Alistair Reid Venom Research Unit, Parasitology Department, Liverpool School of Tropical Medicine, Pembroke Place, Liverpool L3 5QA, United Kingdom.
University of California San Diego, Skaggs School of Pharmacy & Pharmaceutical Sciences, 9500 Gilman Dr, La Jolla, CA 92093, USA; Technische Universität Berlin, Institut für Chemie, Straße des 17.Juni 124, 10623 Berlin, Germany.
J Proteomics. 2018 Feb 10;172:173-189. doi: 10.1016/j.jprot.2017.08.016. Epub 2017 Aug 24.
Mambas (genus Dendroaspis) are among the most feared of the medically important elapid snakes found in sub-Saharan Africa, but many facets of their biology, including the diversity of venom composition, remain relatively understudied. Here, we present a reconstruction of mamba phylogeny, alongside genus-wide venom gland transcriptomic and high-resolution top-down venomic analyses. Whereas the green mambas, D. viridis, D. angusticeps, D. j. jamesoni and D. j. kaimosae, express 3FTx-predominant venoms, black mamba (D. polylepis) venom is dominated by dendrotoxins I and K. The divergent terrestrial ecology of D. polylepis compared to the arboreal niche occupied by all other mambas makes it plausible that this major difference in venom composition is due to dietary variation. The pattern of intrageneric venom variability across Dendroaspis represented a valuable opportunity to investigate, in a genus-wide context, the variant toxicity of the venom, and the degree of paraspecific cross-reactivity between antivenoms and mamba venoms. To this end, the immunological profiles of the five mamba venoms were assessed against a panel of commercial antivenoms generated for the sub-Saharan Africa market. This study provides a genus-wide overview of which available antivenoms may be more efficacious in neutralising human envenomings caused by mambas, irrespective of the species responsible. The information gathered in this study lays the foundations for rationalising the notably different potency and pharmacological profiles of Dendroaspis venoms at locus resolution. This understanding will allow selection and design of toxin immunogens with a view to generating a safer and more efficacious pan-specific antivenom against any mamba envenomation.
The mambas (genus Dendroaspis) comprise five especially notorious medically important venomous snakes endemic to sub-Saharan Africa. Their highly potent venoms comprise a high diversity of pharmacologically active peptides, including extremely rapid-acting neurotoxins. Previous studies on mamba venoms have focused on the biochemical and pharmacological characterisation of their most relevant toxins to rationalize the common neurological and neuromuscular symptoms of envenomings caused by these species, but there has been little work on overall venom composition or comparisons between them. Only very recently an overview of the composition of the venom of two Dendroaspis species, D. angusticeps and D. polylepis, has been unveiled through venomics approaches. Here we present the first genus-wide transcriptomic-proteomic analysis of mamba venom composition. The transcriptomic analyses described in this paper have contributed 29 (D. polylepis), 23 (D. angusticeps), 40 (D. viridis), 25 (D. j. jamesoni) and 21 (D. j. kaimosae), novel full-length toxin sequences to the non-redundant Dendroaspis sequence database. The mamba genus-wide venomic analysis demonstrated that major D. polylepis venom components are Kunitz-fold family toxins. This feature is unique in relation to the relatively conserved three-finger toxin (3FTx)-dominated venom compositions of the green mambas. Venom variation was interpreted in the context of dietary variation due to the divergent terrestrial ecology of D. polylepis compared to the arboreal niche occupied by all other mambas. Additionally, the degree of cross-reactivity conservation of mamba venoms was assessed by antivenomics against a panel of commercial antivenoms generated for the sub-Saharan Africa market. This study provides a genus-wide overview to infer which available antivenoms may be capable of neutralising human envenomings caused by mambas, irrespective of the species responsible. The information gathered in this study lays the foundations for rationalising the pharmacological profiles of mamba venoms at locus resolution. This understanding will contribute to the generation of a safer and more efficacious pan-Dendroaspis therapeutic antivenom against any mamba envenomation.
曼巴蛇(Dendroaspis 属)是撒哈拉以南非洲地区最重要的毒蛇之一,但它们的生物学许多方面,包括毒液成分的多样性,仍相对研究不足。在这里,我们展示了曼巴蛇的系统发育重建,以及全属毒液腺转录组和高分辨率自上而下的毒液组学分析。虽然绿曼巴蛇(D. viridis)、D. angusticeps、D. j. jamesoni 和 D. j. kaimosae 表达以 3FTx 为主的毒液,但黑曼巴蛇(D. polylepis)的毒液则以树栖毒素 I 和 K 为主。与所有其他曼巴蛇栖息在树上的不同,黑曼巴蛇的陆地生态环境明显不同,这使得毒液成分的这种主要差异很可能是由于饮食的变化。Dendroaspis 属内毒液变异的种间模式为在全属范围内研究毒液的变异毒性以及抗蛇毒血清与曼巴蛇毒液之间的种间交叉反应程度提供了宝贵的机会。为此,我们评估了这五种曼巴蛇毒液的免疫谱,使用的是针对撒哈拉以南非洲市场的商业抗蛇毒血清。这项研究提供了一种全面的概述,说明了哪些现有的抗蛇毒血清可能更有效地中和由曼巴蛇引起的人类中毒,而不管负责的物种是什么。本研究收集的信息为合理解释在基因座分辨率下曼巴蛇毒液的显著不同的效力和药理学特征奠定了基础。这种理解将允许选择和设计毒素免疫原,以期产生更安全、更有效的针对任何曼巴蛇中毒的泛特异性抗蛇毒血清。
曼巴蛇(Dendroaspis 属)由五种特别危险的剧毒蛇组成,它们是撒哈拉以南非洲特有的蛇类。它们的毒液含有高度多样化的药理学活性肽,包括非常快速作用的神经毒素。以前对曼巴蛇毒液的研究主要集中在其最相关毒素的生化和药理学特征上,以合理解释由这些物种引起的中毒的常见神经和神经肌肉症状,但对整体毒液成分或它们之间的比较研究甚少。直到最近,通过毒液组学方法才揭示了两种 Dendroaspis 物种,即 D. angusticeps 和 D. polylepis 的毒液成分的概述。本文首次对曼巴蛇毒液组成进行了全属转录组-蛋白质组学分析。本文所述的转录组分析为 D. polylepis(29 个)、D. angusticeps(23 个)、D. viridis(40 个)、D. j. jamesoni(25 个)和 D. j. kaimosae(21 个)的非冗余 Dendroaspis 序列数据库贡献了 29 个、23 个、40 个、25 个和 21 个全长毒素序列。曼巴蛇属的毒液组学分析表明,黑曼巴蛇的主要毒液成分是 Kunitz 折叠家族毒素。与绿曼巴蛇相对保守的以三指毒素(3FTx)为主的毒液组成相比,这一特征是独特的。由于 D. polylepis 与其他所有曼巴蛇栖息在树上的不同,因此毒液的变异可以从饮食的变化方面来解释。此外,通过抗蛇毒血清对针对撒哈拉以南非洲市场的商业抗蛇毒血清进行评估,评估了曼巴蛇毒液交叉反应的保守程度。这项研究提供了一种全面的概述,推断哪些现有的抗蛇毒血清可能有能力中和由曼巴蛇引起的人类中毒,而不管负责的物种是什么。本研究收集的信息为在基因座分辨率下合理化曼巴蛇毒液的药理学特征奠定了基础。这种理解将有助于产生更安全、更有效的针对任何曼巴蛇中毒的泛 Dendroaspis 治疗性抗蛇毒血清。
