Abstract
BackgroundLevels of genetic diversity can strongly influence the dynamics and evolutionary changes of natural populations. Survival and disease resistance have been linked to levels of genetic diversity in eusocial insects, yet these relationships remain untested in gregarious insects where disease transmission can be high and selection for resistance is likely to be strong.Methodology/Principal FindingsHere we use 8 microsatellite loci to examine genetic variation in 12 families of western tent caterpillars, Malacosoma californicum pluviale from four different island populations to determine the relationship of genetic variability to survival and disease resistance. In addition these genetic markers were used to elucidate the population structure of western tent caterpillars. Multiple paternity was revealed by microsatellite markers, with the number of sires estimated to range from one to three per family (mean ± SE = 1.92±0.23). Observed heterozygosity (HO) of families was not associated to the resistance of families to a nucleopolyhedrovirus (NPV) (r = 0.161, F1,12 = 0.271, P = 0.614), a major cause of mortality in high-density populations, but was positively associated with larval survival (r = 0.635, F1,10 = 5.412, P = 0.048). Genetic differentiation among the families was high (FST = 0.269, P<0.0001), and families from the same island were as differentiated as were families from other islands.Conclusion/SignificanceWe have been able to describe and characterize 8 microsatellite loci, which demonstrate patterns of variation within and between families of western tent caterpillars. We have discovered an association between larval survival and family-level heterozygosity that may be relevant to the population dynamics of this cyclic forest lepidopteran, and this will be the topic of future work.
Highlights
For gregarious or colonial animals the opportunities for disease transmission among individuals are likely to be high and selection for resistance to disease is expected to increase [1,2], exceptions occur [3]
We have discovered an association between larval survival and family-level heterozygosity that may be relevant to the population dynamics of this cyclic forest lepidopteran, and this will be the topic of future work
Survival of the family groups up to the time the sample was taken was determined from the total number of 4th instar larvae in each family divided by the number of larvae that had hatched from the egg mass for that family
Summary
For gregarious or colonial animals the opportunities for disease transmission among individuals are likely to be high and selection for resistance to disease is expected to increase [1,2], exceptions occur [3]. It has been proposed that increased genetic variability associated with polyandry reduces the risk of parasitism as selection imposed by parasites favours rare genotypes [8,9]. This prediction, often discussed in the context of the Red Queen hypothesis, has been the stimulus for considerable research on disease resistance and polyandry in eusocial insects such as bees, ants, and termites [10,11,12,13,14]. Survival and disease resistance have been linked to levels of genetic diversity in eusocial insects, yet these relationships remain untested in gregarious insects where disease transmission can be high and selection for resistance is likely to be strong
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