Evolution of pathogen-specific improved survivorship post-infection in populations of Drosophila melanogaster adapted to larval crowding

Kapila, Rohit; Kashyap, Mayank; Poddar, Soumyadip; Gangwal, Shreya; Prasad, Nagaraj Guru

doi:10.1371/journal.pone.0250055

Cited by 11 publications

(12 citation statements)

References 39 publications

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“…For instance, larvae developing in crowded conditions have upregulated expression of heat-shock proteins in response to the stress of the developmental environment, 20 , 21 , 22 which may be involved in a hormesis-like response that leads to increased lifespan and fitness benefits in broader ecological contexts. 21 , 23 , 24 , 25 …”

Section: Introductionmentioning

confidence: 99%

Uric acid metabolism modulates diet-dependent responses to intraspecific competition in Drosophila larvae

Morimoto¹

2022

iScience

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Section: Introductionmentioning

confidence: 99%

Uric acid metabolism modulates diet-dependent responses to intraspecific competition in Drosophila larvae

Morimoto¹

2022

iScience

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“…Female terminal investment in response to dead conspecifics could be favoured in ecological contexts characterized by density booms, where populations are susceptible to infectious outbursts. Firm evidence suggests that D. melanogaster has evolved to cope with such population dynamics (Behrman et al, 2015; Burant et al, 2019; Corbel et al, 2022; Goldschmidt et al, 1955; Paaby et al, 2014), and several drosophilids have evolved adaptations to increased susceptibility of pathogenic and/or parasitic infection during phases of high population density (Fellowes & Godfray, 2000; Kapila et al, 2021; Ye et al, 2009). We hence suggest that D. melanogaster responses to dead conspecifics may have evolved in response to extrinsic mortality cues that are typically encountered at high population densities in the wild.…”

Section: Discussionmentioning

confidence: 99%

“…At high population density, Drosophila are more susceptible to deadly infectious diseases that can cause mass mortality (Biganski et al, 2021; Ebbert, 1995; Fellowes & Godfray, 2000), and evolutionary adaptations to these types of infections are well documented in this genus (e.g. larval encapsulation in response to parasitoids; Fellowes & Godfray, 2000; Kapila et al, 2021; Ye et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Perception of dead conspecifics increases reproductive investment in fruit flies

Corbel

Carazo

2022

Functional Ecology

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1. Adaptive plasticity in life-history traits is often critical to maximize fitness in the face of environmental heterogeneity. For example, many organisms respond to a threat to their survival (and hence residual reproductive value) by adaptively increasing their investment into current reproduction (i.e. 'terminal investment'). 2.A key to successful terminal investment is the use of adequate environmental cues to extrinsic mortality sources. In species that live at high population densities, the presence of dead conspecifics could potentially act as a reliable cue to extrinsic mortality sources (e.g. via pathogens).3. We experimentally tested this idea using the model organism Drosophila melanogaster, a pest species that experiences marked demographic shifts. We monitored the reproductive output of young mated females during repeated bouts of egg laying in the presence (i.e. dead exposed) or absence (i.e. controls) of dead conspecifics, interspersed by mating periods where dead conspecifics were always absent.4. Dead-exposed females produced more offspring than controls when in the presence of dead conspecifics but fewer offspring than controls when dead conspecifics were subsequently removed (i.e. during mating periods). These changes were repeatable across time, and are thus indicative of high plasticity in reproductive behaviour induced by perception of dead conspecifics.5. Flies responded equally to starvation-induced and flash-frozen dead conspecifics, indicating that the cause of death is irrelevant to trigger the plastic response observed, and that females respond to the presence of dead conspecifics per se.6. Finally, we found that dead-exposed females produced heavier daughters (but not sons) than controls when in the presence of dead conspecifics, but not during mating periods (when dead conspecifics were absent). In this species, body size correlates more strongly with female (than male) fitness, so higher investment in daughter weight is congruent with terminal investment. 7. Altogether, these results show that perception of dead conspecifics leads to highly plastic life-history adjustments in the form of increased investment in both the quantity and the quality of offspring. We discuss these results in the context of terminal investment and other alternative hypotheses.

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“…Since larval crowding scenarios are common in nature and are known to affect adult traits (Bierbaum et al, 1989; Kapila, Kashyap, Gulati, et al, 2021; Kapila, Kashyap, Poddar, et al, 2021; Roper et al, 1996; Shenoi, Banerjee, et al, 2016), the effect of larval crowding and evolution under crowded larval environments on sexual selection is an important avenue of research. Crowding is especially important in holometabolous insects such as Drosophila , where adults lay eggs in ephemeral habitats and juveniles are largely restricted to compete at the egg‐laying sites (Atkinson, 1979).…”

Section: Introductionmentioning

confidence: 99%

“…Often, populations may be subjected to larval crowding over multiple generations. Larval crowding can generate stressful environments (Mueller et al, 1991; Prasad & Joshi, 2003) and impose selection not only on the larval but also the adult stages (Kapila, Kashyap, Gulati, et al, 2021; Kapila, Kashyap, Poddar, et al, 2021; Shenoi, Ali, & Prasad, 2016; Shenoi, Banerjee, et al, 2016). Recent studies show that sexual selection may impede adaptation to novel environments (Chenoweth et al, 2015), or environmental changes leading to maladaptation can disrupt how sexual selection acts (Martinossi‐Allibert et al, 2017, 2018).…”

Section: Introductionmentioning

confidence: 99%

Consequences of adaptation to larval crowding on sexual and fecundity selection in Drosophila melanogaster

Narasimhan,

Kapila,

Meena

et al. 2023

J of Evolutionary Biology

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Sexual selection is a major force influencing the evolution of sexually reproducing species. Environmental factors such as larval density can manipulate adult condition and influence the direction and strength of sexual selection. While most studies on the influence of larval crowding on sexual selection are either correlational or singlegeneration manipulations, it is unclear how evolution under chronic larval crowding affects sexual selection. To answer this, we measured the strength of sexual selection on male and female Drosophila melanogaster that had evolved under chronic larval crowding for over 250 generations in the laboratory, along with their controls which had never experienced crowding, in a common garden high-density environment. We measured selection coefficients on male mating success and sex-specific reproductive success, as separate estimates allowed dissection of sex-specific effects. We show that experimental evolution under chronic larval crowding decreases the strength of sexual and fecundity selection in males but not in females, relative to populations experiencing crowding for the first time. The effect of larval crowding in reducing reproductive success is almost twice in females than in males. Our study highlights the importance of studying how evolution in a novel, stressful environment can shape adult fitness in organisms.

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Evolution of pathogen-specific improved survivorship post-infection in populations of Drosophila melanogaster adapted to larval crowding

Cited by 11 publications

References 39 publications

Uric acid metabolism modulates diet-dependent responses to intraspecific competition in Drosophila larvae

Uric acid metabolism modulates diet-dependent responses to intraspecific competition in Drosophila larvae

Perception of dead conspecifics increases reproductive investment in fruit flies

Consequences of adaptation to larval crowding on sexual and fecundity selection in Drosophila melanogaster

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