Monitoring neurodegeneration in diabetes using adult neural stem cells derived from the olfactory bulb.

INTRODUCTION: Neurons have the intrinsic capacity to produce insulin, similar to pancreatic cells. Adult neural stem cells (NSCs), which give rise to functional neurons, can be established and cultured not only by intracerebral collection, which requires difficult surgery, but also by collection from the olfactory bulb (OB), which is relatively easy. Adult neurogenesis in the hippocampus (HPC) is significantly decreased in diabetes patients. As a result, learning and memory functions, for which the HPC is responsible, decrease. METHODS: In the present study, we compared the effect of diabetes on neurogenesis and insulin expression in adult NSCs. Adult NSCs were derived from the HPC or OB of streptozotocin-induced diabetic rats. Comparative gene-expression analyses were carried out by using extracted tissues and established adult NSC cultures from the HPC or OB in diabetic rats. RESULTS: Diabetes progression influenced important genes that were required for insulin expression in both OB- and HPC-derived cells. Additionally, we found that the expression levels of several genes, such as voltage-gated sodium channels, glutamate transporters, and glutamate receptors, were significantly different in OB and HPC cells collected from diabetic rats. CONCLUSIONS: By using identified diabetes-response genes, OB NSCs from diabetes patients can be used during diabetes progression to monitor processes that cause neurodegeneration in the central nervous system (CNS). Because hippocampal NSCs and OB NSCs exhibited similar gene-expression profiles during diabetes progression, OB NSCs, which are more easily collected and established than HPC NSCs, may potentially be used for screening of effective drugs for neurodegenerative disorders that cause malignant damage to CNS functions.

Insulin biosynthesis in neuronal progenitors derived from adult hippocampus and the olfactory bulb.

In the present study, we demonstrated that insulin is produced not only in the mammalian pancreas but also in adult neuronal cells derived from the hippocampus and olfactory bulb (OB). Paracrine Wnt3 plays an essential role in promoting the active expression of insulin in both hippocampal and OB-derived neural stem cells. Our analysis indicated that the balance between Wnt3, which triggers the expression of insulin via NeuroD1, and IGFBP-4, which inhibits the original Wnt3 action, is regulated depending on diabetic (DB) status. We also show that adult neural progenitors derived from DB animals retain the ability to give rise to insulin-producing cells and that grafting neuronal progenitors into the pancreas of DB animals reduces glucose levels. This study provides an example of a simple and direct use of adult stem cells from one organ to another, without introducing additional inductive genes.

Reduction in paracrine Wnt3 factors during aging causes impaired adult neurogenesis.

The mammalian brain contains neural stem cells (NSCs) that enable continued neurogenesis throughout adulthood. However, NSC function and/or numbers decline with increasing age. Adult hippocampal neurogenesis is unique in that astrocytes secreting Wnt3 promote NSC differentiation in a paracrine manner. Here, we show that both the levels of Wnt3 protein and the number of Wnt3-secreting astrocytes influence the impairment of adult neurogenesis during aging. The age-associated reduction in Wnt3 levels affects the regulation of target genes, such as NeuroD1 and retrotransposon L1, as well as the expression of Dcx, which is located adjacent to the L1 loci. Interestingly, the decline in the extrinsic Wnt3 levels and in the intracellular expression of the target genes with aging was reversible. Exercise was found to significantly increase de novo expression of Wnt3 and thereby rescue impaired neurogenesis in aged animals. Furthermore, the chromatin state of NeuroD1, L1, and the L1 loci near Dcx changed relative to Wnt3 levels in an age- or stimulus-associated manner. These results suggest that the regulation of paracrine factors plays a critical role in hippocampal aging and neurogenesis.