Abstract
Endogenous neural stem cells (NSCs) exist in the central canal of mammalian spinal cords. Under normal conditions, these NSCs remain quiescent and express FoxJ1. After spinal cord injury (SCI), the endogenous NSCs of a heterogeneous nature are activated and proliferate and migrate towards the lesion site and mainly differentiate into astrocytes to repair the injured tissue. In vitro, spinal cord NSCs are multipotent and can differentiate into neurons, astrocytes, and oligodendrocytes. The altered microenvironments after SCI play key roles on the fate determination of activated NSCs, especially on the neuronal specification potential. Studies show that the activated spinal cord NSCs can generate interneurons when transplanted into the adult hippocampus. In addition, the spinal cord NSCs exhibit low immunogenicity in a transplantation context, thus implicating a promising therapeutic potential on SCI recovery. Here, we summarize the characteristics of spinal cord NSCs, especially their properties after injury. With a better understanding of endogenous NSCs under normal and SCI conditions, we may be able to employ endogenous NSCs for SCI repair in the future.
Highlights
Neural stem cells (NSCs) exist mainly in two regions in the adult central nervous system (CNS): brain and spinal cord [1,2,3,4,5,6]
Ependymal cells lining the central canal are referred as spinal cord NSC niche
Neurons derived from transplanted NSCs extracted from embryonic forebrains restore disrupted neuronal circuitry in mouse spinal cord injury (SCI) models; another study shows that NSCs from the E14 rat cerebral cortex or the adult rat subventricular zone are restricted to a glial lineage when engrafted into the normal or lesioned spinal cord [78, 79]
Summary
Neural stem cells (NSCs) exist mainly in two regions in the adult central nervous system (CNS): brain and spinal cord [1,2,3,4,5,6]. NSCs remain quiescent under normal physiological conditions and can be activated under certain conditions such as CNS injury [7]. The activated NSCs can self-renew to maintain stem cell pool size and differentiate into neural cells for tissue repair.
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