Book contents
- Frontmatter
- Contents
- Contributors
- Acknowledgements
- Introduction
- 1 Are behavioral classifications blinders to studying natural variation?
- 2 Life beneath silk walls: a review of the primitively social Embiidina
- 3 Postovulation parental investment and parental care in cockroaches
- 4 The spectrum of eusociality in termites
- 5 Maternal care in the Hemiptera: ancestry, alternatives, and current adaptive value
- 6 Evolution of paternal care in the giant water bugs (Heteroptera: Belostomatidae)
- 7 The evolution of sociality in aphids: a clone's-eye view
- 8 Ecology and evolution of social behavior among Australian gall thrips and their allies
- 9 Interactions among males, females and offspring in bark and ambrosia beetles: the significance of living in tunnels for the evolution of social behavior
- 10 Biparental care and social evolution in burying beetles: lessons from the larder
- 11 Subsocial behavior in Scarabaeinae beetles
- 12 The evolution of social behavior in Passalidae (Coleoptera)
- 13 The evolution of social behavior in the augochlorine sweat bees (Hymenoptera: Halictidae) based on a phylogenetic analysis of the genera
- 14 Demography and sociality in halictine bees (Hymenoptera: Halictidae)
- 15 Behavioral environments of sweat bees (Halictinae) in relation to variability in social organization
- 16 Intrinsic and extrinsic factors associated with social evolution in allodapine bees
- 17 Cooperative breeding in wasps and vertebrates: the role of ecological constraints
- 18 Morphologically ‘primitive’ ants: comparative review of social characters, and the importance of queen–worker dimorphism
- 19 Social conflict and cooperation among founding queens in ants (Hymenoptera: Formicidae)
- 20 Social evolution in the Lepidoptera: ecological context and communication in larval societies
- 21 Sociality and kin selection in Acari
- 22 Colonial web-building spiders: balancing the costs and benefits of group-living
- 23 Causes and consequences of cooperation and permanent-sociality in spiders
- 24 Explanation and evolution of social systems
- Organism index
- Subject index
9 - Interactions among males, females and offspring in bark and ambrosia beetles: the significance of living in tunnels for the evolution of social behavior
Published online by Cambridge University Press: 06 July 2010
- Frontmatter
- Contents
- Contributors
- Acknowledgements
- Introduction
- 1 Are behavioral classifications blinders to studying natural variation?
- 2 Life beneath silk walls: a review of the primitively social Embiidina
- 3 Postovulation parental investment and parental care in cockroaches
- 4 The spectrum of eusociality in termites
- 5 Maternal care in the Hemiptera: ancestry, alternatives, and current adaptive value
- 6 Evolution of paternal care in the giant water bugs (Heteroptera: Belostomatidae)
- 7 The evolution of sociality in aphids: a clone's-eye view
- 8 Ecology and evolution of social behavior among Australian gall thrips and their allies
- 9 Interactions among males, females and offspring in bark and ambrosia beetles: the significance of living in tunnels for the evolution of social behavior
- 10 Biparental care and social evolution in burying beetles: lessons from the larder
- 11 Subsocial behavior in Scarabaeinae beetles
- 12 The evolution of social behavior in Passalidae (Coleoptera)
- 13 The evolution of social behavior in the augochlorine sweat bees (Hymenoptera: Halictidae) based on a phylogenetic analysis of the genera
- 14 Demography and sociality in halictine bees (Hymenoptera: Halictidae)
- 15 Behavioral environments of sweat bees (Halictinae) in relation to variability in social organization
- 16 Intrinsic and extrinsic factors associated with social evolution in allodapine bees
- 17 Cooperative breeding in wasps and vertebrates: the role of ecological constraints
- 18 Morphologically ‘primitive’ ants: comparative review of social characters, and the importance of queen–worker dimorphism
- 19 Social conflict and cooperation among founding queens in ants (Hymenoptera: Formicidae)
- 20 Social evolution in the Lepidoptera: ecological context and communication in larval societies
- 21 Sociality and kin selection in Acari
- 22 Colonial web-building spiders: balancing the costs and benefits of group-living
- 23 Causes and consequences of cooperation and permanent-sociality in spiders
- 24 Explanation and evolution of social systems
- Organism index
- Subject index
Summary
ABSTRACT
Parental care and colonial breeding are both widespread in two related groups of weevils known traditionally as Scolytidae and Platypodidae. Within–family cooperative breeding and eusociality also occur; in at least one platypodid ambrosia beetle, non–reproductive females help presumed relatives to raise offspring.
Although they breed in a wide variety of woody tissues, the majority of species fall into two ecological categories, those reproducing under the bark and feeding directly on inner bark (‘bark beetles’, most scolytids) and diverse taxa feeding upon microbial ectosymbionts they have introduced to the walls of their tunnel systems (‘ambrosia beetles’, many scolytids and all true platypodids). In both scolytids and platypodids, females lay eggs over an extended period of time in long tunnels. Males usually remain with females in these tunnel systems, controlling and expelling refuse. We examine hypotheses for prolonged male residence, and find that the most likely explanations for long stays in burrows are either blocking out natural enemies or increasing the reproductive rate of the resident females.
Species reproducing in bark or wood usually breed in large aggregations. In most species, these colonies are an incidental effect of mutual attraction to odors emanating either from the resource itself or from the beetles (pheromones). We suggest that the key feature predisposing these beetles to the evolution of breeding in aggregations is the presence of mate–attracting pheromones coupled with the utilization of resource patches that cannot be monopolized by single families.
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- The Evolution of Social Behaviour in Insects and Arachnids , pp. 181 - 215Publisher: Cambridge University PressPrint publication year: 1997
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