Abstract
The cost of reproduction hypothesis suggests that allocation to current reproduction constrains future reproduction. How organisms accrue reproductive costs and allocate energy across their lifetime may differ among species adapted to different resource types. We test this by comparing lifetime reproductive output, patterns of reproductive allocation, and senescence between two species of burying beetles, Nicrophorus marginatus and N. guttula, that differ in body size, across a range of carcass sizes. These two species of burying beetles maximized lifetime reproductive output on somewhat different–sized resources. The larger N. marginatus did better on large and medium carcasses while the smaller N. guttula did best on small and medium carcasses. For both species, reproduction is costly and reproduction on larger carcasses reduced lifespan more than reproduction on smaller carcasses. Carcass size also affected lifetime reproductive strategies. Each species’ parental investment patterns were consistent with terminal investment on carcasses on which they performed best (optimal carcass sizes). However, they exhibited reproductive restraint on carcass sizes on which they did not perform as well. Reproductive senescence occurred largely in response to carcass size. For both species, reproduction on larger carcasses resulted in more rapid senescence. These data suggest that whether organisms exhibit terminal investment or reproductive restraint may depend on type and amount of resources for reproduction.
Highlights
For iteroparous organisms, fitness is maximized through balancing current reproductive effort with future reproductive opportunities [1]
When an organism allocates resources to current reproduction, that energy is unavailable for somatic maintenance, growth, or future reproduction
The number of offspring for N. marginatus increased with carcass size up to 20 g and plateaued on larger carcass sizes
Summary
Fitness is maximized through balancing current reproductive effort with future reproductive opportunities [1]. When an organism allocates resources to current reproduction, that energy is unavailable for somatic maintenance, growth, or future reproduction Because of this tradeoff, organisms are expected to balance current and future reproduction to maximize total lifetime reproductive output [2,3,4,5]. Organisms are expected to balance current and future reproduction to maximize total lifetime reproductive output [2,3,4,5] As individuals age, this balance between current and future reproduction shifts, which potentially causes a change in how they allocate resources for reproduction. Individuals decrease investment in reproduction as they age to increase the likelihood of additional breeding opportunities (reproductive restraint hypothesis [7]) It is not clear under what circumstances selection will favor one or the other of these allocation strategies
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