Quantitative differences in developmental profiles of spontaneous activity in cortical and hippocampal cultures

Charlesworth, Paul; Cotterill, Ellese; Morton, Andrew; Grant, Seth G. N.; Eglen, Stephen J.

doi:10.1101/009845

Cited by 9 publications

(16 citation statements)

References 25 publications

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“…The neurons fired bursts of matured action potential spontaneously detected both in the current-clamp and voltage-clamp mode ( Figure 1D and 1E ) at day in-vitro 15. The action potential properties calculated through injecting a series of 500ms depolarizing current steps (−40pA to +540pA) were comparable to previously published reports ( Figure EV 1H, 1J, and 1K ) [33,34,36,37]. The presence of robust mEPSCs recorded at the baseline supports the presence of spontaneous excitatory neurotransmission ( Figure 1F and 1G ) [35].…”

Section: Resultssupporting

confidence: 87%

Distinct Regulation of Bioenergetics and Translation by Group I mGluR and NMDAR

Dastidar

Sharma

Chakraborty

et al. 2019

Preprint

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21Neuronal activity is responsible for disproportionally large consumption of energy by 22 the brain. However, little is known about the processes within neurons responsible for 23 such abundant ATP outlay. Here we provide evidence that major fraction of ATP 24 consumed on glutamate stimulation is due to activation of global de-novo protein 25 synthesis mediated by group I mGluRs in cultured cortical neurons. We found mGluR 26 and NMDAR stimulation impacts translation with distinct kinetics; while mGluR lead to 27 rapid and sustained translation activation as measured by eEF2 phosphorylation and 28 metabolic labeling, NMDAR stimulation induced a robust translation inhibition. Our 29 observations established an inverse correlation between the kinetics of translation and 30 change in ATP level for both receptors. We observed an immediate mGluR mediated 31 reduction in neuronal ATP level while NMDA lead to a delayed (≥15 mins) protein 32 synthesis dependent ATP expenditure demonstrating a possibility for NMDAR dependent 33 delayed translation activation. Interestingly, we identified that AMP activated protein 34 kinase (AMPK) has a central role in regulating downstream effects of both mGluR and 35 NMDAR. AMPK activity was reduced on mGluR stimulation even under low ATP levels 36 while there was a rapid increase in AMPK activity on NMDAR stimulation. Perturbing 37 AMPK function prior to either stimulation led to a complete loss of stimulation specific 38 effects on eEF2 phosphorylation and global translation. Our observation therefore 39 established a pivotal role for AMPK-eEF2 signaling axis on receptor specific regulation 40 of global translation.41 42 109 dependent reduction was absent in presence of protein synthesis inhibitors anisomycin 110 (25μM) or cycloheximide (100μg/ml) (Figure 1B) while drugs themselves had no 111 significnat impact on the ATP/(ATP+ADP) ratio. These observations suggest a large 112 increase in protein synthesis on stimulation, responsible for consuming signifcant 113 fraction of neuronal ATP. The identical effects of both anisomycin and cycloheximide 114 negates the possibility of these observations due to non-specific effects of these drugs. 115 Further, to understand the contributions from individual glutamate receptors, we 116 repeated glutamate stimulation inhibiting either ionotropic NMDA and AMPA receptors 117 with a cocktail of D-AP5 (25μM) + CNQX (40μM) (referred to as inotropic glutamate 118 receptor (iGluR) blocker cocktail hereafter) or inhibiting mGluRs with MPEP (10μM). Co-119 stimulation with iGluR blocker cocktail led to significant reduction in ATP/(ATP+ADP) 120 ratio similar to glutamate alone while stimulation along with MPEP abolished the 121 glutamate mediated reduction significantly (Figure 1C). These results therefore, 122 indicate that the observed reduction in ATP on glutamate stimulation is majorly due to 123 mGluR activity with minimal contributions from the iGluRs. Furthermore, Stimulation 124 in presence iGluR blocker cocktail along with protein synthesis inhib...

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Section: Resultssupporting

confidence: 87%

Distinct Regulation of Bioenergetics and Translation by Group I mGluR and NMDAR

Dastidar

Sharma

Chakraborty

et al. 2019

Preprint

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“…Based on these assessments, four burst detectors, namely the MI, logISI, PS and CMA methods, were chosen as the best performing burst detection methods, and used to analyse bursting activity in novel recordings of networks of human induced pluripotent stem cell (hiPSC)-derived neuronal networks over several months of development. This analysis showed a slight increase in the proportion of bursting activity observed in these networks as they mature, although this increase was far lower than that which has been observed in developing rodent neuronal networks [14,19,95].…”

Section: D2mentioning

confidence: 65%

“…Analysis of patterns of bursting activity can thus be used as a proxy for studying the underlying physiological processes and structural features of neuronal networks. A common method of studying bursting activity in vitro involves the use of MEA recordings of spontaneous or evoked neuronal network activity [50,14,69,93]. This approach has been employed to study changes in spontaneous network activity over development [95], and the effect of pharmacological or genetic manipulations [23,15].…”

mentioning

confidence: 99%

“…Instead, a large variety of burst detection methods have been proposed, many of which have been developed and assessed using specific data sets and single experimental conditions. As most studies of bursting activity have been performed on experimental data from recordings of rodent neuronal networks [14,55], this type of data has most often been used to assess the performance of burst detec-tion techniques [19,55,30].…”

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confidence: 99%

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Burst Detection Methods

Cotterill

Eglen

2019

Advances in Neurobiology

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Bursting', defined as periods of high frequency firing of a neuron separated by periods of quiescence, has been observed in various neuronal systems, both in vitro and in vivo. It has been associated with a range of neuronal processes, including efficient information transfer and the formation of functional networks during development, and has been shown to be sensitive to genetic and pharmacological manipulations. Accurate detection of periods of bursting activity is thus an important aspect of characterising both spontaneous and evoked neuronal network activity. A wide variety of computational methods have been developed to detect periods of bursting in spike trains recorded from neuronal networks. In this chapter, we review several of the most popular and successful of these methods.

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“…Spontaneous neuronal activity refers to the ability of an individual neuron to be electro-physiologically active without receiving external stimulation. During development, many parts of the nervous system generate patterns of spontaneous activity [27] and these patterns of activity are thought to be instructive in the assembly of neural connectivity. It is shown that neurons generated from pluripotent stem cells (PSCs) generate random spontaneous spikes that are independent of external stimulation [28].…”

Section: The Modelmentioning

confidence: 99%

Emergence of the small-world architecture in neural networks by activity dependent growth

Gafarov

2016

Physica A: Statistical Mechanics and its Applications

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Quantitative differences in developmental profiles of spontaneous activity in cortical and hippocampal cultures

Cited by 9 publications

References 25 publications

Distinct Regulation of Bioenergetics and Translation by Group I mGluR and NMDAR

Distinct Regulation of Bioenergetics and Translation by Group I mGluR and NMDAR

Burst Detection Methods

Emergence of the small-world architecture in neural networks by activity dependent growth

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