Co-axial printing of convoluted proximal tubule for kidney disease modeling.

Despite the increasing incidence of kidney-related diseases, we are still far from understanding the underlying mechanisms of these diseases and their progression. This lack of understanding is partly because of a poor replication of the diseasesin vitro,limited to planar culture. Advancing towards three-dimensional models, hereby we propose coaxial printing to obtain microfibers containing a helical hollow microchannel. These recapitulate the architecture of the proximal tubule (PT), an important nephron segment often affected in kidney disorders. A stable gelatin/alginate-based ink was formulated to allow printability while maintaining structural properties. Fine-tuning of the composition, printing temperature and extrusion rate allowed for optimal ink viscosity that led to coiling of the microfiber's inner channel. The printed microfibers exhibited prolonged structural stability (42 days) and cytocompatibility in culture. Healthy conditionally immortalized PT epithelial cells and a knockout cell model for cystinosis (CTNS-/-) were seeded to mimic two genotypes of PT. Upon culturing for 14 days, engineered PT showed homogenous cytoskeleton organization as indicated by staining for filamentous actin, barrier-formation and polarization with apical markerα-tubulin and basolateral marker Na+/K+-ATPase. Cell viability was slightly decreased upon prolonged culturing for 14 days, which was more pronounced inCTNS-/-microfibers. Finally,CTNS-/-cells showed reduced apical transport activity in the microfibers compared to healthy PT epithelial cells when looking at breast cancer resistance protein and multidrug resistance-associated protein 4. Engineered PT incorporated in a custom-designed microfluidic chip allowed to assess leak-tightness of the epithelium, which appeared less tight inCTNS-/-PT compared to healthy PT, in agreement with itsin vivophenotype. While we are still on the verge of patient-oriented medicine, this system holds great promise for further research in establishing advancedin vitrodisease models.

Site-directed spin-labeling of the catalytic sites yields insight into structural changes within the F0F1-ATP synthase of Escherichia coli.

Electron spin resonance (ESR) spectroscopy using site-specific cysteine spin-labeling of the catalytic nucleotide binding sites of F(1)-ATPase was employed to investigate conformational changes within the nucleotide binding sites of the enzyme. Mutant Escherichia coli F(1) that had been modified at position beta-Y331C with a spin label showed almost normal catalytic activity and enabled us to study the effects of binding of different nucleotides and of the F(o) subunit b on the conformation of the catalytic binding sites. The ESR spectra of the spin-labeled, nucleotide-depleted F(1) indicate asymmetry within the sites as is expected from the structural models of the enzyme. Nucleotide binding to the enzyme clearly affects the conformation of the sites; the most pronounced feature upon nucleotide binding is the formation of catalytic site(s) in a very open conformation. Using the same beta-331 spin-labeled F(1) and a truncated form of F(o) subunit b, b(24)(-)(156), we found that binding of b(24)(-)(156) to spin-labeled F(1) significantly changes the conformation of the catalytic sites. In this paper we present data that for the first time directly show that a conformational binding change takes place upon binding of nucleotides to the nucleotide binding sites and that also show that binding of b(24)(-)(156) strongly affects the conformation of the catalytic sites, most likely by increasing the population of binding sites that are in the open conformation.