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Coordinated molecular and physiological adaptations enable activity at sub-freezing temperatures in the snow fly Chionea alexandriana

Capek, Matthew ; Suhendra, Richard ; Yang, Zhenzhen ; Omer, Arina D. ; Weisz, David ; Dudchenko, Olga ; Tuthill, John C. ; Aiden, Erez Lieberman ; Kath, William L. and Para, Alessia , et al. (2026) In Current Biology 36(7). p.6-1841
Abstract

Snow flies ( Chionea ) are wingless crane flies uniquely adapted to extreme cold environments. Adults remain active throughout winter and move rapidly across the snow, even at temperatures below freezing. To investigate the molecular adaptations that make this possible, we sequenced and annotated the genome of Chionea alexandriana and compared it with related species and with the cold-adapted midge, Belgica antarctica . We identify ∼20 lineage-specific and 8 shared gene-family expansions in Chionea and Belgica , corresponding to functions ranging from sensory signaling to DNA packaging. The Chionea genome encodes antifreeze proteins (AFPs), and we show that transgenic expression of an AFP in Drosophila is sufficient to protect larvae... (More)

Snow flies ( Chionea ) are wingless crane flies uniquely adapted to extreme cold environments. Adults remain active throughout winter and move rapidly across the snow, even at temperatures below freezing. To investigate the molecular adaptations that make this possible, we sequenced and annotated the genome of Chionea alexandriana and compared it with related species and with the cold-adapted midge, Belgica antarctica . We identify ∼20 lineage-specific and 8 shared gene-family expansions in Chionea and Belgica , corresponding to functions ranging from sensory signaling to DNA packaging. The Chionea genome encodes antifreeze proteins (AFPs), and we show that transgenic expression of an AFP in Drosophila is sufficient to protect larvae from freezing-induced death. Our results also reveal a coordinated expansion of mitochondrial and peroxisomal enzymes, as well as regulators of peroxisome-mitochondria interactions involved in mammalian thermogenesis. Consistent with this, direct measurements reveal that snow flies produce brief bursts of endogenous heat in response to cooling at sub-freezing temperatures, indicating active thermogenic capacity. Finally, our results demonstrate that Chionea has evolved mechanisms to cope with high levels of reactive oxygen species (ROS), a byproduct of mitochondrial activity and a hallmark of cold exposure. These include a 35-fold increase in the threshold for ROS activation of the insect nociceptor TRPA1, as measured in vitro by patch-clamp electrophysiology. Together, our results reveal specific molecular adaptations that enable the snow fly to thrive in extreme cold conditions and suggest that selective gene-family expansion may represent a key mechanism for the adaptation of insects to cold environments.

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organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
antifreeze proteins, cold adaptation, insect, mitochondria, peroxisome, reactive oxygen species, ROS, snow fly, temperature, thermogenesis, TRPA1
in
Current Biology
volume
36
issue
7
pages
6 - 1841
publisher
Elsevier
external identifiers
  • pmid:41881009
  • scopus:105034502638
ISSN
0960-9822
DOI
10.1016/j.cub.2026.02.060
language
English
LU publication?
yes
additional info
Publisher Copyright: © 2026 The Authors.
id
ecf56319-7ecb-40aa-902d-731cee98cb13
date added to LUP
2026-06-22 10:55:07
date last changed
2026-06-23 03:00:01
@article{ecf56319-7ecb-40aa-902d-731cee98cb13,
  abstract     = {{<p>Snow flies ( Chionea ) are wingless crane flies uniquely adapted to extreme cold environments. Adults remain active throughout winter and move rapidly across the snow, even at temperatures below freezing. To investigate the molecular adaptations that make this possible, we sequenced and annotated the genome of Chionea alexandriana and compared it with related species and with the cold-adapted midge, Belgica antarctica . We identify ∼20 lineage-specific and 8 shared gene-family expansions in Chionea and Belgica , corresponding to functions ranging from sensory signaling to DNA packaging. The Chionea genome encodes antifreeze proteins (AFPs), and we show that transgenic expression of an AFP in Drosophila is sufficient to protect larvae from freezing-induced death. Our results also reveal a coordinated expansion of mitochondrial and peroxisomal enzymes, as well as regulators of peroxisome-mitochondria interactions involved in mammalian thermogenesis. Consistent with this, direct measurements reveal that snow flies produce brief bursts of endogenous heat in response to cooling at sub-freezing temperatures, indicating active thermogenic capacity. Finally, our results demonstrate that Chionea has evolved mechanisms to cope with high levels of reactive oxygen species (ROS), a byproduct of mitochondrial activity and a hallmark of cold exposure. These include a 35-fold increase in the threshold for ROS activation of the insect nociceptor TRPA1, as measured in vitro by patch-clamp electrophysiology. Together, our results reveal specific molecular adaptations that enable the snow fly to thrive in extreme cold conditions and suggest that selective gene-family expansion may represent a key mechanism for the adaptation of insects to cold environments.</p>}},
  author       = {{Capek, Matthew and Suhendra, Richard and Yang, Zhenzhen and Omer, Arina D. and Weisz, David and Dudchenko, Olga and Tuthill, John C. and Aiden, Erez Lieberman and Kath, William L. and Para, Alessia and Stensmyr, Marcus and Gallio, Marco}},
  issn         = {{0960-9822}},
  keywords     = {{antifreeze proteins; cold adaptation; insect; mitochondria; peroxisome; reactive oxygen species; ROS; snow fly; temperature; thermogenesis; TRPA1}},
  language     = {{eng}},
  month        = {{04}},
  number       = {{7}},
  pages        = {{6--1841}},
  publisher    = {{Elsevier}},
  series       = {{Current Biology}},
  title        = {{Coordinated molecular and physiological adaptations enable activity at sub-freezing temperatures in the snow fly Chionea alexandriana}},
  url          = {{http://dx.doi.org/10.1016/j.cub.2026.02.060}},
  doi          = {{10.1016/j.cub.2026.02.060}},
  volume       = {{36}},
  year         = {{2026}},
}