic pathway and the association of both substances is more neurotoxic than they alone, starting earlier after 6 h and resulting in a necrotic-like morphology