Flight performance in the altricial zebra finch: Developmental effects and reproductive consequences.

Ondi L Crino,Brett Klaassen Van Oorschot,Creagh W Breuner,Kristen E Crandell,Bret W Tobalske

doi:10.1002/ece3.2775

Ondi L Crino, Brett Klaassen Van Oorschot + Show 3 more

Open Access

https://doi.org/10.1002/ece3.2775

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Abstract

The environmental conditions animals experience during development can have sustained effects on morphology, physiology, and behavior. Exposure to elevated levels of stress hormones (glucocorticoids, GCs) during development is one such condition that can have long‐term effects on animal phenotype. Many of the phenotypic effects of GC exposure during development (developmental stress) appear negative. However, there is increasing evidence that developmental stress can induce adaptive phenotypic changes. This hypothesis can be tested by examining the effect of developmental stress on fitness‐related traits. In birds, flight performance is an ideal metric to assess the fitness consequences of developmental stress. As fledglings, mastering takeoff is crucial to avoid bodily damage and escape predation. As adults, takeoff can contribute to mating and foraging success as well as escape and, thus, can affect both reproductive success and survival. We examined the effects of developmental stress on flight performance across life‐history stages in zebra finches (Taeniopygia guttata). Specifically, we examined the effects of oral administration of corticosterone (CORT, the dominant avian glucocorticoid) during development on ground‐reaction forces and velocity during takeoff. Additionally, we tested for associations between flight performance and reproductive success in adult male zebra finches. Developmental stress had no effect on flight performance at all ages. In contrast, brood size (an unmanipulated variable) had sustained, negative effects on takeoff performance across life‐history stages with birds from small broods performing better than birds from large broods. Flight performance at 100 days posthatching predicted future reproductive success in males; the best fliers had significantly higher reproductive success. Our results demonstrate that some environmental factors experienced during development (e.g. clutch size) have stronger, more sustained effects than others (e.g. GC exposure). Additionally, our data provide the first link between flight performance and a direct measure of reproductive success.

Highlights

The developmental environment can have pervasive and sustained effects on animal phenotype and performance
We found that developmental CORT exposure had no effects on takeoff flight performance despite CORT-fed birds being smaller than control birds at 30 days posthatching
We found that developmental CORT treatment had negative effects on body size, but these effects were only present in birds at 30 days posthatching

Summary

| INTRODUCTION

The developmental environment can have pervasive and sustained effects on animal phenotype and performance. Nestling European starlings reared by mothers with decreased condition (via feather clipping) had decreased flight performance as fledglings (males only; Verspoor, Love, Rowland, Chin, & Williams, 2007) These studies demonstrate that the developmental environment can alter flight performance ability at some life-history stages. Studies that address the longitudinal effects of the early environment on phenotype have much to contribute to our understanding of the fitness consequences of the early developmental environment The goal of this experiment was to examine the effects of the postnatal developmental environment on takeoff flight performance in male and female zebra finches (Figure 1) across life-history stages.

| MATERIALS AND METHODS

Findings

| DISCUSSION