<i>In Vivo</i>Intracellular Recording Suggests That Gray Matter Astrocytes in Mature Cerebral Cortex and Hippocampus Are Electrophysiologically Homogeneous

Mishima, Tatsuya; Hirase, Hajime

doi:10.1523/jneurosci.5065-09.2010

Cited by 58 publications

(56 citation statements)

References 48 publications

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“…The constant E ns term for all activity states was 0.76 × 10 17 ATP/s per centimeter 3 , leading to average P ns,N and P ns,A values of 9.20 × 10 8 ATP/neuron per second and 6.85 × 10 8 ATP/astrocytes per second, respectively, for an OGI range of 5.1-6.0 (20). These values of P ns corresponded to an average R in value of 74 MΩ (SI Text, section 2), which is well within the in vivo range measured for neurons and astrocytes (13,14). As shown in Table 1, despite identical cortical densities of neurons and astrocytes, P ns,N and P ns,A were dissimilar, because slightly different Nernst potentials for Na + and K + and resting membrane potentials were used for neurons and astrocytes (SI Text, section 2), which has been done before (7,8).…”

Section: Calculating Signaling and Nonsignaling Energetics In The Humansupporting

confidence: 71%

“…This difference principally occurs, because Attwell and Laughlin (7) assumed R in,N and R in,A to be around 200 and 500 MΩ, respectively, based on in vitro recordings (30,31). However, our estimates of R in,N and R in,A values of 74 MΩ are in close agreement with in vivo measurements (13,14). Because P ns depends on the reciprocal of R in (SI Text, section 2), the higher R in,N and R in,A values by Attwell and Laughlin (7) are the main basis for their lower P ns,N and P ns,A estimates.…”

Section: Discussionsupporting

confidence: 59%

“…resistances (14). The in vivo results were fit well with the assumption of the major energetic changes with activity being in the neurons.…”

Section: Glial Energy Demand and Excitatory Vs Inhibitory Neuronal Esupporting

confidence: 67%

“…S1) and the average neuronal (η N ) and astrocytic (η A ) densities in the cerebral cortex (Table 1). Because recent R in,x and η x measurements in the rat show that values for neurons and astrocytes are quite similar (13)(14)(15)(16), the calculations were slightly simplified by assuming that R in,N ∼ R in,A and η N ∼ η A (Table 1 and SI Text, section 2). To determine P ns , we needed the metabolic demand for nonsignaling, which was possible for the rat, because state of deep pentobarbital anesthesia in Table S1 …”

Section: Energetics Of Nonsignaling Events From Isoelectric Conditionmentioning

confidence: 99%

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Cortical energy demands of signaling and nonsignaling components in brain are conserved across mammalian species and activity levels

Hyder

Rothman

Bennett

2013

Proc. Natl. Acad. Sci. U.S.A.

226

219

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The continuous need for ion gradient restoration across the cell membrane, a prerequisite for synaptic transmission and conduction, is believed to be a major factor for brain's high oxidative demand. However, do energy requirements of signaling and nonsignaling components of cortical neurons and astrocytes vary with activity levels and across species? We derived oxidative ATP demand associated with signaling (P s ) and nonsignaling (P ns ) components in the cerebral cortex using species-specific physiologic and anatomic data. In rat, we calculated glucose oxidation rates from layer-specific neuronal activity measured across different states, spanning from isoelectricity to awake and sensory stimulation. We then compared these calculated glucose oxidation rates with measured glucose metabolic data for the same states as reported by 2-deoxy-glucose autoradiography. Fixed values for P s and P ns were able to predict the entire range of states in the rat. We then calculated glucose oxidation rates from human EEG data acquired under various conditions using fixed P s and P ns values derived for the rat. These calculated metabolic data in human cerebral cortex compared well with glucose metabolism measured by PET. Independent of species, linear relationship was established between neuronal activity and neuronal oxidative demand beyond isoelectricity. Cortical signaling requirements dominated energy demand in the awake state, whereas nonsignaling requirements were ∼20% of awake value. These predictions are supported by 13 C magnetic resonance spectroscopy results. We conclude that mitochondrial energy support for signaling and nonsignaling components in cerebral cortex are conserved across activity levels in mammalian species.T he brain is one of the most energy demanding tissues in the body (1). 13 C magnetic resonance spectroscopy (MRS) in the rat has shown that, in the resting awake state, ∼80% of cortical energy consumption is used to support signaling as reflected by the rate of glutamate neurotransmitter release and astroglial uptake (2, 3). Cerebral energy demand is also positively correlated with the rate of pyramidal neuron firing in rat cortex (4, 5). 13 C MRS findings in the human cortex have been generally consistent with the rat results (6). However, there remain questions as to how well the energy costs of specific subcellular processes needed to support synaptic transmission and conduction are conserved over different activity levels and/or across species.Recent bottom-up energy budgets for gray matter in the mammalian brain have attempted to understand the energetic costs of neuronal and glial electrical and neurotransmission events occurring in the neuropil (7,8) by calculating the ATP used per neuron for signaling (P s ) and nonsignaling (P ns ) events. In the awake cortex, the total ATP used per unit cortical volume per unit time (E tot ; in units of ATP/s per centimeter 3 ) was determined by multiplying the P s (in units of ATP/neuron per spike) and P ns (in units of ATP/neuron per second) parameter...

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Section: Calculating Signaling and Nonsignaling Energetics In The Humansupporting

confidence: 71%

Section: Discussionsupporting

confidence: 59%

“…resistances (14). The in vivo results were fit well with the assumption of the major energetic changes with activity being in the neurons.…”

Section: Glial Energy Demand and Excitatory Vs Inhibitory Neuronal Esupporting

confidence: 67%

Section: Energetics Of Nonsignaling Events From Isoelectric Conditionmentioning

confidence: 99%

See 2 more Smart Citations

Cortical energy demands of signaling and nonsignaling components in brain are conserved across mammalian species and activity levels

Hyder

Rothman

Bennett

2013

Proc. Natl. Acad. Sci. U.S.A.

226

219

View full text Add to dashboard Cite

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“…So far, V m fluctuations in astrocytes have mostly been reported from in vivo experiments (16,22) In KO Cx43 mice, dye coupling was diminished by 66% in the presence of TTX when injections were performed in glomerular astrocytes (n = 6 for both control and TTX conditions; P < 0.001), whereas in KO Cx30 animals, dye coupling was not affected by TTX treatment (78% of control, n = 10 and n = 6 for control and TTX conditions, respectively; P = 0.1462). Note that in the control condition, the number of coupled cells was reduced by 42% (n = 6, P < 0.001) and 29% (n = 10, P < 0.001) in KO Cx43 and KO Cx30 mice, respectively, compared with wild type (n = 26).…”

Section: Injmentioning

confidence: 99%

Plasticity of astroglial networks in olfactory glomeruli

Roux

Benchenane

Rothstein

et al. 2011

Proc. Natl. Acad. Sci. U.S.A.

119

118

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Several recent findings have shown that neurons as well as astrocytes are organized into networks. Indeed, astrocytes are interconnected through connexin-formed gap junction channels allowing exchanges of ions and signaling molecules. The aim of this study is to characterize astrocyte network properties in mouse olfactory glomeruli where neuronal connectivity is highly ordered. Dyecoupling experiments performed in olfactory bulb acute slices (P16-P22) highlight a preferential communication between astrocytes within glomeruli and not between astrocytes in adjacent glomeruli. Such organization relies on the oriented morphology of glomerular astrocytes to the glomerulus center and the enriched expression of two astroglial connexins (Cx43 and Cx30) within the glomeruli. Glomerular astrocytes detect neuronal activity showing membrane potential fluctuations correlated with glomerular local field potentials. Accordingly, gap junctional coupling of glomerular networks is reduced when neuronal activity is silenced by TTX treatment or after early sensory deprivation. Such modulation is lost in Cx30 but not in Cx43 KO mice, indicating that Cx30-formed channels are the molecular targets of this activity-dependent modulation. Extracellular potassium is a key player in this neuroglial interaction, because (i) the inhibition of dye coupling observed in the presence of TTX or after sensory deprivation is restored by increasing [K + ] e and (ii) treatment with a K ir channel blocker inhibits dye spread between glomerular astrocytes. Together, these results demonstrate that extracellular potassium generated by neuronal activity modulates Cx30-mediated gap junctional communication between glomerular astrocytes, indicating that strong neuroglial interactions take place at this first relay of olfactory information processing.O lfactory glomeruli (OG) represent functional units where olfactory signals are first processed (1, 2). The combination of the anatomical organization and the functional activity results in a highly ordered spatial map of glomerular activation associated with each odor (3, 4). However, this well-described organization refers only to neuronal circuits, and information concerning astroglial connectivity is lacking. In the brain, astrocytes express the highest rate of connexins (Cxs), the protein constituents of gap junction channels that provide the molecular basis for direct cellto-cell communication. Though astrocytes were initially thought to form a glial syncitium, there is now evidence for a more specialized network organization (5). As increasing evidence argues for dynamic interactions between neurons and astrocytes (6), a coordinated population of astrocytes working in concert with neurons could contribute to sensory integration occurring in OG. The goal of this study is to determine how Cx-mediated intercellular communication in astrocytes is organized and modulated in this brain structure characterized by functional units. Features of OG astrocytes studied so far include their morphology (7,8), membrane...

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The glia/neuron ratio: How it varies uniformly across brain structures and species and what that means for brain physiology and evolution

Herculano‐Houzel

2014

Glia

503

350

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It is a widespread notion that the proportion of glial to neuronal cells in the brain increases with brain size, to the point that glial cells represent "about 90% of all cells in the human brain." This notion, however, is wrong on both counts: neither does the glia/neuron ratio increase uniformly with brain size, nor do glial cells represent the majority of cells in the human brain. This review examines the origin of interest in the glia/neuron ratio; the original evidence that led to the notion that it increases with brain size; the extent to which this concept can be applied to white matter and whole brains and the recent supporting evidence that the glia/neuron ratio does not increase with brain size, but rather, and in surprisingly uniform fashion, with decreasing neuronal density due to increasing average neuronal cell size, across brain structures and species. Variations in the glia/neuron ratio are proposed to be related not to the supposed larger metabolic cost of larger neurons (given that this cost is not found to vary with neuronal density), but simply to the large variation in neuronal sizes across brain structures and species in the face of less overall variation in glial cell sizes, with interesting implications for brain physiology. The emerging evidence that the glia/neuron ratio varies uniformly across the different brain structures of mammalian species that diverged as early as 90 million years ago in evolution highlights how fundamental for brain function must be the interaction between glial cells and neurons.

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In VivoIntracellular Recording Suggests That Gray Matter Astrocytes in Mature Cerebral Cortex and Hippocampus Are Electrophysiologically Homogeneous

Cited by 58 publications

References 48 publications

Cortical energy demands of signaling and nonsignaling components in brain are conserved across mammalian species and activity levels

Cortical energy demands of signaling and nonsignaling components in brain are conserved across mammalian species and activity levels

Plasticity of astroglial networks in olfactory glomeruli

The glia/neuron ratio: How it varies uniformly across brain structures and species and what that means for brain physiology and evolution

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