, vegetation changes: 680 implications for speleothem palaeoclimate records, Earth and Planetary Science Letters, vol.681, p.369

L. Dresco-derouet, Contribution a l'e?tude de la biologie de deux Crustace?s 685 aquatiques cavernicoles: Caecosphaeroma burgundum D. et Niphargus virei Ch, vol.10, pp.321-346, 1959.

A. Eraso, Ideas sobre la climática subterránea, Estudios del grupo Espeleológico, vol.689, pp.21-41, 1962.

L. E. Escobar, A. Lira-noriega, and G. Medina-vogel, Potential for spread of the 693 white-nose fungus (Pseudogymnoascus destructans) in the Americas: use of Maxent and 694, 2014.

, NicheA to assure strict model transference, Geospatial health, vol.9, issue.1, pp.221-229

A. Faille, I. Ribera, and L. Deharveng, A molecular phylogeny shows the single origin 697 of the Pyrenean subterranean Trechini ground beetles (Coleoptera: Carabidae), 2010.

, Phylogenetics and Evolution, vol.54, pp.97-106

I. J. Fairchild, Geochemical records in Speleothems, DellaSala D and Goldstein M 701 Encyclopedia of the Anthropocene, 2017.

I. J. Fairchild and A. Baker, Speleothem science: from processes to past environments, 2012.

. Chichester,

I. J. Fairchild and S. Frisia, Definition of the Anthropocene: a view from the underworld, 2014.

C. Waters, J. Zalasiewicz, and J. M. Williams,

, Anthropocene. Geological Society Special Publication, vol.395

, as model systems for macroecological research, Journal of limnology, vol.73, issue.1

F. G. Howarth, Ecology of cave arthropods, Annual review of entomology, vol.28, issue.1, pp.365-767, 1983.

F. G. Howarth, The Zoogeography of specialized cave animals: a bioclimatic model, 1980.

, Evolution, vol.34, pp.394-406

R. B. Huey and J. G. Kingsolver, Evolution of thermal sensitivity of ectotherm 773 performance, Trends in Ecology and Evolution, vol.4, issue.5, pp.131-135, 1989.

J. Issartel, F. Hervant, and Y. Voituron, Behavioural, ventilatory and respiratory 777 responses of epigean and hypogean crustaceans to different temperatures, Comparative 778 Biochemistry and Physiology Part A: Molecular and Integrative Physiology, vol.141, issue.1, pp.1-7, 2005.

Y. Itescu, Are island-like systems biologically similar to islands? A review of the 781 evidence. Ecography, early view, 2018.

C. Juan, M. T. Guzik, and D. Jaume, Evolution in caves: Darwin's 'wrecks of ancient 784 life' in the molecular era, Molecular Ecology, vol.19, issue.18, pp.3865-3880, 2010.

, Annales de Spéléologie, vol.24, pp.75-104

V. M. Kellermann, B. Van-heerwaarden, and A. A. Hoffmann, Very low additive genetic 791 variance and evolutionary potential in multiple populations of two rainforest Drosophila 792 species, Evolution, vol.60, issue.5, pp.1104-1108, 2006.

A. J. Kowalczk and P. N. Froelich, Cave air ventilation and CO2 outgassing by radon-795 222 modeling: how fast do caves breathe, Earth and Planetary Science Letters, vol.289, issue.1-2, pp.796-209, 2010.

A. Kranjc and B. Opara, Temperature monitoring in ?kocjanske Jame Caves, Acta 799 Carsologica, vol.31, pp.85-96, 2002.

M. Krosby, C. B. Wilsey, and J. L. Mcguire, Climate-induced range overlap among 802 closely related species, Nature Climate Change, vol.5, issue.9, p.883, 2015.

. Iucn, The IUCN Red List of Threatened Species, pp.2017-2020, 2017.

J. Lamoreaux, Stygobites are more wide-ranging than troglobites, Journal of Cave 808 and Karst Studies, vol.66, pp.18-19, 2004.

V. Lencioni, P. Bernabò, and L. Latella, Cold resistance in two species of cave-dwelling 811 beetles (Coleoptera: Cholevidae), Journal of Thermal Biology, vol.35, issue.7, pp.37-42, 2010.

F. Perrier, L. Mouël, and J. L. Poirier, Long-term climate change and surface 908 versus underground temperature measurements in Paris, International Journal of 909 Climatology, vol.25, pp.1619-1631, 2005.

T. Pipan, N. Holt, and D. C. Culver, How to protect a diverse, poorly known, inaccessible 912 fauna: identification of source and sink habitats in the epikarst, Aquatic Conservation, p.913, 2010.

, Marine and Freshwater Ecosystems, vol.20, pp.748-755

T. Pipan, H. López, and P. Oromí, Temperature variation and the presence of 916 troglobionts in terrestrial shallow subterranean habitats, Journal of Natural History, vol.45, issue.3-4, pp.917-253, 2011.

T. Pipan, M. Petri?, and S. ?ebela, Analyzing climate change and surface-subsurface 920 interactions using the Postojna Planina Cave System (Slovenia) as a model system, 2018.

,

T. L. Poulson and W. B. White, The cave environment, Science, vol.165, pp.971-981, 1969.

L. Prendini, F. Of, and V. Vignoli, Troglomorphism, trichobothriotaxy and 927 typhlochactid phylogeny (Scorpiones, Chactoidea): more evidence that troglobitism is not 928 an evolutionary dead end, Cladistics, vol.25, pp.1-24, 2009.

M. Protas and W. R. Jeffery, Evolution and development in cave animals: from fish to 931 crustaceans, 933 environment as a model system in ecological, biogeographical and evolutionary research, vol.1, 2012.

, Subterranean Biology, vol.25, pp.1-7

D. Sánchez-fernández, V. Rizzo, and A. Cieslak, Thermal niche estimators and the 967 capability of poor dispersal species to cope with climate change, Scientific Reports, vol.6, p.23381, 2016.

B. D. Santer, M. F. Wehner, and T. Wigley, Contributions of anthropogenic and 971 natural forcing to recent tropopause height changes, Science, vol.301, issue.5632, 2003.

M. Scholze, W. Knorr, and N. W. Arnell, A climate-change risk analysis for world 975 ecosystems, Proceedings of the National Academy of Sciences, vol.103, issue.35, 2006.

S. ?ebela and J. Turk, Local characteristics of Postojna Cave climate, air 979 temperature, and pressure monitoring, Theoretical and Applied Climatology, vol.105, pp.371-386, 2011.

S. ?ebela, J. Turk, and T. Pipan, Cave micro-climate and tourism: towards 200 years 983 (1819-2015) at Postojnska jama (Slovenia), Cave and Karst Science, vol.42, issue.2, pp.78-85, 2015.

S. S. Shu, W. S. Jiang, and T. Whitten, Drought and China's cave species, Science, vol.986, issue.6130, p.272, 2013.

M. H. Simões, M. Souza-silva, and R. L. Ferreira, Cave physical attributes influencing 989 the structure of terrestrial invertebrate communities in Neotropics, Subterranean Biology, vol.990, pp.103-121, 2015.

M. Souza-silva, P. Mr, and L. R. Ferreira, Trophic dynamics in a neotropical 996 limestone cave, Subterranean Biology, vol.9, pp.127-138, 2011.

D. B. Stern, J. Breinholt, and C. Pedraza-lara, Phylogenetic evidence from 999 freshwater crayfishes that cave adaptation is not an evolutionary dead-end, Evolution, vol.1000, issue.10, pp.2522-2532, 2017.

R. G. Taylor, B. Scanlon, and P. Döll, Ground water and climate change, Nature, 1003.

, Climate Change, vol.3, pp.322-329

C. D. Thomas, A. Cameron, and R. E. Green, Extinction risk from climate change, 2004.

, Nature, vol.427, issue.6970, pp.145-148

B. W. Tobin, B. T. Hutchins, and B. F. Schwartz, Spatial and temporal changes in 1009 invertebrate assemblage structure from the entrance to deep-cave zone of a temperate 1010 marble cave, International Journal of Speleology, vol.42, issue.3, pp.203-214, 2013.

E. Trajano, M. R. Carvalho, and . De, Towards a biologically meaningful classification of 1014 subterranean organisms: a critical analysis of the Schiner-Racovitza system from a 1015 historical perspective, difficulties of its application and implications for conservation, 2017.

, Subterranean Biology, vol.22, pp.1-26

E. Trajano, S. Secutti, and M. E. Bichuette, Population decline in a Brazilian cave 1019 catfish, Trichomycterus itacarambiensis Trajano and Pinna, 1986 (Siluriformes): reduced 1020 flashflood as a probable cause, Speleobiology Notes, vol.1, issue.3, pp.859-869, 2009.

M. E. Visser, Keeping up with a warming world; assessing the rate of adaptation to 1031 climate change, Proceedings of the Royal Society of London B: Biological Sciences, vol.1032, pp.649-659, 1635.

Y. Voituron, D. Fraipont, M. Issartel, and J. , Extreme lifespan of the human fish 1035 (Proteus anguinus): a challenge for ageing mechanisms, Biology letters, vol.7, pp.105-107, 1036.

G. R. Walther, E. Post, and P. Convey, Ecological responses to recent climate 1039 change, Nature, vol.416, issue.6879, pp.389-395, 2002.

B. H. Warren, D. Simberloff, and R. E. Ricklefs, Islands as model systems in ecology 1042 and evolution: prospects fifty years after MacArthur-Wilson, Ecology Letters, vol.18, issue.2, pp.200-1043, 2015.

C. N. Waters, J. Zalasiewicz, and C. Summerhayes, Global Boundary Stratotype 1046 Section and Point (GSSP) for the Anthropocene Series: Where and how to look for 1047 potential candidates, Earth-Science Reviews, vol.178, pp.379-429, 1048.

R. J. Whittaker, J. M. Fernández-palacios, and T. J. Matthews, Island biogeography: 1051 Taking the long view of nature's laboratories, Science, vol.357, issue.6354, 2017.

T. Wigley and M. C. Brown, Geophysical applications of heat and mass transfer in 1055 turbulent pipe flow, Boundary-Layer Meteorology, vol.1, pp.300-320, 1971.

F. M. Wilhelm, T. Sj, and G. L. Adams, Comparison of routine metabolic rates of the 1061 stygobite, Gammarus acherondytes (Amphipoda: Gammaridae) and the stygophile, p.1062, 2006.

, Gammarus troglophilus. Freshwater Biology, vol.51, issue.6, pp.1162-1174

J. W. Williams and J. St, Novel climates, no-analog communities, and 1066 ecological surprises, Frontiers in Ecology and the Environment, vol.5, issue.9, pp.475-482, 1067.

M. Williams, J. Zalasiewicz, and P. K. Haff, The anthropocene biosphere. The 1070, 2015.

, Anthropocene Review, vol.2, issue.3, pp.196-219

S. E. Williams, L. P. Shoo, and J. L. Isaac, Towards an integrated framework for 1073 assessing the vulnerability of species to climate change, PLoS biology, vol.6, issue.12, 2008.

E. M. Wolkovich, B. I. Cook, and J. M. Allen, Warming experiments underpredict plant 1077 phenological responses to climate change, Nature, vol.485, issue.7399, pp.494-497, 1078.

J. J. Wynne, E. C. Bernard, and F. G. Howarth, Disturbance relicts in a rapidly changing 1081 world: the Rapa Nui (Easter Island) factor, BioScience, vol.64, issue.8, pp.711-718, 1082.

E. Xoplaki, J. F. González-rouco, and J. Luterbacher, Influences of winter climatic conditions on the 1089 relation between annual mean soil and air temperatures from central to northern Japan, Climate Dynamics Yazaki T, 2004.

, Cold Regions Science and Technology, vol.85, pp.217-224, 1091.