Abstract
It is long known that peptide neurotoxins derived from a diversity of venomous animals evolve by positive selection following gene duplication, yet a force that drives their adaptive evolution remains a mystery. By using maximum-likelihood models of codon substitution, we analyzed molecular adaptation in scorpion sodium channel toxins from a specific species and found ten positively selected sites, six of which are located at the core-domain of scorpion α-toxins, a region known to interact with two adjacent loops in the voltage-sensor domain (DIV) of sodium channels, as validated by our newly constructed computational model of toxin-channel complex. Despite the lack of positive selection signals in these two loops, they accumulated extensive sequence variations by relaxed purifying selection in prey and predators of scorpions. The evolutionary variability in the toxin-bound regions of sodium channels indicates that accelerated substitutions in the multigene family of scorpion toxins is a consequence of dealing with the target diversity. This work presents an example of atypical co-evolution between animal toxins and their molecular targets, in which toxins suffered from more prominent selective pressure from the channels of their competitors. Our discovery helps explain the evolutionary rationality of gene duplication of toxins in a specific venomous species.
Highlights
It is long known that peptide neurotoxins derived from a diversity of venomous animals evolve by positive selection following gene duplication, yet a force that drives their adaptive evolution remains a mystery
By using maximum-likelihood models of codon substitution, we analyzed molecular adaptation in scorpion sodium channel toxins from a specific species and found ten positively selected sites, six of which are located at the core-domain of scorpion α-toxins, a region known to interact with two adjacent loops in the voltage-sensor domain (DIV) of sodium channels, as validated by our newly constructed computational model of toxin-channel complex
The ML estimates (MLEs) under M2a suggest that 27% of sites are under positive selection with ω = 2 .47 (Table 1)
Summary
It is long known that peptide neurotoxins derived from a diversity of venomous animals evolve by positive selection following gene duplication, yet a force that drives their adaptive evolution remains a mystery. Scorpion α -toxins are the firstly identified venom component with lethal effect on both insects and mammals They are only present in species of the Buthidae family[11] and cause a slowing of the inactivation of Nav channels by binding to site 31,12. Sunagar et al showed that α -toxins from several Australian scorpion species had experienced episodic influence of positive selection with 14 sites evolved by positive selection[16] Despite these remarkable progresses, it is still unclear what factors have driven the adaptive evolution of these toxins in a specific species. In combination with structural and evolutionary analyses of Nav channels from both prey and predators of scorpions, we provide convincing evidence for an atypical co-evolutionary manner between scorpions and their competitors, in which toxin-bound regions of the ion channel evolved by relaxed purifying selection to accumulate sequence mutations may act as a driver of the adaptive evolution of toxins. Our work addresses a key question regarding the evolutionary rationality of the presence of multiple paralogous α -toxins in a scorpion’s venom
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