Delineating species with DNA barcodes: a case of taxon dependent method performance in moths.

The accelerating loss of biodiversity has created a need for more effective ways to discover species. Novel algorithmic approaches for analyzing sequence data combined with rapidly expanding DNA barcode libraries provide a potential solution. While several analytical methods are available for the delineation of operational taxonomic units (OTUs), few studies have compared their performance. This study compares the performance of one morphology-based and four DNA-based (BIN, parsimony networks, ABGD, GMYC) methods on two groups of gelechioid moths. It examines 92 species of Finnish Gelechiinae and 103 species of Australian Elachistinae which were delineated by traditional taxonomy. The results reveal a striking difference in performance between the two taxa with all four DNA-based methods. OTU counts in the Elachistinae showed a wider range and a relatively low (ca. 65%) OTU match with reference species while OTU counts were more congruent and performance was higher (ca. 90%) in the Gelechiinae. Performance rose when only monophyletic species were compared, but the taxon-dependence remained. None of the DNA-based methods produced a correct match with non-monophyletic species, but singletons were handled well. A simulated test of morphospecies-grouping performed very poorly in revealing taxon diversity in these small, dull-colored moths. Despite the strong performance of analyses based on DNA barcodes, species delineated using single-locus mtDNA data are best viewed as OTUs that require validation by subsequent integrative taxonomic work.

One species in eight: DNA barcodes from type specimens resolve a taxonomic quagmire.

Each holotype specimen provides the only objective link to a particular Linnean binomen. Sequence information from them is increasingly valuable due to the growing usage of DNA barcodes in taxonomy. As type specimens are often old, it may only be possible to recover fragmentary sequence information from them. We tested the efficacy of short sequences from type specimens in the resolution of a challenging taxonomic puzzle: the Elachista dispunctella complex which includes 64 described species with minuscule morphological differences. We applied a multistep procedure to resolve the taxonomy of this species complex. First, we sequenced a large number of newly collected specimens and as many holotypes as possible. Second, we used all >400 bp examine species boundaries. We employed three unsupervised methods (BIN, ABGD, GMYC) with specified criteria on how to handle discordant results and examined diagnostic bases from each delineated putative species (operational taxonomic units, OTUs). Third, we evaluated the morphological characters of each OTU. Finally, we associated short barcodes from types with the delineated OTUs. In this step, we employed various supervised methods, including distance-based, tree-based and character-based. We recovered 658 bp barcode sequences from 194 of 215 fresh specimens and recovered an average of 141 bp from 33 of 42 holotypes. We observed strong congruence among all methods and good correspondence with morphology. We demonstrate potential pitfalls with tree-, distance- and character-based approaches when associating sequences of varied length. Our results suggest that sequences as short as 56 bp can often provide valuable taxonomic information. The results support significant taxonomic oversplitting of species in the Elachista dispunctella complex.

DNA barcode-based delineation of putative species: efficient start for taxonomic workflows.

The analysis of DNA barcode sequences with varying techniques for cluster recognition provides an efficient approach for recognizing putative species (operational taxonomic units, OTUs). This approach accelerates and improves taxonomic workflows by exposing cryptic species and decreasing the risk of synonymy. This study tested the congruence of OTUs resulting from the application of three analytical methods (ABGD, BIN, GMYC) to sequence data for Australian hypertrophine moths. OTUs supported by all three approaches were viewed as robust, but 20% of the OTUs were only recognized by one or two of the methods. These OTUs were examined for three criteria to clarify their status. Monophyly and diagnostic nucleotides were both uninformative, but information on ranges was useful as sympatric sister OTUs were viewed as distinct, while allopatric OTUs were merged. This approach revealed 124 OTUs of Hypertrophinae, a more than twofold increase from the currently recognized 51 species. Because this analytical protocol is both fast and repeatable, it provides a valuable tool for establishing a basic understanding of species boundaries that can be validated with subsequent studies.

Morphology reinforces proposed molecular phylogenetic affinities: a revised classification for Gelechioidea (Lepidoptera).

Gelechioidea are one of the most species rich and least studied superfamilies of Lepidoptera. We examine the interrelationships within the superfamily using the densest taxon sampling to date, combined with the most extensive ever morphological and molecular character data. We perform partitioned and combined analyses using maximum likelihood, Bayesian and parsimony approaches. The combined dataset consists of 155 exemplar species of Gelechioidea, representing nearly all subfamilies recognized in recent classifications. Parsimony analyses are performed with a dataset including 28 additional terminal taxa with only morphological data available. We use eight genes with a total of 6127 bp, and morphological data with 253 characters derived from larval, pupal, and adult morphology. The analyses of combined data yield more resolved trees and significantly better-supported groupings than either dataset when analysed alone. The recurrent monophyletic groupings in all our model-based analyses support a revision of the family classification. Deeper relationships vary between analyses and data partitions, leaving them ambiguous. The place of the root remains a challenge for future research. We propose a revised classification and suggest the division of Gelechioidea into 16 families. We redefine Depressariidae Meyrick, 1883 for a monophylum that includes Acriinae, Aeolanthinae, Cryptolechiinae, Depressariinae, Ethmiinae, Hypercalliinae, Hypertrophinae, Peleopodinae, Oditinae, Stenomatinae, Carcina, and a diversity of predominantly New World taxa previously excluded from Lypusidae (Amphisbatidae s. authors) but left without family position. A monophyletic Oecophoridae s. s., including Deuterogoniinae and Pleurotinae, is obtained for the first time with significant support. Elachistidae s. l. is found to be polyphyletic, and Elachistidae is restricted to comprise Agonoxeninae, Elachistinae, and Parametriotinae. Batrachedridae are polyphyletic, with several genera pending further study. Apart from the core Batrachedra, the taxa previously included in this family are grouped in an expanded Pterolonchidae, together with Coelopoetinae and Syringopainae. Lypusidae s. s. and Chimabachidae form a monophylum; Chimabachinae is united with Lypusidae as a subfamily, stat. n. Our results contradict the subfamily classifications of several families, notably Lecithoceridae and Autostichidae, but due to insufficient sampling of taxa we refrain from comprehensive taxonomic conclusions on the subfamily level, and encourage focused studies to resolve these groups.

Food regulates reproduction differently in different habitats: experimental evidence in the Goshawk.

Food supplementation experiments have been widely used to get detailed insight into how food supply contributes to the reproductive performance of wild animals. Surprisingly, even though food seldom is distributed evenly in space, variation in local habitat quality has usually not been controlled for in food supplementation studies. With results from a two-year feeding experiment involving a habitat-sensitive avian top predator, the Northern Goshawk Accipiter gentilis, we show that treatment effects on goshawk reproductive performance are habitat dependent. Extra food reduced nestling mortality in low-quality territories where prime habitat (forest) is scarce, but not in high-quality territories where prime habitat is abundant. Consequently, brood size did not differ between treatment categories in heavily forested territories, but fledgling numbers differed between unfed and fed goshawk pairs breeding in territories where forest is scarce. However, because extra food was not superabundant, this artificial increase in offspring number induced a dramatic decrease in nestling condition in low-quality territories. Treatment effects were detected even after controlling statistically for other potentially confounding effects (year, territory identity) and strongly covaried with territory-specific abundances of the most important summer prey species. These results highlight the importance of acknowledging the effect that small-scale variation in habitat quality and availability of natural food may have on the results of food supplementation experiments. In order to assess the generality of food supplementation effects, the integration of habitat heterogeneity and variation in food abundance is thus needed, especially among species in which small-scale variation in habitat quality influences demographic patterns.