Human adult neurogenesis loss corresponds with cognitive decline during epilepsy progression

Aswathy Ammothumkandy; Luis Corona; Kristine Ravina; Victoria Wolseley; Jeremy Nelson; Nadiya Atai; Aidin Abedi; Nora Jimenez; Michelle Armacost; Lina M. D'Orazio; Virginia Zuverza-Chavarria; Alisha Cayce; Carol McCleary; George Nune; Laura Kalayjian; Darrin J. Lee; Brian Lee; Robert H. Chow; Christianne Heck; Jonathan J. Russin; Charles Y. Liu; Jason A.D. Smith; Michael A. Bonaguidi

doi:10.1016/j.stem.2024.11.002

Human adult neurogenesis loss corresponds with cognitive decline during epilepsy progression

Aswathy Ammothumkandy, Luis Corona, Kristine Ravina, Victoria Wolseley, Jeremy Nelson, Nadiya Atai, Aidin Abedi, Nora Jimenez, Michelle Armacost, Lina M. D'Orazio, Virginia Zuverza-Chavarria, Alisha Cayce, Carol McCleary, George Nune, Laura Kalayjian, Darrin J. Lee, Brian Lee, Robert H. Chow, Christianne Heck, Jonathan J. RussinCharles Y. Liu, Jason A.D. Smith, Michael A. Bonaguidi

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

Mesial temporal lobe epilepsy (MTLE) is a syndromic disorder presenting with seizures and cognitive comorbidities. Although seizure etiology is increasingly understood, the pathophysiological mechanisms contributing to cognitive decline and epilepsy progression remain less recognized. We have previously shown that adult hippocampal neurogenesis dramatically declines in MTLE patients with increased disease duration. Here, we investigate when multiple cognitive domains become affected during epilepsy progression and how human neurogenesis levels contribute to it. We find that intelligence, verbal learning, and memory decline at a critical period of 20 years disease duration. In contrast to rodents, the number of human immature neurons positively associates with auditory verbal, rather than visuospatial, learning and memory. Moreover, this association does not apply to mature granule neurons. Our study provides cellular evidence of how adult neurogenesis corresponds with human cognition and signifies an opportunity to advance regenerative medicine for patients with MTLE and other cognitive disorders.

Original language	English (US)
Pages (from-to)	293-301.e3
Journal	Cell Stem Cell
Volume	32
Issue number	2
DOIs	https://doi.org/10.1016/j.stem.2024.11.002
State	Published - Feb 6 2025

Keywords

co-morbidity
cognition
critical period
dementia
epilepsy
human adult neurogenesis
immature neuron
learning
memory
neural stem cell
progressive disorder
Neurons/pathology
Humans
Middle Aged
Male
Cognition
Neurogenesis
Epilepsy, Temporal Lobe/pathology
Young Adult
Epilepsy/pathology
Memory/physiology
Adult
Female
Cognition Disorders/pathology
Hippocampus/pathology
Disease Progression

ASJC Scopus subject areas

Molecular Medicine
Genetics
Cell Biology

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10.1016/j.stem.2024.11.002

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Ammothumkandy, A., Corona, L., Ravina, K., Wolseley, V., Nelson, J., Atai, N., Abedi, A., Jimenez, N., Armacost, M., D'Orazio, L. M., Zuverza-Chavarria, V., Cayce, A., McCleary, C., Nune, G., Kalayjian, L., Lee, D. J., Lee, B., Chow, R. H., Heck, C., ... Bonaguidi, M. A. (2025). Human adult neurogenesis loss corresponds with cognitive decline during epilepsy progression. Cell Stem Cell, 32(2), 293-301.e3. https://doi.org/10.1016/j.stem.2024.11.002

Ammothumkandy, A, Corona, L, Ravina, K, Wolseley, V, Nelson, J, Atai, N, Abedi, A, Jimenez, N, Armacost, M, D'Orazio, LM, Zuverza-Chavarria, V, Cayce, A, McCleary, C, Nune, G, Kalayjian, L, Lee, DJ, Lee, B, Chow, RH, Heck, C, Russin, JJ, Liu, CY, Smith, JAD & Bonaguidi, MA 2025, 'Human adult neurogenesis loss corresponds with cognitive decline during epilepsy progression', Cell Stem Cell, vol. 32, no. 2, pp. 293-301.e3. https://doi.org/10.1016/j.stem.2024.11.002

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title = "Human adult neurogenesis loss corresponds with cognitive decline during epilepsy progression",

abstract = "Mesial temporal lobe epilepsy (MTLE) is a syndromic disorder presenting with seizures and cognitive comorbidities. Although seizure etiology is increasingly understood, the pathophysiological mechanisms contributing to cognitive decline and epilepsy progression remain less recognized. We have previously shown that adult hippocampal neurogenesis dramatically declines in MTLE patients with increased disease duration. Here, we investigate when multiple cognitive domains become affected during epilepsy progression and how human neurogenesis levels contribute to it. We find that intelligence, verbal learning, and memory decline at a critical period of 20 years disease duration. In contrast to rodents, the number of human immature neurons positively associates with auditory verbal, rather than visuospatial, learning and memory. Moreover, this association does not apply to mature granule neurons. Our study provides cellular evidence of how adult neurogenesis corresponds with human cognition and signifies an opportunity to advance regenerative medicine for patients with MTLE and other cognitive disorders.",

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AU - Ammothumkandy, Aswathy

AU - Corona, Luis

AU - Ravina, Kristine

AU - Wolseley, Victoria

AU - Nelson, Jeremy

AU - Atai, Nadiya

AU - Abedi, Aidin

AU - Jimenez, Nora

AU - Armacost, Michelle

AU - D'Orazio, Lina M.

AU - Zuverza-Chavarria, Virginia

AU - Cayce, Alisha

AU - McCleary, Carol

AU - Nune, George

AU - Kalayjian, Laura

AU - Lee, Darrin J.

AU - Lee, Brian

AU - Chow, Robert H.

AU - Heck, Christianne

AU - Russin, Jonathan J.

AU - Liu, Charles Y.

AU - Smith, Jason A.D.

AU - Bonaguidi, Michael A.

PY - 2025/2/6

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N2 - Mesial temporal lobe epilepsy (MTLE) is a syndromic disorder presenting with seizures and cognitive comorbidities. Although seizure etiology is increasingly understood, the pathophysiological mechanisms contributing to cognitive decline and epilepsy progression remain less recognized. We have previously shown that adult hippocampal neurogenesis dramatically declines in MTLE patients with increased disease duration. Here, we investigate when multiple cognitive domains become affected during epilepsy progression and how human neurogenesis levels contribute to it. We find that intelligence, verbal learning, and memory decline at a critical period of 20 years disease duration. In contrast to rodents, the number of human immature neurons positively associates with auditory verbal, rather than visuospatial, learning and memory. Moreover, this association does not apply to mature granule neurons. Our study provides cellular evidence of how adult neurogenesis corresponds with human cognition and signifies an opportunity to advance regenerative medicine for patients with MTLE and other cognitive disorders.

AB - Mesial temporal lobe epilepsy (MTLE) is a syndromic disorder presenting with seizures and cognitive comorbidities. Although seizure etiology is increasingly understood, the pathophysiological mechanisms contributing to cognitive decline and epilepsy progression remain less recognized. We have previously shown that adult hippocampal neurogenesis dramatically declines in MTLE patients with increased disease duration. Here, we investigate when multiple cognitive domains become affected during epilepsy progression and how human neurogenesis levels contribute to it. We find that intelligence, verbal learning, and memory decline at a critical period of 20 years disease duration. In contrast to rodents, the number of human immature neurons positively associates with auditory verbal, rather than visuospatial, learning and memory. Moreover, this association does not apply to mature granule neurons. Our study provides cellular evidence of how adult neurogenesis corresponds with human cognition and signifies an opportunity to advance regenerative medicine for patients with MTLE and other cognitive disorders.

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KW - cognition

KW - critical period

KW - dementia

KW - epilepsy

KW - human adult neurogenesis

KW - immature neuron

KW - learning

KW - memory

KW - neural stem cell

KW - progressive disorder

KW - Neurons/pathology

KW - Humans

KW - Middle Aged

KW - Male

KW - Cognition

KW - Neurogenesis

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KW - Young Adult

KW - Epilepsy/pathology

KW - Memory/physiology

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KW - Female

KW - Cognition Disorders/pathology

KW - Hippocampus/pathology

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SN - 1934-5909

VL - 32

SP - 293-301.e3

JO - Cell Stem Cell

JF - Cell Stem Cell

IS - 2

ER -

Human adult neurogenesis loss corresponds with cognitive decline during epilepsy progression

Abstract

Keywords

ASJC Scopus subject areas

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