Marisa M. Merino scite author profile

SummaryViable yet damaged cells can accumulate during development and aging. Although eliminating those cells may benefit organ function, identification of this less fit cell population remains challenging. Previously, we identified a molecular mechanism, based on “fitness fingerprints” displayed on cell membranes, which allows direct fitness comparison among cells in Drosophila. Here, we study the physiological consequences of efficient cell selection for the whole organism. We find that fitness-based cell culling is naturally used to maintain tissue health, delay aging, and extend lifespan in Drosophila. We identify a gene, azot, which ensures the elimination of less fit cells. Lack of azot increases morphological malformations and susceptibility to random mutations and accelerates tissue degeneration. On the contrary, improving the efficiency of cell selection is beneficial for tissue health and extends lifespan.

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Survival of the Fittest: Essential Roles of Cell Competition in Development, Aging, and Cancer

Merino

Levayer

Moreno

2016

Trends in Cell Biology

123

103

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“Fitness Fingerprints” Mediate Physiological Culling of Unwanted Neurons in Drosophila

et al. 2013

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Culling Less Fit Neurons Protects against Amyloid-β-Induced Brain Damage and Cognitive and Motor Decline

et al. 2018

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SummaryAlzheimer’s disease (AD) is the most common form of dementia, impairing cognitive and motor functions. One of the pathological hallmarks of AD is neuronal loss, which is not reflected in mouse models of AD. Therefore, the role of neuronal death is still uncertain. Here, we used a Drosophila AD model expressing a secreted form of human amyloid-β42 peptide and showed that it recapitulates key aspects of AD pathology, including neuronal death and impaired long-term memory. We found that neuronal apoptosis is mediated by cell fitness-driven neuronal culling, which selectively eliminates impaired neurons from brain circuits. We demonstrated that removal of less fit neurons delays β-amyloid-induced brain damage and protects against cognitive and motor decline, suggesting that contrary to common knowledge, neuronal death may have a beneficial effect in AD.

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A role for Flower and cell death in controlling morphogen gradient scaling

et al. 2022

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To fit or not to fit: death decisions from morphogen fields

Merino¹,

González‐Gaitán²

2023

Trends in Cell Biology

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Culling less fit neurons protects against amyloid-β-induced brain damage and cognitive and motor decline

Coelho

Schwartz

Merino

et al. 2018

Preprint

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Alzheimer's disease (AD) is the most common form of dementia, impairing cognitive and motor functions. One of the pathological hallmarks of AD is neuronal loss, which is not reflected in mouse models of AD. Therefore, the role of neuronal death is still uncertain.Here, we used a Drosophila AD model expressing a secreted form of human amyloid-β42 peptide and show that it recapitulates key aspects of AD pathology, including neuronal death and impaired long-term memory. We found that neuronal apoptosis is mediated by cell fitness-driven neuronal culling, which selectively eliminates impaired neurons from brain circuits. We show that removal of less fit neurons delays amyloid-β42-induced brain damage and protects against cognitive and motor decline, suggesting that -contrary to common knowledge -neuronal death may have a beneficial effect in AD.

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Azot expression in the Drosophila gut modulates organismal lifespan

Merino

2022

Communicative & Integrative Biology

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Cell Competition emerged in Drosophila as an unexpected phenomenon, when confronted clones of fit vs unfit cells genetically induced. During the last decade, it has been shown that this mechanism is physiologically active in Drosophila and higher organisms. In Drosophila , Flower (Fwe) eliminates unfit cells during development, regeneration and disease states. Furthermore, studies suggest that Fwe signaling is required to eliminate accumulated unfit cells during adulthood extending Drosophila lifespan. Indeed, ahuizotl ( azot ) mutants accumulate unfit cells during adulthood and after physical insults in the brain and other epithelial tissues, showing a decrease in organismal lifespan. On the contrary, flies carrying three functional copies of the gene, unfit cell culling seems to be more efficient and show an increase in lifespan. During aging, Azot is required for the elimination of unfit cells, however, the specific organs modulating organismal lifespan by Azot remain unknown. Here we found a potential connection between gut-specific Azot expression and lifespan which may uncover a more widespread organ-specific mechanism modulating organismal survival.

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Marisa M. Merino

Elimination of Unfit Cells Maintains Tissue Health and Prolongs Lifespan

Survival of the Fittest: Essential Roles of Cell Competition in Development, Aging, and Cancer

“Fitness Fingerprints” Mediate Physiological Culling of Unwanted Neurons in Drosophila

Culling Less Fit Neurons Protects against Amyloid-β-Induced Brain Damage and Cognitive and Motor Decline

A role for Flower and cell death in controlling morphogen gradient scaling

To fit or not to fit: death decisions from morphogen fields

Culling less fit neurons protects against amyloid-β-induced brain damage and cognitive and motor decline

Azot expression in the Drosophila gut modulates organismal lifespan

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