A Toll-receptor map underlies structural brain plasticity

Li, Guiyi; Forero, Manuel G.; Wentzell, Jill S.; Durmus, Ilgim; Wolf, Ronni; Anthoney, Niki; Parker, M. Virginia; Jiang, Ruiying; Hasenauer, Jacob; Strausfeld, Nicholas J.; Heisenberg, Martin; Hidalgo, Alicia

doi:10.7554/elife.52743

Cited by 38 publications

(138 citation statements)

References 80 publications

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“…A population of about 40 adult neural progenitors has been reported in the optic lobe and a population of glial progenitors has been reported in the central brain ( Fernández-Hernández et al, 2013 ; Foo et al, 2017 ). Upon damage or cell loss, hallmarks of cycling have been shown to be activated, although the overall level of proliferation in the adult brain remains very low ( Crocker et al, 2020 ; Fernandez-Hernandez et al, 2019 ; Fernández-Hernández et al, 2013 ; Foo et al, 2017 ; Li et al, 2020 ). Thus, the brain of the adult fly is thought to be almost entirely postmitotic with most cells in G0 with a diploid (2C) DNA content.…”

Section: Introductionmentioning

confidence: 99%

Polyploidy in the adult Drosophila brain

Nandakumar

Grushko

Buttitta

2020

eLife

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Long-lived cells such as terminally differentiated postmitotic neurons and glia must cope with the accumulation of damage over the course of an animal’s lifespan. How long-lived cells deal with ageing-related damage is poorly understood. Here we show that polyploid cells accumulate in the adult fly brain and that polyploidy protects against DNA damage-induced cell death. Multiple types of neurons and glia that are diploid at eclosion, become polyploid in the adult Drosophila brain. The optic lobes exhibit the highest levels of polyploidy, associated with an elevated DNA damage response in this brain region. Inducing oxidative stress or exogenous DNA damage leads to an earlier onset of polyploidy, and polyploid cells in the adult brain are more resistant to DNA damage-induced cell death than diploid cells. Our results suggest polyploidy may serve a protective role for neurons and glia in adult Drosophila melanogaster brains.

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Section: Introductionmentioning

confidence: 99%

Polyploidy in the adult Drosophila brain

Nandakumar

Grushko

Buttitta

2020

eLife

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“…The presence of cycling cells in the adult brain was confirmed using other G1, S-phase and G2 markers, PCNA-GFP and FUCCI, at the adult critical period (up to five days post-eclosion). PCNA-GFP + cells were found in normal brains [ 6 ]. With FUCCI, degron fusion-proteins to tagged cell cycling proteins E2F-GFP and cyclin-B-RFP are degraded as cells enter S phase or G1, respectively [ 39 ] (see Figure 2 a).…”

Section: There Are Proliferating Cells In the Adult Drosmentioning

confidence: 99%

“…Thus, FUCCI labels cells that are in G1, S, G2/M, or M/G1 phases of the cell cycle and does not label post-mitotic cells that are in G0 [ 39 ]. Control brains bearing the transgenes to visualise these markers but otherwise normal, also revealed the presence of FUCCI + cells in G1/S, G2 and G2/M, potentially undergoing mitosis [ 6 ]. Presence of cells cycling through G2/M was also visualised using GFP-tagged Cdc25/String (Stg), whch is expressed in G2 and triggers the G2/M transition [ 6 , 40 , 41 ].…”

Section: There Are Proliferating Cells In the Adult Drosmentioning

confidence: 99%

“…Control brains bearing the transgenes to visualise these markers but otherwise normal, also revealed the presence of FUCCI + cells in G1/S, G2 and G2/M, potentially undergoing mitosis [ 6 ]. Presence of cells cycling through G2/M was also visualised using GFP-tagged Cdc25/String (Stg), whch is expressed in G2 and triggers the G2/M transition [ 6 , 40 , 41 ]. Accordingly, proliferating cells exist in the Drosophila adult brain, and most prominently at the critical period between 1 and 6 days post-eclosion [ 6 , 34 , 37 ].…”

Section: There Are Proliferating Cells In the Adult Drosmentioning

confidence: 99%

“…Acquiring evidence of adult neurogenesis is technically challenging. Both in mammals (including humans) and in invertebrates, evidence has generally relied on cell cycle and lineage tracing markers, such as 5-Bromo-2-deoxyuridine (BrdU), and neural stem cell markers [ 1 , 2 , 3 , 4 , 5 , 6 ]. However, the ability to detect these markers could depend on exactly how experiments were carried out, and as a result, disparate findings have been feeding the controversy [ 1 ].…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Adult Neurogenesis in the Drosophila Brain: The Evidence and the Void

Hidalgo

2020

IJMS

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Establishing the existence and extent of neurogenesis in the adult brain throughout the animals including humans, would transform our understanding of how the brain works, and how to tackle brain damage and disease. Obtaining convincing, indisputable experimental evidence has generally been challenging. Here, we revise the state of this question in the fruit-fly Drosophila. The developmental neuroblasts that make the central nervous system and brain are eliminated, either through apoptosis or cell cycle exit, before the adult fly ecloses. Despite this, there is growing evidence that cell proliferation can take place in the adult brain. This occurs preferentially at, but not restricted to, a critical period. Adult proliferating cells can give rise to both glial cells and neurons. Neuronal activity, injury and genetic manipulation in the adult can increase the incidence of both gliogenesis and neurogenesis, and cell number. Most likely, adult glio- and neuro-genesis promote structural brain plasticity and homeostasis. However, a definitive visualisation of mitosis in the adult brain is still lacking, and the elusive adult progenitor cells are yet to be identified. Resolving these voids is important for the fundamental understanding of any brain. Given its powerful genetics, Drosophila can expedite discovery into mammalian adult neurogenesis in the healthy and diseased brain.

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Critical periods shaping the social brain: A perspective from Drosophila

Dombrovski

Condron

2020

BioEssays

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Many sensory processing regions of the central brain undergo critical periods of experience-dependent plasticity. During this time ethologically relevant information shapes circuit structure and function. The mechanisms that control critical period timing and duration are poorly understood, and this is of special importance for those later periods of development, which often give rise to complex cognitive functions such as social behavior. Here, we review recent findings in Drosophila, an organism that has some unique experimental advantages, and introduce novel views for manipulating plasticity in the post-embryonic brain. Critical periods in larval and young adult flies resemble classic vertebrate models with distinct onset and termination, display clear connections with complex behaviors, and provide opportunities to control the time course of plasticity. These findings may extend our knowledge about mechanisms underlying extension and reopening of critical periods, a concept that has great relevance to many human neurodevelopmental disorders.

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A Toll-receptor map underlies structural brain plasticity

Cited by 38 publications

References 80 publications

Polyploidy in the adult Drosophila brain

Polyploidy in the adult Drosophila brain

Adult Neurogenesis in the Drosophila Brain: The Evidence and the Void

Critical periods shaping the social brain: A perspective from Drosophila

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