Abstract
The measurement of stable isotopes in ‘bulk’ animal and plant tissues (e.g., muscle or leaf) has become an important tool for studies of functional diversity from organismal to continental scales. In consumers, isotope values reflect their diet, trophic position, physiological state, and geographic location. However, interpretation of bulk tissue isotope values can be confounded by variation in primary producer baseline values and by overlapping values among potential food items. To resolve these issues, biologists increasingly use compound-specific isotope analysis (CSIA), in which the isotope values of monomers that constitute a macromolecule (e.g., amino acids in protein) are measured. In this review, we provide the theoretical underpinnings for CSIA, summarize its methodology and recent applications, and identify future research directions. The key principle is that some monomers are reliably routed directly from the diet into animal tissue, whereas others are biochemically transformed during assimilation. As a result, CSIA of consumer tissue simultaneously provides information about an animal’s nutrient sources (e.g., food items or contributions from gut microbes) and its physiology (e.g., nitrogen excretion mode). In combination, these data clarify many of the confounding issues in bulk analysis and enable novel precision for tracing nutrient and energy flow within and among organisms and ecosystems.
Highlights
The measurement of stable isotopes in ‘bulk’ animal and plant tissues has become an important tool for studies of functional diversity from organismal to continental scales
The key premises of isotope ecology are that: (1) carbon isotope (δ13 C) values vary among primary producers, and this variation persists in higher trophic-level consumers [2]; (2) nitrogen isotope (δ15 N) values increase systematically moving up a food chain with consumers having higher δ15 N values than their food [3,4]; and (3) hydrogen (δ2 H) and oxygen (δ18 O) isotope values of consumer tissues are influenced by local precipitation as well as food, allowing them to be used to characterize animal movement [5,6]
Other isotope systems have ecological applications, here we focus on carbon, nitrogen, and hydrogen
Summary
The measurement of the abundance of naturally-occurring stable isotopes within animal and plant tissues has proven to be a powerful and cost-effective tool for a wide range of ecological and physiological studies [1]. The most prevalent is that isotope values of primary producers at the base of the food web (i.e., baseline values) can vary across space and time, confounding interpretations of the values of organisms at higher trophic levels To account for this variation, researchers must sample potential dietary items from appropriate locations and times, after careful consideration of the turnover rates of the consumer tissue(s) being analyzed [19,20]. Animals can synthesize protein components such as non-essential amino acids (AANESS ) using carbon from dietary carbohydrates or lipids, creating differences between the δ13 C values of protein in consumer tissues and their diet items [23]. These challenging dynamics provide a wealth of potential hypotheses under which to evaluate ∆13 CC-D , we anticipate that the application of CSIA to FA will continue to expand
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