Transcriptome Analysis of the NematodeCaenorhabditis elegansin Acidic Stress Environments

Ocean acidification and acid rain, caused by modern industries' fossil fuel burning, lead to a decrease in the living environmental pH, which results in a series of negative effects on many organisms. However, the underlying mechanisms of animals' response to acidic pH stress are largely u...

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Bibliographic Details
Published in:Frontiers in Physiology
Main Authors: Cong, Yanyi, Yang, Hanwen, Zhang, Pengchi, Xie, Yusu, Cao, Xuwen, Zhang, Liusuo
Format: Report
Language:English
Published: FRONTIERS MEDIA SA 2020
Subjects:
pH stress
acidic environment
cuticle collagens
xenobiotic detoxification
P450
Caenorhabditis elegans
Physiology
Ocean acidification
Online Access:http://ir.qdio.ac.cn/handle/337002/168937
http://ir.qdio.ac.cn/handle/337002/168938
https://doi.org/10.3389/fphys.2020.01107
Description
Summary:Ocean acidification and acid rain, caused by modern industries' fossil fuel burning, lead to a decrease in the living environmental pH, which results in a series of negative effects on many organisms. However, the underlying mechanisms of animals' response to acidic pH stress are largely unknown. In this study, we used the nematodeCaenorhabditis elegansas an animal model to explore the regulatory mechanisms of organisms' response to pH decline. Two major stress-responsive pathways were found through transcriptome analysis in acidic stress environments. First, when the pH dropped from 6.33 to 4.33, the worms responded to the pH stress by upregulation of thecol,nas, anddpygenes, which are required for cuticle synthesis and structure integrity. Second, when the pH continued to decrease from 4.33, the metabolism of xenobiotics by cytochrome P450 pathway genes (cyp,gst,ugt, and ABC transporters) played a major role in protecting the nematodes from the toxic substances probably produced by the more acidic environment. At the same time, the slowing down of cuticle synthesis might be due to its insufficient protective ability. Moreover, the systematic regulation pattern we found in nematodes might also be applied to other invertebrate and vertebrate animals to survive in the changing pH environments. Thus, our data might lay the foundation to identify the master gene(s) responding and adapting to acidic pH stress in further studies, and might also provide new solutions to improve assessment and monitoring of ecological restoration outcomes, or generate novel genotypes via genome editing for restoring in challenging environments especially in the context of acidic stress through global climate change.

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