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Incubation temperature shapes growth and mitochondrial metabolism across embryonic development in Japanese quail

Thoral, Elisa LU ; Correia, Maria Gomez LU ; Chamkha, Imen LU ; Elmér, Eskil LU orcid and Nord, Andreas LU orcid (2025) In Proceedings of the Royal Society B: Biological Sciences 292(2054).
Abstract

Incubation temperature affects both growth and energy metabolism in birds after hatching. Changes in cellular mechanisms, including mitochondrial function, are a likely but unexplored explanation for these effects. To test whether temperature-dependent changes to mitochondria may link embryonic development to the post-natal phenotype, we incubated Japanese quail eggs at constant low (36.0°C), medium (37.5°C) or high (39.0°C) temperature and studied mitochondrial function and growth during embryogenesis and at hatching. Embryos grew faster and had higher mitochondrial metabolism at the high incubation temperature. Low incubation temperature slowed embryonic development and decreased phosphorylating respiration but was associated with... (More)

Incubation temperature affects both growth and energy metabolism in birds after hatching. Changes in cellular mechanisms, including mitochondrial function, are a likely but unexplored explanation for these effects. To test whether temperature-dependent changes to mitochondria may link embryonic development to the post-natal phenotype, we incubated Japanese quail eggs at constant low (36.0°C), medium (37.5°C) or high (39.0°C) temperature and studied mitochondrial function and growth during embryogenesis and at hatching. Embryos grew faster and had higher mitochondrial metabolism at the high incubation temperature. Low incubation temperature slowed embryonic development and decreased phosphorylating respiration but was associated with higher adenosine triphosphate production efficiency. These respiration changes were mirrored by differences in mitochondrial content, which was the lowest in cold embryos. Neither treatment affected reactive oxygen species production. Hence, improved coupling efficiency in cold embryos may have partially compensated for lower adenosine triphosphate production without increasing oxidative stress. Size differences had disappeared by hatching. However, cold-incubated chicks had a higher mitochondrial content compared with the other groups. Our study suggests that thermal suppression of embryonic metabolism may be compensated by a combination of increased coupling, longer developmental time and late-occurring upregulation of mitochondrial content. The long-term implications of these results should be studied further.

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author
; ; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
birds, citrate synthase, embryonic development, energy metabolism, oxidative stress, reactive oxygen species
in
Proceedings of the Royal Society B: Biological Sciences
volume
292
issue
2054
article number
20251752
publisher
Royal Society Publishing
external identifiers
  • pmid:40925569
  • scopus:105015437192
ISSN
0962-8452
DOI
10.1098/rspb.2025.1752
language
English
LU publication?
yes
id
7b5cb81f-8154-4b1a-8a63-7650a29f959d
date added to LUP
2025-10-15 11:06:57
date last changed
2025-10-29 12:06:55
@article{7b5cb81f-8154-4b1a-8a63-7650a29f959d,
  abstract     = {{<p>Incubation temperature affects both growth and energy metabolism in birds after hatching. Changes in cellular mechanisms, including mitochondrial function, are a likely but unexplored explanation for these effects. To test whether temperature-dependent changes to mitochondria may link embryonic development to the post-natal phenotype, we incubated Japanese quail eggs at constant low (36.0°C), medium (37.5°C) or high (39.0°C) temperature and studied mitochondrial function and growth during embryogenesis and at hatching. Embryos grew faster and had higher mitochondrial metabolism at the high incubation temperature. Low incubation temperature slowed embryonic development and decreased phosphorylating respiration but was associated with higher adenosine triphosphate production efficiency. These respiration changes were mirrored by differences in mitochondrial content, which was the lowest in cold embryos. Neither treatment affected reactive oxygen species production. Hence, improved coupling efficiency in cold embryos may have partially compensated for lower adenosine triphosphate production without increasing oxidative stress. Size differences had disappeared by hatching. However, cold-incubated chicks had a higher mitochondrial content compared with the other groups. Our study suggests that thermal suppression of embryonic metabolism may be compensated by a combination of increased coupling, longer developmental time and late-occurring upregulation of mitochondrial content. The long-term implications of these results should be studied further.</p>}},
  author       = {{Thoral, Elisa and Correia, Maria Gomez and Chamkha, Imen and Elmér, Eskil and Nord, Andreas}},
  issn         = {{0962-8452}},
  keywords     = {{birds; citrate synthase; embryonic development; energy metabolism; oxidative stress; reactive oxygen species}},
  language     = {{eng}},
  number       = {{2054}},
  publisher    = {{Royal Society Publishing}},
  series       = {{Proceedings of the Royal Society B: Biological Sciences}},
  title        = {{Incubation temperature shapes growth and mitochondrial metabolism across embryonic development in Japanese quail}},
  url          = {{http://dx.doi.org/10.1098/rspb.2025.1752}},
  doi          = {{10.1098/rspb.2025.1752}},
  volume       = {{292}},
  year         = {{2025}},
}