An investigation into the relevance of the pattern of temporal activation with respect to erector spinae muscle endurance

The aim of the present study was to evaluate the viability of a relationship between the temporal activation pattern of parts of the erector spinae muscle and endurance. Seven subjects performed intermittent isometric contractions [4 s at 7007o maximal voluntary contraction (MVC), 2 s rest] until exhaustion, during which the electromyographical (EMG) activity of the multifidus, iliocostalis thoracis and longissimus muscle segments was recorded. Endurance was defined as the time until exhaustion. Subjects were divided into a high and a low endurance group. The high endurance group showed significantly more variability of EMG amplitude over succeeding contractions. This group demonstrated significantly more alternations of EMG activity between parts of the muscle also. Variability of the EMG amplitude within the contractions did not differ between the groups, nor did MVC. The results indicated that alternating activity between different parts of the erector spinae muscle may function to postpone exhaustion of this muscle as a whole.     

Trypanosomiasis-induced Th17-like immune responses in carp

Background

In mammalian vertebrates, the cytokine interleukin (IL)-12 consists of a heterodimer between p35 and p40 subunits whereas interleukin-23 is formed by a heterodimer between p19 and p40 subunits. During an immune response, the balance between IL-12 and IL-23 can depend on the nature of the pathogen associated molecular pattern (PAMP) recognized by, for example TLR2, leading to a preferential production of IL-23. IL-23 production promotes a Th17-mediated immune response characterized by the production of IL-17A/F and several chemokines, important for neutrophil recruitment and activation. For the cold blooded vertebrate common carp, only the IL-12 subunits have been described so far.

Methodology/Principal Findings

Common carp is the natural host of two protozoan parasites: Trypanoplasma borreli and Trypanosoma carassii. We found that these parasites negatively affect p35 and p40a gene expression in carp. Transfection studies of HEK293 and carp macrophages show that T. carassii-derived PAMPs are agonists of carp TLR2, promoting p19 and p40c gene expression. The two protozoan parasites induce different immune responses as assessed by gene expression and histological studies. During T. carassii infections, in particular, we observed a propensity to induce p19 and p40c gene expression, suggestive of the formation of IL-23. Infections with T. borreli and T. carassii lead to an increase of IFN-γ2 gene expression whereas IL-17A/F2 gene expression was only observed during T. carasssii infections. The moderate increase in the number of splenic macrophages during T. borreli infection contrasts the marked increase in the number of splenic neutrophilic granulocytes during T. carassii infection, along with an increased gene expression of metalloproteinase-9 and chemokines.

Conclusion/Significance

This is the first study that provides evidence for a Th17-like immune response in fish in response to infection with a protozoan parasite.     

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.     

Biological Nitrogen Fixation is not a Major Contributor to the Nitrogen Demand of a Commercially Grown South African Sugarcane Cultivar

It has previously been reported that endophytic diazotrophic bacteria contribute significantly to the nitrogen budgets of some graminaceous species. In this study the contribution of biological nitrogen fixation to the N-budget of a South African sugarcane cultivar was evaluated using ¹⁵N natural abundance, acetylene reduction and ¹⁵N incorporation. Plants were also screened for the presence of endophytic diazotrophic bacteria using acetylene reduction and nifH-gene targeted PCR with the pure bacterial strains. ¹⁵N natural abundance studies on field-grown sugarcane indicated that the plants did not rely extensively on biological nitrogen fixation. Furthermore, no evidence was found for significant N₂-fixation or nitrogenase activity in field-grown or glasshouse-grown plants using ¹⁵N incorporation measurements and acetylene reduction assays. Seven endophytic bacterial strains were isolated from glasshouse-grown and field-grown plants and cultured on N-free medium. The diazotrophic character of these seven strains could not be confirmed using acetylene reduction and PCR screening for nifH. Thus, although biological nitrogen fixation may occur in South African sugarcane varieties, the contribution of this N-source in the tested cultivar was not significant.     

A tritrophic signal that attracts parasitoids to host-damaged plants withstands disruption by non-host herbivores

Background  

Volatiles emitted by herbivore-infested plants are highly attractive to parasitoids and therefore have been proposed to be part of an indirect plant defense strategy. However, this proposed function of the plant-provided signals remains controversial, and it is unclear how specific and reliable the signals are under natural conditions with simultaneous feeding by multiple herbivores. Phloem feeders in particular are assumed to interfere with plant defense responses. Therefore, we investigated how attack by the piercing-sucking cicadellid Euscelidius variegatus influences signaling by maize plants in response to the chewing herbivore Spodoptera littoralis.     

Next-generation sequencing identifies mutations of SMPX, which encodes the small muscle protein, X-linked, as a cause of progressive hearing impairment

In a Dutch family with an X-linked postlingual progressive hearing impairment, a critical linkage interval was determined to span a region of 12.9 Mb flanked by the markers DXS7108 and DXS7110. This interval overlaps with the previously described DFNX4 locus and contains 75 annotated genes. Subsequent next-generation sequencing (NGS) detected one variant within the linkage interval, a nonsense mutation in SMPX. SMPX encodes the small muscle protein, X-linked (SMPX). Further screening was performed on 26 index patients from small families for which X-linked inheritance of nonsyndromic hearing impairment (NSHI) was not excluded. We detected a frameshift mutation in SMPX in one of the patients. Segregation analysis of both mutations in the families in whom they were found revealed that the mutations cosegregated with hearing impairment. Although we show that SMPX is expressed in many different organs, including the human inner ear, no obvious symptoms other than hearing impairment were observed in the patients. SMPX had previously been demonstrated to be specifically expressed in striated muscle and, therefore, seemed an unlikely candidate gene for hearing impairment. We hypothesize that SMPX functions in inner ear development and/or maintenance in the IGF-1 pathway, the integrin pathway through Rac1, or both.     

Green fluorescent protein-based biosensor to detect and quantify stress responses induced by DNA-degrading colicins

Here we report the development of a whole-cell biosensor to detect and quantify the induction of the SOS response activated by DNA-degrading colicins. This biosensor utilizes the SOS-responsive cda promoter to regulate the expression of green fluorescent protein. The biosensor assay revealed induction of stress for all DNA-degrading reference colicins (E2, E7, and E8).