State and location dependence of action potential metabolic cost in cortical pyramidal neurons

Hallermann, Stefan; Kock, De; Stuart, Gregory J; Kole, Maarten H. P.

doi:10.1038/nn.3132

Cited by 156 publications

(239 citation statements)

References 58 publications

Supporting

Mentioning

225

Contrasting

Order By: Relevance

“…This is not, however, their sole function; action potentials are also important for preventing noise accumulation in successive layers of information processing in neural circuits. The energy consumption of a single action potential within a single neuron would be challenging to measure directly, so typically it is estimated by converting the electrical signals into the total amount of work the 3Na + /2K + pump must do to restore ion gradients (Box 1) [9,[25][26][27][28][29][30][31][32][33][34][35][36]. Estimates of action potential energy consumption are, consequently, dependent upon accurate measurement of biophysical parameters including channel kinetics, conductance magnitudes and membrane capacitances.…”

Section: Action Potential Energy Consumptionmentioning

confidence: 99%

“…It was assumed that the energy consumption of this action was broadly representative of other action potentials [9]; however, this was dispelled by combining experimental measurements and computational modelling of a range of action potentials primarily from mammalian neurons [26][27][28][29]. This demonstrated that the squid giant axon action potential was profligate in its energy consumption compared to most other action potentials, and revealed a hitherto unappreciated heterogeneity in the biophysics of the currents generating action potentials and their consequences for the energy consumption of the action potential [25][26][27][28][29][30][31][32][33][34][35][36]. The major cause of differences in energy consumption was identified as the overlap between the inward and outward currents during the action potential [26,28,34,35]: A large overlap inflates energy consumption whereas complete separation of the currents reduces energy consumption close to the minimum possible.…”

Section: Heterogeneity In Action Potential Costsmentioning

confidence: 99%

See 1 more Smart Citation

Neuronal energy consumption: biophysics, efficiency and evolution

Niven

2016

Current Opinion in Neurobiology

122

View full text Add to dashboard Cite

Electrical and chemical signaling within and between neurons consumes energy. Recent studies have sought to refine our understanding of the processes that consume energy and their relationship to information processing by coupling experiments with computational models and energy budgets. These studies have produced insights into both how neurons and neural circuits function, and why they evolved to function in the way they do. Introduction Neurons consume energy. Appreciating that they do so is essential for understanding and interpreting the function and evolution of neurons, neural circuits and, ultimately, whole brains. Yet we must go beyond mere appreciation by relating specific molecular components and processes to the energy they consume and the work they contribute to processing information and generating behavior. This permits determination of both 'how' and 'why' processes consume energy, and an understanding of the key trade-offs that have influenced neural evolution (reviewed in [1,2]). Although neuronal energy consumption has been studied for over 80 years [3,4], conceptual and methodological breakthroughs [5][6][7][8][9] have prompted renewed interest in the causes and consequences of neuronal energy consumption over the last ~20 years. Here I review this recent progress in our understanding of how the physiology and anatomy of neurons and neural circuits reflect fundamental relationships between energy consumption, biophysics and performance. Addresses

show abstract

Section: Action Potential Energy Consumptionmentioning

confidence: 99%

Section: Heterogeneity In Action Potential Costsmentioning

confidence: 99%

Neuronal energy consumption: biophysics, efficiency and evolution

Niven

2016

Current Opinion in Neurobiology

122

View full text Add to dashboard Cite

show abstract

“…To mimic this situation of suprathreshold neuronal activity, Na ϩ recordings were performed in dendrites following a transient large increase in [Na ϩ ] i . The energy cost for turn-over of Na,K-ATPase is estimated to be ϳ50% of total brain energy consumption (16) and because sev-eral lines of evidence suggest that the majority of this Na ϩ current dependent energy is expended postsynaptically rather than presynaptically (17), the Na ϩ imaging studies were performed on dendrites.…”

mentioning

confidence: 99%

A Specific and Essential Role for Na,K-ATPase α3 in Neurons Co-expressing α1 and α3

Azarias

Kruusmägi

Connor

et al. 2013

Journal of Biological Chemistry

112

View full text Add to dashboard Cite

show abstract

“…From the total Na + flux during an action potential in both somatic and axonic compartments, and using standard methods (e.g. Alle et al, 2009;Sengupta et al, 2010), we calculate the cost of a single action potential in a P neuron to be about 10 9 ATP molecules (Fig.4C); this is similar to, but on the high end of the range of, previous estimates for other neurons (Attwell and Laughlin, 2001;Lennie, 2003;Hallermann et al, 2012). Note that such estimates depend strongly on the relative gating kinetics of the Na + and K + channels and can vary significantly between neurons (Sengupta et al, 2010).…”

Section: Electromotor Network: Pacemaker Nucleusmentioning

confidence: 67%

“…Alle et al, 2009;Sengupta et al, 2010). Such estimates suggest that each action potential consumes between 10 7 and 10 9 ATP molecules depending on neuron type (Attwell and Laughlin, 2001;Lennie, 2003;Sengupta et al, 2010;Hallermann et al, 2012;. Thus, an action potential in just a single neuron can consume an order of magnitude more energy than the minimal amount required to assemble the electric field, suggesting that the actual cost of EOD generation must be several orders of magnitude higher than this theoretical lower bound.…”

Section: Action Potential Energeticsmentioning

confidence: 99%

The energetics of electric organ discharge generation in gymnotiform weakly electric fish

Salazar

Krahe

Lewis

2013

Journal of Experimental Biology

View full text Add to dashboard Cite

SummaryGymnotiform weakly electric fish produce an electric signal to sense their environment and communicate with conspecifics. Although the generation of such relatively large electric signals over an entire lifetime is expected to be energetically costly, supporting evidence to date is equivocal. In this article, we first provide a theoretical analysis of the energy budget underlying signal production. Our analysis suggests that wave-type and pulse-type species invest a similar fraction of metabolic resources into electric signal generation, supporting previous evidence of a trade-off between signal amplitude and frequency. We then consider a comparative and evolutionary framework in which to interpret and guide future studies. We suggest that species differences in signal generation and plasticity, when considered in an energetics context, will not only help to evaluate the role of energetic constraints in the evolution of signal diversity but also lead to important general insights into the energetics of bioelectric signal generation.

show abstract

State and location dependence of action potential metabolic cost in cortical pyramidal neurons

Cited by 156 publications

References 58 publications

Neuronal energy consumption: biophysics, efficiency and evolution

Neuronal energy consumption: biophysics, efficiency and evolution

A Specific and Essential Role for Na,K-ATPase α3 in Neurons Co-expressing α1 and α3

The energetics of electric organ discharge generation in gymnotiform weakly electric fish

Contact Info

Product

Resources

About