[1].Effects of Dietary Protein Variations at Different Life-stages on Vocal Dominance of the African Clawed Frogs[J].Asian Herpetological Research,2020,11(3):249-256.[doi:10.16373/j.cnki.ahr.200003]
 Yan CAO,Jiangyan SHEN,Xiaocui WANG,et al.Effects of Dietary Protein Variations at Different Life-stages on Vocal Dominance of the African Clawed Frogs[J].Asian Herpetological Research(AHR),2020,11(3):249-256.[doi:10.16373/j.cnki.ahr.200003]
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Effects of Dietary Protein Variations at Different Life-stages on Vocal Dominance of the African Clawed Frogs()
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Asian Herpetological Research[ISSN:2095-0357/CN:51-1735/Q]

卷:
11
期数:
2020年3期
页码:
249-256
栏目:
出版日期:
2020-09-25

文章信息/Info

Title:
Effects of Dietary Protein Variations at Different Life-stages on Vocal Dominance of the African Clawed Frogs
文章编号:
AHR-2020-0003
Author(s):
Yan CAO123 Jiangyan SHEN13 Xiaocui WANG13 Song TAN13 Ping LI13 Jianghong RAN2 Yezhong TANG1* and Jingfeng CHEN1*
1 Thematic Area of Biodiversity and Ecosystem Services, Chengdu Institute of Biology, Chinese Academy of Sciences, Chengdu 610041, Sichuan, China
2 Key Laboratory of Bio-Resources and Eco-Environment of Ministry of Education, College of Life Sciences, Sichuan University, Chengdu 610041, Sichuan, China
3 University of the Chinese Academy of Sciences, Beijing 100049, China
Keywords:
aggression developmental effects environmental-matching silver spoon social status vocal competition Xenopus laevis
DOI:
10.16373/j.cnki.ahr.200003
Abstract:
How nutritional conditions during early development affect an organism’s phenotype at adulthood is still poorly understood despite a plethora of research on developmental plasticity. The “environmental matching” hypothesis predicts that individuals will have high fitness providing that their adult environment “matches” what they experienced during development. In contrast, the “silver spoon” hypothesis predicts that individuals who obtain better developmental resources will be generally superior. Here we tested these two hypotheses and examined the underlying hormonal mechanisms by manipulating the early dietary protein content of African clawed frogs (Xenopus laevis) for a year with a 2×2 factorial experimental design. We found that only a low-protein food during development enhanced the vocal competition ability of male X. laevis, and that vocal dominance was associated with higher cortisol levels but not related with testosterone content. These results were not congruent with the “environmental matching” hypothesis or with the “silver spoon” hypothesis, suggesting the behavioral plasticity during development is more complex than our expectation in amphibians.

参考文献/References:

Archie E. A., Altmann J., Alberts S. C. 2012. Social status predicts wound healing in wild baboons. P Natl Acad Sci USA, 109: 9017–9022
Barrett E. L. B., Hunt J., Moore A. J., Moore P. J. 2009. Separate and combined effects of nutrition during juvenile and sexual development on female life-history trajectories: The thrifty phenotype in a cockroach. P Roy Soc B–Biol Sci, 276: 3257–3264
Beaulieu M., Mboumba S., Willaume E., Kappeler P. M., Charpentier M. J. E. 2014. The oxidative cost of unstable social dominance. J Exp Biol, 217: 2629–2632
Briffa M., Sneddon L. U. 2007. Physiological constraints on contest behaviour. Funct Ecol, 21: 627–637
Butler M. W., McGraw K. J. 2012. Differential effects of early- and late-life access to carotenoids on adult immune function and ornamentation in mallard ducks (Anas platyrhynchos). PloS One, 7: e38043
Creel S. F. 2005. Dominance, aggression, and glucocorticoid levels in social carnivores. J Mammal, 86: 255–264
Desai M., Crowther N. J., Ozanne S. E., Lucas A., Hales C. N. 1995. Adult glucose and lipid-metabolism may be programmed during fetal life. Biochem Soc T, 23: 331–335
Dmitriew C., Rowe L. 2011. The effects of larval nutrition on reproductive performance in a food-limited adult environment. PloS One, 6: e17399
Dodman N. H., Reisner I., Shuster L., Rand W., Luescher U. A., Robinson I. 1996. Effect of dietary protein content on behavior in dogs. J Am Vet Med Assoc, 208: 376–379
Firth D. 2005. Bradley-Terry models in R. J Stat Softw, 12: 1–12
Gluckman P. D., Hanson M. A., Spencer H. G. 2005. Predictive adaptive responses and human evolution. Trends Ecol Evol, 20: 527–533
Habig B., Doellman M. M., Woods K., Olansen J., Archie E. A. 2018. Social status and parasitism in male and female vertebrates: A meta-analysis. Sci Rep, 8(1): 3629
Han C. S., Dingemanse N. J. 2017. You are what you eat: Diet shapes body composition, personality and behavioural stability. Bmc Evol Biol, 17(1): 8
Hopwood P. E., Moore A. J., Royle N. J. 2014. Effects of resource variation during early life and adult social environment on contest outcomes in burying beetles: A context-dependent silver spoon strategy? P Roy Soc B–Biol Sci, 281: 20133102
Huntingford F. A., Taylor A. C., Smith I. P., Thorpe K. E. 1995. Behavioural and physiological studies of aggression in swimming crabs. J Exp Mar Biol Ecol, 193: 21–39
Johnstone R. A. 1995. Sexual selection, honest advertisement and the handicap principle – Reviewing the evidence. Biol Rev, 70: 1–65
Joshi A. M., Narayan E. J., Gramapurohit N. P. 2019. Vocalisation and its association with androgens and corticosterone in a night frog (Nyctibatrachus humayuni) with unique breeding behaviour. Ethology, 125: 774–784
Kay A. D., Zumbusch T., Heinen J. L., Marsh T. C., Holway D. A. 2010. Nutrition and interference competition have interactive effects on the behavior and performance of Argentine ants. Ecology, 91: 57–64
Kelly P. W., Pfennig D. W., Buzon S. D., Pfennig K. S. 2019. Male sexual signal predicts phenotypic plasticity in offspring: Implications for the evolution of plasticity and local adaptation. Philos T R Soc B, 374: 20180179
Konarzewski M., Diamond J. 1995. Evolution of basal metabolic rate and organ masses in laboratory mice. Evolution, 49: 1239–1248
Lindstrom J. 1999. Early development and fitness in birds and mammals. Trends Ecol Evol, 14: 343–348
Lindstrom J., Pike T. W., Blount J. D., Metcalfe N. B. 2009. Optimization of resource allocation can explain the temporal dynamics and honesty of sexual signals. Am Nat, 174: 515–525
Liu J. H., Raine A. 2006. The effect of childhood malnutrition on externalizing behavior. Curr Opin Pediatr, 18: 565–570
Martins F. M. S., Oom M. D., Rebelo R., Rosa G. M. 2013. Differential effects of dietary protein on early life-history and morphological traits in natterjack toad (Epidalea calamita) tadpoles reared in captivity. Zoo Biol, 32: 457–462
Mathot K. J., Dingemanse N. J. 2015. Energetics and behavior: Unrequited needs and new directions. Trends Ecol Evol, 30: 199–206
McInerney E. P., Silla A. J., Byrne P. G. 2016. The influence of carotenoid supplementation at different life-stages on the foraging performance of the southern corroboree frog (Pseudophryne corroboree): A test of the silver spoon and environmental matching hypotheses. Behav Process, 125: 26–33
Monaghan P. 2008. Early growth conditions, phenotypic development and environmental change. Philos T R Soc B, 363: 1635–1645
Moore F. L., Boyd S. K., Kelley D. B. 2005. Historical perspective: Hormonal regulation of behaviors in amphibians. Horm Behav, 48: 373–383
Nowicki S., Searcy W. A., Peters S. 2002. Brain development, song learning and mate choice in birds: A review and experimental test of the "nutritional stress hypothesis". J Comp Physiol A, 188: 1003–1014
Pillay N., Rimbach R., Rymer T. 2016. Pre- and postnatal dietary protein deficiency influences anxiety, memory and social behaviour in the African striped mouse Rhabdomys dilectus chakae. Physiol Behav, 161: 38–46
Pottinger T. G., Carrick T. R. 2001. Stress responsiveness affects dominant-subordinate relationships in rainbow trout. Horm Behav, 40: 419–427
Rhodes H. J., Stevenson R. J., Ego C. L. 2014. Male-male clasping may be part of an alternative reproductive tactic in Xenopus laevis. PloS One, 9: e97761
Royaute R., Garrison C., Dalos J., Berdal M. A., Dochtermann N. A. 2019. Current energy state interacts with the developmental environment to influence behavioural plasticity. Anim Behav, 148: 39–51
Saastamoinen M., van der Sterren D., Vastenhout N., Zwaan B. J., Brakefield P. M. 2010. Predictive adaptive responses: condition-dependent impact of adult nutrition and flight in the tropical butterfly Bicyclus anynana. Am Nat, 176: 686–698
Silla A. J., McInerney E. P., Byrne P. G. 2016. Dietary carotenoid supplementation improves the escape performance of the southern corroboree frog. Anim Behav, 112: 213–220
Simon N. G., Kaplan J. R., Hu S., Register T. C., Adams M. R. 2004. Increased aggressive behavior and decreased affiliative behavior in adult male monkeys after long-term consumption of diets rich in soy protein and isoflavones. Horm Behav, 45: 278–284
Speakman J. R., McQueenie J. 1996. Limits to sustained metabolic rate: The link between food intake, basal metabolic rate, and morphology in reproducing mice, Mus musculus. Physiol Zool, 69: 746–769
Stuart-Fox D. M., Firth D., Moussalli A., Whiting M. J. 2006. Multiple signals in chameleon contests: designing and analysing animal contests as a tournament. Anim Behav, 71: 1263–1271
Taborsky B. 2006. The influence of juvenile and adult environments on life-history trajectories. P Roy Soc B–Biol Sci, 273: 741–750
Tinsley R. C., Kobel H. R. 1996. The biology of Xenopus. Oxford University Press, Oxford, New York
Tobias M. L., Barnard C., O’Hagan R., Horng S. H., Rand M., Kelley D. B. 2004. Vocal communication between male Xenopus laevis. Anim Behav, 67: 353–365
Tobias M. L., Corke A., Korsh J., Yin D., Kelley D. B. 2010. Vocal competition in male Xenopus laevis frogs. Behav Ecol Sociobiol, 64: 1791–1803.
Tobias M. L., Korsh J., Kelley D. B. 2014. Evolution of male and female release calls in African clawed frogs. Behaviour, 151: 1313–1334.
Tobias M. L., Viswanathan S. S., Kelley D. B. 1998. Rapping, a female receptive call, initiates male-female duets in the South African clawed frog. P Natl Acad Sci USA, 95: 1870–1875
Van de Pol M., Bruinzeel L. W., Heg D., Van der Jeugd H. P., Verhulst S. 2006. A silver spoon for a golden future: Long-term effects of natal origin on fitness prospects of oystercatchers (Haematopus ostralegus). J Anim Ecol, 75: 616–626
Venesky M. D., Wilcoxen T. E., Rensel M. A., Rollins-Smith L., Kerby J. L., Parris M. J. 2012. Dietary protein restriction impairs growth, immunity, and disease resistance in southern leopard frog tadpoles. Oecologia, 169: 23–31
Wells J. C. K. 2006. Is early development in humans a predictive adaptive response anticipating the adult environment? Trends Ecol Evol, 21: 424–425
Wells J. C. K. 2007. The thrifty phenotype as an adaptive maternal effect. Biol Rev, 82: 143–172
West-Eberhard M. J. 2003. Phenotypic accommodation: Adaptive innovation due to developmental plasticity, with or without genetic change. Integr Comp Biol, 43: 970
Wilson A. D. M., Whattam E. M., Bennett R., Visanuvimol L., Lauzon C., Bertram S. M. 2010. Behavioral correlations across activity, mating, exploration, aggression, and antipredator contexts in the European house cricket, Acheta domesticus. Behav Ecol Sociobiol, 64: 703–715
Xu F., Cui J. G., Song J., Brauth S. E., Tang Y. Z. 2012. Male competition strategies change when information concerning female receptivity is available. Behav Ecol, 23: 307–312

更新日期/Last Update: 2020-09-25