1,444 research outputs found
The developmental environment modulates mating-induced aggression and fighting success in adult female Drosophila
Funding Information Rhodes Trust Brazilian Research Council. Grant Number: 211668/2013‐3 St. John's College, University of Oxford Christ Church College, University of Oxford Biotechnology and Biological Sciences Research Council. Grant Number: BB/K014544/1Peer reviewedPublisher PD
Tumor necrosis factor receptor I blockade shows that TNF-dependent and independent mechanisms synergise in TNF receptor associated periodic syndrome
TNF receptor associated periodic syndrome (TRAPS) is an autoinflammatory disease involving recurrent episodes of fever and inflammation. It is associated with autosomal dominant mutations in TNF receptor superfamily 1A gene localised to exons encoding the ectodomain of the p55 TNF receptor, TNF receptor-1 (TNFR1). The aim of this study was to investigate the role of cell surface TNFR1 in TRAPS, and the contribution of TNF-dependent and TNF-independent mechanisms to the production of cytokines. HEK-293 and SK-HEP-1 cell lines were stably transfected with WT or TRAPS-associated variants of human TNF receptor superfamily 1A gene. An anti-TNFR1 single domain antibody (dAb), and an anti-TNFR1 mAb, bound to cell surface WT and variant TNFR1s. In HEK-293 cells transfected with death domain-inactivated (R347A) TNFR1, and in SK-HEP-1 cells transfected with normal (full-length) TNFR1, cytokine production stimulated in the absence of exogenous TNF by the presence of certain TNFR1 variants was not inhibited by the anti-TNFR1 dAb. In SK-Hep-1 cells, specific TRAPS mutations increased the level of cytokine response to TNF, compared to WT, and this augmented cytokine production was suppressed by the anti-TNFR1 dAb. Thus, TRAPS-associated variants of TNFR1 enhance cytokine production by a TNF-independent mechanism and by sensitising cells to a TNF-dependent stimulation. The TNF-dependent mechanism requires cell surface expression of TNFR1, as this is blocked by TNFR1-specific dAb
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ERA: On-the-fly networking for collaborative geology fieldwork
BACKGROUND
Field-based activities are regarded as essential to the development of a range of professional and personal skills for undergraduate students within geography, earth and environmental sciences. Students are taught investigative skills to enable them to interpret features within the landscape, establish technical skills such as sketching and the use of field equipment, and learn to collaborate with peers. Students enjoy field activities, and these improve deeper learning and understanding. However, due to issues such as cost and access some have little opportunity to participate in field-based studies. The ERA (Enabling Remote Activity) project is investigating how mobile and communication technologies might enhance field learning experiences for all participants. We identify two ways in which supporting technologies can enable greater participation and add value to existing fieldwork: remote access and collaborative groupwork.
METHODS
In 2006 we enabled a single mobility impaired student to direct a remote geologist in the field, supporting remote access. A rapidly deployable, lightweight, battery powered wireless network was built (which we refer to as an ‘on-the fly network’) to enable the transmission of video, audio, and high resolution still images from the field to the student. In 2007 we supported three groups of volunteers undertaking remote collaboration, with half the participants in a university laboratory and the others in the field location. Each group was carrying out a separate specific geological investigation; graphic logging, paleontology, or mineralogy and paleocurrents. A network infrastructure supported communication and data transmission between the groups. Field and laboratory participants had their own distinct, significant roles and the trials explored how technology enhanced collaboration may be used to improve student learning.
CONTRIBUTION
ERA has tested highly mobile, easily configurable low cost network tools to explore how on-the-fly networking can support geology field studies at undergraduate level in remote locations. We have explored two differing configurations, developed through a collaborative design process undertaken between technology developers and course managers.
EVALUATION AND REFLECTION
A range of evaluation tools were used to enable analysis of the trials. Field journals were kept by all participants, which found ready acceptance with the geologists as an extension of their standard practice of keeping field notes. A wiki was used by the technical team to capture lessons learnt during the development and trial periods. Participants were gathered together for post-trial debrief sessions. In the second trial, participants’ responses were collected through written questionnaires and focus group discussions (audio recorded). Participants’ activities were also captured on video camera and this was analysed to capture critical incidents. Key findings underline the importance of co-designing technology and pedagogy, orchestration of multiple groups, on-site testing, and planning for graceful degradation of technologies and learning activities.
In 2008 we will be looking to move the system from a development prototype to a production model that could be could be replicated by geology departments across the UK without intensive technical support, and the proving of specific technical enhancements including VOIP (Voice Over Internet Protocol) communication and the use of wireless digital cameras
Local association of Trypanosoma cruzi chronic infection foci and enteric neuropathic lesions at the tissue micro-domain scale
Chagas disease (American trypanosomiasis) is caused by the protozoan parasite Trypanosoma cruzi. Chagas disease has two types, the cardiac form and the digestive form; some patients have symptoms of both. How the parasite causes digestive disease is poorly understood. It is known that damage to the gut’s nervous system is an important factor, but it has been unclear exactly where and when this damage occurs during the course of an infection and also why only a subset of infected people suffer from this outcome. We studied infections in mice and found certain combinations of strains of parasites and mice that exhibited symptoms similar to human digestive Chagas patients, including a problem with peristalsis that localised specifically to the colon. Using parasites that were genetically engineered to emit both bioluminescent and fluorescent light, we tracked infections over time and were able to analyse rare infected cells deep within the muscle tissue of the wall of the colon. We found evidence of damaged neurons in the same location as these infection foci over 6 months after initial infection. Our results show that digestive Chagas disease probably develops as a result of chronic infection and inflammation, which potentially changes approaches to treatment
In Vivo Analysis of Trypanosoma cruzi Persistence Foci at Single-Cell Resolution
Infections with Trypanosoma cruzi are usually lifelong despite generating a strong adaptive immune response. Identifying the sites of parasite persistence is therefore crucial to understanding how T. cruzi avoids immune-mediated destruction. However, this is a major technical challenge, because the parasite burden during chronic infections is extremely low. Here, we describe an integrated approach involving comprehensive tissue processing, ex vivo imaging, and confocal microscopy, which allowed us to visualize infected host cells in murine tissue with exquisite sensitivity. Using bioluminescence-guided tissue sampling, with a detection level of 200 parasites, which we term mega-nests. In contrast, during the acute stage, when the total parasite burden is considerably higher and many cells are infected, nests containing >50 parasites are rarely found. In C3H/HeN mice, but not BALB/c mice, we identified skeletal muscle as a major site of persistence during the chronic stage, with most parasites being found in large mega-nests within the muscle fibers. Finally, we report that parasites are also frequently found in the skin during chronic murine infections, often in multiple infection foci. In addition to being a site of parasite persistence, this anatomical reservoir could play an important role in insect-mediated transmission and have implications for drug development.IMPORTANCETrypanosoma cruzi causes Chagas disease, the most important parasitic infection in Latin America. Major pathologies include severe damage to the heart and digestive tract, although symptoms do not usually appear until decades after infection. Research has been hampered by the complex nature of the disease and technical difficulties in locating the extremely low number of parasites. Here, using highly sensitive imaging technology, we reveal the sites of parasite persistence during chronic-stage infections of experimental mice at single-cell resolution. We show that parasites are frequently located in smooth muscle cells in the circular muscle layer of the colon and that skeletal muscle cells and the skin can also be important reservoirs. This information provides a framework for investigating how the parasite is able to survive as a lifelong infection, despite a vigorous immune response. It also informs drug development strategies by identifying tissue sites that must be accessed to achieve a curative outcome
Species assembly in model ecosystems, II: Results of the assembly process
In the companion paper of this set (Capitan and Cuesta, 2010) we have
developed a full analytical treatment of the model of species assembly
introduced in Capitan et al. (2009). This model is based on the construction of
an assembly graph containing all viable configurations of the community, and
the definition of a Markov chain whose transitions are the transformations of
communities by new species invasions. In the present paper we provide an
exhaustive numerical analysis of the model, describing the average time to the
recurrent state, the statistics of avalanches, and the dependence of the
results on the amount of available resource. Our results are based on the fact
that the Markov chain provides an asymptotic probability distribution for the
recurrent states, which can be used to obtain averages of observables as well
as the time variation of these magnitudes during succession, in an exact
manner. Since the absorption times into the recurrent set are found to be
comparable to the size of the system, the end state is quickly reached (in
units of the invasion time). Thus, the final ecosystem can be regarded as a
fluctuating complex system where species are continually replaced by newcomers
without ever leaving the set of recurrent patterns. The assembly graph is
dominated by pathways in which most invasions are accepted, triggering small
extinction avalanches. Through the assembly process, communities become less
resilient (e.g., have a higher return time to equilibrium) but become more
robust in terms of resistance against new invasions.Comment: 14 pages, 13 figures. Revised versio
Physiological deterioration in the Emergency Department: the SNAP40-ED study
Continuous novel ambulatory monitoring may detect deterioration in Emergency Department (ED) patients more rapidly, prompting treatment and preventing adverse events. Single-centre, open-label, prospective, observational cohort study recruiting high/medium acuity (Manchester triage category 2 and 3) participants, aged over 16 years, presenting to ED. Participants were fitted with a novel wearable monitoring device alongside standard clinical care (wired monitoring and/or manual clinical staff vital sign recording) and observed for up to 4 hours in the ED. Primary outcome was time to detection of deterioration. Two-hundred and fifty (250) patients were enrolled. In 82 patients (32.8%) with standard monitoring (wired monitoring and/or manual clinical staff vital sign recording), deterioration in at least one vital sign was noted during their four-hour ED stay. Overall, the novel device detected deterioration a median of 34 minutes earlier than wired monitoring (Q1, Q3 67,194; n=73, mean difference 39.48, p<0.0001). The novel device detected deterioration a median of 24 minutes (Q1, Q3 2,43; n=42) earlier than wired monitoring and 65 minutes (Q1, Q3 28,114; n=31) earlier than manual vital signs. Deterioration in physiology was common in ED patients. ED staff spent a significant amount of time performing observations and responding to alarms, with many not escalated. The novel device detected deterioration significantly earlier than standard care
Species assembly in model ecosystems, I: Analysis of the population model and the invasion dynamics
Recently we have introduced a simplified model of ecosystem assembly (Capitan
et al., 2009) for which we are able to map out all assembly pathways generated
by external invasions in an exact manner. In this paper we provide a deeper
analysis of the model, obtaining analytical results and introducing some
approximations which allow us to reconstruct the results of our previous work.
In particular, we show that the population dynamics equations of a very general
class of trophic-level structured food-web have an unique interior equilibrium
point which is globally stable. We show analytically that communities found as
end states of the assembly process are pyramidal and we find that the
equilibrium abundance of any species at any trophic level is approximately
inversely proportional to the number of species in that level. We also find
that the per capita growth rate of a top predator invading a resident community
is key to understand the appearance of complex end states reported in our
previous work. The sign of these rates allows us to separate regions in the
space of parameters where the end state is either a single community or a
complex set containing more than one community. We have also built up
analytical approximations to the time evolution of species abundances that
allow us to determine, with high accuracy, the sequence of extinctions that an
invasion may cause. Finally we apply this analysis to obtain the communities in
the end states. To test the accuracy of the transition probability matrix
generated by this analytical procedure for the end states, we have compared
averages over those sets with those obtained from the graph derived by
numerical integration of the Lotka-Volterra equations. The agreement is
excellent.Comment: 16 pages, 8 figures. Revised versio
In Vivo Analysis of Trypanosoma cruzi Persistence Foci at Single-Cell Resolution.
Infections with Trypanosoma cruzi are usually lifelong despite generating a strong adaptive immune response. Identifying the sites of parasite persistence is therefore crucial to understanding how T. cruzi avoids immune-mediated destruction. However, this is a major technical challenge, because the parasite burden during chronic infections is extremely low. Here, we describe an integrated approach involving comprehensive tissue processing, ex vivo imaging, and confocal microscopy, which allowed us to visualize infected host cells in murine tissue with exquisite sensitivity. Using bioluminescence-guided tissue sampling, with a detection level of 200 parasites, which we term mega-nests. In contrast, during the acute stage, when the total parasite burden is considerably higher and many cells are infected, nests containing >50 parasites are rarely found. In C3H/HeN mice, but not BALB/c mice, we identified skeletal muscle as a major site of persistence during the chronic stage, with most parasites being found in large mega-nests within the muscle fibers. Finally, we report that parasites are also frequently found in the skin during chronic murine infections, often in multiple infection foci. In addition to being a site of parasite persistence, this anatomical reservoir could play an important role in insect-mediated transmission and have implications for drug development.IMPORTANCE Trypanosoma cruzi causes Chagas disease, the most important parasitic infection in Latin America. Major pathologies include severe damage to the heart and digestive tract, although symptoms do not usually appear until decades after infection. Research has been hampered by the complex nature of the disease and technical difficulties in locating the extremely low number of parasites. Here, using highly sensitive imaging technology, we reveal the sites of parasite persistence during chronic-stage infections of experimental mice at single-cell resolution. We show that parasites are frequently located in smooth muscle cells in the circular muscle layer of the colon and that skeletal muscle cells and the skin can also be important reservoirs. This information provides a framework for investigating how the parasite is able to survive as a lifelong infection, despite a vigorous immune response. It also informs drug development strategies by identifying tissue sites that must be accessed to achieve a curative outcome
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