Harriet Nilsson

The gut microbiota influences blood-brain barrier permeability in mice

The intestinal microbiota helps to maintain the integrity of the blood-brain barrier in fetal and adult mice. The Gut Microbiota and the Blood-Brain Barrier The blood-brain barrier is an important gateway that controls the passage of molecules and nutrients in and out of the brain. An intact blood-brain barrier is a crucial checkpoint for appropriate development and function of the brain. Braniste et al. now show that germ-free pregnant dams, devoid of maternal microbes, have offspring that show increased permeability of the blood-brain barrier. This elevated permeability was also observed in adult germ-free mice. However, fecal transplants from mice exposed to bacteria into adult germ-free mice reduced blood-brain barrier permeability, possibly through the regulation of tight junction proteins. These findings suggest that crosstalk between the gut microbiota and the brain, initiated during the intrauterine period, is perpetuated throughout life. Pivotal to brain development and function is an intact blood-brain barrier (BBB), which acts as a gatekeeper to control the passage and exchange of molecules and nutrients between the circulatory system and the brain parenchyma. The BBB also ensures homeostasis of the central nervous system (CNS). We report that germ-free mice, beginning with intrauterine life, displayed increased BBB permeability compared to pathogen-free mice with a normal gut flora. The increased BBB permeability was maintained in germ-free mice after birth and during adulthood and was associated with reduced expression of the tight junction proteins occludin and claudin-5, which are known to regulate barrier function in endothelial tissues. Exposure of germ-free adult mice to a pathogen-free gut microbiota decreased BBB permeability and up-regulated the expression of tight junction proteins. Our results suggest that gut microbiota–BBB communication is initiated during gestation and propagated throughout life.

Bicarbonate and functional CFTR channel are required for proper mucin secretion and link cystic fibrosis with its mucus phenotype

Ileal mucus in CftrΔ508 mice is more adherent, denser, and less penetrable than that of WT mice, but addition of bicarbonate normalizes the properties of CftrΔ508 mucus.

Calcium and pH-dependent packing and release of the gel-forming MUC2 mucin

MUC2, the major colonic mucin, forms large polymers by N-terminal trimerization and C-terminal dimerization. Although the assembly process for MUC2 is established, it is not known how MUC2 is packed in the regulated secretory granulae of the goblet cell. When the N-terminal VWD1-D2-D′D3 domains (MUC2-N) were expressed in a goblet-like cell line, the protein was stored together with full-length MUC2. By mimicking the pH and calcium conditions of the secretory pathway we analyzed purified MUC2-N by gel filtration, density gradient centrifugation, and transmission electron microscopy. At pH 7.4 the MUC2-N trimer eluted as a single peak by gel filtration. At pH 6.2 with Ca2+ it formed large aggregates that did not enter the gel filtration column but were made visible after density gradient centrifugation. Electron microscopy studies revealed that the aggregates were composed of rings also observed in secretory granulae of colon tissue sections. The MUC2-N aggregates were dissolved by removing Ca2+ and raising pH. After release from goblet cells, the unfolded full-length MUC2 formed stratified layers. These findings suggest a model for mucin packing in the granulae and the mechanism for mucin release, unfolding, and expansion.

CFTR and tight junctions in cultured bronchial epithelial cells.

Airway epithelial salt and water transport takes place through paracellular and transcellular pathways. This transport depends critically on the epithelial sodium channel (ENaC) and the cystic fibrosis transmembrane conductance regulator (CFTR), operating in concert with the paracellular pathway through the tight junctions (TJ). Normal (16HBE14o-), cystic fibrosis (CFBE41o-), and corrected CFBE41o- (CFBE41o-pCep4 overexpressing wtCFTR) airway epithelial cell lines were cultured under isotonic conditions. Transepithelial electrical resistance (TEER) was measured as indicator of the tightness of the cultures. Morphology was investigated by immunofluorescence and paracellular permeability by lanthanum nitrate or [14C] mannitol as permeability markers. The CFTR-defective cell line CFBE41o- developed higher TEER than its corrected counterpart CFBE41o-pCep4. Addition of a specific inhibitor of CFTR (CFTR(inh)-172) to 16HBE14o- and CFBE41o-pCep4 cells resulted in a time-dependent increase in TEER, whereas stimulation of CFTR by IBMX and forskolin caused a decrease. Permeability to lanthanum and [14C] mannitol was lower in CFBE41o- and in 16HBE14o- cells exposed to CFTR(inh)-172, compared to untreated 16HBE14o- and CFBE41o-pCep4 cells, respectively. 16HBE14o- cells exposed to IBMX and forskolin showed higher permeability to lanthanum but lower permeability to [14C] mannitol compared to control. Immunofluorescence revealed a disorganization of F-actin and alpha-tubulin in 16HBE14o- cells and CFBE41o- pCep4 exposed to CFTR(inh)-172 and in CFBE41o- cells. Changes in F-actin and alpha-tubulin in 16HBE14o- cells exposed to IBMX and forskolin were also seen. These results suggest the possibility of an interaction between CFTR and the TJ protein complex, probably via the cytoskeleton.

The normal trachea is cleaned by MUC5B mucin bundles from the submucosal glands coated with the MUC5AC mucin

To understand the mucociliary clearance system, mucins were visualized by light, confocal and electron microscopy, and mucus was stained by Alcian blue and tracked by video microscopy on tracheal explants of newborn piglets. We observed long linear mucus bundles that appeared at the submucosal gland openings and were transported cephalically. The mucus bundles were shown by mass spectrometry and immunostaining to have a core made of MUC5B mucin and were coated with MUC5AC mucin produced by surface goblet cells. The transport speed of the bundles was slower than the airway surface liquid flow. We suggest that the goblet cell MUC5AC mucin anchors the mucus bundles and thus controls their transport. Normal clearance of the respiratory tree of pigs and humans, both rich in submucosal glands, is performed by thick and long mucus bundles.

X-ray Microanalysis of Apical Fluid in Cystic Fibrosis Airway Epithelial Cell Lines

The ionic composition of the fluid lining the airways (airway surface liquid, ASL) in healthy subjects and patients with cystic fibrosis (CF) has been a matter of controversy. It has been attempted to resolve conflicting theories by using cell cultures, but published results show a wide variety of values for the ionic concentrations in the apical fluid in these cultures. To investigate CFTR-mediated HCO 3 -conductance and the role of HCO 3 - in regulating ASL pH we determined the pH of the fluid covering the apical surface of airway epithelial cells. A normal (16HBE14o - ) and a CF (CFBE41o - ) bronchial epithelial cell line were grown on membrane inserts in both a liquid-liquid interface culture system for 7 days, and in an air-liquid interface culture system for one month. The elemental composition of the fluid covering the apical surface was determined by X-ray microanalysis of frozen-hydrated specimens, or by X-ray microanalysis of Sephadex beads that had been equilibrated with the apical fluid. Analysis showed that the apical fluid had a Na + and Cl -concentration of about 80-100 mM and thus was slightly hypotonic. The ionic concentrations were somewhat higher in air-liquid interface than in liquid-liquid interface cultures. The apical fluid in CF cells had significantly higher concentrations of Na and Cl than that in control cultures. In control cultures, the concentrations of Na and Cl in the apical fluid increased if glibenclamide, an inhibitor of the cystic fibrosis transmembrane conductance regulator (CFTR) was added to the apical medium. Exposing the cells to the metabolic inhibitor NaCN also resulted in a significant increase of the Na and Cl concentrations in the apical fluid. The results agree with the notion that these cell cultures are mainly absorptive cells, and that ion absorption by the CF cells is reduced compared to that in normal cells. The pH measurements of the fluid covering the apical part of cell cultures support the notion that bicarbonate ions may be transported by CFTR, and that this can be inhibited by specific CFTR inhibitors.

Bri2 BRICHOS client specificity and chaperone activity are governed by assembly state

Protein misfolding and aggregation is increasingly being recognized as a cause of disease. In Alzheimer’s disease the amyloid-β peptide (Aβ) misfolds into neurotoxic oligomers and assembles into amyloid fibrils. The Bri2 protein associated with Familial British and Danish dementias contains a BRICHOS domain, which reduces Aβ fibrillization as well as neurotoxicity in vitro and in a Drosophila model, but also rescues proteins from irreversible non-fibrillar aggregation. How these different activities are mediated is not known. Here we show that Bri2 BRICHOS monomers potently prevent neuronal network toxicity of Aβ, while dimers strongly suppress Aβ fibril formation. The dimers assemble into high-molecular-weight oligomers with an apparent two-fold symmetry, which are efficient inhibitors of non-fibrillar protein aggregation. These results indicate that Bri2 BRICHOS affects qualitatively different aspects of protein misfolding and toxicity via different quaternary structures, suggesting a means to generate molecular chaperone diversity.The BRICHOS domain is a chaperone that can act against amyloid-β peptide fibril formation and non-fibrillar protein aggregation. Here the authors use a multidisciplinary approach and show that the Bri2 BRICHOS domain has qualitatively different chaperone activities depending on its quaternary structure.

Granule-stored MUC5B mucins are packed by the non-covalent formation of N-terminal head-to-head tetramers

Most MUC5B mucin polymers in the upper airways of humans and pigs are produced by submucosal glands. MUC5B forms N-terminal covalent dimers that are further packed into larger assemblies because of low pH and high Ca2+ in the secretory granule of the mucin-producing cell. We purified the recombinant MUC5B N-terminal covalent dimer and used single-particle electron microscopy to study its structure under intracellular conditions. We found that, at intragranular pH, the dimeric MUC5B organized into head-to-head noncovalent tetramers where the von Willebrand D1–D2 domains hooked into each other. These N-terminal tetramers further formed long linear complexes from which, we suggest, the mucin domains and their C termini project radially outwards. Using conventional and video microscopy, we observed that, upon secretion into the submucosal gland ducts, a flow of bicarbonate-rich fluid passes the mucin-secreting cells. We suggest that this unfolds and pulls out the MUC5B assemblies into long linear threads. These further assemble into thicker mucin bundles in the glandular ducts before emerging at the gland duct opening. We conclude that the combination of intracellular packing of the MUC5B mucin and the submucosal gland morphology creates an efficient machine for producing linear mucin bundles.

WS12.1 Assembly of MUC2 N-terminal with relevance for mucus formation

WS12.1 Assembly of MUC2 N-terminal with relevance for mucus formation H.E. Nilsson1,2, D. Ambort1, M. Bäckström1,3, E. Thomsson3, P. Koeck4, H. Hebert2,4, G.C. Hansson1. 1University of Gothenburg, Medical Biochemistry, Gothenburg, Sweden; 2Karolinska Intstitutet, Bioscience and Nutrition, Huddinge, Sweden; 3University of Gothenburg, Mammalian Protein Expression Core Facility, Gothenburg, Sweden; 4School of Technology and Health, KTH Royal Institute of Technology, Huddinge, Sweden

55* Molecular structure, packing and release of MUC2 with relevance to cystic fibrosis

In Cystic Fibrosis extremely viscous fluid is built up likely connected to impaired release and expansion of mucins. MUC2 is mainly expressed in small and large intestine, but also in inflamed airways, and it is stored as a multimer in secretory granules of goblet cells at high [Ca 2+ ] and low pH. The extracellular milieu have to trigger the unpacking of MUC2 controled by its N-terminus, a not yet fully understood process. The aim is to elucidate organization and structure of MUC2 when it is packed and secreted. The N-terminal part of MUC2 was expressed in CHO cells. The secreted trimerized recombinant mucin was purified from culture medium by anion exchange chromatography. Crosslinked samples were purified by density ultracentrifugation. Analysis was performed by transmission electron microscopy (TEM). The pH in the buffers was varied in the range from 5.2 to 8 to mimic conditions of secretory pathway and extracellular environment by adding HAc (pH 5.2), MES (pH 6.2) or Tris (pH 7.4 and pH 8) with or without calcium. Samples were adsorbed onto carbon coated EM grids and negative stained. Processing of micrographs was performed using EMAN1 software. When pH was low and or calcium present, rings with an outer and inner diameter of 25-30 and 20-25 nm respectively were observed. Without calcium rings were assembled at pH 5.2 and 6.2, but vanished with increasing pH. 2D refinements of the projections showed rotational 5- or 6- folded symmetry. Assemblies of laterally concatenated rings were obtained in the high density fraction of MUC2 N-terminus. The formations of these rings are probably vital for proper packing and release of full length MUC2. Harriet N. and Daniel A. have contributed equally