Endocytosis of low-density lipoprotein by human pancreatic beta cells and uptake in lipid-storing vesicles, which increase with age.

Studies with I(125)-labeled low-density lipoproteins (LDLs) have shown the presence of high-affinity LDL receptors on insulin-producing beta cells but not on neighboring alpha cells. By using gold-labeled lipoproteins, we demonstrate receptor-mediated endocytosis of LDLs and very low-density lipoproteins in rat and human beta cells. Specific for human beta cells is the fusion of LDL-containing endocytotic vesicles with lipid-storing vesicles (LSVs; diameter, 0.6-3.6 microm), which are absent in rodent beta cells. LSVs also occur in human pancreatic alpha and duct cells, but these sequester little gold-labeled LDL. In humans <25 years old, LSVs occupy 1% of the cytoplasmic surface area in beta, alpha, and duct cells. In humans >50 years old, LSV surface area in beta cells (11 +/- 2% of cytoplasmic surface area) is fourfold higher than in alpha and duct cells and 10-fold higher than in beta cells at younger ages (P < 0.001); the mean LSV diameter in these beta cells (1.8 +/- 0.04 microm) is larger than at younger ages (1.1 +/- 0.2 microm; P < 0.005). Oil red O staining on pancreatic sections confirms that neutral lipids accumulate in beta cells of older donors. We conclude that human beta cells can incorporate LDL and very low-density lipoprotein material in LSVs. The marked increase in the LSV area of aging human beta cells raises the question whether it is caused by prolonged exposure to high lipoprotein levels such as occurs in Western populations and whether it is causally related to the higher risk for type 2 diabetes with aging.

Implantation of standardized beta-cell grafts in a liver segment of IDDM patients: graft and recipients characteristics in two cases of insulin-independence under maintenance immunosuppression for prior kidney graft.

Islet allografts in insulin-dependent diabetic (IDDM) patients exhibit variable survival lengths and low rates of insulin-independence despite treatment with anti-T-cell antibodies and maintenance immunosuppression. Use of poorly characterized freshly isolated preparations makes it difficult to determine whether failures are caused by variations in donor tissue. This study assesses survival of standardized beta-cell allografts in C-peptide negative IDDM patients on maintenance immunosuppression following kidney transplantation and without receiving anti-T-cell antibodies or additional immunosuppression. Human islets were isolated from pancreatic segments after maximal 20 h cold-preservation. During culture, preparations were selected according to quality control tests and combined with grafts with standardized cell composition (> or = 50% beta cells), viability (> or = 90%), total beta-cell number (1 to 2 x 10(6)/kg body weight) and insulin-producing capacity (2 to 4 nmol x graft(-1) x h(-1)). Grafts were injected in a liver segment through the repermeabilized umbilical vein. After 2 weeks C-peptide positivity, four out of seven recipients became C-peptide negative; two of them were initially GAD65-antibody positive and exhibited a rise in titre during graft destruction. The other three patients remained C-peptide positive for more than 1 year, two of them becoming insulin-independent with near-normal fasting glycaemia and HbA1c; they remained GAD65- and islet cell antibody negative. The three patients with surviving grafts presented a history of anti-thymocyte globulin therapy at kidney transplantation. Long-term surviving grafts increased C-peptide release following intravenous glucagon or oral glucose but not following intravenous glucose. Thus, cultured human beta-cells can survive for more than 1 year in IDDM patients on maintenance anti-rejection therapy for a prior kidney graft and without the need for an increased immunosuppression at the time of implantation. The use of functionally standardized beta-cell grafts helps to identify recipient and graft factors which influence their survival and metabolic effects. Insulin-independence can be achieved by injection of 1.5 million beta-cells per kg body weight in a liver segment. These beta-cell implants respond well to adenylcyclase activators but poorly to glucose.

Low density lipoprotein binding and uptake by human and rat islet beta cells.

Abnormalities in lipoprotein metabolism are common in diabetes. It is unknown whether variations in form or concentration of lipoproteins influence the function of pancreatic beta cells. This study investigates whether low density lipoproteins (LDL) exhibit specific interactions with islet beta cells. Radioactively labeled LDL (125I-LDL) and fluorescently labeled LDL (DiI-LDL) were used as tracers. Rat islet cells express high affinity LDL binding sites (K(d) = 9 nM), which are also recognized by very low density lipoproteins and which are down-regulated by LDL. Binding of LDL appears restricted to the beta cells, as it was not detected on islet endocrine non-beta cells. At 37 C, LDL is taken up and lysosomally degraded by islet beta cells but not by islet non-beta cells. Human islet cells were also found to present LDL binding, uptake, and degradation. Compared with rat islet cells, human islet cells exhibit 10-fold less binding sites (2.10(7) vs. 2.10(8) per 10(3) cells) with a 2-fold lower K(d) value (5 nM) and an equal sensitivity to LDL-induced down-regulation. In conclusion, human and rat islet beta cells express LDL receptors that can internalize the lipoprotein. This pathway should be examined for its potential role in (dys)regulating pancreatic beta cell functions.