Divergent Cellular Energetics, Glutamate Metabolism, and Mitochondrial Function Between Human and Mouse Cerebral Cortex

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

Divergent Cellular Energetics, Glutamate Metabolism, and Mitochondrial Function Between Human and Mouse Cerebral Cortex. / Westi, Emil W.; Jakobsen, Emil; Voss, Caroline M.; Bak, Lasse K.; Pinborg, Lars H.; Aldana, Blanca, I; Andersen, Jens, V.

In: Molecular Neurobiology, Vol. 59, 2022, p. 7495–7512 .

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Westi, EW, Jakobsen, E, Voss, CM, Bak, LK, Pinborg, LH, Aldana, BI & Andersen, JV 2022, 'Divergent Cellular Energetics, Glutamate Metabolism, and Mitochondrial Function Between Human and Mouse Cerebral Cortex', Molecular Neurobiology, vol. 59, pp. 7495–7512 . https://doi.org/10.1007/s12035-022-03053-5

APA

Westi, E. W., Jakobsen, E., Voss, C. M., Bak, L. K., Pinborg, L. H., Aldana, B. I., & Andersen, J. V. (2022). Divergent Cellular Energetics, Glutamate Metabolism, and Mitochondrial Function Between Human and Mouse Cerebral Cortex. Molecular Neurobiology, 59, 7495–7512 . https://doi.org/10.1007/s12035-022-03053-5

Vancouver

Westi EW, Jakobsen E, Voss CM, Bak LK, Pinborg LH, Aldana BI et al. Divergent Cellular Energetics, Glutamate Metabolism, and Mitochondrial Function Between Human and Mouse Cerebral Cortex. Molecular Neurobiology. 2022;59:7495–7512 . https://doi.org/10.1007/s12035-022-03053-5

Author

Westi, Emil W. ; Jakobsen, Emil ; Voss, Caroline M. ; Bak, Lasse K. ; Pinborg, Lars H. ; Aldana, Blanca, I ; Andersen, Jens, V. / Divergent Cellular Energetics, Glutamate Metabolism, and Mitochondrial Function Between Human and Mouse Cerebral Cortex. In: Molecular Neurobiology. 2022 ; Vol. 59. pp. 7495–7512 .

Bibtex

@article{aacb3fbda76143c1a7bb7d990c2042ef,
title = "Divergent Cellular Energetics, Glutamate Metabolism, and Mitochondrial Function Between Human and Mouse Cerebral Cortex",
abstract = "Disruptions of brain energy and neurotransmitter metabolism are associated with several pathological conditions including neurodegenerative diseases such as Alzheimer{\textquoteright}s disease. Transgenic rodent models, and in vitro preparations hereof, are often applied for studying pathological aspects of brain metabolism. However, despite the conserved cerebral development across mammalian species, distinct differences in cellular composition and structure may influence metabolism of the rodent and human brain. To address this, we investigated the metabolic function of acutely isolated brain slices and non-synaptic mitochondria obtained from the cerebral cortex of mice and neurosurgically resected neocortical tissue of humans. Utilizing dynamic isotope labeling with 13C-enriched metabolic substrates, we show that metabolism of glucose, acetate, β-hydroxybutyrate, and glutamine operates at lower rates in human cerebral cortical slices when compared to mouse slices. In contrast, human cerebral cortical slices display a higher capacity for converting exogenous glutamate into glutamine, which subsequently supports neuronal GABA synthesis, whereas mouse slices primarily convert glutamate into aspartate. In line with the reduced metabolic rate of the human brain slices, isolated non-synaptic mitochondria of the human cerebral cortex have a lower oxygen consumption rate when provided succinate as substrate. However, when provided pyruvate and malate, human mitochondria display a higher coupled respiration and lower proton leak, signifying a more efficient mitochondrial coupling compared to mouse mitochondria. This study reveals key differences between mouse and human brain metabolism concerning both neurons and astrocytes, which must be taken into account when applying in vitro rodent preparations as a model system of the human brain.",
keywords = "Animal models, Astrocytes, Glutamate, Glutamine, Ketone bodies, Mitochondria, Neurotransmitter recycling",
author = "Westi, {Emil W.} and Emil Jakobsen and Voss, {Caroline M.} and Bak, {Lasse K.} and Pinborg, {Lars H.} and Aldana, {Blanca, I} and Andersen, {Jens, V}",
year = "2022",
doi = "10.1007/s12035-022-03053-5",
language = "English",
volume = "59",
pages = "7495–7512 ",
journal = "Molecular Neurobiology",
issn = "0893-7648",
publisher = "Springer",

}

RIS

TY - JOUR

T1 - Divergent Cellular Energetics, Glutamate Metabolism, and Mitochondrial Function Between Human and Mouse Cerebral Cortex

AU - Westi, Emil W.

AU - Jakobsen, Emil

AU - Voss, Caroline M.

AU - Bak, Lasse K.

AU - Pinborg, Lars H.

AU - Aldana, Blanca, I

AU - Andersen, Jens, V

PY - 2022

Y1 - 2022

N2 - Disruptions of brain energy and neurotransmitter metabolism are associated with several pathological conditions including neurodegenerative diseases such as Alzheimer’s disease. Transgenic rodent models, and in vitro preparations hereof, are often applied for studying pathological aspects of brain metabolism. However, despite the conserved cerebral development across mammalian species, distinct differences in cellular composition and structure may influence metabolism of the rodent and human brain. To address this, we investigated the metabolic function of acutely isolated brain slices and non-synaptic mitochondria obtained from the cerebral cortex of mice and neurosurgically resected neocortical tissue of humans. Utilizing dynamic isotope labeling with 13C-enriched metabolic substrates, we show that metabolism of glucose, acetate, β-hydroxybutyrate, and glutamine operates at lower rates in human cerebral cortical slices when compared to mouse slices. In contrast, human cerebral cortical slices display a higher capacity for converting exogenous glutamate into glutamine, which subsequently supports neuronal GABA synthesis, whereas mouse slices primarily convert glutamate into aspartate. In line with the reduced metabolic rate of the human brain slices, isolated non-synaptic mitochondria of the human cerebral cortex have a lower oxygen consumption rate when provided succinate as substrate. However, when provided pyruvate and malate, human mitochondria display a higher coupled respiration and lower proton leak, signifying a more efficient mitochondrial coupling compared to mouse mitochondria. This study reveals key differences between mouse and human brain metabolism concerning both neurons and astrocytes, which must be taken into account when applying in vitro rodent preparations as a model system of the human brain.

AB - Disruptions of brain energy and neurotransmitter metabolism are associated with several pathological conditions including neurodegenerative diseases such as Alzheimer’s disease. Transgenic rodent models, and in vitro preparations hereof, are often applied for studying pathological aspects of brain metabolism. However, despite the conserved cerebral development across mammalian species, distinct differences in cellular composition and structure may influence metabolism of the rodent and human brain. To address this, we investigated the metabolic function of acutely isolated brain slices and non-synaptic mitochondria obtained from the cerebral cortex of mice and neurosurgically resected neocortical tissue of humans. Utilizing dynamic isotope labeling with 13C-enriched metabolic substrates, we show that metabolism of glucose, acetate, β-hydroxybutyrate, and glutamine operates at lower rates in human cerebral cortical slices when compared to mouse slices. In contrast, human cerebral cortical slices display a higher capacity for converting exogenous glutamate into glutamine, which subsequently supports neuronal GABA synthesis, whereas mouse slices primarily convert glutamate into aspartate. In line with the reduced metabolic rate of the human brain slices, isolated non-synaptic mitochondria of the human cerebral cortex have a lower oxygen consumption rate when provided succinate as substrate. However, when provided pyruvate and malate, human mitochondria display a higher coupled respiration and lower proton leak, signifying a more efficient mitochondrial coupling compared to mouse mitochondria. This study reveals key differences between mouse and human brain metabolism concerning both neurons and astrocytes, which must be taken into account when applying in vitro rodent preparations as a model system of the human brain.

KW - Animal models

KW - Astrocytes

KW - Glutamate

KW - Glutamine

KW - Ketone bodies

KW - Mitochondria

KW - Neurotransmitter recycling

U2 - 10.1007/s12035-022-03053-5

DO - 10.1007/s12035-022-03053-5

M3 - Journal article

C2 - 36201140

VL - 59

SP - 7495

EP - 7512

JO - Molecular Neurobiology

JF - Molecular Neurobiology

SN - 0893-7648

ER -

ID: 322786393