Abstract. In simple epithelial cells, apical and basolateral proteins are sorted into separate vesicular carriers before delivery to the appropriate plasma membrane domains. To dissect the putative sorting machinery, we have solubilized Golgi-derived transport vesicles with the detergent CHAPS and shown that an apical marker, influenza haemagglutinin (HA), formed a large complex together with several integral membrane proteins. Remarkably, a similar set of CHAPS-insoluble proteins was found after solubilization of a total cellular membrane fraction. This allowed the cloning of a cDNA encoding one protein of this complex, VIP21 (Vesicular Integral-membrane Protein of 21 kD). The transiently expressed protein appeared on the Golgi-apparatus, the plasma membrane and vesicular structures. We propose that VIP21 is a component of the molecular machinery of vesicular transport.
It is well-known that protein-modified implant surfaces such as TiO(2) show a higher bioconductivity. Fibronectin is a glycoprotein from the extracellular matrix (ECM) with a major role in cell adhesion. It can be applied on titanium oxide surfaces to accelerate implant integration. Not only the surface concentration but also the presentation of the protein plays an important role for the cellular response. We were able to show that TiO(X) surfaces modified with biotinylated fibronectin adsorbed on a streptavidin-silane self-assembly multilayer system are more effective regarding osteoblast adhesion than surfaces modified with nonspecifically bound fibronectin. The adsorption and conformation behavior of biotinylated and nonbiotinylated (native) fibronectin was studied by surface plasmon resonance (SPR) spectroscopy and atomic force microscopy (AFM). Imaging of the protein modification revealed that fibronectin adopts different conformations on nonmodified compared to streptavidin-modified TiO(X) surfaces. This conformational change of biotinylated fibronectin on the streptavidin monolayer delivers a fibronectin structure similar to the conformation inside the ECM and therefore explains the higher cell affinity for these surfaces.
Four different genomic clones which contain the genes coding for epidermal keratins Ia (mol. wt. approximately 68 000), Ib (68 000), III (60 000) and VIb (54 500) have been selected using cDNA probes and identified by hybrid‐selection translation. The genes vary considerably in length, primarily due to differences in intron sizes: keratin Ia, 9.3 kb (approximately 2.55 kb total exons); keratin Ib, 6.0 kb (2.25 kb exons); keratin III, 6.0 kb (2.2 kb exons); keratin VIb, 4.4 kb (1.85 kb exons). The genes for all three representatives of the basic (type II) cytokeratin subfamily, i.e., keratins Ia, Ib and III, contain eight introns of variable sizes (0.1‐1.8 kb) and their exon patterns are very similar. The gene coding for keratin VIb, a representative of the acidic (type I) subfamily, contains seven introns, and the size pattern of its five innermost exons closely resembles that of the genes of the type II keratins. Most of the introns are located in regions coding for the alpha‐helical cores of these proteins. Mapping of the intron positions by the S1 nuclease technique and sequencing of some exon‐intron boundaries has revealed that some of the introns of all four keratin genes have similar positions to each other and to those of the hamster vimentin gene.(ABSTRACT TRUNCATED AT 250 WORDS)
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