351 research outputs found
Where Next for Microbiome Research?
The development of high-throughput sequencing technologies has transformed our capacity to investigate the composition and dynamics of the microbial communities that populate diverse habitats. Over the past decade, these advances have yielded an avalanche of metagenomic data. The current stage of “van Leeuwenhoek”–like cataloguing, as well as functional analyses, will likely accelerate as DNA and RNA sequencing, plus protein and metabolic profiling capacities and computational tools, continue to improve. However, it is time to consider: what’s next for microbiome research? The short pieces included here briefly consider the challenges and opportunities awaiting microbiome research
An End to Endless Forms: Epistasis, Phenotype Distribution Bias, and Nonuniform Evolution
Studies of the evolution of development characterize the way in which gene
regulatory dynamics during ontogeny constructs and channels phenotypic
variation. These studies have identified a number of evolutionary regularities:
(1) phenotypes occupy only a small subspace of possible phenotypes, (2) the
influence of mutation is not uniform and is often canalized, and (3) a great
deal of morphological variation evolved early in the history of multicellular
life. An important implication of these studies is that diversity is largely the
outcome of the evolution of gene regulation rather than the emergence of new,
structural genes. Using a simple model that considers a generic property of
developmental maps—the interaction between multiple genetic elements
and the nonlinearity of gene interaction in shaping phenotypic
traits—we are able to recover many of these empirical regularities. We
show that visible phenotypes represent only a small fraction of possibilities.
Epistasis ensures that phenotypes are highly clustered in morphospace and that
the most frequent phenotypes are the most similar. We perform phylogenetic
analyses on an evolving, developmental model and find that species become more
alike through time, whereas higher-level grades have a tendency to diverge.
Ancestral phenotypes, produced by early developmental programs with a low level
of gene interaction, are found to span a significantly greater volume of the
total phenotypic space than derived taxa. We suggest that early and late
evolution have a different character that we classify into micro- and
macroevolutionary configurations. These findings complement the view of
development as a key component in the production of endless forms and highlight
the crucial role of development in constraining biotic diversity and
evolutionary trajectories
Rapid Qualitative Urinary Tract Infection Pathogen Identification by SeptiFast® Real-Time PCR
Background
Urinary tract infections (UTI) are frequent in outpatients. Fast pathogen identification is mandatory for shortening the time of discomfort and preventing serious complications. Urine culture needs up to 48 hours until pathogen identification. Consequently, the initial antibiotic regimen is empirical.
Aim
To evaluate the feasibility of qualitative urine pathogen identification by a commercially available real-time PCR blood pathogen test (SeptiFast®) and to compare the results with dipslide and microbiological culture.
Design of study
Pilot study with prospectively collected urine samples.
Setting
University hospital.
Methods
82 prospectively collected urine samples from 81 patients with suspected UTI were included. Dipslide urine culture was followed by microbiological pathogen identification in dipslide positive samples. In parallel, qualitative DNA based pathogen identification (SeptiFast®) was performed in all samples.
Results
61 samples were SeptiFast® positive, whereas 67 samples were dipslide culture positive. The inter-methodological concordance of positive and negative findings in the gram+, gram- and fungi sector was 371/410 (90%), 477/492 (97%) and 238/246 (97%), respectively. Sensitivity and specificity of the SeptiFast® test for the detection of an infection was 0.82 and 0.60, respectively. SeptiFast® pathogen identifications were available at least 43 hours prior to culture results.
Conclusion
The SeptiFast® platform identified bacterial DNA in urine specimens considerably faster compared to conventional culture. For UTI diagnosis sensitivity and specificity is limited by its present qualitative setup which does not allow pathogen quantification. Future quantitative assays may hold promise for PCR based UTI pathogen identification as a supplementation of conventional culture methods
Economic Growth and the Diffusion of Clean Technologies: Explaining Environmental Kuznets Curves
Production often causes pollution as a by-product. Once environmental degradation becomes too severe, regulation is introduced by which society forces the economy to make a transition to cleaner production processes. We model this transition as a change in general purpose technology" and investigate how it interferes with economic growth driven by quality-improvements. The model gives an explanation for the inverted U-shaped pollution-income relation found in empirical research for many pollutants (Environmental Kuznets Curve). We provide an analytical foundation for the claim that the rise and decline of pollution can be explained by policy-induced technology shifts and intrasectoral changes
Most Networks in Wagner's Model Are Cycling
In this paper we study a model of gene networks introduced by Andreas Wagner in the 1990s that has been used extensively to study the evolution of mutational robustness. We investigate a range of model features and parameters and evaluate the extent to which they influence the probability that a random gene network will produce a fixed point steady state expression pattern. There are many different types of models used in the literature, (discrete/continuous, sparse/dense, small/large network) and we attempt to put some order into this diversity, motivated by the fact that many properties are qualitatively the same in all the models. Our main result is that random networks in all models give rise to cyclic behavior more often than fixed points. And although periodic orbits seem to dominate network dynamics, they are usually considered unstable and not allowed to survive in previous evolutionary studies. Defining stability as the probability of fixed points, we show that the stability distribution of these networks is highly robust to changes in its parameters. We also find sparser networks to be more stable, which may help to explain why they seem to be favored by evolution. We have unified several disconnected previous studies of this class of models under the framework of stability, in a way that had not been systematically explored before
Decoupling Environment-Dependent and Independent Genetic Robustness across Bacterial Species
The evolutionary origins of genetic robustness are still under debate: it may arise as a consequence of requirements imposed by varying environmental conditions, due to intrinsic factors such as metabolic requirements, or directly due to an adaptive selection in favor of genes that allow a species to endure genetic perturbations. Stratifying the individual effects of each origin requires one to study the pertaining evolutionary forces across many species under diverse conditions. Here we conduct the first large-scale computational study charting the level of robustness of metabolic networks of hundreds of bacterial species across many simulated growth environments. We provide evidence that variations among species in their level of robustness reflect ecological adaptations. We decouple metabolic robustness into two components and quantify the extents of each: the first, environmental-dependent, is responsible for at least 20% of the non-essential reactions and its extent is associated with the species' lifestyle (specialized/generalist); the second, environmental-independent, is associated (correlation = ∼0.6) with the intrinsic metabolic capacities of a species—higher robustness is observed in fast growers or in organisms with an extensive production of secondary metabolites. Finally, we identify reactions that are uniquely susceptible to perturbations in human pathogens, potentially serving as novel drug-targets
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