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  • 1.
    Jönsson, K. Ingemar
    Lund University.
    The evolution of life histories in holo-anhydrobiotic animals: a first approach2005In: Integrative and Comparative Biology, ISSN 1540-7063, E-ISSN 1557-7023, Vol. 45, no 5, p. 764-770Article in journal (Refereed)
    Abstract [en]

    The life histories of holo-anhydrobiotic animals differ from those of all other organisms by a regular or irregular entrance into an ametabolic state induced by desiccation. Such ametabolic periods will arrest growth and reproduction completely and thus affect primary life history parameters dramatically. The selective forces and the genetic and physiological trade-offs acting on anhydrobiotic animals are to a large extent unknown. Assuming low growth rates and low juvenile to adult survival, general theoretical models on life history responses to stress predict that anhydrobiotic animals will be selected for a high degree of iteroparity, with low fecundity, large egg size, and low total reproductive investment. A high degree of variability in growth and reproduction should create a selective force in the same direction. Although basic empirical data on life history parameters are very scarce, available observations seem to be consistent with this prediction.

  • 2.
    Sanders, Kate L.
    et al.
    School of Earth and Environmental Sciences, University of Adelaide, South Australia, Australia.
    Rasmussen, Arne R.
    The Royal Danish Academy of Fine Arts, Schools of Architecture, Design and Conservation, Copenhagen.
    Elmberg, Johan
    Kristianstad University, School of Education and Environment.
    Independent innovation in the evolution of paddle-shaped tails in viviparous sea snakes (Elapidae Hydrophiinae)2012In: Integrative and Comparative Biology, ISSN 1540-7063, E-ISSN 1557-7023, Vol. 52, no 2, p. 311-320Article in journal (Refereed)
    Abstract [en]

    The viviparous sea snakes (Hydrophiinae) comprise ∼90% of living marine reptiles and display many physical and behavioral adaptations for breathing, diving, and achieving osmotic balance in marine habitats. Among the most important innovations found in marine snakes are their paddle-shaped (dorsoventrally expanded) tails, which provide propulsive thrust in the dense aquatic medium. Here, we reconstruct the evolution of caudal paddles in viviparous sea snakes using a dated molecular phylogeny for all major lineages and computed tomography of internal osteological structures. Bayesian ancestral state reconstructions show that extremely large caudal paddles supported by elongated vertebral processes are unlikely to have been present in the most recent common ancestor of extant sea snakes. Instead, these characters appear to have been acquired independently in two highly marine lineages of relatively recent origin. Both the Aipysurus and Hydrophis lineages have elongated neural spines that support the dorsal edge of their large paddles. However, whereas in the Aipysurus lineage the ventral edge of the paddle is supported by elongated haemapophyses, this support is provided by elongated and ventrally directed pleurapophyses in the Hydrophis lineage. Three semi-marine lineages (Hydrelaps, Ephalophis, and Parahydrophis) form the sister group to the Hydrophis clade and have small paddles with poorly developed dorsal and ventral supports, consistent with their amphibious lifestyle. Overall, our results suggest that not only are the viviparous hydrophiines the only lineage of marine snakes to have acquired extremely large, skeletally supported caudal paddles but also that this innovation has occurred twice in the group in the past ∼2–6 million years.

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