Environmental Temperatures Shape Thermal Physiology As Well As

Environmental Temperatures Shape Thermal Physiology As Well As

Environmental temperatures shape thermal physiology as well as diversification and genome-wide substitution rates in lizards Joan Garcia-Porta, Iker Irisarri, Martin Kirchner, Ariel Rodríguez, Sebastian Kirchhof, Jason L. Brown, Amy Macleod, Alexander P. Turner, Faraham Ahmadzadeh, Gonzalo Albaladejo, et al. To cite this version: Joan Garcia-Porta, Iker Irisarri, Martin Kirchner, Ariel Rodríguez, Sebastian Kirchhof, et al.. Environ- mental temperatures shape thermal physiology as well as diversification and genome-wide substitution rates in lizards. Nature Communications, Nature Publishing Group, 2019, 10.1038/s41467-019-11943- x. hal-02414507 HAL Id: hal-02414507 https://hal.archives-ouvertes.fr/hal-02414507 Submitted on 16 Dec 2019 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. ARTICLE https://doi.org/10.1038/s41467-019-11943-x OPEN Environmental temperatures shape thermal physiology as well as diversification and genome-wide substitution rates in lizards Joan Garcia-Porta et al.# Climatic conditions changing over time and space shape the evolution of organisms at multiple levels, including temperate lizards in the family Lacertidae. Here we reconstruct a 1234567890():,; dated phylogenetic tree of 262 lacertid species based on a supermatrix relying on novel phylogenomic datasets and fossil calibrations. Diversification of lacertids was accompanied by an increasing disparity among occupied bioclimatic niches, especially in the last 10 Ma, during a period of progressive global cooling. Temperate species also underwent a genome- wide slowdown in molecular substitution rates compared to tropical and desert-adapted lacertids. Evaporative water loss and preferred temperature are correlated with bioclimatic parameters, indicating physiological adaptations to climate. Tropical, but also some popu- lations of cool-adapted species experience maximum temperatures close to their preferred temperatures. We hypothesize these species-specific physiological preferences may con- stitute a handicap to prevail under rapid global warming, and contribute to explaining local lizard extinctions in cool and humid climates. Correspondence and requests for materials should be addressed to M.V. (email: [email protected]) or to K.C.W.V. (email: [email protected]). #A full list of authors and their affiliations appears at the end of the paper. NATURE COMMUNICATIONS | (2019) 10:4077 | https://doi.org/10.1038/s41467-019-11943-x | www.nature.com/naturecommunications 1 ARTICLE NATURE COMMUNICATIONS | https://doi.org/10.1038/s41467-019-11943-x he intricate relationships between biodiversity and climate We set a first goal to achieve a reliable understanding of the have intrigued scientists since the pioneering work of evolutionary relationships of lacertids, as a baseline for all further T 1 Alexander von Humboldt, over 200 years ago . Climatic macroevolutionary analyses, using phylogenomic approaches. conditions, and their change over time and space, influence Lacertids are phylogenetically divided into two major clades, the organisms at multiple levels2,3. For instance, numerous traits Gallotiinae and the Lacertinae, and the latter are divided into two originated through adaptation to climate4, present-day biotas clades: the tribe Eremiadini of mainly African-Near Eastern dis- have been shaped by paleoclimate5, and salient climate-related tribution, inhabiting warmer climates, and the tribe Lacertini of macroecological patterns such as the tropical peak of species mainly European and Asian distribution in cooler climates. richness6 apply to organisms across the entire tree of life. Despite enormous progress in lacertid systematics since the pio- Squamates (lizards, amphisbaenians, snakes), are no exception neering work of Arnold19 and colleagues, the phylogenetic rela- to this rule7, as is evident from their spectacular diversity of form tionships within Lacertidae are still incompletely resolved14,18,20. and function in tropical rainforests and overall rareness in cooler Very short phylogenetic branches at the base of the Lacertini parts of the globe. Species richness in textbook examples of suggest rapid diversification, jeopardizing phylogenetic adaptive radiations such as Anolis lizards peaks in the tropics8 inference20,21. Lacertid divergence times are controversial as well; and overall, far fewer squamates inhabit the cool areas of the for instance, estimates of the Lacertini crown age-range between globe9. Yet, lizards are different from other vertebrates in 15 and 47 Ma14,18,20,22. that their species richness is also high in arid bioclimatic zones of Secondly, we analyze how the contemporary climatic condi- Australia, Africa, and central Asia9. Lizards are typically seen as tions experienced by lacertids are related to their physiological heliotherms (i.e., gaining energy from controlled sun exposure), and genomic adaptations. These lizards in general are excellent and this active thermoregulation might have favored the evolu- thermoregulators and thus are expected to compensate behavio- tion of a number of species-rich lizard clades in seasonal and rally for suboptimal environmental temperatures23–25; they temperate biomes. also have been observed to adapt quickly to novel temperature Many species of lizards worldwide are facing decline, as a regimes26. A study of Zootoca vivipara at its northernmost probable consequence of a global temperature increase combined margin found that its preferred temperature was not available in with changes in precipitation patterns, habitat loss and frag- the habitat during much of the day, so thermoregulation (in this mentation10. Theory predicts that declines should be especially case heliothermy) would have been selectively advantageous over acute in (i) forest-dwelling tropical lizards which often live close thermoconformity despite its activity cost17,27. We expect that to the upper limit of their physiological tolerances and are ther- such heliotherms will be most successful in seasonal environ- moconformers with a low potential for behavioral thermo- ments and that this is reflected in their species richness patterns. regulation, unable to compensate for rising temperatures10,11; and Considering records of variation of thermal tolerances and pre- (ii) montane microendemics that may be driven to extinction ferences among lacertid species28, we also predict that their when upslope range shifts become impossible and competitor preferred and field active body temperatures, across species, will species move to higher elevations, or when water loss rates and most strongly be correlated with environmental solar radiation. thus physiological stress increase10,12. Understanding physiolo- At the molecular level, change can be expected to accelerate with gical constraints under which a species operates13, and the increasing temperature, and we hypothesize such increased sub- paleoclimatic history under which these constraints evolved, is stitution rates would affect the entire genome. crucial to improve our ability to predict its response to future At the macroevolutionary level, we expect that paleoclimate climatic change. acts as a strong modulator of the adaptive evolution and diver- A lizard group particularly suitable for integrative research on sification of lacertids. Given the physiological constraints limiting climate adaptation, combining paleorecords, genomics, physiol- high-temperature tolerances of animals, the process of adaptation ogy and mechanistic models, is the Old World family Lacertidae. to cold rather than heat would be expected to play a major role13. Lacertids are the most diverse and ubiquitous squamates in the We therefore predict a prevalent origin of thermal adaptations Western Palearctic14 containing around 340 species of rather during episodes of global cooling. We also predict that the cli- conserved morphology. As predominant lizards in Europe, they matic changes in the Cenozoic will have had a great impact on have become a well-studied model group in hundreds of phy- diversification rates—in particular, episodes of warming should siological, ecological and evolutionary studies, for instance have led to range fragmentation of cool-adapted species and yielding fundamental insights into evolutionary adaptation in thus have increased diversification rates via allopatric speciation. diet, morphology, and metabolism15,16. Lacertids inhabit diverse Our analysis finds that cold-adapted species have on average habitats, from rainforests to deserts, at sea level and on high smaller distribution ranges, that physiological traits and mole- mountains. Some species occur in extremely hot and xeric cular substitution rates of lacertid species are closely linked to the environments in the Namib Desert16 while one species (Zootoca climatic conditions they experience, and places the origin of these vivipara) has the largest and northernmost distribution of all thermal niche adaptations in a period of progressive global terrestrial squamates, reaching subarctic regions17,18. Because cooling. The

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