Abstract
The theory of life history evolution generally predicts a negative across-environment correlation between development time and size at maturity in response to variations in environmental quality. Deviations from this pattern occur under specific circumstances. In particular, organisms may mature both early and at a small size when (1) some ultimate change (e.g. time constraint, resource exhaustion) in the environment precludes further growth, or (2) when there are predictable among-environment differences in mortality rates. The first scenario is frequently documented in insects but evidence for the second possibility is scarce. Here we report a crowding-induced plastic response resulting in a clear positive across-environment correlation between final weight and development time in a geometrid moth. The response was apparent during the entire larval period and in the last larval instar. Crowding also led to increased growth rates. As outbreaks have not been reported for this species it is unlikely that early pupation is a response to anticipated food shortage. Instead, we suggest that crowded larvae may perceive a higher risk of predation, perhaps because they are unable to distinguish conspecifics from potential predators. A possibility for a plastic increase in growth rate implies that the uncrowded larvae grow at submaximal rates, which indicates a cost of high growth rate.
Highlights
A negative across-environment correlation between final size and development time is predicted by classical models of life history evolution (Stearns & Koella; 1986, Roff, 1992; Stearns, 1992)
There was a positive acrosstreatment relationship between body size and development time caused by larval crowding, i.e. a pattern which contrasts to the “standard” case – a negative correlation typically induced by variations in food quality
Our experimental design allowed us to show that the positive relationship between final size and development time is manifested both at the level of the entire larval period and the last larval instar
Summary
A negative across-environment correlation between final size and development time is predicted by classical models of life history evolution (Stearns & Koella; 1986, Roff, 1992; Stearns, 1992). Within a species, juvenile organisms which grow slowly due to poor environmental conditions typically have longer development times, but such compensation is almost never complete as their final sizes are smaller than of those that develop in more favourable environments. This situation is represented by the negative slope of the bivariate reaction norm between size and time at maturity (Stearns & Koella, 1986; Marty et al, 2011). The outcome can be different in more complex cases when mortality is size-selective (Gårdmark & Dieckmann, 2006), time-dependent (Rudolf & Rödel, 2007) or correlated with environment-specific growth rates (Marty et al, 2011), or when the (plastic) growth rate as such affects the risk of being killed by predators (Abrams & Rowe, 1996)
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