Insect mitochondrial genomics: the complete mitochondrial genome sequence of the meadow spittlebug Philaenus spumarius (Hemiptera: Auchenorrhyncha: Cercopoidae).

We present the complete mitochondrial genome sequence of the meadow spittlebug Philaenus spumarius (Auchenorrhyncha: Cercopoidae). This contribution represents the second mitochondrial genome from the Hemiptera and the second of the three hemipteran suborders sampled. The genome is a circular molecule of 16 324 bp with a total A+T content of 77.0% and 76.7% for coding regions only. The gene content, order, and structure are consistent with the Drosophila yakuba genome structure (Clary and Wolstenholme 1985) and the hypothesized ancestral arthropod genome arrangement (Crease 1999). Nucleotide composition and codon usage are near the means observed in other insect mitochondria sequenced to date but have a higher A+T richness compared with the other hemipteran example, the kissing bug Triatoma dimidiata (Dotson and Beard. 2001. Insect Mol. Biol. 10: 205-215). The major noncoding region (the A+T rich region or putative control region) between the small ribosomal subunit and the tRNAIle gene includes two extensive repeat regions. The first repeat region includes 19 tandem repeats of a 46-bp sequence, whereas the second contains a longer sequence (146 bp) tandemly repeated four times.     

Dysregulation of T Lymphocyte Proliferative Responses in Autoimmunity

T cells are critically dependent on cellular proliferation in order to carry out their effector functions. Autoimmune strains are commonly thought to have uncontrolled T cell proliferation; however, in the murine model of autoimmune diabetes, hypo-proliferation of T cells leading to defective AICD was previously uncovered. We now determine whether lupus prone murine strains are similarly hyporesponsive. Upon extensive characterization of T lymphocyte activation, we have observed a common feature of CD4 T cell activation shared among three autoimmune strains–NOD, MRL, and NZBxNZW F1s. When stimulated with a polyclonal mitogen, CD4 T cells demonstrate arrested cell division and diminished dose responsiveness as compared to the non-autoimmune strain C57BL/6, a phenotype we further traced to a reliance on B cell mediated costimulation, which underscores the success of B cell directed immune therapies in preventing T cell mediated tissue injury. In turn, the diminished proliferative capacity of these CD4 T cells lead to a decreased, but activation appropriate, susceptibility to activation induced cell death. A similar decrement in stimulation response was observed in the CD8 compartment of NOD mice; NOD CD8 T cells were distinguished from lupus prone strains by a diminished dose-responsiveness to anti-CD3 mediated stimulation. This distinction may explain the differential pathogenetic pathways activated in diabetes and lupus prone murine strains.     

Effectively Communicating the Uncertainties Surrounding Ebola Virus Transmission

The current Ebola virus outbreak has highlighted the uncertainties surrounding many aspects of Ebola virus virology, including routes of transmission. The scientific community played a leading role during the outbreak—potentially, the largest of its kind—as many of the questions surrounding ebolaviruses have only been interrogated in the laboratory. Scientists provided an invaluable resource for clinicians, public health officials, policy makers, and the lay public in understanding the progress of Ebola virus disease and the continuing outbreak. Not all of the scientific communication, however, was accurate or effective. There were multiple instances of published articles during the height of the outbreak containing potentially misleading scientific language that spurred media overreaction and potentially jeopardized preparedness and policy decisions at critical points. Here, we use articles declaring the potential for airborne transmission of Ebola virus as a case study in the inaccurate reporting of basic science, and we provide recommendations for improving the communication about unknown aspects of disease during public health crises.     

Recognition of the Trachypetidae stat.n. as a new extant family of Ichneumonoidea (Hymenoptera), based on molecular and morphological evidence

The Trachypetinae (type genus Trachypetus Guérin de Méneville) comprise seven species of large-bodied wasps in three genera (Cercobarcon Tobias, Megalohelcon Turner and Trachypetus) endemic to continental Australia. Historically they have been variously treated, as members of the Helconinae in the case of Megalohelcon, or as separate subfamilies (Cercobarconinae and Trachypetinae). Some 25 years ago they were united in a single subfamily, the Trachypetinae, based on a number of characters. Although there has been conflicting evidence from morphological and molecular phylogenetic studies as to how best to treat the group, there has been a growing consensus that they fall outside the rest of the Braconidae, although taxon sampling has been a limiting factor for molecular studies. We generated a molecular dataset comprising five gene fragments (nuclear 28S ribosomal rDNA, nuclear 18S, elongation factor 1-alpha, mitochondrial 16S rDNA, and mitochondrial cytochrome oxidase subunit 1) for a taxonomically broad range of Braconidae, Ichneumonidae, trachypetines and outgroup hymenopterans including the first molecular data for the trachypetines Cercobarcon and Trachypetus obtained using specially designed internal primers. Molecular and combined molecular and morphological analyses confirm the monophyly of the Trachypetinae and robustly place them as sister to the Braconidae. Detailed morphological analysis including newly recognized characters shows that trachypetines lack several synapomorphies that define the Braconidae, and that they possess a number of symplesiomorphies absent from this family but found in some ichneumonids. We conclude that family-level status is warranted for the group based on both molecular and morphological criteria, and hence we propose the new family, Trachypetidae Schulz stat.n. (type genus Trachypetus Guérin de Méneville), for it. As a result, the remaining extant Braconidae become clearly defined based on synapomorphies not present in Trachypetidae stat.n. This published work has been registered on ZooBank, http://zoobank.org/urn:lsid:urn:lsid:zoobank.org:pub:5418F709-D724-4F14-89D8-1E054D1D27D0 .