Evolution of ageing, costs of reproduction and the fecundity–longevity trade-off in eusocial insects

Blacher, Pierre; Huggins, Timothy J.; Bourke, Andrew F. G.

doi:10.1098/rspb.2017.0380

Cited by 62 publications

(60 citation statements)

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“…Comparing milkweed species that vary more substantially in cardenolide toxicity, we found that host plants with increased and more nonpolar cardenolides have negative effects on A. nerii development and fecundity, consistent with other studies that have demonstrated that plant species characterized by more toxic cardenolides are negatively associated with A. nerii population growth (Agrawal, ; Colvin, Snyder, & Thacker, ; de Roode et al., ). In the first fitness experiment, there was evidence of greater longevity on more highly defended plants (Figure e), perhaps indicative of trade‐offs between fecundity and longevity (Blacher, Huggins, & Bourke, ; Miyatake, ). However, we interpret this result with caution, both because the effect was not replicated in the second experiment (Fig.…”

Section: Discussionmentioning

confidence: 97%

Transcriptional profile and differential fitness in a specialist milkweed insect across host plants varying in toxicity

2017

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Interactions between plants and herbivorous insects have been models for theories of specialization and co-evolution for over a century. Phytochemicals govern many aspects of these interactions and have fostered the evolution of adaptations by insects to tolerate or even specialize on plant defensive chemistry. While genomic approaches are providing new insights into the genes and mechanisms insect specialists employ to tolerate plant secondary metabolites, open questions remain about the evolution and conservation of insect counterdefences, how insects respond to the diversity defences mounted by their host plants, and the costs and benefits of resistance and tolerance to plant defences in natural ecological communities. Using a milkweed-specialist aphid (Aphis nerii) model, we test the effects of host plant species with increased toxicity, likely driven primarily by increased secondary metabolites, on aphid life history traits and whole-body gene expression. We show that more toxic plant species have a negative effect on aphid development and lifetime fecundity. When feeding on more toxic host plants with higher levels of secondary metabolites, aphids regulate a narrow, targeted set of genes, including those involved in canonical detoxification processes (e.g., cytochrome P450s, hydrolases, UDP-glucuronosyltransferases and ABC transporters). These results indicate that A. nerii marshal a variety of metabolic detoxification mechanisms to circumvent milkweed toxicity and facilitate host plant specialization, yet, despite these detoxification mechanisms, aphids experience reduced fitness when feeding on more toxic host plants. Disentangling how specialist insects respond to challenging host plants is a pivotal step in understanding the evolution of specialized diet breadths.

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Section: Discussionmentioning

confidence: 97%

Transcriptional profile and differential fitness in a specialist milkweed insect across host plants varying in toxicity

2017

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“…While specialized life history strategies are widely recognized (Sibly and Brown 2009), birth rates are governed by metabolic scaling (Lindstedt and Calder 1981) and are not easy to change permanently without physiological tradeoffs. Elevated reproductive rates lead to shortened lifespan, as limited resources enforce a compromise between investment in reproduction and somatic maintenance (Edward and Chapman 2011, Blacher et al 2017).…”

Section: Demographic Paths To Evolutionary Expansionmentioning

confidence: 99%

The scaling of expansive energy under the Red Queen predicts Cope’s Rule

Žliobaitė

2019

Preprint

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The Red Queen’s hypothesis portrays evolution as a never-ending competition for expansive energy, where one species’ gain is another species’ loss. The Red Queen is neutral with respect to body size, implying that neither small nor large species have a universal competitive advantage. The maximum population growth in ecology; however, clearly depends on body size – the smaller the species, the shorter the generation length, and the faster it can expand. Here we ask whether, and if so how, the Red Queen’s hypothesis can accommodate a spectrum of body sizes. We theoretically analyse scaling of expansive energy with body mass and demonstrate that in the Red Queen’s zero-sum game for resources, neither small nor large species have a universal evolutionary advantage. We argue that smaller species have an evolutionary advantage only when resources in the environment are not fully occupied, such as after mass extinctions or following key innovations allowing expansion into freed up or previously unoccupied resource space. Under such circumstances, we claim, generation length is the main limiting factor for population growth. When competition for resources is weak, smaller species can indeed expand faster, but to sustain this growth they also need more resources. In the Red Queen’s realm, where resources are fully occupied and the only way for expansion is to outcompete other species, acquisition of expansive energy becomes the limiting factor and small species lose their physiological advantage. A gradual transition from unlimited resources to a zero-sum game offers a direct mechanistic explanation for observed body mass trends in the fossil record, known as Cope’s Rule. When the system is far from the limit of resources and competition is not maximally intense, small species take up ecological space faster. When the system approaches the limits of its carrying capacity and competition tightens, small species lose their evolutionary advantage and we observe a wider range of successful body masses, and, as a result, an increase in the average body mass within lineages.

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“…Reproduction itself is central to the Evolution of species [1]. Indeed, it is the slow drift of genotypes along successive generations of living species that gives rise to increasing variability of individuals, and occasio to speciation [2][3][4][5][6]. Speciation occurs when individuals from the same original species become unable to interbreed (and thus do not reproduce).…”

Section: Introductionmentioning

confidence: 99%

Role of Hormones in the Control of Reproductive Physiology and Reproductive Behavior

Nguyen¹

2019

IJBMR

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In multicellular organisms, intercellular mediators such as hormones or growth factors and morphogens play primary roles in development and reproduction. Evolution of the signaling pathways in which these mediators are involved has thus played an important role in the appearance and success of these species. There are many reproductive modes and behaviours in the animal kingdom. A reproductive behaviour can be defined as all the actions taken by an organism toward the generation of one or more other organism that possesses at least some of its genetic patrimony. From a strict evolutionary point of view, the goal of an organism is to spread its genetic patrimony as much as possible in the next generations of its kind. This egoistic behaviour typically benefits for the entire species since the individuals spreading the most their genetic patrimony is generally those with the best genes and are thus helping their species to be the most fitted possible. In the present review, I briefly describe the implication of hormones in the control of mammals Reproduction and in their Sexual Behavior. In addition, since most multicellular organisms exhibit sexual reproduction, I also take into account hormonal control of reproduction together with sexual behavior.

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Evolution of ageing, costs of reproduction and the fecundity–longevity trade-off in eusocial insects

Cited by 62 publications

References 50 publications

Transcriptional profile and differential fitness in a specialist milkweed insect across host plants varying in toxicity

Transcriptional profile and differential fitness in a specialist milkweed insect across host plants varying in toxicity

The scaling of expansive energy under the Red Queen predicts Cope’s Rule

Role of Hormones in the Control of Reproductive Physiology and Reproductive Behavior

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