Your search keyword '"Sun SJ"' showing total 8 results

1. Selection on the joint actions of pairs leads to divergent adaptation and coadaptation of care-giving parents during pre-hatching care.

Author

Jarrett BJM, Mashoodh R, Issar S, Pascoal S, Rebar D, Sun SJ, Schrader M, and Kilner RM

Subjects

Animals, Male, Female, Selection, Genetic, Social Behavior, Biological Evolution, Maternal Behavior, Paternal Behavior, Coleoptera physiology, Nesting Behavior

Abstract

The joint actions of animals in partnerships or social groups evolve under both natural selection from the wider environment and social selection imposed by other members of the pair or group. We used experimental evolution to investigate how jointly expressed actions evolve upon exposure to a new environmental challenge. Our work focused on the evolution of carrion nest preparation by pairs of burying beetles Nicrophorus vespilloides , a joint activity undertaken by the pair but typically led by the male. In previous work, we found that carrion nest preparation evolved to be faster in experimental populations without post-hatching care (No Care: NC lines) than with post-hatching care (Full Care: FC lines). Here, we investigate how this joint activity evolved. After 15 generations of experimental evolution, we created heterotypic pairs (NC females with FC males and NC males with FC females) and compared their carrion nest making with homotypic NC and FC pairs. We found that pairs with NC males prepared the nest more rapidly than pairs with FC males, regardless of the female's line of origin. We discuss how social coadaptations within pairs or groups could act as a post-mating barrier to gene flow.

Published

2024

2. Biomechanical adaptations enable phoretic mite species to occupy distinct spatial niches on host burying beetles.

Author

Sun SJ, Chen S, Federle W, and Kilner RM

Subjects

Animals, Reproduction, Mites, Coleoptera

Abstract

Niche theory predicts that ecologically similar species coexist by minimizing interspecific competition through niche partitioning. Therefore, understanding the mechanisms of niche partitioning is essential for predicting interactions and coexistence between competing organisms. Here, we study two phoretic mite species, Poecilochirus carabi and Macrocheles nataliae that coexist on the same host burying beetle Nicrophorus vespilloides and use it to 'hitchhike' between reproductive sites. Field observations revealed clear spatial partitioning between species in distinct host body parts. Poecilochirus carabi preferred the ventral side of the thorax, whereas M. nataliae were exclusively found ventrally at the hairy base of the abdomen. Experimental manipulations of mite density showed that each species preferred these body parts, largely regardless of the density of the other mite species on the host beetle. Force measurements indicated that this spatial distribution is mediated by biomechanical adaptations, because each mite species required more force to be removed from their preferred location on the beetle. While P. carabi attached with large adhesive pads to the smooth thorax cuticle, M. nataliae gripped abdominal setae with their chelicerae. Our results show that specialist biomechanical adaptations for attachment can mediate spatial niche partitioning among species sharing the same host.

Published

2024

3. Digest: Deprivation of parental care reveals the value of sibling cooperation in burying beetles.

Author

Sun SJ and Narayan VP

Subjects

Animals, Behavior, Animal, Humans, Larva, Social Behavior, Coleoptera genetics, Siblings

Abstract

What conditions favor cooperation in sibling interactions? In burying beetles of the genus Nicrophorus, Prang et al. found that dependence on parental care cannot solely explain the degree of offspring cooperation. While only larvae of independent species cooperated when receiving pre-hatching care, both independent and dependent species cooperated in the absence of pre-hatching care. This finding suggests that offspring cooperation has persisted from an early ancestor of the genus Nicrophorus to the present species, highlighting the evolution from facultative to obligatory social behavior., (© 2022 The Authors. Evolution published by Wiley Periodicals LLC on behalf of The Society for the Study of Evolution.)

Published

2022

4. Digest: Nature and nurture: Influences of parental care and rearing environment on phenotypic plasticity in Nicrophorus vespilloides.

Author

Sun SJ, Narayan VP, Wang Y, and Wasana N

Subjects

Adaptation, Physiological, Animals, Larva, Coleoptera

Abstract

What conditions favor niche expansion in nature? In the burying beetle Nicrophorus vespilloides, Schrader et al. found that larvae reared with parental care on larger carcasses were better equipped for resource use than individuals reared without parental care on smaller carcasses. This finding illustrates that developmental plasticity induced by parental care and carcass size has the potential to influence adaptive diversification., (© 2022 The Authors. Evolution © 2022 The Society for the Study of Evolution.)

Published

2022

5. Antagonistic effects of intraspecific cooperation and interspecific competition on thermal performance.

Author

Tsai HY, Rubenstein DR, Chen BF, Liu M, Chan SF, Chen DP, Sun SJ, Yuan TN, and Shen SF

Subjects

Animals, Calliphoridae physiology, Competitive Behavior, Ecology, Ecosystem, Female, Male, Reproduction, Behavior, Animal physiology, Climate Change, Coleoptera physiology, Temperature

Abstract

Understanding how climate-mediated biotic interactions shape thermal niche width is critical in an era of global change. Yet, most previous work on thermal niches has ignored detailed mechanistic information about the relationship between temperature and organismal performance, which can be described by a thermal performance curve. Here, we develop a model that predicts the width of thermal performance curves will be narrower in the presence of interspecific competitors, causing a species' optimal breeding temperature to diverge from that of its competitor. We test this prediction in the Asian burying beetle Nicrophorus nepalensis , confirming that the divergence in actual and optimal breeding temperatures is the result of competition with their primary competitor, blowflies. However, we further show that intraspecific cooperation enables beetles to outcompete blowflies by recovering their optimal breeding temperature. Ultimately, linking abiotic factors and biotic interactions on niche width will be critical for understanding species-specific responses to climate change., Competing Interests: HT, DR, BC, ML, SC, DC, SS, TY, SS No competing interests declared, (© 2020, Tsai et al.)

Published

2020

6. Temperature stress induces mites to help their carrion beetle hosts by eliminating rival blowflies.

Author

Sun SJ and Kilner RM

Subjects

Animals, Cadaver, Calliphoridae growth & development, Coleoptera growth & development, Larva growth & development, Larva physiology, Mites growth & development, Nymph growth & development, Nymph physiology, Ovum physiology, Population Density, Stress, Physiological, Calliphoridae physiology, Coleoptera physiology, Mites physiology, Symbiosis, Temperature

Abstract

Ecological conditions are known to change the expression of mutualisms though the causal agents driving such changes remain poorly understood. Here we show that temperature stress modulates the harm threatened by a common enemy, and thereby induces a phoretic mite to become a protective mutualist. Our experiments focus on the interactions between the burying beetle Nicrophorus vespilloides , an associated mite species Poecilochirus carabi and their common enemy, blowflies, when all three species reproduce on the same small vertebrate carrion. We show that mites compete with beetle larvae for food in the absence of blowflies, and reduce beetle reproductive success. However, when blowflies breed on the carrion too, mites enhance beetle reproductive success by eating blowfly eggs. High densities of mites are especially effective at promoting beetle reproductive success at higher and lower natural ranges in temperature, when blowfly larvae are more potent rivals for the limited resources on the carcass., Competing Interests: SS, RK No competing interests declared, (© 2020, Sun and Kilner.)

Published

2020

7. A chemically triggered transition from conflict to cooperation in burying beetles.

Author

Chen BF, Liu M, Rubenstein DR, Sun SJ, Liu JN, Lin YH, and Shen SF

Subjects

Animals, Breeding, Larva, Social Behavior, Coleoptera

Abstract

Although interspecific competition has long been recognised as a major driver of trait divergence and adaptive evolution, relatively little effort has focused on how it influences the evolution of intraspecific cooperation. Here we identify the mechanism by which the perceived pressure of interspecific competition influences the transition from intraspecific conflict to cooperation in a facultative cooperatively breeding species, the Asian burying beetle Nicrophorus nepalensis. We not only found that beetles are more cooperative at carcasses when blowfly maggots have begun to digest the tissue, but that this social cooperation appears to be triggered by a single chemical cue - dimethyl disulfide (DMDS) - emitted from carcasses consumed by blowflies, but not from control carcasses lacking blowflies. Our results provide experimental evidence that interspecific competition promotes the transition from intraspecific conflict to cooperation in N. nepalensis via a surprisingly simple social chemical cue that is a reliable indicator of resource competition between species., (© 2020 John Wiley & Sons Ltd/CNRS.)

Published

2020

8. Climate-mediated cooperation promotes niche expansion in burying beetles.

Author

Sun SJ, Rubenstein DR, Chen BF, Chan SF, Liu JN, Liu M, Hwang W, Yang PS, and Shen SF

Subjects

Animals, Climate Change, Competitive Behavior, Cooperative Behavior, Environment, Linear Models, Multivariate Analysis, Reproduction, Taiwan, Temperature, Coleoptera metabolism, Coleoptera physiology, Social Behavior

Abstract

The ability to form cooperative societies may explain why humans and social insects have come to dominate the earth. Here we examine the ecological consequences of cooperation by quantifying the fitness of cooperative (large groups) and non-cooperative (small groups) phenotypes in burying beetles (Nicrophorus nepalensis) along an elevational and temperature gradient. We experimentally created large and small groups along the gradient and manipulated interspecific competition with flies by heating carcasses. We show that cooperative groups performed as thermal generalists with similarly high breeding success at all temperatures and elevations, whereas non-cooperative groups performed as thermal specialists with higher breeding success only at intermediate temperatures and elevations. Studying the ecological consequences of cooperation may not only help us to understand why so many species of social insects have conquered the earth, but also to determine how climate change will affect the success of these and other social species, including our own.DOI: http://dx.doi.org/10.7554/eLife.02440.001., (Copyright © 2014, Sun et al.)

Published

2014