Seasonal variation in the intensity of competition and predation among dragonfly larvae

In nature, both similar and disparate sizes of Libellula lydia and L. luctuosa larvae frequently co-occur in time and space. To determine if these larvae interact as competitors, and/or predators and prey, I used artificial ponds to manipulate density, species composition, and size range of co-occur...

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Bibliographic Details
Published in:Ecology (Durham) 1989-08, Vol.70 (4), p.1017-1027
Main Author: Wissinger, Scott A.
Format: Article
Language:English
Subjects:
ABNORMAL BEHAVIOUR
Animal and plant ecology
Animal behavior
Animal ecology
Animal, plant and microbial ecology
Animals
Biological and medical sciences
COMPORTAMIENTO ANORMAL
COMPORTEMENT ANORMAL
Demecology
DENSIDAD DE LA POBLACION
DENSITE DE POPULATION
DEPREDACION
Ecological competition
Ecology
ESSAI
Freshwater
Fundamental and applied biological sciences. Psychology
Insects
Instars
LARVAE
Larval development
LARVAS
LARVE
Libellula luctuosa
Libellula lydia
Libellulidae
Mortality
ODONATA
POPULATION DENSITY
Population ecology
PREDATION
Predators
Protozoa. Invertebrata
PRUEBAS
SEASONAL VARIATION
TRIALS
VARIACION ESTACIONAL
VARIATION SAISONNIERE
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Summary:In nature, both similar and disparate sizes of Libellula lydia and L. luctuosa larvae frequently co-occur in time and space. To determine if these larvae interact as competitors, and/or predators and prey, I used artificial ponds to manipulate density, species composition, and size range of co-occurring larvae. Detailed life history data were used to design separate fall and spring experiments. In both experiments, @'competition treatments@' contained only larvae similar in size, whereas @'predation treatments@' contained larvae disparate in size. In fall competition treatments there were no density-dependent growth responses. However, in the spring experiment, larvae of both species grew significantly faster in low density than in high density treatments. This seasonal difference in competition was attributed to fluctuations in resource abundance. Competition did not directly affect survivorship. In spring and fall predation treatments, mortality was significantly higher than it was in competition treatments. Inter-odonate predation accounted for 25-45% of total larval mortality in fall, but only 10-15% in spring. In the absence of inter-odonate predation, total mortality was lower for larger larvae than smaller larvae, suggesting the latter are more susceptible to predation by other invertebrate predators. Thus, competition, by decreasing growth rates, should indirectly affect larval survivorship. These data provide evidence that competition and predation will simultaneously affect coexistence between these two dragonfly species. Predation early in larval development should ameliorate the intensity of subsequent competitive interactions at a time when resources are most likely to be limiting. This type of mixed competition/predation interaction is analogous to predator-mediated coexistence, and might explain how such ecologically similar species can coexist at such high densities.
ISSN:0012-9658
1939-9170
DOI:10.2307/1941370