Browsing by Subject "Natural selection"
Now showing 1 - 3 of 3
Results Per Page
Sort Options
Item Evolution of sex-limited mimicry in swallowtail butterflies(2008-12) Kunte, Krushnamegh Jagannath, 1973-; Gilbert, Lawrence E.; Juenger, ThomasMany organisms are sexually dimorphic for ecologically and socially important traits. One of the major foci of biology is to understand the evolution of such sexually dimorphic traits. Here I present my work on the evolution of a dimorphic trait, female-limited Batesian mimicry, in Papilio swallowtail butterflies. I begin by developing a character state path network to study the diversity of mimicry types and directionality of trait change during the evolution of female-limited mimicry. My phylogenetic analysis showed that female-limited mimicry has evolved independently in several groups of swallowtails, mainly via single-step character changes from monomorphic non-mimetic ancestors to female-limited mimetic descendents. Mimetic polymorphism has evolved in tandem with female-limited mimicry, the two being tightly correlated among mimetic species. Most traditional explanations of female-limited mimicry and mimetic polymorphism invoke sexual selection. In reviewing these hypotheses, I show that their key assumptions and predictions remain untested, and that sexual selection cannot maintain female polymorphism under some conditions. Sexual selection hypotheses are also unable to explain community ecological aspects of mimicry rings. Hence, I developed a novel model of female-limited mimicry based on sex-specific, frequency- and density-dependent advantages of mimicry. This model shows that both-sex mimicry, female-limited mimicry and mimetic polymorphism are favored along a gradient of relative mimic frequency. My ecological data from south Indian mimicry rings support a key prediction of this model. Finally, I employ the patterns of female-limited mimicry among swallowtail butterflies to highlight the contrast between Darwin’s sexual selection model and Wallace’s natural selection model of sexual dimorphism. I show that most of the sexual dimorphism in swallowtail wing color patterns is a product of natural selection for protective female coloration, predominantly in the form of female-limited mimicry. Thus, swallowtails support Wallace’s model of sexual dimorphism, underlining the importance of natural selection.Item Evolutionary genetics and ecology of water use efficiency ([delta]¹³C) in Ipomopsis agregata and Arabidopsis thaliana(2011-12) Kenney, Amanda Marie; Juenger, Thomas; Bolnick, Daniel I.; Linder, C. Randal; Roux, Stanley J.; McKay, John K.My dissertation research investigates the genetic architecture and evolutionary significance of physiological variation in two wildflower species, Ipomopsis aggregata and Arabidopsis thaliana. In particular, my work focuses on water use efficiency (WUE), a critical physiological trait that dictates plant growth and performance in resource-limited environments. I used a combination of quantitative trait loci (QTL) mapping, field selection experiments, and classic quantitative genetics to investigate 1) the genetic architecture of water use efficiency and flowering time, 2) patterns of natural selection on water use efficiency, flowering time, and other ecological traits in I. aggregata, and 3) additive genetic variation, genetic correlations, and selection on water use efficiency, flowering time, and plasticity to drought in Arabidopsis thaliana. Using an Ipomopsis aggregata genetic mapping population, I identified four QTL underlying WUE, three QTL-QTL epistatic interactions, and evidence for a possible QTL x cytoplasmic interaction affecting WUE. I found a similar genetic architecture underlying flowering time, with four main effect QTLs that all adjacently localized to the same linkage groups as WUE, and three QTL-QTL epistatic interactions, which occur between the same chromosome pairs as the WUE interactions. The combined main and interactive effects explain 35% and 40% of the phenotypic variation in WUE and flowering time, respectively. The adjacent localization suggests a possible role for the evolution of co-inheritance or, if the true QTL positions actually overlap, a possible role for pleiotropy underlying the phenotypic correlation between WUE and flowering time. Additionally, these results suggest epistasis is a significant factor affecting phenotypic variation in nature. In a reciprocal transplant and water addition experiment, I demonstrated variable natural selection on WUE, flowering time, and nectar production in I. aggregata across elevation/habitat and differential water availability. At low elevation in the water addition treatment, natural selection favors early flowering and greater nectar sugar concentration, while dry conditions favor high WUE and early flowering time. At high elevation, where the growing season is shorter and drier, selection favors early flowering regardless of water addition. These results suggest natural selection on ecophysiological and floral traits varies with resource availability (e.g. water availability and pollinator visitation). Using data from a glasshouse experiment involving a global panel of accessions of Arabidopsis thaliana, I demonstrated strong positive genetic correlation between WUE and flowering time, as well as selection for low WUE and early flowering under experimental season-ending drought. Finally, I found significant genetic variation in plasticity as well as selection favoring greater WUE plasticity under drought, indicating plasticity to drought is adaptive in A. thaliana.Item Intrasexual selection and warning color evolution in an aposematic poison dart frog(2014-05) Crothers, Laura Rose; Cummings, Molly E.; Bolnick, Daniel; Hofmann, Hans; Ryan, Michael; Summers, KyleFlamboyant colors are widespread throughout the animal kingdom. While many of these traits arise through sexual selection, bright coloration can also evolve through natural selection. Many aposematic species, for example, use conspicuous warning coloration to communicate their noxiousness to predators. Recent research suggests these signals can also function in the context of mate choice. Studies of warning color evolution can therefore provide new insights into how the interplay of natural and sexual selection impact the trajectory of conspicuous signal evolution. For my dissertation, I investigated the potential for male-male competition to impact the warning color evolution of a species of poison frog. I focused my work on an exceptionally bright and toxic population of the strawberry poison frog (Oophaga pumilio) where males are brighter than females, a classic signature of sexual selection. In Chapter 1, I used theoretical models of predator and frog visual systems to determine which can see the variation in bright warning coloration within this population. I found that birds, the presumed major predator, likely cannot see this variation, indicating that sexual selection can work under the radar of predators in this species. In Chapter 2, I tested the aggressive responses of males using a two-way choice paradigm that manipulated the perceived brightness of stimulus males. I found that males directed more of their behaviors to bright stimulus frogs, and brighter focal frogs more readily approached stimuli and directed more of their attention to the brighter rival. In Chapter 3, I tested the outcomes of dyadic interactions between males of varying brightness and observed male reactions to simulated intruders in their territories. I found that brighter males initiated aggressive interactions with rivals more readily, and brightness asymmetries between males settled interactions in a way that is consistent with classic hypotheses about male sexual signals. In Chapter 4 I sought to describe physiological correlates of male warning color brightness. While male brightness did not co-vary with classic measures of body condition (circulating testosterone and skin carotenoids), it did correlate with toxins sequestered from the diet and thus appears to be a reliable signal of toxicity in this population.