TY - JOUR
T1 - Hatching behavior of eastern long-necked turtles (Chelodina longicollis) : the influence of asynchronous environments on embryonic heart rate and phenotype
AU - McGlashan, Jessica K.
AU - Loudon, Fiona K.
AU - Thompson, Michael B.
AU - Spencer, Ricky-John
PY - 2015
Y1 - 2015
N2 - Variable temperatures within a nest cause asynchronous development within clutches of freshwater turtle embryos, yet synchronous hatching occurs and is thought to be an important survival strategy for hatchlings. Metabolic compensation and circadian rhythms in heart rates of embryonic turtles indicate the potential of communication between embryos in a nest. Heart rates were used to identify metabolic circadian rhythms in clutches of an Australian freshwater turtle (Chelodina longicollis) and determine whether embryos metabolically compensate and hatch synchronously when incubated in asynchronous environments. The effects of a group environment during incubation on egg development and incubation period were also investigated during the final 3. weeks of development. Chelodina longicollis hatch synchronously and metabolically compensate so that less advanced embryos catch up to more advanced clutch-mates. Heart rates of embryos remained stable from week 4-7 in asynchronous (M = 89. bpm) and synchronous (M = 92. bpm) groups and declined in the final 2. weeks of incubation (M = 72 and 77. bpm). Circadian rhythms were present throughout development and diel heart rates of embryos in asynchronous groups showed less deviation from the mean (M = - 0.5. bpm) than synchronous groups (M = - 4. bpm). Eggs incubated in groups had a significantly shorter incubation period than eggs incubated individually. Phenotypic traits including size, performance, and growth of all hatchlings were not affected. Egg position within a turtle nest is important for coordinating development throughout incubation and facilitating synchronous hatching.
AB - Variable temperatures within a nest cause asynchronous development within clutches of freshwater turtle embryos, yet synchronous hatching occurs and is thought to be an important survival strategy for hatchlings. Metabolic compensation and circadian rhythms in heart rates of embryonic turtles indicate the potential of communication between embryos in a nest. Heart rates were used to identify metabolic circadian rhythms in clutches of an Australian freshwater turtle (Chelodina longicollis) and determine whether embryos metabolically compensate and hatch synchronously when incubated in asynchronous environments. The effects of a group environment during incubation on egg development and incubation period were also investigated during the final 3. weeks of development. Chelodina longicollis hatch synchronously and metabolically compensate so that less advanced embryos catch up to more advanced clutch-mates. Heart rates of embryos remained stable from week 4-7 in asynchronous (M = 89. bpm) and synchronous (M = 92. bpm) groups and declined in the final 2. weeks of incubation (M = 72 and 77. bpm). Circadian rhythms were present throughout development and diel heart rates of embryos in asynchronous groups showed less deviation from the mean (M = - 0.5. bpm) than synchronous groups (M = - 4. bpm). Eggs incubated in groups had a significantly shorter incubation period than eggs incubated individually. Phenotypic traits including size, performance, and growth of all hatchlings were not affected. Egg position within a turtle nest is important for coordinating development throughout incubation and facilitating synchronous hatching.
KW - Chelodina longicollis
KW - circadian rhythms
KW - eggs
KW - heart beat
KW - synchronous hatching
KW - turtles
UR - http://handle.uws.edu.au:8081/1959.7/uws:31696
U2 - 10.1016/j.cbpa.2015.06.018
DO - 10.1016/j.cbpa.2015.06.018
M3 - Article
SN - 1095-6433
VL - 188
SP - 58
EP - 64
JO - Comparative Biochemistry and Physiology. Part A: Molecular and Integrative Physiology
JF - Comparative Biochemistry and Physiology. Part A: Molecular and Integrative Physiology
ER -