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The number of ribosomal operons in bacterial genomes correlates with both growth rate and carbon use efficiency, likely via proteome allocation trade-offs, providing clues into how microbial communities are structured to make best use of available nutrients.
Structural determination of the secreted haem-binding protein from Candida albicans reveals a novel fold and haem coordination environment that facilitates the shuttling of the haem cofactor across the cell wall to the cell surface.
Technological breakthroughs in cryo-electron microscopy are allowing the capture of virus structures, leading to advances in the field of viral microbiology almost daily. An innovative structure–function study on Aichi virus reveals that novel entry mechanisms, yet undiscovered, may exist for non-enveloped viruses.
Optical and force nanoscopy enable visualization of intracellular and extracellular microbial structures with unprecedented resolution. This Review discusses the principles, advantages and limitations of the main optical and force nanoscopy techniques available.
The spirochaete flagella, unlike those of other bacteria, are located entirely within the periplasm of the bacteria. New work highlights another unique spirochaete characteristic — an unusual covalent linkage that mediates flagellar hook self-polymerization and is required for motility.
Regulation of transcriptional termination in archaea has remained a mystery. Now, a high-throughput RNA sequencing approach identifies multiple archaeal genes that contain consecutive terminators, suggesting new ways by which these microorganisms regulate transcription.
Metagenomic analysis of Antarctic sea-ice and brine reveals the presence of hgcAB-like genes in the microaerophilic marine bacterium Nitrospina. These are similar to ones responsible for mercury methylation in anaerobic microorganisms and provide a plausible mechanism for mercury methylation in oxic marine environments.
A new, publicly available, collection of cultured bacterial species from the mouse gut, the Mouse Intestinal Bacterial Collection, opens up opportunities for deepening microbiome research. Cultured isolates allow the functions of specific species and controlled consortia to be determined through in vitro experimentation.
Patients with atopic dermatitis have fundamentally different skin microbial populations compared with people with healthy skin. Bacteria associated with atopic dermatitis express genes for survival in dry conditions and for ammonia production, modulating the pH of this distinct environment and driving complex ecological interactions.
Accurate estimates of disease burden are possible by building high-resolution geographical models. However, novel pathogens such as Zika virus pose substantial challenges, requiring both new analytical techniques and, where possible, serological surveys.
Protein-synthesizing bacterial and archaeal cells can now be visualized by an adaptation of the BONCAT method, and sorted from complex samples for sequencing. A demonstration on the uncultivated, slow-growing methane-oxidizing consortia shows the high potential of this new method.
A new study provides clues to the physiological function of amyloid-β (Aβ), the plaque-forming peptide associated with Alzheimer's disease and finds a role for Aβ in fighting infection in the brain, by entangling pathogens in a web of amyloid fibrils. These data add to a growing appreciation of the role of microorganisms in neurodegenerative disease.
Scientific analysis of funding support suggests that interdisciplinary research proposals are less successful than those focused on single disciplines. This has negative implications for the development of interdisciplinary research such as microbiology, and may hinder our ability to solve society's grand challenges.
The surprising discovery of viable mutants that retain a peptidoglycan cell wall but lack the essential director of normal cytokinesis, FtsZ, reveals that Escherichia coli can proliferate in a completely unexpected manner.
Deep sequencing of hydrothermal vent and upper ocean water samples further implicate the ocean as a microbial ‘seed bank’. Do these data finally reveal that everything is everywhere? To some extent, but questions remain as to whether these ocean-borne microbes are, in fact, viable and colonize distant locales.
Inspection of more than 286,000 gene families has shed light on the most recent common ancestors of all life. The last universal common ancestor was likely to have been a thermophilic, anaerobic, N2-fixing organism that used the Wood–Ljungdahl pathway to fix CO2, using H2 as an electron donor.
Regulated splicing of some influenza virus RNAs is necessary for the synthesis of various essential proteins. Processing of these transcripts is now found to occur in nuclear speckles, previously considered storage sites for cellular splicing factors.
A combination of metagenomics and stable isotope probing provides new insight into the community-wide degradation of hydrocarbons released during the 2010 Deepwater Horizon oil spill.
Single-particle cryo-electron microscopy is transforming our ability to study the most intimate details of supramolecular multi-protein complexes. The recently observed atomic structure of the T4 phage baseplate paves the way towards understanding the molecular dynamics of other contractile machines such as the bacterial type VI secretion system.