Effect of substrate rigidity in tissue culture on the function of insulin-secreting INS-1E cells.

Insulin-secreting INS-1E cells are a useful tool in diabetes research. However, during permanent culture the cells tend to lose their ß cell phenotype, with resultant loss of insulin-secretory responsiveness. This can be at least partially attributed to inappropriate cell culture conditions. One of the important causative factors is the rigidity of the extracellular matrix. We have therefore systematically studied the performance of INS-1E insulin-secreting cells cultured on polyacrylamide gels of different stiffnesses and analysed changes in insulin content and secretion, glucokinase enzyme activity, gene expression of ß cell transcription factors and cell death and proliferation rates. INS-1E cells were cultured on polyacrylamide gels with a wide range of rigidities, including the one that simulates the stiffness of the pancreas. We detected changes in insulin content and the insulin-secretory response to glucose stimulation in parallel to the increasing stiffness of the polyacrylamide gels in the range 1700-111 000 Pa. On substrates with the highest and lowest rigidities, 322 and 111 000 Pa, the cells mainly formed pseudo-islets, while at rigidities of 1700-64800 Pa, including the rigidity of native pancreas tissue (3100 Pa), cells grew as a monolayer attached to the polyacrylamide gel surface. These observations provide evidence for an apparent mechanosensitivity of insulin-secreting INS-1E cells affecting morphology and cellular functions. The results can also provide practical advice regarding a selection of the materials appropriate for successful cell culture of insulin-secreting cells. Copyright © 2014 John Wiley & Sons, Ltd.

Overexpression of the antioxidant enzyme catalase does not interfere with the glucose responsiveness of insulin-secreting INS-1E cells and rat islets.

AIMS/HYPOTHESIS: Hydrogen peroxide (H2O2)-inactivating enzymes such as catalase are produced in extraordinarily low levels in beta cells. Whether this low expression might be related to a signalling function of H2O2 within the beta cell is unknown. A high level of H2O2-inactivating enzymes could potentially be incompatible with glucose-induced insulin secretion. Therefore the effect of catalase overexpression on mitochondrial function and physiological insulin secretion was studied in insulin-secreting INS-1E and primary islet cells. METHODS: INS-1E and rat islet cells were lentivirally transduced to overexpress catalase in the cytosol (CytoCat) or in mitochondria (MitoCat). Cell viability and caspase-3 activation were assessed after cytokine incubation and hypoxia. Insulin secretion was quantified and expression of the gene encoding the mitochondrial uncoupling protein 2 (Ucp2) was measured in parallel to mitochondrial membrane potential and reactive oxygen species (ROS) formation. RESULTS: The ability to secret insulin in a glucose-dependent manner was not suppressed by catalase overexpression, although the glucose-dependent increase in the mitochondrial membrane potential was attenuated in MitoCat cells along with an increased Ucp2 expression and reduced mitochondrial ROS formation. In addition, MitoCat overexpressing cells were significantly more resistant against pro-inflammatory cytokines and hypoxia than CytoCat and control cells. CONCLUSIONS/INTERPRETATION: The results demonstrate that an improved antioxidative defence status of insulin-secreting cells allowing efficient H2O2 inactivation is not incompatible with proper insulin secretory responsiveness to glucose stimulation and provide no support for a signalling role of H2O2 in insulin-secreting cells. Interestingly, the results also document for the first time that the decreased ROS formation with increasing glucose concentrations is of mitochondrial origin.

[Pluripotent stem cells for cell replacement therapy of diabetes]. / Pluripotente Stammzellen zur Zellersatztherapie des Diabetes mellitus.

The use of pluripotent stem cells (PSCs) harbours great potential for a future use in the cell replacement therapy of diabetes mellitus. The in vitro differentiation of human or mouse embryonic stem cells has yielded pancreatic progenitor cells, but not authentic insulin-producing beta cells. Induced pluripotent cells are a class of a pluripotent stem cells potentially suited as a cell source for cell replacement therapy. These patient specific pluripotent cells are generated by reprogramming but unfortunately accumulate genetic and epigenetic errors during reprogramming, precluding their use for therapeutic purposes in humans.

An efficient experimental strategy for mouse embryonic stem cell differentiation and separation of a cytokeratin-19-positive population of insulin-producing cells.

OBJECTIVES: Embryonic stem cells are a potential source for insulin-producing cells, but existing differentiation protocols are of limited efficiency. Here, the aim has been to develop a new one, which drives development of embryonic stem cells towards insulin-producing cells rather than to neuronal cell types, and to combine this with a strategy for their separation from insulin-negative cells. MATERIALS AND METHODS: The cytokeratin-19 (CK19) promoter was used to control the expression of enhanced yellow fluorescence protein in mouse embryonic stem cells during their differentiation towards insulin-producing cells, using a new optimized four-stage protocol. Two cell populations, CK19(+) and CK19(-) cells, were successfully fluorescence sorted and analysed. RESULTS: The new method reduced neuronal progeny and suppressed differentiation into glucagon- and somatostatin-producing cells. Concomitantly, beta-cell like characteristics of insulin-producing cells were strengthened, as documented by high gene expression of the Glut2 glucose transporter and the transcription factor Pdx1. This novel protocol was combined with a cell-sorting technique. Through the combined procedure, a fraction of glucose-responsive insulin-secreting CK19(+) cells was obtained with 40-fold higher insulin gene expression and 50-fold higher insulin content than CK19(-) cells. CK19(+) cells were immunoreactive for C-peptide and had ultrastructural characteristics of an insulin-secretory cell. CONCLUSION: Differentiated CK19(+) cells reflect an endocrine precursor cell type of ductal origin, potentially suitable for insulin replacement therapy in diabetes.