Surface-enhanced Raman (SERS) signatures were measured from single living cells at different times after the uptake of gold nanoparticles. The spectra are indicative of chemical changes in the environment of the nanostructures over time. The increase of the SERS signal strength and parallel TEM studies indicate the formation of nanoaggregates providing optimum SERS enhancement for ultrasensitive probing inside the endosomal compartment. The results have implications for medical and biotechnology applications of SERS nanosensors in cells.
Blood vessel endothelium has been recently shown to induce endocrine pancreatic development. Because pancreatic endocrine cells or islets express high levels of vascular endothelial growth factors, VEGFs, we investigated the role of a particular VEGF, VEGF-A, on islet vascularization and islet function. By deleting VEGF-A in the mouse pancreas, we show that endocrine cells signal back to the adjacent endothelial cells to induce the formation of a dense network of fenestrated capillaries in islets. Interestingly, VEGF-A is not required for the development of all islet capillaries. However, the few remaining capillaries found in the VEGF-A-deficient islets are not fenestrated and contain an unusual number of caveolae. In addition, glucose tolerance tests reveal that the VEGF-A-induced capillary network is not strictly required for blood glucose control but is essential for fine-tuning blood glucose regulation. In conclusion, we speculate that islet formation takes place in two sequential steps: in the first step, signals from blood vessel endothelium induce islet formation next to the vessels, and in the second step, the islets signal to the endothelium. The second step involves paracrine VEGF-A signaling to elaborate the interaction of islets with the circulatory system.
To determine the role of the phosphatidylinositol 3-kinase (PI3-K) pathway in pancreas development, we generated a pancreas-specific knockout of Pten, a negative regulator of PI3-K signaling. Knockout mice display progressive replacement of the acinar pancreas with highly proliferative ductal structures that contain abundant mucins and express Pdx1 and Hes1, two markers of pancreatic progenitor cells. Moreover, a fraction of these mice develop ductal malignancy. We provide evidence that ductal metaplasia results from the expansion of centroacinar cells rather than transdifferentiation of acinar cells. These results indicate that Pten actively maintains the balance between different cell types in the adult pancreas and that misregulation of the PI3-K pathway in centroacinar cells may contribute to the initiation of pancreatic carcinoma in vivo.
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