Mitochondrial gene divergence of Colombian Drosophila pseudoobscura

Isolated populations of drosophila pseudoobscura, separated from North American populations by about 2,400 km, were found in Colombia in 1960. We compared for sequences of the small ribosomal RNA (srRNA) gene on the mitochondria between North American and Colombian D. pseudoobscura in order to clarify the age of the Colombian isolates. The North American populations were not genetically different from each other but were genetically different from the Colombian populations. The Mexican strains represent the area from which the Colombian founders might have come. The estimated net nucleotide divergence between Mexican and Colombian D. pseudoobscura indicates that the Colombian population is not an ancient lineage. Phylogenies using both distance and parsimony methodologies reinforced this conclusion. The Colombian samples group together with both methods but, according to the bootstrap analysis, not significantly. It appears that the populations have not been separated long enough for their DNA sequences to show much divergence.      

Species status of Neisseria gonorrhoeae: evolutionary and epidemiological inferences from multilocus sequence typing

Background  

Various typing methods have been developed for Neisseria gonorrhoeae, but none provide the combination of discrimination, reproducibility, portability, and genetic inference that allows the analysis of all aspects of the epidemiology of this pathogen from a single data set. Multilocus sequence typing (MLST) has been used successfully to characterize the related organisms Neisseria meningitidis and Neisseria lactamica. Here, the same seven locus Neisseria scheme was used to characterize a diverse collection of N. gonorrhoeae isolates to investigate whether this method would allow differentiation among isolates, and to distinguish these three species.     

Complement activation by phospholipids: the interplay of factor H and C1q

Complement proteins in blood recognize charged particles. The anionic phospholipid (aPL) cardiolipin binds both complement proteins C1q and factor H. C1q is an activator of the complement classical pathway, while factor H is an inhibitor of the alternative pathway. To examine opposing effects of C1q and factor H on complement activation by aPL, we surveyed C1q and factor H binding, and complement activation by aPL, either coated on microtitre plates or in liposomes. Both C1q and factor H bound to all aPL tested, and competed directly with each other for binding. All the aPL activated the complement classical pathway, but negligibly the alternative pathway, consistent with accepted roles of C1q and factor H. However, in this system, factor H, by competing directly with C1q for binding to aPL, acts as a direct regulator of the complement classical pathway. This regulatory mechanism is distinct from its action on the alternative pathway. Regulation of classical pathway activation by factor H was confirmed by measuring C4 activation by aPL in human sera in which the C1q:factor H molar ratio was adjusted over a wide range. Thus factor H, which is regarded as a down-regulator only of the alternative pathway, has a distinct role in downregulating activation of the classical complement pathway by aPL. A factor H homologue, β2-glycoprotein-1, also strongly inhibits C1q binding to cardiolipin. Recombinant globular domains of C1q A, B and C chains bound aPL similarly to native C1q, confirming that C1q binds aPL via its globular heads.     

Quirks of dye nomenclature. 8. Methylene blue,azure and violet

Methylene blue was synthesized in 1877 and soon found application in medicine, staining for microscopy and as an industrial dye and pigment. An enormous literature has accumulated since its introduction. Early on, it was known that methylene blue could be degraded easily by demethylation; consequently, the purity of commercial samples often was low. Therefore, demethylation products, such as azures and methylene violet, also are considered here. The names and identity of the components, their varying modes of manufacture, analytical methods and their contribution to biological staining are discussed.     

Therian Teeth of Unusual Design from the Mid-Cretaceous (Albian–Cenomanian) Cedar Mountain Formation of Utah

Enigmatic, abundant mammalian teeth from the medial Cretaceous of Utah are shown to belong to antemolar loci, based on dentulous jaw fragments; isolated teeth representing several upper premolar loci and the reconstructed c-p4 series are identified. Three species, differing in size and morphology, can be recognized. Morphological appropriateness, relative abundance, and distributional data indicate that the teeth can be referred with some confidence to the three symmetrodonts known from the Cedar Mountain Formation: Spalacolestes cretulablatta, S. inconcinnus, and Spalacotheridium noblei. If the specimens represent replacement or successional teeth, they are strikingly atypical for Mesozoic mammals, particularly in their low crowns and high degree of molarization at posterior loci. Jaw structure, wear pattern, and aspects of tooth morphology (e.g., proportions, degree of molarization, enamel thickness) favor the alternative hypothesis that these teeth are deciduous. Diphyodonty at all antemolar loci is generally assumed to represent the primitive condition for mammals, though fossil evidence is scant; some of the earliest mammals are known to undergo replacement only at the last premolar locus, with ontogenetic loss (rather than replacement) mesially. Available evidence suggests that, like the eupantothere Dryolestes, North American spalacotheriid symmetrodonts probably underwent single replacement at most or all premolar loci and that the deciduous series became progressively more molariform distally, particularly at the p3–4 loci. Assuming that these teeth are deciduous, their great abundance in the Cedar Mountain Formation (and, apparently, elsewhere in the Cretaceous of North America) suggests that North American spalacotheriids were subject to unusually high juvenile mortality rates or, more probably, that succession at premolar loci took place late in ontogeny, compared to other Mesozoic mammals.     

Protein kinase C�� is required for cardiomyocyte survival and cardiac remodeling

Protein kinase Cs (PKCs) constitute a family of serine/threonine kinases, which has distinguished and specific roles in regulating cardiac responses, including those associated with heart failure. We found that the PKCθ isoform is expressed at considerable levels in the cardiac muscle in mouse, and that it is rapidly activated after pressure overload. To investigate the role of PKCθ in cardiac remodeling, we used PKCθ^−/− mice. In vivo analyses of PKCθ^−/− hearts showed that the lack of PKCθ expression leads to left ventricular dilation and reduced function. Histological analyses showed a reduction in the number of cardiomyocytes, combined with hypertrophy of the remaining cardiomyocytes, cardiac fibrosis, myofibroblast hyper-proliferation and matrix deposition. We also observed p38 and JunK activation, known to promote cell death in response to stress, combined with upregulation of the fetal pattern of gene expression, considered to be a feature of the hemodynamically or metabolically stressed heart. In keeping with these observations, cultured PKCθ^−/− cardiomyocytes were less viable than wild-type cardiomyocytes, and, unlike wild-type cardiomyocytes, underwent programmed cell death upon stimulation with α1-adrenergic agonists and hypoxia. Taken together, these results show that PKCθ maintains the correct structure and function of the heart by preventing cardiomyocyte cell death in response to work demand and to neuro-hormonal signals, to which heart cells are continuously exposed.     

Selective breeding of entomopathogenic nematodes for enhanced attraction to a root signal did not reduce their establishment or persistence after field release

We recently showed that the efficacy of an entomopathogenic nematode (EPN) as a biological control agent against a root pest could be enhanced through artificial selection. The EPN Heterorhabditis bacteriophora was selected for higher responsiveness towards (E)-β-caryophyllene (EβC), a sesquiterpene that is emitted by maize roots in response to feeding damage by the western corn rootworm (WCR). EβC is normally only weakly attractive to H. bacteriophora, which is one of the most infectious nematodes against WCR. By selecting H. bacteriophora to move more readily along a EβC gradient we obtained a strain that was almost twice more efficient in controlling WCR population in fields planted with an EβC-producing maize variety. However, artificial selection for one trait may come at a cost for other important traits such as infectiousness, establishment and/or persistence in the field. Indeed, infectiousness was slightly but significantly reduced in the selected strain. Yet, this apparent cost was largely compensated for by the higher responsiveness to the root signal. Here we show that the selection process had no negative effect on establishment and persistence of field-released EPN. This knowledge, combined with the previously reported results, attest to the feasibility of manipulating key traits to improve the efficacy of beneficial organisms.Key words: entomopathogenic nematodes, tritrophic interactions, artificial selection, biological control, Diabrotica virgifera virgifera, western corn rootworm, persistence, establishmentDiabrotica virgifera virgifera LeConte (Chrysomelidae: Coleptera, western corn rootworm, WCR) is a major well established pest of maize in the American Corn Belt and more recently also in Europe.¹ The larval stages of this beetle can cause significant damages to maize roots, leading to reduction of plant growth, deficiencies in nutrient and water uptake, lodging, increased susceptibility to water stress and reduced grain yield.² This combination of factors result in an estimated loss of one billion US dollars per year in the USA.³ The pest has been introduced in Europe in the early ''90s,⁴ and it is expected that at full establishment the costs resulting from WCR damages will be half a billion Euros.⁵ Several strategies are available to control this soil-dwelling pest, including crop rotation, pesticides and transgenic Bt maize, but WCR can readily evolve resistance to each of these methods.^6–8 This is why efforts have been invested in biological control alternatives.Entomopathogenic nematodes (EPN) show great promise as biological agents against WCR.⁹ Root-produced volatiles appear to play an important role in the recruitment of EPN^10–13 and one such volatile, (E)-β-caryophyllene (EβC), has recently been identified for maize roots¹⁴ and was found to be an ideal below-ground alarm signal.¹⁵ EPN efficacy can be improved by exploiting the ability of WCR-damaged maize roots to emit the attractant.¹⁴ Further studies have shown the importance of choosing the right species of nematodes.¹⁶ Among the EPN species tested against WCR, Heterorhabditis bacteriophora has proven to be one of the most virulent nematodes,¹⁷ but it barely responds to EβC.¹⁶ We therefore recently selected H. bacteriophora for higher responsiveness to EβC.¹⁸ In the field, the selected strain exhibited better abilities to control WCR larvae, but logically only in maize plots with plants that emitted EβC. However, previous studies have shown that enhancing beneficial traits through selective breeding can incur costs and negatively alter other traits in the selected strain.¹⁹ For EPN such trade-offs after selective breeding have also been reported, for instance resulting in reduced storage stability²⁰ or a lower capacity to kill their hosts.²¹ After selection for enhanced responsiveness to EβC response, we observed a small, but significant negative effect on infectiousness of the selected strains. However, this drawback was readily outweighed by the improved ability to locate hosts in the field.¹⁸Not only infectiousness is a crucial trait for the successful use of EPN in biological control: establishment and persistence in the field are of decisive importance as well. These traits vary with EPN species and are determined by biotic factors such as pathogens and predators²² or abiotic factors such as soil type,²³ humidity,²⁴ temperature²⁵ or pH.²⁴ But the main factor that is thought to determine long-term persistence in the field is the presence of available host insects.²⁵ In field trials in Hungary, three EPN species, H. bacteriophora, H. megidis and Steinernema feltiae, were released to test their control potential against WCR. They all persisted at least as long WCR were present in soil, during the same year.²⁶ There was no significant difference between the three species in the establishment or persistence. Yet, independent of timing of application, EPN populations dramatically decreased within five months after application. The authors²⁶ propose that this short persistence is due to the absence of suitable alternative hosts in intensively cultivated crop fields in Europe.To determine if the selection for enhanced responsiveness to EβC went at a cost for establishment and persistence we compared these key traits for the original and the EβC-selected stains. Using a metal auger (2 cm diam.; 20 cm high), 310 soil samples were dug out either two days (establishment) or 28 days (persistence) after EPN application. The soil was placed in plastic boxes (4.5 cm diam.; 60 cm high) and as previously described²⁶ Tenebrio molitor (Coleoptera: Tenebrionidae) larva was placed as bait in the boxes. Presence/absence of EPN was evaluated by visually checking T. molitor larvae for EPN infection. Soil samples from areas where no EPN were applied served as controls. No significant differences were found between the original and selected strain of H. bacteriophora strain (factor “strain”), neither in establishment after two days nor in persistence after 28 days (factor “time”) (Fig. 1, two-way ANOVA, Ftime_1,35 = 2.937, p = 0.097; Fstrain_2,35 = 10.359, p < 0.001; Ftime × strain_2,35 = 1.202, p = 0.315, statistical differences within factors were calculated using a Bonferoni post-hoc test). Hence, the selection of H. bacteriophora for a better response to EβC had no consequence for how the nematodes settled in the experimental fields. Future efforts to improve the effectiveness H. bacteriophora against WCR might also include selection for increased persistence in soil. This would allow lower application rates and could provide growers with an affordable and efficient control strategy against this voracious pest.Open in a separate windowFigure 1Establishment and persistence of the original and a selected strain of H. bacteriophora. The selected strain (squares) established and persisted as well as the original strain (diamonds). The triangles represent control samples from plots where no nematodes were released. Establishment (after two days) and persistence (after 28 days) was equal for both strains. Moreover, the number of soil samples containing EPN after 28 days was not significantly lower than after 2 days, independently of treatment. A few nematodes were detected in the control samples but again no differences over time were detected. Error bars indicate the SEM. Different lower-case letters indicate statistical differences within establishment (after 2 days) or persistence (after 28 days) (p <0.05).So far, manipulation of tritrophic systems in order to improve biological control has been largely theoretical.^27–29 We show here that for EPN this approach is realistic and that their responsiveness to root-produced foraging signals can be enhanced without significant costs for other relevant traits. It has also been shown that the emissions of the signals by the plants can be enhanced.³⁰ Combining these strategies opens new perspectives for the development of ecologically sound strategies in pest management.     

2D proteome analysis initiates new Insights on the Salmonella Typhimurium LuxS protein

Background  

Quorum sensing is a term describing a bacterial communication system mediated by the production and recognition of small signaling molecules. The LuxS enzyme, catalyzing the synthesis of AI-2, is conserved in a wide diversity of bacteria. AI-2 has therefore been suggested as an interspecies quorum sensing signal. To investigate the role of endogenous AI-2 in protein expression of the Gram-negative pathogen Salmonella enterica serovar Typhimurium (S. Typhimurium), we performed a 2D-DIGE proteomics experiment comparing total protein extract of wildtype S. Typhimurium with that of a luxS mutant, unable to produce AI-2.