Abstract
Diapause is a form of dormancy, and Bombyx mori silkworm embryos are ideal models for studying diapause in insects. However, molecular events in eggs during the onset of diapause remain unclear. In this study, transcriptome analyses were performed on silkworm diapause eggs via RNA sequencing at 20 and 48 h after oviposition. A total of 6402 differentially expressed genes (DEGs) were detected in diapause eggs at 48 h versus that at 20 h after oviposition. Gene ontology enrichment analysis showed that DEGs in diapause eggs at 48 h versus that at 20 h after oviposition were involved in ribosome-related metabolism and hydrogen transport. Kyoto Encyclopedia of Genes and Genomes analysis revealed several significantly enriched biological pathways, namely the oxidative phosphorylation, Forkhead box protein O3 (FoxO) signaling, ribosome, endoplasmic reticular protein processing, and autophagy pathways. Fifteen DEGs from the FoxO signaling pathway were selected, and their expression profiles were consistent with the transcriptome results from real-time quantitative reverse transcription polymerase chain reaction. Our results can improve understanding of the diapause mechanism in silkworm eggs and identified key pathways for future studies.
Highlights
The external environment is not always suitable for the growth of organisms, especially the case in ectotherms
Clarifying the mechanism of embryonic diapause is relevant to both sericultural production and scientific research
The transcriptome analysis revealed that Differentially expressed genes (DEGs) involved in energy metabolism pathways, for example, the oxidative phosphorylation and insulin/Forkhead box protein O3 (FoxO) signaling pathways, were significantly enriched, which may cause changes in energy and metabolism during diapause
Summary
The external environment is not always suitable for the growth of organisms, especially the case in ectotherms. Dormancy is a strategy that enables bacteria, plants, and animals to survive and reproduce by minimizing metabolic activity to conserve energy. Diapause is a form of dormancy involving predictability [1], metabolic inhibition, developmental arrest, and enhanced stress tolerance [2]. It involves various “programmed” physiological and molecular processes. Organisms can switch their developmental state to a diapause state to survive and/or reproduce under seasonal variations. Numerous animals, including nematodes, insects, fish, and mammals [2,3,4,5], exhibit this phenomenon
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