Bell Jack, Sukiran Nur Afiqah, Walsh Stephen, Fitches Elaine C
Durham University, Department of Biosciences, Stockton Rd, Durham, DH1 3LE, UK.
Durham University, Department of Biosciences, Stockton Rd, Durham, DH1 3LE, UK.
Toxicon. 2021 Jul 15;197:79-86. doi: 10.1016/j.toxicon.2021.04.003. Epub 2021 Apr 20.
The nemertide toxins from the phylum Nemertea are a little researched family of neurotoxins with potential for development as biopesticides. Here we report the recombinant production of nemertide α-1 (α-1), a 65-residue inhibitor cystine knot (ICK) peptide from Lineus longissimus, known to target insect voltage-gated sodium channels. The insecticidal activity of α-1 was assessed and compared with the well characterised ICK venom peptide, ω-atracotoxin/hexatoxin-Hv1a (Hv1a). α-1 elicited potent spastic paralysis when injected into cabbage moth (Mamestra brassicae) larvae; conferring an ED 3.90 μg/larva (10.30 nmol/g larva), followed by mortality (60% within 48 h after 10 μg injection). By comparison, injection of M. brassicae larvae with recombinant Hv1a produced short-lived flaccid paralysis with an ED over 6 times greater than that of α-1 at 26.20 μg/larva (64.70 nmol/g larva). Oral toxicity of α-1 was demonstrated against two aphid species (Myzus persicae and Acyrthosiphon pisum), with respective LC values of 0.35 and 0.14 mg/mL, some 6-fold lower than those derived for recombinant Hv1a. When delivered orally to M. brassicae larvae, α-1 caused both paralysis (ED 11.93 μg/larva, 31.5 nmol/g larva) and mortality. This contrasts with the lack of oral activity of Hv1a, which when fed to M. brassicae larvae had no effect on feeding or survival. Hv1a has previously been shown to be non-toxic by injection to the beneficial honeybee (Apis mellifera). By contrast, rapid paralysis and 100% mortality was observed following injection of α-1 (31.6 nmol/g insect). These results demonstrate the great potential of naturally occurring non-venomous peptides, such as α-1, for development as novel effective biopesticides, but equally highlights the importance of understanding the phyletic specificity of a given toxin at an early stage in the quest to discover and develop safe and sustainable pesticides.
纽形动物门的纽形动物毒素是一类研究较少的神经毒素家族,具有开发为生物杀虫剂的潜力。在此,我们报告了纽形动物α-1(α-1)的重组生产,α-1是一种来自长带纽虫的含65个残基的抑制性胱氨酸结(ICK)肽,已知其靶向昆虫电压门控钠通道。评估了α-1的杀虫活性,并与特征明确的ICK毒液肽ω-阿特拉毒素/六毒素-Hv1a(Hv1a)进行了比较。将α-1注射到甘蓝夜蛾(Mamestra brassicae)幼虫中会引发强烈的痉挛性麻痹;其半数有效剂量为3.90μg/幼虫(10.30nmol/g幼虫),随后出现死亡(注射10μg后48小时内死亡率为60%)。相比之下,向甘蓝夜蛾幼虫注射重组Hv1a会产生短暂的弛缓性麻痹,其半数有效剂量超过α-1的6倍,为26.20μg/幼虫(64.70nmol/g幼虫)。α-1对两种蚜虫(桃蚜和豌豆蚜)表现出口服毒性,其半数致死浓度分别为0.35和0.14mg/mL,比重组Hv1a的半数致死浓度低约6倍。当口服给予甘蓝夜蛾幼虫时,α-1会导致麻痹(半数有效剂量为11.93μg/幼虫,31.5nmol/g幼虫)和死亡。这与Hv1a缺乏口服活性形成对比,将Hv1a喂给甘蓝夜蛾幼虫对其取食或存活没有影响。此前已证明,注射Hv1a对有益蜜蜂(Apis mellifera)无毒。相比之下,注射α-1(31.6nmol/g昆虫)后观察到蜜蜂迅速麻痹并100%死亡。这些结果表明,天然存在的无毒肽,如α-1,具有开发为新型有效生物杀虫剂的巨大潜力,但同样突出了在寻求发现和开发安全可持续农药的早期阶段了解特定毒素系统发育特异性的重要性。
