Key Laboratory of Bioresources and Ecoenvironment (Ministry of Education), College of Life Sciences, Sichuan University, Chengdu, People's Republic of China.
Sichuan Key Laboratory for Medicinal American Cockroach, Chengdu, Sichuan, People's Republic of China.
Arch Insect Biochem Physiol. 2022 Dec;111(4):e21956. doi: 10.1002/arch.21956. Epub 2022 Aug 7.
The synanthropic pest and a model organism for entomological research, American cockroach, Periplaneta americana (Linnaeus), can survive in unfavorable environments for humans. To investigate the genetic mechanisms of success in environmental adaptation of P. americana, we de novo reassembled its whole genome based on next-generation sequencing and PacBio sequencing. The final genome reassembly consisted of approximately 3.34 Gb with scaffold N50 of 465.51 Kb. The completeness (95.4%) of the complete genome was evaluated with single-copy orthologous genes using BUSCO. We identified 18,618 protein-coding genes, 16,443 (88.32%) of which were well supported by public protein databases. We identified 482.04 Mb (approximately 14.45%) repeat elements, 1,385,093 perfect microsatellites simple sequence repeats in P. americana genome, which was higher than other four Blattaria insects. Comparative genomics analysis revealed obvious expansion in the gene families associated with chemoreception (olfactory receptors, gustatory receptors, ionotropic glutamate receptors, chemosensory protein, and sensory neuron membrane protein), which provided the necessary information for functional characterization of the chemosensory receptors of P. americana, with potential for new or refined applications of semiochemicals-based control of this pest insect. Similarly, gene families (cytochrome P450s, carboxyl/choline esterases, and UDP-glycosyl-transferases) encoding receptors for bitter or toxic substances and detoxification enzymes were obviously expanded in P. americana, enabling its ability to detect and detoxify many toxins. Enrichment analysis of positively selected genes in P. americana revealed items associated with metabolic process and catalytic activity, which possibly contributed to the pesticide resistance of P. americana. We also analyzed the homologs to antimicrobial peptide genes reported in the Drosophila genome, and identified two attacins and seven defensins in P. americana. Our data and findings will substantially facilitate molecular studies in P. americana, including elucidation of detoxification mechanisms of xenobiotic, as well as development of new pest management strategies for the control of pests like P. americana.
拟栖生物害虫和昆虫学研究的模式生物,美洲大蠊(Periplaneta americana)(Linnaeus),能够在不利于人类的环境中生存。为了研究美洲大蠊在环境适应方面成功的遗传机制,我们基于下一代测序和 PacBio 测序从头重新组装了它的整个基因组。最终基因组重组成约 3.34Gb,支架 N50 为 465.51Kb。使用 BUSCO 评估单拷贝直系同源基因,评估完整基因组的完整性(95.4%)。我们鉴定了 18618 个蛋白质编码基因,其中 16443 个(88.32%)被公共蛋白质数据库很好地支持。我们鉴定了 482.04Mb(约 14.45%)重复元件,美洲大蠊基因组中有 1385093 个完美的微卫星简单序列重复,高于其他四种蜚蠊目昆虫。比较基因组学分析显示,与化学感受(嗅觉受体、味觉受体、离子型谷氨酸受体、化学感受蛋白和感觉神经元膜蛋白)相关的基因家族明显扩张,这为美洲大蠊化学感受受体的功能特征提供了必要的信息,为基于半化学物质控制这种害虫昆虫提供了新的或改进的应用的可能性。同样,编码苦味或有毒物质受体和解毒酶的基因家族(细胞色素 P450s、羧酸/胆碱酯酶和 UDP-糖基转移酶)在美洲大蠊中明显扩张,使其能够检测和解毒许多毒素。美洲大蠊中阳性选择基因的富集分析显示出与代谢过程和催化活性相关的项目,这可能有助于美洲大蠊的抗药性。我们还分析了在果蝇基因组中报道的抗菌肽基因的同源物,并在美洲大蠊中鉴定了两个 attacins 和七个 defensins。我们的数据和发现将极大地促进美洲大蠊的分子研究,包括阐明外来生物的解毒机制,以及为控制像美洲大蠊这样的害虫开发新的害虫管理策略。
