Molecular Mechanisms Underlying Substance Transport, Signal Transduction, and Anti-Stress Regulation, as Well as Anti-Alkaline Regulation via <i>Bursicon</i> in the Cerebral Ganglion of Chinese Mitten Crab <i>Eriocheir sinensis</i> Under Alkaline Stress

Molecular Mechanisms Underlying Substance Transport, Signal Transduction, and Anti-Stress Regulation, as Well as Anti-Alkaline Regulation via <i>Bursicon</i> in the Cerebral Ganglion of Chinese Mitten Crab <i>Eriocheir sinensis</i> Under Alkaline Stress

(1) Background: Global climate change is intensifying, and the vigorous development and utilization of saline–alkali land is of great significance. As an important economic aquatic species in the context of saline–alkali aquaculture, it is highly significant to explore the regulatory mechanisms of &...

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Bibliographic Details
Main Authors: Meiyao Wang, Jun Zhou, Jiachun Ge, Gangchun Xu, Yongkai Tang
Format: Article
Language:English
Published: MDPI AG 2025-01-01
Series:Biology
Subjects:
<i>Eriocheir sinensis</i>
cerebral ganglia
alkalinity stress
<i>bursicon</i>
signal transduction
Online Access:https://www.mdpi.com/2079-7737/14/1/84
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Summary:(1) Background: Global climate change is intensifying, and the vigorous development and utilization of saline–alkali land is of great significance. As an important economic aquatic species in the context of saline–alkali aquaculture, it is highly significant to explore the regulatory mechanisms of <i>Eriocheir sinensis</i> under alkaline conditions. In particular, the brain (cerebral ganglion for crustaceans) serves as a vital regulatory organ in response to environmental stress; (2) Methods: In this study, a comparative transcriptome approach was employed to investigate the key regulatory genes and molecular regulatory mechanisms in the cerebral ganglion of <i>E. sinensis</i> under alkaline stress. (3) Results: The results demonstrated that the cerebral ganglion of <i>E. sinensis</i> exhibited a positive response to acute alkaline stress. Pathways associated with signal transduction and substance transportation, such as “phagosome” and “regulation of actin cytoskeleton”, along with regulatory genes involved in antioxidation, were upregulated synergistically to maintain homeostasis under alkaline stress. Furthermore, it was discovered for the first time that <i>bursicon</i> plays a positive regulatory role in the adaptation of <i>E. sinensis</i> to alkalinity. (4) Conclusions: The present study elucidates the molecular regulatory pattern of the cerebral ganglion in <i>E. sinensis</i> under acute alkaline stress as well as revealing a novel role of <i>bursicon</i> in facilitating adaptation to alkalinity in <i>E. sinensis</i>, providing valuable theoretical insights into the molecular regulatory mechanisms underlying the responses of cerebral ganglia to saline–alkali environments. These findings also offer a theoretical reference for promoting the sustainable development of the <i>E. sinensis</i> breeding industry under saline–alkali conditions.
ISSN:2079-7737

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