Inferring Extinct Reptilian Response To Global Warming: Insights From Modern Stable Isotope Ratios

Riegler, Mitchell Scott

04 June 2018

Lizard ecology through time is largely unknown. Understanding ecology is important because of today’s drastic climate change, but this is not a unique event. Early Cenozoic hyperthermals were comparable to the perturbations currently experienced by living species. Understanding ecology through time must acknowledge the dynamic relationship between an organism and its environment on multiple scales. Ecological inferences can be based on form equaling function, correlating certain features (e.g. leaf-shaped dentition) with certain behaviors (e.g. herbivorous diet). Though this applies to specific taxa, there are confounding examples. Ecology can also be inferred through indirect means, but these are disconnected from the taxon of interest. Stable isotope geochemistry, however, provides an independent test. I analyzed stable isotope ratios (δ¹⁸O, δ¹³C) from enamel, providing new data on the connection between morphology, diet, and environment. I find a trophic separation in δ¹³C, and indications of aridity through δ¹⁸O. I applied this framework to extinct lizards from an Early Eocene (Wa4) assemblage, a key time between two major global warming events (Paleocene-Eocene Thermal Maximum and Early Eocene Climatic Optimum). I identify xenosaurid and glyptosaurine squamates and alethinophidian snakes. The xenosaurid is one of the youngest representatives of Restes rugosus, and I provide the first testable hypothesis of its ecology. These δ¹⁸O values corroborate hypotheses of a wet, tropical environment, and the δ¹³C values indicate an insectivorous or carnivorous diet for both taxa. My study provides an independent test of ecology of both extant and fossil lizards, with implications for differing survivorship throughout the early Cenozoic. / MS / We know little about the diet and habitat of lizards. We have a limited knowledge of these characteristics in living species, but these represents a fraction of the total number of all lizard species that have ever lived. There are several ways to try to understand the ecology of an animal. We can observe it directly, we can infer things about it from comparisons to other living species, or we can make inferences through indirect proxies. All of these methods have their limitations, however. I am interested in how lizard ecology changes through geologic time as preserved in the fossil record. This requires understanding the ecology of extinct lizards. For my thesis, I quantified ecology using stable isotope ratios in both living and extinct lizard species. Through my analyses, I was able to differentiate their diets and habitats. My examination of lizard fossils from ~54 million years ago identifies two lizards and one snake, and analyses of the fossil lizards indicate they were carnivorous or insectivorous and lived in a tropical climate. These stable isotope analyses not only have the potential to infer diet and habitat, but also track illegal pet trade and determine if an organism is warm or cold blooded.

lizards

stable isotopes

Anguimorpha

ecology

Systematics of Platynotan Lizards

Barr, Braden N.

Unknown Date

No description available.

Platynota

Anguimorpha

Systematics

Phylogeny

Morphology

Necrosauridae