Figure 1
Figure 1. Model of HSC niche regulation in steady state. (A) Perivascular niches harboring active HSCs that regenerate the hematopoietic system. Active HSCs are in contact with perivascular nestin+ MSCs and sinusoidal endothelial cells. Both MSCs and sinusoidal endothelial cells express SDF-1, transmembrane SCF, and VCAM-1 that retain HSCs within the niche via adhesive and chemotactic interactions. (B) Endosteal niches harboring quiescent HSCs. Quiescent HSCs are in contact with nestin+ MSCs or osteoprogenitors or both. (C) Interactions between niches cells, HSCs, and adrenergic neurons. CD68+ CD169+ macrophages and osteomacs forming support function of nestin+ MSCs, osteoprogenitors and osteoblasts which in turn maintain HSCs in steady state (stimulating feed-back illustrated by green arrow). Sympathetic β3 adrenergic nerves inhibit SDF-1 secretion by MSCs and osteoblasts after a circadian pulse (negative pulse illustrated by dotted red bars).

Model of HSC niche regulation in steady state. (A) Perivascular niches harboring active HSCs that regenerate the hematopoietic system. Active HSCs are in contact with perivascular nestin+ MSCs and sinusoidal endothelial cells. Both MSCs and sinusoidal endothelial cells express SDF-1, transmembrane SCF, and VCAM-1 that retain HSCs within the niche via adhesive and chemotactic interactions. (B) Endosteal niches harboring quiescent HSCs. Quiescent HSCs are in contact with nestin+ MSCs or osteoprogenitors or both. (C) Interactions between niches cells, HSCs, and adrenergic neurons. CD68+ CD169+ macrophages and osteomacs forming support function of nestin+ MSCs, osteoprogenitors and osteoblasts which in turn maintain HSCs in steady state (stimulating feed-back illustrated by green arrow). Sympathetic β3 adrenergic nerves inhibit SDF-1 secretion by MSCs and osteoblasts after a circadian pulse (negative pulse illustrated by dotted red bars).

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