Trade-offs in insect eye nanocoatings: implications for vision, ecology, and climate sensitivity

Mikhail Kryuchkov; Vladimir Savitsky; Marc Jobin; Stanislav Smirnov; Mirza Karamehmedović; Jana Valnohova; Vladimir L. Katanaev

doi:10.1038/s44319-025-00685-1

Trade-offs in insect eye nanocoatings: implications for vision, ecology, and climate sensitivity

Mikhail Kryuchkov^*
, Vladimir Savitsky
, Marc Jobin
, Stanislav Smirnov
, Mirza Karamehmedović
, Jana Valnohova
, Vladimir L. Katanaev^*

^*Corresponding author for this work

University of Geneva
Lomonosov Moscow State University
University of Applied Sciences Western Switzerland
St. Petersburg State University
Technical University of Denmark

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

Abstract

Functional traits shape ecological niches, yet the interplay between nanoscale structural modifications, sexual dimorphism, and habitat range remains poorly understood. In fireflies, cuticular nanostructures that enhance bioluminescent signaling efficiency also impose ecological constraints. Anti-reflective nanocoatings improve cuticle transparency and optical performance but typically increase surface adhesion, reducing fitness. In Luciola lusitanica, this trade-off is mitigated by temperature-sensitive nanocoatings that form only within a narrow thermal range, limiting habitat expansion. This study presents the first thermodynamic analysis of environmentally constrained nanocoating formation, demonstrating how small temperature fluctuations can destabilize protein-lipid self-assembly. These findings link nanoscale biophysics to ecological resilience, providing a framework to understand how the environmental sensitivity of structural self-organization shapes adaptation, species distribution, and evolutionary potential.

Original language	English
Pages (from-to)	975-992
Number of pages	18
Journal	EMBO Reports
Volume	27
Issue number	4
DOIs	https://doi.org/10.1038/s44319-025-00685-1
Publication status	Published - 25 Feb 2026
Externally published	Yes

Keywords

Ecological Resilience
Nanostructures
Reaction-Diffusion
Sexual Dimorphism
Thermodynamic Analysis

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10.1038/s44319-025-00685-1

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title = "Trade-offs in insect eye nanocoatings: implications for vision, ecology, and climate sensitivity",

abstract = "Functional traits shape ecological niches, yet the interplay between nanoscale structural modifications, sexual dimorphism, and habitat range remains poorly understood. In fireflies, cuticular nanostructures that enhance bioluminescent signaling efficiency also impose ecological constraints. Anti-reflective nanocoatings improve cuticle transparency and optical performance but typically increase surface adhesion, reducing fitness. In Luciola lusitanica, this trade-off is mitigated by temperature-sensitive nanocoatings that form only within a narrow thermal range, limiting habitat expansion. This study presents the first thermodynamic analysis of environmentally constrained nanocoating formation, demonstrating how small temperature fluctuations can destabilize protein-lipid self-assembly. These findings link nanoscale biophysics to ecological resilience, providing a framework to understand how the environmental sensitivity of structural self-organization shapes adaptation, species distribution, and evolutionary potential.",

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doi = "10.1038/s44319-025-00685-1",

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T2 - implications for vision, ecology, and climate sensitivity

AU - Kryuchkov, Mikhail

AU - Savitsky, Vladimir

AU - Jobin, Marc

AU - Smirnov, Stanislav

AU - Karamehmedović, Mirza

AU - Valnohova, Jana

AU - Katanaev, Vladimir L.

N1 - Publisher Copyright: © The Author(s) 2026.

PY - 2026/2/25

Y1 - 2026/2/25

N2 - Functional traits shape ecological niches, yet the interplay between nanoscale structural modifications, sexual dimorphism, and habitat range remains poorly understood. In fireflies, cuticular nanostructures that enhance bioluminescent signaling efficiency also impose ecological constraints. Anti-reflective nanocoatings improve cuticle transparency and optical performance but typically increase surface adhesion, reducing fitness. In Luciola lusitanica, this trade-off is mitigated by temperature-sensitive nanocoatings that form only within a narrow thermal range, limiting habitat expansion. This study presents the first thermodynamic analysis of environmentally constrained nanocoating formation, demonstrating how small temperature fluctuations can destabilize protein-lipid self-assembly. These findings link nanoscale biophysics to ecological resilience, providing a framework to understand how the environmental sensitivity of structural self-organization shapes adaptation, species distribution, and evolutionary potential.

AB - Functional traits shape ecological niches, yet the interplay between nanoscale structural modifications, sexual dimorphism, and habitat range remains poorly understood. In fireflies, cuticular nanostructures that enhance bioluminescent signaling efficiency also impose ecological constraints. Anti-reflective nanocoatings improve cuticle transparency and optical performance but typically increase surface adhesion, reducing fitness. In Luciola lusitanica, this trade-off is mitigated by temperature-sensitive nanocoatings that form only within a narrow thermal range, limiting habitat expansion. This study presents the first thermodynamic analysis of environmentally constrained nanocoating formation, demonstrating how small temperature fluctuations can destabilize protein-lipid self-assembly. These findings link nanoscale biophysics to ecological resilience, providing a framework to understand how the environmental sensitivity of structural self-organization shapes adaptation, species distribution, and evolutionary potential.

KW - Ecological Resilience

KW - Nanostructures

KW - Reaction-Diffusion

KW - Sexual Dimorphism

KW - Thermodynamic Analysis

UR - https://www.scopus.com/pages/publications/105031153829

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DO - 10.1038/s44319-025-00685-1

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SN - 1469-221X

VL - 27

SP - 975

EP - 992

JO - EMBO Reports

JF - EMBO Reports

IS - 4

ER -

Trade-offs in insect eye nanocoatings: implications for vision, ecology, and climate sensitivity

Abstract

Keywords

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