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Biomodal patterns of mortality from nuclear polyhedrosis virus in gypsy moth (Lymantria dispar) populations

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Abstract

A bimodal temporal pattern of mortality caused by the nuclear polyhedrosis virus (NPV) was observed in nine gypsy moth (Lymantria dispar) populations of varying densities. In all cases, peak mortality from NPV occurred during the second wave (late larval instars) and the highest mortality occurred in high density populations. Patterns of NPV mortality were established several weeks before being expressed. There was no discernible correlation between weekly mortality rates and temperature, rainfall, or total solar radiation. The bimodality was also apparent in NPV contamination on foliage which was measured by bioassay. A similar pattern was observed in the laboratory among larvae reared in groups from field-collected egg masses and from eggs artificially contaminated with NPV from a laboratory population. As in field populations, the period of low mortality from NPV between the two waves occurred when most larvae were late third and fourth instars. Larvae reared individually did not exhibit the second wave of mortality.

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