The importance of the gut-brain axis in maintaining homeostasis has long been appreciated. However, the past 15 yr have seen the emergence of the microbiota (the trillions of microorganisms within ...

The Microbiota-Gut-Brain Axis

Observational findings achieved during the past two decades suggest that the intestinal microbiota may contribute to the metabolic health of the human host and, when aberrant, to the pathogenesis of various common metabolic disorders including obesity, type 2 diabetes, non-alcoholic liver disease, cardio-metabolic diseases and malnutrition. However, to gain a mechanistic understanding of how the gut microbiota affects host metabolism, research is moving from descriptive microbiota census analyses to cause-and-effect studies. Joint analyses of high-throughput human multi-omics data, including metagenomics and metabolomics data, together with measures of host physiology and mechanistic experiments in humans, animals and cells hold potential as initial steps in the identification of potential molecular mechanisms behind reported associations. In this Review, we discuss the current knowledge on how gut microbiota and derived microbial compounds may link to metabolism of the healthy host or to the pathogenesis of common metabolic diseases. We highlight examples of microbiota-targeted interventions aiming to optimize metabolic health, and we provide perspectives for future basic and translational investigations within the nascent and promising research field. In this Review, Fan and Pedersen discuss how the gut microbiota and derived microbial compounds may contribute to human metabolic health and to the pathogenesis of common metabolic diseases, and highlight examples of microbiota-targeted interventions aiming to optimize metabolic health.

Gut microbiota in human metabolic health and disease.

Escherichia coli is the organism of choice for the production of recombinant proteins. Its use as a cell factory is well-established and it has become the most popular expression platform. For this reason, there are many molecular tools and protocols at hand for the high-level production of recombinant proteins, such as a vast catalog of expression plasmids, a great number of engineered strains and many cultivation strategies. We review the different approaches for the synthesis of recombinant proteins in E. coli and discuss recent progress in this ever-growing field.

/pdf/recombinant-protein-expression-in-escherichia-coli-advances-13zp3322p0.pdf

Recombinant protein expression in Escherichia coli: advances and challenges.

Gut Microbiota Regulation of Tryptophan Metabolism in Health and Disease

The gut microbiota benefits humans via short-chain fatty acid (SCFA) production from carbohydrate fermentation, and deficiency in SCFA production is associated with type 2 diabetes mellitus (T2DM). We conducted a randomized clinical study of specifically designed isoenergetic diets, together with fecal shotgun metagenomics, to show that a select group of SCFA-producing strains was promoted by dietary fibers and that most other potential producers were either diminished or unchanged in patients with T2DM. When the fiber-promoted SCFA producers were present in greater diversity and abundance, participants had better improvement in hemoglobin A1c levels, partly via increased glucagon-like peptide-1 production. Promotion of these positive responders diminished producers of metabolically detrimental compounds such as indole and hydrogen sulfide. Targeted restoration of these SCFA producers may present a novel ecological approach for managing T2DM.

http://science.sciencemag.org/content/sci/359/6380/1151.full.pdf

Gut bacteria selectively promoted by dietary fibers alleviate type 2 diabetes

https://www.repository.cam.ac.uk/bitstream/1810/246092/3/Chimerel%20et%20al%202014%20Cell%20Reports.pdf

Bacterial Metabolite Indole Modulates Incretin Secretion from Intestinal Enteroendocrine L Cells

The efficient transmission of multicopy plasmids to daughter cells at division requires that a high copy number is maintained. Plasmid multimers depress copy number, thereby causing instability. Various mechanisms exist to counter multimerization and thus ensure stable maintenance. One well-studied example is the multimer resolution system of the Escherichia coli plasmid ColE1 which carries a recombination site (cer) at which multimers are resolved to monomers by the XerCD recombinase. A promoter within cer initiates synthesis of a short transcript (Rcd) in multimer-containing cells. The Rcd checkpoint hypothesis proposes that Rcd delays cell division until multimer resolution is complete. We have identified tryptophanase (which catabolizes tryptophan to pyruvate and indole) as an Rcd binding protein. Furthermore, the stabilization of multicopy plasmids by Rcd is shown to be tryptophanase dependent, and a tryptophanase-deficient strain is resistant to growth inhibition by Rcd overexpression. Rcd increases the affinity of tryptophanase for its substrate tryptophan which causes increased indole production by cells in low-density cultures. Thus Rcd-mediated stabilization of multicopy plasmids is dependent upon indole acting as a signalling molecule. This is an novel role for this molecule which previously has been implicated in quorum sensing-like processes at high cell density.

https://onlinelibrary.wiley.com/doi/pdf/10.1111/j.1365-2958.2006.05481.x

Indole signalling contributes to the stable maintenance of Escherichia coli multicopy plasmids

Summary
Multimer formation reduces plasmid copy number and is an established cause of segregational instability. Nevertheless, it is difficult to rationalize observations that low levels of dimers can cause severe instability, if we assume they are distributed evenly in cell populations. We report here that dimer distribution is in fact heterogeneous in recombination-proficient strains. Most cells in the population contain only monomers; dimers are confined to a small sub-population from which plasmid-free daughters arise at high frequency. In a rec+ culture where 4% of pBR322 molecules are dimers, more than half are in dimer-only cells. We show that this situation is inevitable because dimers replicate at twice the rate of monomers. Runaway multimerization is avoided because dimer-containing cells grow more slowly than their monomer-containing counterparts. A computer simulation is used to show how dimers proliferate after formation by homologous recombination. The equilibrium concentration of dimers is proportional to the inter-plasmid recombination rate and is essentially independent of the rate at which homologous recombination converts dimers to monomers.

Multicopy plasmid instability: the dimer catastrophe hypothesis

Indole prevents Escherichia coli cell division by modulating membrane potential.

Multicopy plasmids of Escherichia coli are distributed randomly at cell division and, as long as copy number remains high, plasmid-free cells arise only rarely. Copy number variation is minimized by plasmid-encoded control circuits, and the limited data available suggest that deviations are corrected efficiently under most circumstances. However, plasmid multimers confuse control circuits, leading to copy number depression. To make matters worse, multimers out-replicate monomers and accumulate clonally within the culture, creating a subpopulation of cells with a significantly increased rate of plasmid loss. Multimers of natural multicopy plasmids, such as ColE1, are resolved to monomers by a site-specific recombination system (Xer-cer) whose activity is limited to intramolecular recombination. Recombination requires the heterodimeric XerCD recombinase plus two accessory proteins (ArgR and PepA), which activate recombination and prevent intermolecular events. Evidence is accumulating that Xer-cer recombination is relatively slow, and there is a risk that cells might divide before multimer resolution is complete. The Rcd transcript encoded within cer may solve this problem by preventing the division of multimer-containing cells. Working in concert, the triumvirate of copy number control, multimer resolution and cell division control achieve an extremely high fidelity of plasmid maintenance.

Timing, self‐control and a sense of direction are the secrets of multicopy plasmid stability

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