| 1. |
- Braga, Mariana P., et al.
(författare)
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Bayesian Inference of Ancestral Host-Parasite Interactions under a Phylogenetic Model of Host Repertoire Evolution
- 2020
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Ingår i: Systematic Biology. - : Oxford University Press (OUP). - 1063-5157 .- 1076-836X. ; 69:6, s. 1149-1162
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Tidskriftsartikel (refereegranskat)abstract
- Intimate ecological interactions, such as those between parasites and their hosts, may persist over long time spans, coupling the evolutionary histories of the lineages involved. Most methods that reconstruct the coevolutionary history of such interactions make the simplifying assumption that parasites have a single host. Many methods also focus on congruence between host and parasite phylogenies, using cospeciation as the null model. However, there is an increasing body of evidence suggesting that the host ranges of parasites are more complex: that host ranges often include more than one host and evolve via gains and losses of hosts rather than through cospeciation alone. Here, we develop a Bayesian approach for inferring coevolutionary history based on a model accommodating these complexities. Specifically, a parasite is assumed to have a host repertoire, which includes both potential hosts and one or more actual hosts. Over time, potential hosts can be added or lost, and potential hosts can develop into actual hosts or vice versa. Thus, host colonization is modeled as a two-step process that may potentially be influenced by host relatedness. We first explore the statistical behavior of our model by simulating evolution of host-parasite interactions under a range of parameter values. We then use our approach, implemented in the program RevBayes, to infer the coevolutionary history between 34 Nymphalini butterfly species and 25 angiosperm families. Our analysis suggests that host relatedness among angiosperm families influences how easily Nymphalini lineages gain new hosts.
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| 2. |
- Eriksson, Maertha, et al.
(författare)
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Structural plasticity of olfactory neuropils in relation to insect diapause
- 2020
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Ingår i: Ecology and Evolution. - : Wiley. - 2045-7758. ; 10:24, s. 14423-14434
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Tidskriftsartikel (refereegranskat)abstract
- Many insects that live in temperate zones spend the cold season in a state of dormancy, referred to as diapause. As the insect must rely on resources that were gathered before entering diapause, keeping a low metabolic rate is of utmost importance. Organs that are metabolically expensive to maintain, such as the brain, can therefore become a liability to survival if they are too large. Insects that go through diapause as adults generally do so before entering the season of reproduction. This order of events introduces a conflict between maintaining low metabolism during dormancy and emerging afterward with highly developed sensory systems that improve fitness during the mating season. We investigated the timing of when investments into the olfactory system are made by measuring the volumes of primary and secondary olfactory neuropils in the brain as they fluctuate in size throughout the extended diapause life-period of adult Polygonia c-album butterflies. Relative volumes of both olfactory neuropils increase significantly during early adult development, indicating the importance of olfaction to this species, but still remain considerably smaller than those of nondiapausing conspecifics. However, despite butterflies being kept under the same conditions as before the dormancy, their olfactory neuropil volumes decreased significantly during the postdormancy period. The opposing directions of change in relative neuropil volumes before and after diapause dormancy indicate that the investment strategies governing structural plasticity during the two life stages could be functionally distinct. As butterflies were kept in stimulus-poor conditions, we find it likely that investments into these brain regions rely on experience-expectant processes before diapause and experience-dependent processes after diapause conditions are broken. As the shift in investment strategies coincides with a hard shift from premating season to mating season, we argue that these developmental characteristics could be adaptations that mitigate the trade-off between dormancy survival and reproductive fitness.
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| 3. |
- Lindestad, Olle, 1988-
(författare)
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Geographic variation in life cycles : Local adaptation and ecological genetics in a temperate butterfly
- 2020
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Doktorsavhandling (övrigt vetenskapligt/konstnärligt)abstract
- Conditions in nature change with the seasons, necessitating seasonal adaptations that synchronize the life cycles of organisms with their surroundings. Such regulatory adaptations must vary between populations to track local variation in climate and seasonality; this local adaptation is facilitated by locally specific seasonal cues, but may be hampered by gene flow and genetic history. For populations of temperate insects, two central features of adaptation to local climate are voltinism, the yearly number of generations; and diapause, the state of arrested development and suppressed metabolism in which most temperate insects spend winter. Delaying diapause allows for an additional generation to be produced within the same year, but this is only adaptive if the season is sufficiently long to safely accommodate such a life cycle. Hence, selection to express a locally adaptive voltinism should drive divergence between populations in diapause regulation and associated life history traits. In this thesis, I investigate variation in voltinism and life cycle regulation in a set of populations of the butterfly Pararge aegeria. Population-level variation in seasonal plasticity was tested in two sets of experiments. The first (Paper I) focused on photoperiodic plasticity during the growing season, and revealed considerable differences between populations in diapause induction and developmental reaction norms. Mechanistic modeling based on the laboratory results indicated that differences in voltinism are actively maintained by these genetic differences. Next, I tested the idea that shorter diapause may help populations achieve higher voltinism through earlier emergence in the spring (Paper II). This idea was not supported; instead, populations differed in a manner that suggests that diapause duration is selected upon by the need to avoid premature development under warm autumn conditions. The genetic background of seasonal adaptation in these populations was also explored. Phylogeographic structures inferred from genome-wide data put the results of the laboratory experiments into a historic context, and were used as the basis for a scan for genetic loci showing signs of differential selection (Paper III). The scan revealed novel variation in two circadian genes that have been shown to be linked to diapause control in P. aegeria, including a large deletion in the gene timeless. Finally, a test of two previously described circadian mutations (Paper IV) showed that, while these mutations may affect photoperiodic plasticity on a between-population level, they seemingly have no effect within a single population located at intermediate latitudes. Closer inspection revealed novel, locally unique mutations in the same genes, possibly compensating for the effect of diapause-delaying variants in a setting where an attempted second generation is not adaptive. I have shown that voltinism variation in P. aegeria is enabled by population differences in seasonal plasticity, with population differences playing a greater role during some parts of the year than others. These results present voltinism as a complex trait resulting from plasticity acting at different levels of geographic specificity. Although much of the genetic variation enabling the observed local adaptation remains uncharacterized, the considerably variable circadian genes seen in these populations provide an intriguing target for future investigation.
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| 4. |
- Ma, Lijun, et al.
(författare)
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A phylogenomic tree inferred with an inexpensive PCR-generated probe kit resolves higher-level relationships among Neptis butterflies (Nymphalidae: Limenitidinae)
- 2020
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Ingår i: Systematic Entomology. - : Wiley. - 0307-6970 .- 1365-3113. ; 45:4, s. 924-934
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Tidskriftsartikel (refereegranskat)abstract
- Recent advances in obtaining reduced representation libraries for next-generation sequencing permit phylogenomic analysis of species-rich, recently diverged taxa. In this study, we performed sequence capture with homemade PCR-generated probes to study diversification among closely related species in a large insect genus to examine the utility of this method. We reconstructed the phylogeny of Neptis Fabricius, a large and poorly studied nymphalid butterfly genus distributed throughout the Old World. We inferred relationships among 108 Neptis samples using 89 loci totaling up to 84 519 bp per specimen. Our taxon sample focused on Palearctic, Oriental and Australasian species, but included 8 African species and outgroups from 5 related genera. Maximum likelihood and Bayesian analyses yielded identical trees with full support for almost all nodes. We confirmed that Neptis is not monophyletic because Lasippa heliodore (Fabricius) and Phaedyma amphion (Linnaeus) are nested within the genus, and we redefine species groups for Neptis found outside of Africa. The statistical support of our results demonstrates that the probe set we employed is useful for inferring phylogenetic relationships among Neptis species and likely has great value for intrageneric phylogenetic reconstruction of Lepidoptera. Based on our results, we revise the following two taxa: Neptis heliodore comb. rev. and Neptis amphion comb. rev.
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