Evolutionary history of burrowing asps (Lamprophiidae: Atractaspidinae) with emphasis on fang evolution and prey selection

Portillo, Frank; Stanley, Edward L.; Branch, William R.; Conradie, Werner; Rödel, Mark‐Oliver; Penner, Johannes; Barej, Michael F.; Kusamba, Chifundera; Muninga, Wandege M.; Aristote, Mwenebatu M.; Bauer, Aaron M.; Trape, Jean‐François; Nagy, Zoltán T.; Carlino, Piero; Pauwels, Olivier S. G.; Menegon, Michele; Ineich, Ivan; Burger, Marius; Zassi-Boulou, Ange-Ghislain; Mazuch, Tomáš; Jackson, Kate; Hughes, Daniel F.; Behangana, Mathias; Greenbaum, Eli

doi:10.1371/journal.pone.0214889

Cited by 25 publications

(24 citation statements)

References 83 publications

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“… Sites of positive selection in α1-nAChR ligand-binding domain. Topology constructed from the consensus of TimeTree.org and taxon-specific phylogenies [ 43 , 44 , 45 , 46 , 47 , 48 , 49 , 50 , 51 ]. The most common amino acid sequence of the α1-nAChR ligand-binding is displayed for one species ( Danio rerio ) and differences from this sequence are displayed for all other species.…”

Section: Resultsmentioning

confidence: 99%

“…The nucleotide sequences were translated into amino acids, manually aligned, and trimmed down to the 14 codons of the ligand-binding domain using AliView 1.18 ( ) [ 79 ]. A phylogeny of all the species included in our dataset was compiled from a consensus generated by TimeTree.org and reconciled with taxon-specific phylogenies [ 43 , 44 , 45 , 46 , 47 , 48 , 49 , 50 , 51 ]. The data set was separated into five major clades: Actinopterygii, Mammalia, Archelosauria, toxicoferan lizards, and Serpentes.…”

Section: Methodsmentioning

confidence: 99%

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Widespread Evolution of Molecular Resistance to Snake Venom α-Neurotoxins in Vertebrates

Khan

Dashevsky

Kerkkamp

et al. 2020

Toxins

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Venomous snakes are important subjects of study in evolution, ecology, and biomedicine. Many venomous snakes have alpha-neurotoxins (α-neurotoxins) in their venom. These toxins bind the alpha-1 nicotinic acetylcholine receptor (nAChR) at the neuromuscular junction, causing paralysis and asphyxia. Several venomous snakes and their predators have evolved resistance to α-neurotoxins. The resistance is conferred by steric hindrance from N-glycosylated asparagines at amino acids 187 or 189, by an arginine at position 187 that has been hypothesized to either electrostatically repulse positively charged neurotoxins or sterically interfere with α-neurotoxin binding, or proline replacements at positions 194 or 197 of the nAChR ligand-binding domain to inhibit α-neurotoxin binding through structural changes in the receptor. Here, we analyzed this domain in 148 vertebrate species, and assessed its amino acid sequences for resistance-associated mutations. Of these sequences, 89 were sequenced de novo. We find widespread convergent evolution of the N-glycosylation form of resistance in several taxa including venomous snakes and their lizard prey, but not in the snake-eating birds studied. We also document new lineages with the arginine form of inhibition. Using an in vivo assay in four species, we provide further evidence that N-glycosylation mutations reduce the toxicity of cobra venom. The nAChR is of crucial importance for normal neuromuscular function and is highly conserved throughout the vertebrates as a result. Our research shows that the evolution of α-neurotoxins in snakes may well have prompted arms races and mutations to this ancient receptor across a wide range of sympatric vertebrates. These findings underscore the inter-connectedness of the biosphere and the ripple effects that one adaption can have across global ecosystems.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Widespread Evolution of Molecular Resistance to Snake Venom α-Neurotoxins in Vertebrates

Khan

Dashevsky

Kerkkamp

et al. 2020

Toxins

View full text Add to dashboard Cite

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“…To our knowledge, the venoms from these arthropod-eating species have not been studied. Among Lamprophiidae, the subfamily Atractaspidinae includes the rear-fanged genus Aparallactus (11 species) that feeds on centipedes (with the exception of Aparallactus modestus, a fangless species that feeds on earthworms; Portillo et al, 2018Portillo et al, , 2019.…”

Section: Non-front-fanged Species Specialized On Venomous Arthropodsmentioning

confidence: 99%

“…Among Lamprophiidae, the following rear-fanged genera (belonging to the tribe Atractaspidinae) feed mostly on snakes and fossorial squamates: Amblyodipsas, Brachyophis, Chilorhinophis, Hypoptophis, Macrelaps, Polemon, and Xenocalamus (32 species; Portillo et al, 2018Portillo et al, , 2019. Given its peculiar dentition (enlarged front and back maxillary teeth), use of venom and inclusion of skinks in its diet, the "mock viper" (genus Psammodynastes, 2 species, family Lamprophiidae) also deserves special interest (Jackson and Fritts, 1996).…”

Section: Non-front-fanged Species Specialized On Gastropod Molluscsmentioning

confidence: 99%

Snake Venom in Context: Neglected Clades and Concepts

2019

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Despite the fact that venom is an intrinsically ecological trait, the ecological perspective has been widely neglected in toxinological research. This neglect has hindered our understanding of the evolution of venom by causing us to ignore the interactions which shape this evolution, interactions that take place between venomous snakes and their prey and predators, as well as among conspecific venomous snakes within populations. In this opinion piece, we introduce and briefly discuss several ecologically oriented concepts that may be of interest to toxinologists, before reviewing a range of non-front-fanged snake taxa that have been neglected toxinologically, but which represent the majority of extant ecological diversity amongst snakes. We conclude by noting that the ecological perspective even has something to offer to clinical toxinology, in the wake of the World Health Organization reinstating snakebite envenoming to its list of Neglected Tropical Diseases.

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“…In non-front-fanged snakes, ducts leading from the venom glands open into the mouth near the back of the maxilla [29]. All three of the front-fanged lineages have independently evolved maxillae that are reduced in size and number of teeth, which brings these anterior teeth and associated venom ducts towards the front of the mouth and simplifies the mechanical process of envenomation [30,31]. At the same time, these families' teeth were further adapted to become large (especially in Viperidae and Atractaspidae), tubular fangs which can conduct venom directly from the venom duct into the snake's target [32].…”

Section: Snake Venomsmentioning

confidence: 99%

Novelty in three-finger toxin evolution

Dashevsky¹

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Snakes are a striking taxon on many levels and have an indelible place in the collective culture of humanity. This is due to a number of unusual features including their limblessness, ability to ingest large prey, but most importantly their venom. From a biological perspective, snakes are equally fascinating, showing how a simple body plan can be used to great effect in an extremely broad variety of niches. Snakes are globally distributed and ecologically diverse; as a result, since recent research has shown that most snakes are venomous to some degree, their venom is equally diverse. This thesis focuses on one major toxin family: three-finger toxins (3FTx). These toxins can be found in virtually all venomous snake lineages and are often neurotoxic. Since their original recruitment there have been numerous instances of structural and functional innovation within this toxin family. The research in this thesis pertains to several such novel adaptations in snakes of the colubrid and elapid families, many of whose venom is composed primarily of these toxins. Chapter 2 deals with the ancestral version 3FTx and how, in the colubrine genus Boiga, simple mutations in toxins can lead to structural changes, in this case additional cysteines enable the formation of dimeric toxins with increased potency. These novel toxins can, in turn, open up new niches to the snakes which possess those toxins. In B. irregularis they facilitated a destructive invasion event and may have similarly assisted in the spread of an ancestral Boiga since our research shows that several other species possess similar dimeric toxins. This echoes a process that occurred in the ancestor of the elapids where the loss of a pair of cysteines and their disulfide bond was followed by an incredible diversification of these toxins and the snakes that produce them. Chapter 3 explores venom composition and activity of the genus Calliophis, the most basal genus of the elapids. C. bivirgatus and C. intestinalis both possess extremely elongated venom glands and each produce 3FTx with novel sodium channel toxicity. However, the two venoms produce opposite effects from one another. These results suggests some intriguing possibilities about the evolutionary history of these novel traits in Calliophis and the general composition of their venoms inform our understanding of how the venoms of more derived elapids evolved.Chapters 4 and 5 focus on the genus Micrurus. This genus from the Americas is by far the most speciose genus of elapids and belongs to the coral snake clade which is the next branch in the phylogeny of the elapids after Calliophis. The venoms of these snakes all contain a high number of unique 3FTx, though some venoms may be dominated by PLA2 toxins in terms of overall composition. Chapter 4 focuses on the sequence diversity of 3FTx from this genus and the selection regimes under which they operate. This diversity may lay the groundwork for rapid changes in the toxin composition of the venom and accompanying changes in venom activity. Chapter 5 directly ...

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Evolutionary history of burrowing asps (Lamprophiidae: Atractaspidinae) with emphasis on fang evolution and prey selection

Cited by 25 publications

References 83 publications

Widespread Evolution of Molecular Resistance to Snake Venom α-Neurotoxins in Vertebrates

Widespread Evolution of Molecular Resistance to Snake Venom α-Neurotoxins in Vertebrates

Snake Venom in Context: Neglected Clades and Concepts

Novelty in three-finger toxin evolution

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