The relationship between bone, hemopoietic stem cells, and vasculature.

A large body of evidence suggests hemopoietic stem cells (HSCs) exist in an endosteal niche close to bone, whereas others suggest that the HSC niche is intimately associated with vasculature. In this study, we show that transplanted hemopoietic stem and progenitor cells (HSPCs) home preferentially to the trabecular-rich metaphysis of the femurs in nonablated mice at all time points from 15 minutes to 15 hours after transplantation. Within this region, they exist in an endosteal niche in close association with blood vessels. The preferential homing of HSPCs to the metaphysis occurs rapidly after transplantation, suggesting that blood vessels within this region may express a unique repertoire of endothelial adhesive molecules. One candidate is hyaluronan (HA), which is highly expressed on the blood vessel endothelium in the metaphysis. Analysis of the early stages of homing and the spatial dis-tribution of transplanted HSPCs at the single-cell level in mice devoid of Has3-synthesized HA, provides evidence for a previously undescribed role for HA expressed on endothelial cells in directing the homing of HSPCs to the metaphysis.

IGF-I stimulates neurogenesis in the hypothalamus of adult rats.

In the brain of adult rats neurogenesis persists in the subventricular zone of the lateral ventricles and in the dentate gyrus of the hippocampus. By contrast, low proliferative activity was observed in the hypothalamus. We report here that, after intracerebroventricular treatment with insulin-like growth factor I (IGF-I), cell proliferation significantly increased in both the periventricular and the parenchymal zones of the whole hypothalamus. Neurons, astrocytes, tanycytes, microglia and endothelial cells of the local vessels were stained with the proliferative marker 5-bromo-2'-deoxyuridine (BrdU) in response to IGF-I. Conversely, we never observed BrdU-positive ciliated cubic ependymal cells. Proliferation was intense in the subventricular area of a distinct zone of the mid third ventricle wall limited dorsally by ciliated cubic ependyma and ventrally by tanycytic ependyma. In this area, we saw a characteristic cluster of proliferating cells. This zone of the ventricular wall displayed three cell layers: ciliated ependyma, subependyma and underlying tanycytes. After IGF-I treatment, proliferating cells were seen in the subependyma and in the layer of tanycytes. In the subependyma, proliferating glial fibrillary acidic protein-positive astrocytes contacted the ventricle by an apical process bearing a single cilium and there were many labyrinthine extensions of the periventricular basement membranes. Both features are typical of neurogenic niches in other brain zones, suggesting that the central overlapping zone of the rat hypothalamic wall could be considered a neurogenic niche in response to IGF-I.

EphB4 is developmentally and differentially regulated in blood vessels throughout the forebrain neurogenic niche in the mouse brain: Implications for vascular remodeling.

Neurogenesis is a process influenced by environmental cues that create highly specific functional niches. Recently, the role of blood vessels in the maintenance and functioning of neurogenic niches during development and in adult life has been hallmarked. In addition to their trophic support for the highly demanding neurogenic process, blood vessels regulate neuroblast differentiation and migration and define functional domains. Since neurogenesis along the forebrain neurogenic niche (FNN) is a multistage process, in which neuroblast proliferation, differentiation and migration are spatially restricted to specific locations; we evaluated the structural features of vascular beds that support these processes during critical time points in their development. Additionally, we studied the molecular identity of the endothelial components of vascular beds using the expression of the venous marker EphB4. Our results show that blood vessels along the FNN: 1) are present very early in development; 2) define the borders of the FNN since early developmental stages; 3) experience constant remodeling until achieving their mature structure; 4) show venous features during perinatal developmental times; and 5) down-regulate their EphB4 expression as development proceeds. Collectively, our results describe the formation of the intricate vascular network that may support neurogenesis along the FNN and show that blood vessels along this neurogenic niche are dynamic entities that experience significant structural and molecular remodeling throughout development.