Parallel Mechanosensory Pathways Direct Oviposition Decision-Making in Drosophila

Female Drosophila choose their sites for oviposition with deliberation. Female flies employ sensitive chemosensory systems to evaluate chemical cues for egg-laying substrates, but how they determine the physical quality of an oviposition patch remains largely unexplored. Here we report that flies ev...

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Published inCurrent biology Vol. 30; no. 16; pp. 3075 - 3088.e4
Main Authors Zhang, Liwei, Yu, Jie, Guo, Xuan, Wei, Jianhuan, Liu, Ting, Zhang, Wei
Format Journal Article
LanguageEnglish
Published England Elsevier Inc 17.08.2020
Subjects
Drosophila
egg-laying
Inactive
mechanosensation
mechanosensitive channels
Nanchung
Piezo
TRP channel
TRP channel
Drosophila
egg-laying
Inactive
Piezo
mechanosensitive channels
mechanosensation
Nanchung
Online AccessGet full text
ISSN0960-9822
1879-0445
1879-0445
DOI10.1016/j.cub.2020.05.076

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Abstract Female Drosophila choose their sites for oviposition with deliberation. Female flies employ sensitive chemosensory systems to evaluate chemical cues for egg-laying substrates, but how they determine the physical quality of an oviposition patch remains largely unexplored. Here we report that flies evaluate the stiffness of the substrate surface using sensory structures on their appendages. The TRPV family channel Nanchung is required for the detection of all stiffness ranges tested, whereas two other proteins, Inactive and DmPiezo, interact with Nanchung to sense certain spectral ranges of substrate stiffness differences. Furthermore, Tmc is critical for sensing subtle differences in substrate stiffness. The Tmc channel is expressed in distinct patterns on the labellum and legs and the mechanosensory inputs coordinate to direct the final decision making for egg laying. Our study thus reveals the machinery for deliberate egg-laying decision making in fruit flies to ensure optimal survival for their offspring. [Display omitted] •Drosophila females prefer a softer substrate to lay eggs•Stiffness sensation relies on multiple mechanosensory organs•Single-dendritic labellum neurons detect subtle stiffness differences•Discrimination of large differences is mediated via leg mechanosensory neurons Zhang et al. show that female flies employ parallel mechanosensory pathways on their appendages to evaluate the stiffness of egg-laying substrate. Such machinery directs deliberate egg-laying decision making in female flies to ensure optimal survival for their offspring.
AbstractList Female Drosophila choose their sites for oviposition with deliberation. Female flies employ sensitive chemosensory systems to evaluate chemical cues for egg-laying substrates, but how they determine the physical quality of an oviposition patch remains largely unexplored. Here we report that flies evaluate the stiffness of the substrate surface using sensory structures on their appendages. The TRPV family channel Nanchung is required for the detection of all stiffness ranges tested, whereas two other proteins, Inactive and DmPiezo, interact with Nanchung to sense certain spectral ranges of substrate stiffness differences. Furthermore, Tmc is critical for sensing subtle differences in substrate stiffness. The Tmc channel is expressed in distinct patterns on the labellum and legs and the mechanosensory inputs coordinate to direct the final decision making for egg laying. Our study thus reveals the machinery for deliberate egg-laying decision making in fruit flies to ensure optimal survival for their offspring. [Display omitted] •Drosophila females prefer a softer substrate to lay eggs•Stiffness sensation relies on multiple mechanosensory organs•Single-dendritic labellum neurons detect subtle stiffness differences•Discrimination of large differences is mediated via leg mechanosensory neurons Zhang et al. show that female flies employ parallel mechanosensory pathways on their appendages to evaluate the stiffness of egg-laying substrate. Such machinery directs deliberate egg-laying decision making in female flies to ensure optimal survival for their offspring.
Female Drosophila choose their sites for oviposition with deliberation. Female flies employ sensitive chemosensory systems to evaluate chemical cues for egg-laying substrates, but how they determine the physical quality of an oviposition patch remains largely unexplored. Here we report that flies evaluate the stiffness of the substrate surface using sensory structures on their appendages. The TRPV family channel Nanchung is required for the detection of all stiffness ranges tested, whereas two other proteins, Inactive and DmPiezo, interact with Nanchung to sense certain spectral ranges of substrate stiffness differences. Furthermore, Tmc is critical for sensing subtle differences in substrate stiffness. The Tmc channel is expressed in distinct patterns on the labellum and legs and the mechanosensory inputs coordinate to direct the final decision making for egg laying. Our study thus reveals the machinery for deliberate egg-laying decision making in fruit flies to ensure optimal survival for their offspring.Female Drosophila choose their sites for oviposition with deliberation. Female flies employ sensitive chemosensory systems to evaluate chemical cues for egg-laying substrates, but how they determine the physical quality of an oviposition patch remains largely unexplored. Here we report that flies evaluate the stiffness of the substrate surface using sensory structures on their appendages. The TRPV family channel Nanchung is required for the detection of all stiffness ranges tested, whereas two other proteins, Inactive and DmPiezo, interact with Nanchung to sense certain spectral ranges of substrate stiffness differences. Furthermore, Tmc is critical for sensing subtle differences in substrate stiffness. The Tmc channel is expressed in distinct patterns on the labellum and legs and the mechanosensory inputs coordinate to direct the final decision making for egg laying. Our study thus reveals the machinery for deliberate egg-laying decision making in fruit flies to ensure optimal survival for their offspring.
Female Drosophila choose their sites for oviposition with deliberation. Female flies employ sensitive chemosensory systems to evaluate chemical cues for egg-laying substrates, but how they determine the physical quality of an oviposition patch remains largely unexplored. Here we report that flies evaluate the stiffness of the substrate surface using sensory structures on their appendages. The TRPV family channel Nanchung is required for the detection of all stiffness ranges tested, whereas two other proteins, Inactive and DmPiezo, interact with Nanchung to sense certain spectral ranges of substrate stiffness differences. Furthermore, Tmc is critical for sensing subtle differences in substrate stiffness. The Tmc channel is expressed in distinct patterns on the labellum and legs and the mechanosensory inputs coordinate to direct the final decision making for egg laying. Our study thus reveals the machinery for deliberate egg-laying decision making in fruit flies to ensure optimal survival for their offspring.
Author Zhang, Liwei
Yu, Jie
Guo, Xuan
Zhang, Wei
Wei, Jianhuan
Liu, Ting
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Keywords TRP channel
Drosophila
egg-laying
Inactive
Piezo
mechanosensitive channels
mechanosensation
Nanchung
Language English
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Snippet Female Drosophila choose their sites for oviposition with deliberation. Female flies employ sensitive chemosensory systems to evaluate chemical cues for...
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Index Database
Enrichment Source
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StartPage 3075
SubjectTerms Drosophila
egg-laying
Inactive
mechanosensation
mechanosensitive channels
Nanchung
Piezo
TRP channel
Title Parallel Mechanosensory Pathways Direct Oviposition Decision-Making in Drosophila
URI https://dx.doi.org/10.1016/j.cub.2020.05.076
https://www.ncbi.nlm.nih.gov/pubmed/32649914
https://www.proquest.com/docview/2423066821
Volume 30
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