Intestinal Cathelicidin Antimicrobial Peptide Shapes a Protective Neonatal Gut Microbiota Against Pancreatic Autoimmunity.

BACKGROUND & AIMS: Alteration of the gut microbiota is implicated in the development of autoimmune type 1 diabetes (T1D), as shown in humans and the nonobese diabetic (NOD) mouse model. However, how gut dysbiosis arises and promotes the autoimmune response remains an open question. We investigated whether early events affecting the intestinal homeostasis in newborn NOD mice may explain the development of the autoimmune response in the adult pancreas. METHODS: We profiled the transcriptome and the microbiota in the colon between newborn NOD mice and nonautoimmune strains. We identified a seminal defect in the intestinal homeostasis of newborn NOD mice and deciphered the mechanism linking this defect to the diabetogenic response in the adult. RESULTS: We determined that the cathelicidin-related antimicrobial peptide (CRAMP) expression was defective in the colon of newborn NOD mice, allowing inducing dysbiosis. Dysbiosis stimulated the colonic epithelial cells to produce type I interferons that pathologically imprinted the local neonatal immune system. This pathological immune imprinting later promoted the pancreatic autoimmune response in the adult and the development of diabetes. Increasing colonic CRAMP expression in newborn NOD mice by means of local CRAMP treatment or CRAMP-expressing probiotic restored colonic homeostasis and halted the diabetogenic response, preventing autoimmune diabetes. CONCLUSIONS: We identified whether a defective colonic expression in the CRAMP antimicrobial peptide induces dysbiosis, contributing to autoimmunity in the pancreas. Hence, the manipulation of intestinal antimicrobial peptides may be considered a relevant therapeutic approach to prevent autoimmune diabetes in at-risk children.

Single ion free energy calculation in ASIC1: the importance of the HG loop.

Acid Sensing Ion Channels (ASICs) are one of the most studied channels of the Epithelial Sodium Channel/Degenerin (ENaC/DEG) superfamily. They are responsible for excitatory responses following acidification of the extracellular medium and are involved in several important physiological roles. The ASIC1 subunit can form a functional homotrimeric channel and its structure is currently the most characterised of the whole ENaC/DEG family. Here we computed the free energy profiles for single ion permeation in two different structures of ASIC1 using both Na+ and Cl- as permeating ions. The first structure is the open structure of the channel from the PDB entry 4NTW, and the second structure is the closed structure with the re-entrant loop which contains the highly conserved 'HG' motif form PDB entry 6VTK. Both structures show cation selective free energy profiles, however the profiles of the permeating Na+ differ significantly between the two structures. Indeed, whereas there is only a small energetically favorable (-0.5 kcal mol-1) location for Na+ in the open channel (4NTW) near the end of the pore, we observed a clear ion binding site (-7.8 kcal mol-1) located in between the 'GAS' belt and the 'HG' loop for the channel containing the re-entrant loop (6VTK). Knowing that the 'GAS' motif was determined as the selectivity filter, our results support previous observations while addressing the importance of the 'HG' motif for the interactions between the pore and the permeating cations.

Ion Selectivity in the ENaC/DEG Family: A Systematic Review with Supporting Analysis.

The Epithelial Sodium Channel/Degenerin (ENaC/DEG) family is a superfamily of sodium-selective channels that play diverse and important physiological roles in a wide variety of animal species. Despite their differences, they share a high homology in the pore region in which the ion discrimination takes place. Although ion selectivity has been studied for decades, the mechanisms underlying this selectivity for trimeric channels, and particularly for the ENaC/DEG family, are still poorly understood. This systematic review follows PRISMA guidelines and aims to determine the main components that govern ion selectivity in the ENaC/DEG family. In total, 27 papers from three online databases were included according to specific exclusion and inclusion criteria. It was found that the G/SxS selectivity filter (glycine/serine, non-conserved residue, serine) and other well conserved residues play a crucial role in ion selectivity. Depending on the ion type, residues with different properties are involved in ion permeability. For lithium against sodium, aromatic residues upstream of the selectivity filter seem to be important, whereas for sodium against potassium, negatively charged residues downstream of the selectivity filter seem to be important. This review provides new perspectives for further studies to unravel the mechanisms of ion selectivity.

Exploiting the metabolism of PYC expressing HEK293 cells in fed-batch cultures.

The expression of recombinant yeast pyruvate carboxylase (PYC) in animal cell lines was shown in previous studies to reduce significantly the formation of waste metabolites, although it has translated into mixed results in terms of improved cellular growth and productivity. In this work, we demonstrate that the unique phenotype of PYC expressing cells can be exploited through the application of a dynamic fed-batch strategy and lead to significant process enhancements. Metabolically engineered HEK293 cells stably producing human recombinant IFNα2b and expressing the PYC enzyme were cultured in batch and fed-batch modes. Compared to parental cells, the maximum cell density in batch was increased 1.5-fold and the culture duration was extended by 2.5 days, but the product yield was only marginally increased. Further improvements were achieved by developing and implementing a dynamic fed-batch strategy using a concentrated feed solution. The feeding was based on an automatic control-loop to maintain a constant glucose concentration. This strategy led to a further 2-fold increase in maximum cell density (up to 10.7×10(6)cells/ml) and a final product titer of 160mg/l, representing nearly a 3-fold yield increase compared to the batch process with the parental cell clone.