Conflicting mitochondrial and nuclear paraphyly in small‐sized West African house bats (Vespertilionidae)

Vallo, P., Benda, P., Červený, J. & Koubek, P. (2012). Conflicting mitochondrial and nuclear paraphyly in small‐sized West African house bats (Vespertilionidae). —Zoologica Scripta, 42, 1–12. Hybridization between species may result in introgression of mitochondrial DNA from one species to another. Phylogenetic inference, therefore, may not recover true evolutionary relationships. In bats, there are only a few reported cases of introgressive hybridization. House bats are a genus with obscure phylogeny and taxonomy, caused mainly by morphological similarity. We undertook a detailed analysis of small‐sized West African house bats (Scotophilus), tentatively identified as S. nigritellus, to clarify relationships between two sympatric colour forms. These forms were recovered in paraphyletic position to each other in both mitochondrial and nuclear phylogenies, signifying that they are two distinct species. While the yellow‐bellied form could be assigned beyond doubt to S. nigritellus s. str., the white‐bellied form may be an as yet undescribed species. Moreover, the white‐bellied form clustered as a sister mitochondrial lineage to another species, Scotophilus leucogaster. These sister lineages differed by only 2.6–2.8% sequence divergence, which lies within the intraspecific range for this genus. Two nuclear markers, however, contradicted the sister relationship, showing them instead to be distantly related. The apparent conflict between the mitochondrial and nuclear signals suggests that past hybridization may have occurred between these morphologically distinct species.     

Experimental suppression of ants foraging on rainforest vegetation in New Guinea: testing methods for a whole‐forest manipulation of insect communities

1. Ants are extremely abundant in lowland tropical forests where they are important predators, plant mutualists, and herbivores. Their complex role in tropical plant–insect food webs can be best assessed by experimental manipulation of their abundance. Historically, ant exclusion experiments have had a small‐scale focus, such as single trees. Here, we test a new ‘whole‐forest' method of ant exclusion, using treated canopy bait stations, in a diverse tropical rainforest in New Guinea. 2. We conducted a 10‐month manipulative experiment in primary and secondary rainforests. In each forest type, a 625 m² treatment plot was isolated from the surrounding forest and 135 bait stations treated with fipronil, S‐methoprene, and hydramethylnon were placed in trees to suppress ants. Ant activity was monitored in the forest canopy and understorey with an additional 65 stations in treatment and control plots. 3. We achieved a dramatic decline in ant abundance in treatment plots compared with controls in both forest types, with an average decrease in ant numbers per station of 82.4% in primary and 91.2% in secondary forest. In particular, native dominant species Oecophylla smaragdina, Anonychomyrma cf. scrutator in primary forest, and invasive Anoplolepis gracilipes in secondary forest were greatly affected. In contrast, Tapinoma melanocephalum flourished in treatment plots, perhaps benefiting from reduced competition from other ant species. 4. Our study demonstrates that it is possible to selectively eradicate most of the foraging ants in a structurally complex tropical forest. We propose whole‐forest manipulation as a novel tool for studying the role of ants in shaping plant–insect food webs.     

The role of size and colour pattern in protection of developmental stages of the red firebug (Pyrrhocoris apterus) against avian predators

We investigated how predator/prey body‐size ratio and prey colour pattern affected efficacy of prey warning signals. We used great and blue tits (Parus major and Cyanistes caeruleus), comprising closely related and ecologically similar bird species differing in body size, as experimental predators. Two larval instars and adults of the unpalatable red firebug (Pyrrhocoris apterus), differing in body size and/or coloration, were used as prey. We showed that prey body size did not influence whether a predator attacked the prey or not during the first encounter. However, smaller prey were attacked, killed, and eaten more frequently in repetitive encounters. We assumed that body size influences the predator through the amount of repellent chemicals better than through the amount of optical warning signal. The larger predator attacked, killed and ate all forms of firebug more often than the smaller one. The difference between both predators was more pronounced in less protected forms of firebug (chemically as well as optically). Colour pattern also substantially affected the willingness of predators to attack the prey. Larval red–black coloration did not provide a full‐value warning signal, although a similarly conspicuous red‐black coloration of the adults reliably protected them. © 2010 The Linnean Society of London, Biological Journal of the Linnean Society, 2010, 100 , 890–898.     

Inferring larval taxonomy and morphology in Maladera species (Coleoptera: Scarabaeidae: Sericini) using DNA taxonomy tools

Based on a comparative molecular study of scarab chafers we matched adult and larval instars to identify and describe unknown larvae of Sericini. Here, we use for the first time a two‐fold DNA taxonomy approach based on: (i) mitochondrial and nuclear DNA markers of a local sample (from Nepal) of adults and larvae, in combination with character and tree‐based species delimitation methods; and (ii) a global search of cytochrome c oxidase subunit I (cox1) sequences with GenBank data. In the latter analysis we used a sequence of a specimen that resulted in the first analysis conspecific with the larvae of Maladera affinis (Blanchard) as the query sequence in GenBank, and checked in a minimum evolution tree whether larva–adult matches from the local approach were altered through interference with other taxa of the worldwide database. Both approaches unambiguously identified the unknown larvae as belonging to M. affinis and Maladera cardoni (Brenske). Based on this robust framework of taxonomic identification we could associate names to the larval morphology of the third larval instar of these two Nepalese Maladera species, which are both known for their economical importance in agriculture. They are described here in detail and are compared with known related taxa, especially with Maladera castanea (Arrow).     

Mark–recapture on large spatial scale reveals long distance dispersal in the Marsh Fritillary,Euphydryas aurinia

1. Long distance dispersal (LDD), or movements far beyond the occupied habitat borders, maintains the integrity of metapopulations in fragmented landscapes. Recent studies on butterflies increasingly reveal that LDD exists even in species that were long regarded as sedentary. Mark–recapture (MR) studies covering larger study areas typically reveal movements among distant colonies. 2. We studied dispersal of the EU‐protected, regionally endangered Euphydryas aurinia Rottemburg butterfly in the Czech Republic, using two complementary MR approaches. The single system study was carried out for eight seasons within 30 habitat patches covering 28 ha. The multiple populations study was carried out for a single season, but covering almost all Czech colonies of the species (82 colonies, 110 distinct patches, total area 324 ha within ca 1500 km²). 3. Single system mean lifetime movements were consistently higher for males, but slopes of dispersal kernel power functions were shallower for females, implying that higher proportions of females crossed distances of several kilometres. 4. The multiple populations study allowed detection of 51 lifetime movements exceeding 5 km (41 males, 10 females) and 14 movements exceeding 10 km (13 males, 1 female). Both mean lifetime movements and slopes of the dispersal kernels varied among systems, with no consistent pattern between sexes. All Czech Republic populations are within 0.1% movement probability of both sexes, whereas 1% movement probability delimits three separate management units. 5. Dispersal predictions from local data underestimate total mobility, warning against the use of local MR data for extrapolating long‐distance movements. Local dispersal data, however, remain useful for analysing finer details of insect mobility.