Multiple mechanisms of action of an extremely painful venom

Lydia J Borjon, Luana C de Assis Ferreira, Jonathan C Trinidad, Suncica Sasic, Andrea G Hohmann, W Daniel Tracey
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Abstract

Evolutionary arms races between predator and prey can lead to extremely specific and effective defense mechanisms. Such defenses include venoms that deter predators by targeting nociceptive (pain-sensing) pathways. Through co-evolution, venom toxins can become extremely efficient modulators of their molecular targets. The venom of velvet ants (Hymenoptera: Mutillidae) is notoriously painful. The intensity of a velvet ant sting has been described as "Explosive and long lasting, you sound insane as you scream. Hot oil from the deep fryer spilling over your entire hand." The effectiveness of the velvet ant sting as a deterrent against potential predators has been shown across vertebrate orders, including mammals, amphibians, reptiles, and birds. The venom's low toxicity suggests it has a targeted effect on nociceptive sensory mechanisms. This leads to the hypothesis that velvet ant venom targets a conserved nociception mechanism, which we sought to uncover using Drosophila melanogaster as a model system. Drosophila larvae have peripheral sensory neurons that sense potentially damaging (noxious) stimuli such as high temperature, harsh mechanical touch, and noxious chemicals. These polymodal nociceptors are called class IV multidendritic dendritic arborizing (cIV da) neurons, and they share many features with vertebrate nociceptors, including conserved sensory receptor channels. We found that velvet ant venom strongly activated Drosophila nociceptors through heteromeric Pickpocket/Balboa (Ppk/Bba) ion channels. Furthermore, we found a single venom peptide (Do6a) that activated larval nociceptors at nanomolar concentrations through Ppk/Bba. Drosophila Ppk/Bba is homologous to mammalian Acid Sensing Ion Channels (ASICs). However, the Do6a peptide did not produce behavioral signs of nociception in mice, which was instead triggered by other non-specific, less potent, peptides within the venom. This suggests that Do6a is an insect-specific venom component that potently activates insect nociceptors. Consistent with this, we showed that the velvet ant's defensive sting produced aversive behavior in a predatory praying mantis. Together, our results indicate that velvet ant venom evolved to target nociceptive systems of both vertebrates and invertebrates, but through different molecular mechanisms.
极痛毒液的多种作用机制
捕食者和猎物之间的进化军备竞赛会产生极其特殊和有效的防御机制。这种防御机制包括通过靶向痛觉(痛感)通路来威慑捕食者的毒液。通过共同进化,毒液毒素可以成为其分子目标的极其有效的调节剂。绒蚁(膜翅目:恙蚁科)的毒液以疼痛著称。绒蚁螫伤的剧烈程度被描述为 "爆炸性的、持续时间长的,你尖叫的声音听起来就像疯了一样。油炸锅里的热油溅到你的整个手上"。绒蚁毒刺对潜在捕食者的威慑作用已在脊椎动物中得到证实,包括哺乳动物、两栖动物、爬行动物和鸟类。毒液的低毒性表明,它对痛觉感觉机制具有针对性的作用。我们试图利用黑腹果蝇作为模型系统来揭示这一机制。果蝇幼虫的外周感觉神经元能感知潜在的破坏性(有害)刺激,如高温、刺耳的机械触觉和有害化学物质。这些多模式痛觉感受器被称为第四类多树突树突化(cIV da)神经元,它们与脊椎动物的痛觉感受器有许多共同特征,包括保守的感觉受体通道。我们发现,天鹅绒蚁毒通过异构的Pickpocket/Balboa(Ppk/Bba)离子通道强烈激活果蝇的痛觉感受器。此外,我们还发现一种单一毒肽(Do6a)在纳摩尔浓度下可通过Ppk/Bba激活幼虫的痛觉感受器。果蝇的 Ppk/Bba 与哺乳动物的酸感应离子通道(ASIC)同源。然而,Do6a肽并没有在小鼠体内产生痛觉的行为表现,而是由毒液中其他非特异性、效力较弱的肽引发。这表明 Do6a 是一种昆虫特异性毒液成分,能有效激活昆虫的痛觉感受器。与此相一致的是,我们发现绒蚁的防御性刺痛会对捕食性螳螂产生厌恶行为。总之,我们的研究结果表明,绒蚁毒液是通过不同的分子机制,针对脊椎动物和无脊椎动物的痛觉系统进化而来的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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