2021
DOI: 10.3390/insects12050396
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Identification of Novel Toxin Genes from the Stinging Nettle Caterpillar Parasa lepida (Cramer, 1799): Insights into the Evolution of Lepidoptera Toxins

Abstract: Many animal species can produce venom for defense, predation, and competition. The venom usually contains diverse peptide and protein toxins, including neurotoxins, proteolytic enzymes, protease inhibitors, and allergens. Some drugs for cancer, neurological disorders, and analgesics were developed based on animal toxin structures and functions. Several caterpillar species possess venoms that cause varying effects on humans both locally and systemically. However, toxins from only a few species have been investi… Show more

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Cited by 4 publications
(2 citation statements)
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References 124 publications
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“…Previously, Alo peptides present in Hemiptera and Coleoptera were proposed to evolve via horizontal gene transfer from plants or fungi based on the idea that its knottin domain is unique to plants and fungi [ 20 ]. However, recent studies show that proteins containing knottin domain play essential roles in many animal toxins, including nettle caterpillars, spiders, scorpions, and cone snails [ 73 ]. Thus, the evolution of arthropod Alo peptides may also be explained by multiple gene gains and loss events.…”
Section: Discussionmentioning
confidence: 99%
“…Previously, Alo peptides present in Hemiptera and Coleoptera were proposed to evolve via horizontal gene transfer from plants or fungi based on the idea that its knottin domain is unique to plants and fungi [ 20 ]. However, recent studies show that proteins containing knottin domain play essential roles in many animal toxins, including nettle caterpillars, spiders, scorpions, and cone snails [ 73 ]. Thus, the evolution of arthropod Alo peptides may also be explained by multiple gene gains and loss events.…”
Section: Discussionmentioning
confidence: 99%
“…To remove potentially nontoxic orthologs, all candidate toxin unigenes were used as queries for the local BLASTX search (e-value = 1e-5) against two databases: (1) animal-reviewed proteins in the UniprotKB and (2) toxin protein database, as explained previously. Unigenes were ltered out from the candidate toxin gene dataset if the BLAST score of the best hit from the animal protein database was higher than the animal toxin database results [14].…”
Section: Bioinformatic Analysismentioning
confidence: 99%