We report evidence of adaptive evolution in juvenile development time on a decadal timescale for the cinnabar moth Tyria jacobaeae (Lepidoptera: Arctiidae) colonizing new habitats and hosts from the Willamette Valley to the Coast Range and Cascades Mountains in Oregon. Four lines of evidence reveal shorter egg to pupa juvenile development times evolved in the mountains, where cooler temperatures shorten the growing season: (i) field observations showed that the mountain populations have shorter phenological development; (ii) a common garden experiment revealed genetic determination of phenotypic differences in juvenile development time between Willamette Valley and mountain populations correlated with the growing season; (iii) a laboratory experiment rearing offspring from parental crosses within and between Willamette Valley and Cascades populations demonstrated polygenic inheritance, high heritability, and genetic determination of phenotypic differences in development times; and (iv) statistical tests that exclude random processes (founder effect, genetic drift) in favor of natural selection as explanations for observed differences in phenology. These results support the hypothesis that rapid adaptation to the cooler mountain climate occurred in populations established from populations in the warmer valley climate. Our findings should motivate regulators to require evaluation of evolutionary potential of candidate biological control organisms prior to release.
We report evidence of adaptive evolution in juvenile development time on a decadal timescale for the cinnabar moth Tyria jacobaeae (Lepidoptera: Arctiidae)
colonizing new habitats and hosts from the Willamette Valley to the Coast Range
and Cascades Mountains in Oregon. Four lines of evidence reveal shorter egg to
pupa juvenile development times evolved in the mountains, where cooler temperatures shorten the growing season: (i) ?eld observations showed that the
mountain populations have shorter phenological development; (ii) a common
garden experiment revealed genetic determination of phenotypic differences in
juvenile development time between Willamette Valley and mountain populations
correlated with the growing season; (iii) a laboratory experiment rearing offspring from parental crosses within and between Willamette Valley and Cascades
populations demonstrated polygenic inheritance, high heritability, and genetic
determination of phenotypic differences in development times; and (iv) statistical
tests that exclude random processes (founder effect, genetic drift) in favor of natural selection as explanations for observed differences in phenology. These results
support the hypothesis that rapid adaptation to the cooler mountain climate
occurred in populations established from populations in the warmer valley climate. Our ?ndings should motivate regulators to require evaluation of evolutionary potential of candidate biological control organisms prior to release.