Evolutionary convergence of muscle architecture in relation to locomotor ecology in snakes.

The epaxial muscles in snakes are responsible for locomotion and as such can be expected to show adaptations in species living in different environments. Here, we tested whether the structural units that comprise the superficial epaxial muscles (semispinalis-spinalis, SSP; longissimus dorsi, LD; iliocostalis, IC) were different in animals occupying similar habitats. To do so, we analyzed and compared the muscle architecture (mass, fiber length, and physiological cross-sectional area) of the superficial epaxial muscle segments in snakes that differ in their habitat use (e.g., arboreal, terrestrial, and aquatic). Our results showed that arboreal species have on average longer muscles and tendons spanning more segments likely important during gap bridging. Moreover, aquatic snakes show relatively heavier semispinalis-spinalis muscles with a greater cross-sectional area. The longissimus dorsi muscles also showed a greater cross-sectional area compared with terrestrial and especially arboreal snakes. Whereas the more strongly developed muscles in aquatic snakes are likely associated with the dense and viscous environment through which they move, the lighter muscles in arboreal snakes may provide an advantage when climbing. Future studies comparing other ecologies (e.g., burrowing snakes) and additional muscle units (e.g., multifidus; hypaxial muscles) are needed to better understand the structural features driving variation in locomotor performance and efficiency in snakes.

The first reported snakebite by an African snake-eater, Polemon spp. (Atractaspididae, Aparallactinae); Local envenoming by Reinhardt's snake-eater, Polemon acanthias (Reinhardt, 1860).

The first reported snakebite by an African snake-eater, Polemon spp. (Atractaspididae, Aparallactinae); Local envenoming by Reinhardt's snake-eater, Polemon acanthias (Reinhardt, 1860). Toxicon XX, xxx. A 51-yr-old male herpetologist was bitten on the left index finger by a captive male Polemon acanthias while manually removing fragments of incompletely shed skin from the specimen. The snake sustained its bite for approximately 2 mins, advancing its jaws several times. The victim rapidly developed moderate pain, erythema, progressive edema that ultimately extended to the left wrist; a blister later developed in the wound site, as well as joint stiffness in the bitten and adjacent two fingers that limited flexion and extension. These effects regressed during the week following the bite, but recurred thereafter and were similar to the effects that developed immediately post-envenoming. There were no systemic signs or symptoms. The victim sought medical advice and was treated with broad-spectrum antibiotics, antihistamines and wound care; no laboratory investigations were conducted. He improved during the subsequent month with complete resolution in 5 and one-half weeks. This is the first documented bite by a Polemon spp. and the victim's clinical course suggests the development of local effects from venom components. The phylogenetic relationship of Polemon spp. with the burrowing asps (Atractaspis spp.) and the similarity of some of the features of this local envenoming by P. acanthias with mild/moderate envenoming by some Atractaspis spp., suggests that none of these snakes should be handled; they should be considered capable of inflicting potentially serious envenoming.