Adult and Immature Calvertiellidae (Insecta: Palaeodictyoptera) from the Upper Paleozoic of New Mexico and Czechoslovakia

Volume: 83Start Page: 79End Page: 9

9-Genes Reinforce the Phylogeny of Holometabola and Yield Alternate Views on the Phylogenetic Placement of Strepsiptera

Background: The extraordinary morphology, reproductive and developmental biology, and behavioral ecology of twisted wing parasites (order Strepsiptera) have puzzled biologists for centuries. Even today, the phylogenetic position of these enigmatic “insects from outer space” [1] remains uncertain and contentious. Recent authors have argued for the placement of Strepsiptera within or as a close relative of beetles (order Coleoptera), as sister group of flies (order Diptera), or even outside of Holometabola.Methodology/Principal Findings Here, we combine data from several recent studies with new data (for a total of 9 nuclear genes and ∼13 kb of aligned data for 34 taxa), to help clarify the phylogenetic placement of Strepsiptera. Our results unequivocally support the monophyly of Neuropteroidea ( = Neuropterida + Coleoptera) + Strepsiptera, but recover Strepsiptera either derived from within polyphagan beetles (order Coleoptera), or in a position sister to Neuropterida. All other supra-ordinal- and ordinal-level relationships recovered with strong nodal support were consistent with most other recent studies. Conclusions/Significance: These results, coupled with the recent proposed placement of Strepsiptera sister to Coleoptera, suggest that while the phylogenetic neighborhood of Strepsiptera has been identified, unequivocal placement to a specific branch within Neuropteroidea will require additional study.Organismic and Evolutionary Biolog

Single-copy nuclear genes resolve the phylogeny of the holometabolous insects

Background: Evolutionary relationships among the 11 extant orders of insects that undergo complete metamorphosis, called Holometabola, remain either unresolved or contentious, but are extremely important as a context for accurate comparative biology of insect model organisms. The most phylogenetically enigmatic holometabolan insects are Strepsiptera or twisted wing parasites, whose evolutionary relationship to any other insect order is unconfirmed. They have been controversially proposed as the closest relatives of the flies, based on rDNA, and a possible homeotic transformation in the common ancestor of both groups that would make the reduced forewings of Strepsiptera homologous to the reduced hindwings of Diptera. Here we present evidence from nucleotide sequences of six single-copy nuclear protein coding genes used to reconstruct phylogenetic relationships and estimate evolutionary divergence times for all holometabolan orders. Results: Our results strongly support Hymenoptera as the earliest branching holometabolan lineage, the monophyly of the extant orders, including the fleas, and traditionally recognized groupings of Neuropteroidea and Mecopterida. Most significantly, we find strong support for a close relationship between Coleoptera (beetles) and Strepsiptera, a previously proposed, but analytically controversial relationship. Exploratory analyses reveal that this relationship cannot be explained by long-branch attraction or other systematic biases. Bayesian divergence times analysis, with reference to specific fossil constraints, places the origin of Holometabola in the Carboniferous (355 Ma), a date significantly older than previous paleontological and morphological phylogenetic reconstructions. The origin and diversification of most extant insect orders began in the Triassic, but flourished in the Jurassic, with multiple adaptive radiations producing the astounding diversity of insect species for which these groups are so well known. Conclusion: These findings provide the most complete evolutionary framework for future comparative studies on holometabolous model organisms and contribute strong evidence for the resolution of the 'Strepsiptera problem', a long-standing and hotly debated issue in insect phylogenetics

Muscle precursor cells in the developing limbs of two isopods (Crustacea, Peracarida): an immunohistochemical study using a novel monoclonal antibody against myosin heavy chain

In the hot debate on arthropod relationships, Crustaceans and the morphology of their appendages play a pivotal role. To gain new insights into how arthropod appendages evolved, developmental biologists recently have begun to examine the expression and function of Drosophila appendage genes in Crustaceans. However, cellular aspects of Crustacean limb development such as myogenesis are poorly understood in Crustaceans so that the interpretative context in which to analyse gene functions is still fragmentary. The goal of the present project was to analyse muscle development in Crustacean appendages, and to that end, monoclonal antibodies against arthropod muscle proteins were generated. One of these antibodies recognises certain isoforms of myosin heavy chain and strongly binds to muscle precursor cells in malacostracan Crustacea. We used this antibody to study myogenesis in two isopods, Porcellio scaber and Idotea balthica (Crustacea, Malacostraca, Peracarida), by immunohistochemistry. In these animals, muscles in the limbs originate from single muscle precursor cells, which subsequently grow to form multinucleated muscle precursors. The pattern of primordial muscles in the thoracic limbs was mapped, and results compared to muscle development in other Crustaceans and in insects

Origin and biogeography of the beetles (Coleoptera) of the Galapagos Archipelago, Ecuador

The islands, 800-1000 km W of the coast of Ecuador, have been available for terrestial colonization for about 3 million years. At least 54 families, 214 genera and 366 species are present. Comparatively few families (10) contain endemic genera (13) that may represent early colonizations. Species flocks occur in usually flightless members of 7 genera. Adaptive radiation is evident in 3 genera of tenebrionids. The species are 24% native (having naturally dispersed from C or S America), 67% being endemic to ≥1 islands, and 9% have been introduced by man. Virtually nothing is known of the bionomics of the species. The fauna of 335 native and endemic species is estimated to have originated from at least 257 successful ancestral colonizations. Over 3 million years this is an average rate of one successful colonization every 11 700 yr, and 1.4 new species per ancestral colonization. Most of the colonists reached the islands either through the air as "aerial plankton' (60%) or by rafting on oceanic flotsam (39%) from C or S America. Extinctions were more prevalent in "glacial-arid' periods, and colonizations more prevalent in "interglacial-humid' periods. Rate of species introduction has increased with human visitation and colonization. Factors suppressing species proliferation in Galapagos beetles, compared with those in other insular areas, seem to be as follows, in probable order of importance: lack of strong ecological diversity, proximity to mainland areas, proximity of main islands to each other, geological youth, and recent development of a more suitable (wetter) climate. An appendix presents new beetle records for the islands. -from Author

Zoraptera wing structures: evidence for new genera and relationship with the blattoid orders (Insecta: Blattoneoptera)

Abstract. The order Zoraptera has traditionally been thought to contain only one family (Zorotypidae) and one genus (Zorotypus Silvestri). An analysis of known zorapteran wings shows that the wing venation contains character sets indicative of the existence of seven genera: Zorotypus, Brazilozoros gen.n., Centrozoros gen.n., Floridazoros gen.n., Latinozoros gen.n., Meridozoros gen.n. and Usazoros gen.n. The wing venation of Meridozoros leleupi (Weidner) from the Galapagos Islands, Ecuador and Venezuela is described here for the first time. The major wing structures show that Zoraptera belong to the blattoid lineage. Head and abdomen characters indicate that Zoraptera probably diverged from the Blattoneoptera stock early, almost certainly before the (Protelytroptera + Dermaptera) line, and much before the (Isoptera + (Blattodea + Mantodea)) line. A homologized wing vein system is proposed for the Isoptera. The homologized wing vein system is based on the hypothesis that the Pterygota originated with the development of protowings, which then diverged through separate but characteristic adaptations for flapping flight. Therefore the basic wing venation pattern is monophyletic, but the changes in wing musculature, articulation and basic braces between main veins are different in the major (super‐ordinal) pterygote lineages (Pleconeoptera, Orthoneoptera, Blattoneoptera, Hemineoptera and Endoneoptera). Thus, these characters provide an extremely useful, almost untapped, source of data for higher‐level systematics. Both higher‐level and lower‐level wing characters have been applied here to the phylogeny of Zoraptera and are discussed. Copyrigh

Beetles (Coleoptera) of an oil-bird cave: Cueva del Guacharo, Venezuela

A community of 29 species of scavenging, seed-feeding, and predacious beetles is supported by Steatornis caripenis. -from Author