Exploring the isotopic niche: isotopic variance, physiological incorporation, and the temporal dynamics of foraging

TL;DR

This paper develops a mechanistic framework linking ecological and physiological processes to isotopic niche dynamics, revealing how diet, specialization, and temporal changes influence isotopic variance in consumers.

Contribution

It introduces a novel analytical model connecting ecological mechanisms to isotopic niche variation, accounting for diet dynamics and prey mixing space geometry.

Findings

Moderate prey specialization maximizes isotopic niche width.

Dietary transitions cause peaks in isotopic variance.

The framework explains complex isotopic data in ecological studies.

Abstract

Consumer foraging behaviors are dynamic, changing in response to prey availability, seasonality, competition, and even the consumer's physiological state. The isotopic composition of a consumer is a product of these factors as well as the isotopic 'landscape' of its prey, i.e. the isotopic mixing space. Here we build a mechanistic framework that links the ecological and physiological processes of an individual consumer to the isotopic distribution that describes its diet, and ultimately to the isotopic composition of its own tissues, defined as its 'isotopic niche'. By coupling these processes, we systematically investigate under what conditions the isotopic niche of a consumer changes as a function of both the geometric properties of its mixing space and foraging strategies that may be static or dynamic over time. Results of our derivations reveal general insight into the conditions impacting isotopic niche width as a function of consumer specialization on prey, as well as the consumer's ability to transition between diets over time. We show analytically that moderate specialization on isotopically unique prey can serve to maximize a consumer's isotopic niche width, while temporally dynamic diets will tend to result in peak isotopic variance during dietary transitions. We demonstrate the relevance of our theoretical findings by examining a marine system composed of nine invertebrate species commonly consumed by sea otters. In general, our analytical framework highlights the complex interplay of mixing space geometry and consumer dietary behavior in driving expansion and contraction of the isotopic niche. Because this approach is established on ecological mechanism, it is well-suited for enhancing the ecological interpretation, and uncovering the root causes, of observed isotopic data.