Physiological, Morphological and Behavioural Responses of Self-Feeding Precocial Chicks Copying with Contrasting Levels of Water Salinity during Development.

Afonso R Rocha,Juan M Sánchez-Guzmán,José A Masero,Rita Silva,Jaime A Ramos,Auxiliadora Villegas

doi:10.1371/journal.pone.0165364

Afonso R Rocha, Juan M Sánchez-Guzmán + Show 4 more

Open Access

https://doi.org/10.1371/journal.pone.0165364

Copy DOI

Journal: PloS one	Publication Date: Oct 27, 2016
Citations: 7	License type: CC BY 4.0

Affiliation: University of Extremadura, University of Coimbra

Abstract

Combined physiological and behavioural responses to salt loads during development have rarely been studied in air-breathing vertebrates able to inhabit hypersaline habitats, but they may be of particular importance in understanding, for example, the differences among species in patterns of habitat use or ontogenetic diet switches. Here, we compared the physiological and behavioural responses of self-feeding precocial chicks developed in contrasting levels of water salinity. The model species was the Black-winged Stilt (Himantopus himantopus) a precocial shorebird that breeds in a range of habitats from freshwater to hypersaline wetlands. Specifically, we compared resting metabolic rate (RMR), heat shock proteins (Hsp70), plasma ions, hematocrit, body mass, body size, growth rate and head-shaking behaviour of captive-reared Black-winged Stilt fledglings developed under fresh (0 ‰), saline (20 ‰), and hypersaline (60 ‰) water. Contrary to expectations, none of the physiological and morphological variables measured differed significantly among treatments. Likewise, the RMR of wild and captive-reared fledglings was similar. Surprisingly, the saltgland mass of wild fledglings from freshwater and those from hypersaline habitats was also similar. However, head-shaking, a behavioural response associated to minimize salt intake and to expel the secretions of salt glands, differed according to salinity source: head-shaking rate increased with increasing salinity. The results of this study support the key role of behavioural osmoregulation in avoiding salt stress during development.

Highlights

Salinity is a crucial environmental factor affecting physiological performance in organisms, and represents one of the main natural sources of stress shaping the biodiversity of ecosystems [1]
Shorebirds inhabiting hypersaline habitats rely on hypoosmotic prey such as brine shrimp and diptera larvae and adults, whose body water content is about 78–87% of body mass [11]
This study supports that chicks reared at 20 or 60 ‰ salinity did not face major osmoregulatory costs, based on the fact that there were no significant differences in resting metabolic rate (RMR), growth rate, body size, and body mass among the salinity treatments

Summary

Introduction

Salinity is a crucial environmental factor affecting physiological performance in organisms, and represents one of the main natural sources of stress shaping the biodiversity of ecosystems [1]. During their seasonal movements, billions of vertebrates as diverse as fishes, birds, reptiles, marine mammals and amphibians are subjected to large changes in the salinity of their. Responses to Salinity during Growth of Self-Feeding Precocial Chicks

Methods

Results

Conclusion