The first chromosome‐level genome assembly and transcriptome sequencing provide insights into cantharidin production of the blister beetles

Blister beetles (Coleoptera: Meloidae) produce a natural defensive toxin cantharidin (CTD), which has been used for various cancer treatments and other diseases. Currently, the lack of chromosome‐level reference genomes in Meloidae limits further understanding of the mechanism of CTD biosynthesis an...

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Bibliographic Details
Published in:Integrative zoology 2024-09, Vol.19 (5), p.929-940
Main Authors: ZHOU, Chuang, ZHENG, Xiaofeng, WANG, Lei, YUE, Bisong, DU, Chao, LIU, Xu
Format: Article
Language:English
Subjects:
Adaptation
Animals
Biosynthesis
blister beetle
Cancer therapies
Cantharidin - metabolism
cantharidin biosynthesis
Chromosomes
Chromosomes, Insect - genetics
chromosome‐level genome
Coleoptera
Coleoptera - genetics
Coleoptera - metabolism
Cytochrome P450
Cytochromes
differentially expressed gene
Farnesol
Farnesol dehydrogenase
Gene families
Genes
Genome, Insect
Genomes
Hormones
Juvenile hormones
Juvenile Hormones - biosynthesis
Juvenile Hormones - metabolism
Male
Meloidae
Mylabris phalerata
Odorant-binding protein
Odour
Protein transport
Sequencing
sexual dimorphism
Toxins
Transcriptome
Transcriptomes
Transcriptomics
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Summary:Blister beetles (Coleoptera: Meloidae) produce a natural defensive toxin cantharidin (CTD), which has been used for various cancer treatments and other diseases. Currently, the lack of chromosome‐level reference genomes in Meloidae limits further understanding of the mechanism of CTD biosynthesis and environmental adaptation. In this study, the chromosome‐level genome assembly of Mylabris phalerata was generated based on PacBio and Hi‐C sequencing. This reference genome was about 136.68 Mb in size with contig N50 of 9.17 Mb and composed of 12 chromosomes. In comparison to six other Coleoptera insects, M. phalerata exhibited multiple expanded gene families enriched in juvenile hormone (JH) biosynthetic process pathway, farnesol dehydrogenase activity, and cytochrome P450, which may be related to CTD biosynthesis. Consistently, the transcriptomic analysis suggested the “terpenoid backbone biosynthesis” pathway and “the juvenile hormone” as putative core pathways of CTD biosynthesis and presented eight up‐regulated differential expression genes in male adults as candidate genes. It is possible that the restricted feeding niche and lifestyle of M. phalerata were the cause of the gene family's contraction of odorant binding proteins. The ABC transporters (ABCs) related to exporting bound toxins out of the cell and the resistance to the self‐secreted toxins (e.g. CTD) were also contracted, possibly due to other self‐protection strategies in M. phalerata. A foundation of understanding CTD biosynthesis and environmental adaptation of blister beetles will be established by our reference genome and discoveries. The blister beetles (Coleoptera: Meloidae) could produce a natural defensive toxin of cantharidin, which has been used for various cancer treatments and other diseases. The first chromosome‐level genome assembly and transcriptome sequencing can help understand the cantharidin production of the blister beetles.
ISSN:1749-4877
1749-4869
1749-4877
DOI:10.1111/1749-4877.12783