Abstract
Adaptive radiations present fascinating opportunities for studying the evolutionary process. Most cases come from isolated lakes or islands, where unoccupied ecological space is filled through novel adaptations. Here, we describe an unusual example of an adaptive radiation: symbiotic mussels that colonized island-like chemosynthetic environments such as hydrothermal vents, cold seeps and sunken organic substrates on the vast deep-sea floor. Our time-calibrated molecular phylogeny suggests that the group originated and acquired sulfur-oxidizing symbionts in the Late Cretaceous, possibly while inhabiting organic substrates and long before its major radiation in the Middle Eocene to Early Oligocene. The first appearance of intracellular and methanotrophic symbionts was detected only after this major radiation. Thus, contrary to expectations, the major radiation may have not been triggered by the evolution of novel types of symbioses. We hypothesize that environmental factors, such as increased habitat availability and/or increased dispersal capabilities, sparked the radiation. Intracellular and methanotrophic symbionts were acquired in several independent lineages and marked the onset of a second wave of diversification at vents and seeps. Changes in habitat type resulted in adaptive trends in shell lengths (related to the availability of space and energy, and physiological trade-offs) and in the successive colonization of greater water depths.
Highlights
Adaptive radiation is broadly defined as the rapid diversification of species and of their adaptations to the environment in response to natural selection and ecological opportunities [1]
We describe an unusual example of an adaptive radiation: symbiotic mussels that colonized island-like chemosynthetic environments such as hydrothermal vents, cold seeps and sunken organic substrates on the vast deep-sea floor
The species tree inferred from the concatenated dataset revealed support for 10 clades, which were consistent with those observed in previous studies [9,33,34]
Summary
Adaptive radiation is broadly defined as the rapid diversification of species and of their adaptations to the environment in response to natural selection and ecological opportunities [1]. Mussels of the bivalve family Mytilidae are suitable as model organisms to study the roles of ecological opportunities, symbioses and other adaptations in the evolution of deep-sea chemosymbiotic faunas They dominate many vents and seeps, but are common in other sulfiderich habitats such as whale carcasses and sunken wood [7], which are considered to be evolutionary stepping stones to deep-sea vents [8]. In an analysis of five gene fragments, including mitochondrial and nuclear DNA, calibrated with three reliable fossils, we (i) characterized speciation rates through time; (ii) reconstructed the evolution of habitat use (environmental type and depth), body size, symbiont type (sulfur and/or methane oxidizer) and the degree of the physiological integration of the symbiont with the host (intracellular versus extracellular symbioses); and (iii) evaluated the impact of these biological and ecological factors on speciation rates, and their respective roles in the evolution of deep-sea symbiotic mussels. I. macdonaldi * I. sp Med (b) habitat: A. iwaotakii ESU C sulfur-oxidizing symbionts: organic substrates hydrothermal vent
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