Developmental pruning of sensory neurites by mechanical tearing in <i>Drosophila</i>

Krämer, Rafael; Wolterhoff, Neele; Galic, Milos; Rumpf, Sebastian

doi:10.1083/jcb.202205004

Cited by 4 publications

(4 citation statements)

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“…Why a role for neuron-autonomous EcR signaling is more fully revealed when astrocytes are also blocked from transformation is an open question. A recent study showed that neuronal ecdysone signaling allows ddaC neurons to become competent for pruning by driving microtubule rearrangement, with subsequent physical force caused by tissue movement in the body wall during metamorphosis driving the severing and fragmentation of dendrites (Krämer, Wolterhoff et al 2023). It is possible that neuronal ecdysone signaling may make Beat-Va M neurons competent for remodeling through similar mechanisms, but execution of fragmentation requires a secondary mechanical event.…”

Section: Discussionmentioning

confidence: 99%

Astrocyte-dependent local neurite pruning and Hox gene-mediated cell death in Beat-Va neurons

Lehmann,

Hupp,

Jefferson

et al. 2023

Preprint

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Neuronal remodeling is extensive and mechanistically diverse across the nervous systems of complex metazoans. To explore circuit refinement mechanisms, we screened for new neuronal subtypes in theDrosophilanervous system that undergo remodeling early in metamorphosis. We find Beat-VaMneurons elaborate a highly branched neurite network during larval stages that undergoes local neurite pruning during early metamorphosis. Surprisingly, Beat-VaMneurons remodel their branches despite blockade of steroid hormone signaling and instead depend on signaling from astrocytes to activate pruning. We show Beat-VaLneurons undergo steroid hormone-dependent cell death in posterior but not anterior abdominal segments. Correct activation of apoptotic cell death relies on segment-specific expression of the hox geneAbd-B, which is capable of activating cell death in any Beat-VaLneuron. Our work provides new model cells in which to study neuronal remodeling, highlights an important role for astrocytes in activating local pruning inDrosophilaindependent of steroid signaling, and defines a Hox gene-mediated mechanism for segment-specific cell elimination.SummaryLehmann et al. characterize two new populations of neurons that undergo remodeling duringDrosophilametamorphosis. Beat-VaMneurons undergo drastic neurite pruning that is largely independent of ecdysone signaling and instead is driven by astrocytes. Beat-VaLneurons undergoAbd-Bmediated, caspase driven cell death in a segmentally restricted manner.

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Section: Discussionmentioning

confidence: 99%

Astrocyte-dependent local neurite pruning and Hox gene-mediated cell death in Beat-Va neurons

Lehmann,

Hupp,

Jefferson

et al. 2023

Preprint

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“…Dendrite severing in the C4da neurons takes place during the period of elevated movements of pupal tissue, which applies mechanical forces to break dendrites. This suggests that mechanical tearing may be a novel mechanism underlying dendrite pruning [ 62 ]. It has been found that the axons and proximal regions of dendrites in C4da neurons are encapsulated by peripheral glial cells [ 63 ], and thus mechanical dendritic dissection during pruning may be affected by these surrounding cells.…”

Section: Polycomb Group (Pcg) Proteins Mechanical Forces and Translat...mentioning

confidence: 99%

Recent progress in dendritic pruning of Drosophila C4da sensory neurons

Rui

2024

Open Biol.

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The brain can adapt to changes in the environment through alterations in the number and structure of synapses. During embryonic and early postnatal stages, the synapses in the brain undergo rapid expansion and interconnections to form circuits. However, many of these synaptic connections are redundant or incorrect. Neurite pruning is a conserved process that occurs during both vertebrate and invertebrate development. It requires precise spatiotemporal control of local degradation of cellular components, comprising cytoskeletons and membranes, refines neuronal circuits, and ensures the precise connectivity required for proper function. The Drosophila ’s class IV dendritic arborization (C4da) sensory neuron has a well-characterized architecture and undergoes dendrite-specific sculpting, making it a valuable model for unravelling the intricate regulatory mechanisms underlie dendritic pruning. In this review, I attempt to provide an overview of the present state of research on dendritic pruning in C4da sensory neurons, as well as potential functional mechanisms in neurodevelopmental disorders.

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“…Cell biological pathways underlying neurite pruning therefore must involve mechanisms for spatial regulation of neurite destruction and maintenance. This spatial aspect of pruning may in part be due to cytoskeleton regulation [ 2 ] and tissue mechanical aspects [ 3 ]. Following pruning, remodeling neurons often regrow new neurites with a morphology adapted to subsequent developmental stages.…”

Section: Introductionmentioning

confidence: 99%

TORC1 regulation of dendrite regrowth after pruning is linked to actin and exocytosis

et al. 2023

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Neurite pruning and regrowth are important mechanisms to adapt neural circuits to distinct developmental stages. Neurite regrowth after pruning often depends on differential regulation of growth signaling pathways, but their precise mechanisms of action during regrowth are unclear. Here, we show that the PI3K/TORC1 pathway is required for dendrite regrowth after pruning in Drosophila peripheral neurons during metamorphosis. TORC1 impinges on translation initiation, and our analysis of 5’ untranslated regions (UTRs) of remodeling factor mRNAs linked to actin suggests that TOR selectively stimulates the translation of regrowth over pruning factors. Furthermore, we find that dendrite regrowth also requires the GTPase RalA and the exocyst complex as regulators of polarized secretion, and we provide evidence that this pathway is also regulated by TOR. We propose that TORC1 coordinates dendrite regrowth after pruning by coordinately stimulating the translation of regrowth factors involved in cytoskeletal regulation and secretion.

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Developmental pruning of sensory neurites by mechanical tearing in Drosophila

Cited by 4 publications

References 50 publications

Astrocyte-dependent local neurite pruning and Hox gene-mediated cell death in Beat-Va neurons

Astrocyte-dependent local neurite pruning and Hox gene-mediated cell death in Beat-Va neurons

Recent progress in dendritic pruning of Drosophila C4da sensory neurons

TORC1 regulation of dendrite regrowth after pruning is linked to actin and exocytosis

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