Inflammatory regulators of redirected neural migration in the injured brain

Brain injury following stroke or trauma induces the migration of neuroblasts derived from subventricular zone neural precursor cells (NPCs) towards the damaged tissue, where they then have the potential to contribute to repair. Enhancing the recruitment of new cells thus presents an enticing prospect for the development of new therapeutic approaches to treat brain injury; to this end, an understanding of the factors regulating this process is required. During the neuroinflammatory response to ischemic and traumatic brain injuries, a plethora of pro- and anti-inflammatory cytokines, chemokines and growth factors are released in the damaged tissue, and recent work indicates that a variety of these are able to influence injury-induced migration. In this review, we will discuss the contribution of specific chemokines and growth factors towards stimulating NPC migration in the injured brain.     

Adult neural stem cells: response to stroke injury and potential for therapeutic applications

The plasticity of neural stem/progenitor cells allows a variety of different responses to many environmental cues. In the past decade, significant research has gone into understanding the regulation of neural stem/progenitor cell properties, because of their promise for cell replacement therapies in adult neurological diseases. Both endogenous and grafted neural stem/progenitor cells are known to have the ability to migrate long distances to lesioned sites after brain injury and differentiate into new neurons. Several chemokines and growth factors, including stromal cell-derived factor-1 and vascular endothelial growth factor, have been shown to stimulate the proliferation, differentiation, and migration of neural stem/progenitor cells, and investigators have now begun to identify the critical downstream effectors and signaling mechanisms that regulate these processes. Both our own lab and others have shown that the extracellular matrix and matrix remodeling factors play a critical role in directing cell differentiation and migration of adult neural stem/progenitor cells within injured sites. Identification of these and other molecular pathways involved in stem cell homing into ischemic areas is vital for the development of new treatments. To ensure the best functional recovery, regenerative therapy may require the application of a combination approach that includes cell replacement, trophic support, and neural protection. Here we review the current state of our knowledge about endogenous adult and exogenous neural stem/progenitor cells as potential therapeutic agents for central nervous system injuries.     

神经干细胞迁移的研究进展

神经干细胞的定向迁移是胚胎神经系统发育的先决条件,同时在成体组织的许多生理、病理过程中也起着重要作用;研究发现,许多神经退行性疾病都与神经干细胞迁移的缺陷相关。近年来,越来越多的证据表明,无论是内源性的还是移植的神经干细胞都有向大脑损伤部位迁移的特性,显示出神经干细胞用于神经再生及损伤修复治疗的潜能。该文着重在神经干细胞的基本特性以及神经干细胞定向迁移的细胞与分子机制研究等方面进行了综述。     

A Galvanotaxis Assay for Analysis of Neural Precursor Cell Migration Kinetics in an Externally Applied Direct Current Electric Field

The discovery of neural stem and progenitor cells (collectively termed neural precursor cells) (NPCs) in the adult mammalian brain has led to a body of research aimed at utilizing the multipotent and proliferative properties of these cells for the development of neuroregenerative strategies. A critical step for the success of such strategies is the mobilization of NPCs toward a lesion site following exogenous transplantation or to enhance the response of the endogenous precursors that are found in the periventricular region of the CNS. Accordingly, it is essential to understand the mechanisms that promote, guide, and enhance NPC migration. Our work focuses on the utilization of direct current electric fields (dcEFs) to promote and direct NPC migration - a phenomenon known as galvanotaxis. Endogenous physiological electric fields function as critical cues for cell migration during normal development and wound repair. Pharmacological disruption of the trans-neural tube potential in axolotl embryos causes severe developmental malformations¹. In the context of wound healing, the rate of repair of wounded cornea is directly correlated with the magnitude of the epithelial wound potential that arises after injury, as shown by pharmacological enhancement or disruption of this dcEF^2-3. We have demonstrated that adult subependymal NPCs undergo rapid and directed cathodal migration in vitro when exposed to an externally applied dcEF. In this protocol we describe our lab''s techniques for creating a simple and effective galvanotaxis assay for high-resolution, long-term observation of directed cell body translocation (migration) on a single-cell level. This assay would be suitable for investigating the mechanisms that regulate dcEF transduction into cellular motility through the use of transgenic or knockout mice, short interfering RNA, or specific receptor agonists/antagonists.     

The life, death, and replacement of oligodendrocytes in the adult CNS

Oligodendrocytes (OLs) are mature glial cells that myelinate axons in the brain and spinal cord. As such, they are integral to functional and efficient neuronal signaling. The embryonic lineage and postnatal development of OLs have been well-studied and many features of the process have been described, including the origin, migration, proliferation, and differentiation of precursor cells. Less clear is the extent to which OLs and damaged/dysfunctional myelin are replaced following injury to the adult CNS. OLs and their precursors are very vulnerable to conditions common to CNS injury and disease sites, such as inflammation, oxidative stress, and elevated glutamate levels leading to excitotoxicity. Thus, these cells become dysfunctional or die in multiple pathologies, including Alzheimer's disease, spinal cord injury, Parkinson's disease, ischemia, and hypoxia. However, studies of certain conditions to date have detected spontaneous OL replacement. This review will summarize current information on adult OL progenitors, mechanisms that contribute to OL death, the consequences of their loss and the pathological conditions in which spontaneous oligodendrogenesis from endogenous precursors has been observed in the adult CNS.     

The duality of epidermal growth factor receptor (EGFR) signaling and neural stem cell phenotype: cell enhancer or cell transformer?

Recruitment of neural stem cells (NSCs) represents an elegant strategy for replacing adult central nervous system (CNS) cells lost to injury or disease. However, except in the rostral migratory stream to the olfactory bulb, the adult CNS harbors a relatively non permissive environment for motility of neural stem cells. This opens the possibility of therapeutic enhancement of NSC motility towards sites of CNS injury or disease. The Epidermal Growth Factor Receptor (EGFR) is involved in the activation of a number of downstream pathways that regulate the phenotype of progenitor cells. Activated EGFR tyrosine kinase activity enhances NSC migration, proliferation, and survival. However, EGFR signaling is also known to play a role in the most malignant and highly invasive of human tumors, glioblastoma multiforme (GBM). Recent evidence supports the theory that GBM derives from a 'cancer stem cell' and that EGFR signals are commonly altered in these precursor cells. This article will review the role of EGFR signaling as it relates to neural stem cell motility and invasion. The duality of altered EGFR signaling in neural progenitor cells is discussed and opportunities for enhancing the recruitment of adult progenitors, and consequences of altering EGFR signaling in progenitor cells will be highlighted.     

肾上腺素受体在大鼠中枢神经系统发育中的作用研究

去甲肾上腺素和肾上腺素受体在大鼠中枢神经系统（CNS）的发育早期开始表达,且受体表达的时空模式与脑发育过程中某些脑区神经元的迁移和分化相一致,这提示去甲肾上腺素在中枢神经系统的发育中具有重要作用。本文论述了胚胎和新出生的大鼠不同脑区肾上腺素受体mRNA的表达模式以及这些受体对体外培养的成熟细胞和相应的前体细胞的调控效应,通过离体和在体研究的实验证据,阐述肾上腺素受体介导了去甲肾上腺素对神经前体细胞的增殖、生长、迁移、分化和存活的调控作用。进一步明确了去甲肾上腺素在CNS发育中所起的作用,使其可作为成体脑修复的助动剂而赋予新的意义。     

Regenerative medicine in multiple sclerosis: identifying pharmacological targets of adult neural stem cell differentiation

Progressive axonal loss from chronic demyelination in multiple sclerosis (MS) is the key contributor to clinical decline. Failure to regenerate myelin by adult oligodendrocyte precursor cells (OPCs), a widely distributed neural stem cell population in the adult brain, is one of the major causes of axonal degeneration. In order to develop successful therapies to protect the integrity of axons in MS, it is important to identify and understand the key molecular pathways involved in myelin regeneration (remyelination) by adult OPCs. This review highlights recent findings on the critical signaling pathways associated with OPC differentiation following CNS demyelination. We discuss the role of LINGO-1, Notch, Wnt, and retinoid X receptor (RXR) signaling, and how they might be useful pharmacological targets to overcoming remyelination failure in MS.     

神经干细胞移植的临床研究进展

神经系统损伤会导致脑内神经干细胞（neural stem cells,NSCs）的扩增以实现自我修复功能,而通过外源细胞移植的方式来加速这一进程,可能是一种更有效的治疗手段。当前,神经干细胞临床研究所面临的主要问题是如何评价细胞在移植后的行为和功能。该文综述了近几年使用神经干细胞移植治疗几种主要神经系统疾病的临床研究成果,并着重关注了干细胞移植后的示踪研究。     

Adult subependymal neural precursors, but not differentiated cells, undergo rapid cathodal migration in the presence of direct current electric fields

Background

The existence of neural stem and progenitor cells (together termed neural precursor cells) in the adult mammalian brain has sparked great interest in utilizing these cells for regenerative medicine strategies. Endogenous neural precursors within the adult forebrain subependyma can be activated following injury, resulting in their proliferation and migration toward lesion sites where they differentiate into neural cells. The administration of growth factors and immunomodulatory agents following injury augments this activation and has been shown to result in behavioural functional recovery following stroke.

Methods and Findings

With the goal of enhancing neural precursor migration to facilitate the repair process we report that externally applied direct current electric fields induce rapid and directed cathodal migration of pure populations of undifferentiated adult subependyma-derived neural precursors. Using time-lapse imaging microscopy in vitro we performed an extensive single-cell kinematic analysis demonstrating that this galvanotactic phenomenon is a feature of undifferentiated precursors, and not differentiated phenotypes. Moreover, we have shown that the migratory response of the neural precursors is a direct effect of the electric field and not due to chemotactic gradients. We also identified that epidermal growth factor receptor (EGFR) signaling plays a role in the galvanotactic response as blocking EGFR significantly attenuates the migratory behaviour.

Conclusions

These findings suggest direct current electric fields may be implemented in endogenous repair paradigms to promote migration and tissue repair following neurotrauma.     

Adult neural stem cells: an endogenous tool to repair brain injury?

Research on stem cells has developed as one of the most promising areas of neurobiology. In the beginning of the 1990s, neurogenesis in the adult brain was indisputably accepted, eliciting great research efforts. Neural stem cells in the adult mammalian brain are located in the ‘neurogenic’ areas of the subventricular and subgranular zones. Nevertheless, many reports indicate that they subsist in other regions of the adult brain. Adult neural stem cells have arisen considerable interest as these studies can be useful to develop new methods to replace damaged neurons and treat severe neurological diseases such as neurodegeneration, stroke or spinal cord lesions. In particular, a promising field is aimed at stimulating or trigger a self‐repair system in the diseased brain driven by its own stem cell population. Here, we will revise the latest findings on the characterization of active and quiescent adult neural stem cells in the main regions of neurogenesis and the factors necessary to maintain their active and resting states, stimulate migration and homing in diseased areas, hoping to outline the emerging knowledge for the promotion of regeneration in the brain based on endogenous stem cells.     

Interplay between autophagy and programmed cell death in mammalian neural stem cells

Mammalian neural stem cells (NSCs) are of particular interest because of their role in brain development and function. Recent findings suggest the intimate involvement of programmed cell death (PCD) in the turnover of NSCs. However, the underlying mechanisms of PCD are largely unknown. Although apoptosis is the best-defined form of PCD, accumulating evidence has revealed a wide spectrum of PCD encompassing apoptosis, autophagic cell death (ACD) and necrosis. This mini-review aims to illustrate a unique regulation of PCD in NSCs. The results of our recent studies on autophagic death of adult hippocampal neural stem (HCN) cells are also discussed. HCN cell death following insulin withdrawal clearly provides a reliable model that can be used to analyze the molecular mechanisms of ACD in the larger context of PCD. More research efforts are needed to increase our understanding of the molecular basis of NSC turnover under degenerating conditions, such as aging, stress and neurological diseases. Efforts aimed at protecting and harnessing endogenous NSCs will offer novel opportunities for the development of new therapeutic strategies for neuropathologies. [BMB Reports 2013; 46(8): 383-390]     

Tenascins and inflammation in disorders of the nervous system

In vitro and in vivo studies on the role of tenascins have shown that the two paradigmatic glycoproteins of the tenascin family, tenascin-C (TnC) and tenascin-R (TnR) play important roles in cell proliferation and migration, fate determination, axonal pathfinding, myelination, and synaptic plasticity. As components of the extracellular matrix, both molecules show distinct, but also overlapping dual functions in inhibiting and promoting cell interactions depending on the cell type, developmental stage and molecular microenvironment. They are expressed by neurons and glia as well as, for TnC, by cells of the immune system. The functional relationship between neural and immune cells becomes relevant in acute and chronic nervous system disorders, in particular when the blood brain and blood peripheral nerve barriers are compromised. In this review, we will describe the functional parameters of the two molecules in cell interactions during development and, in the adult, in synaptic activity and plasticity, as well as regeneration after injury, with TnC being conducive for regeneration and TnR being inhibitory for functional recovery. Although not much is known about the role of tenascins in neuroinflammation, we will describe emerging knowledge on the interplay between neural and immune cells in autoimmune diseases, such as multiple sclerosis and polyneuropathies. We will attempt to point out the directions of experimental approaches that we envisage would help gaining insights into the complex interplay of TnC and TnR with the cells that express them in pathological conditions of nervous and immune systems.     

Insulin-like growth factor-1 is a radial cell-associated neurotrophin that promotes neuronal recruitment from the adult songbird ependyma/subependyma

In the adult songbird forebrain, neurons continue to be produced from precursor cells in the forebrain ependymal/subependymal zone (SZ), from which they migrate upon radial guide fibers. The new neurons and their radial cell partners may coderive from a common SZ progenitor, which may be the radial cell itself. On this basis, we asked whether radial cells might provide trophic support for the migration or survival of newly generated neurons. We focused upon the insulin-like growth factors (IGFs) IGF-1 and IGF-2, which have previously been shown to support the survival and differentiation of neural progenitor cells. We found that IGF-1 immunoreactivity was expressed heavily by adult zebra finch radial cells and their fibers, with little expression otherwise. IGF-2, in contrast, was expressed by parenchymal astrocytes and exhibited little radial cell expression. Despite their distinct distributions, IGF-1 and IGF-2 exerted similar trophic effects on finch SZ cells in vitro; both greatly increased the number of neurons migrating from explants of the adult finch SZ, relative to explants raised in low-insulin, IGF-1-deficient media. However, neither factor extended neuronal survival. These results suggest that in neurogenic regions of the adult avian forebrain, IGF-1 acts as a radial cell-associated neuronal differentiation and/or departure factor, which may serve to regulate neuronal recruitment into the adult brain. © 1998 John Wiley & Sons, Inc. J Neurobiol 36: 1–15, 1998     

GABA Effects During Neuronal Differentiation of Stem Cells

Gamma-amino butyrate (GABA) is the most prevalent inhibitory neurotransmitter in the adult brain. In this review, we summarize the pharmacology and regulation of GABAergic transmission components (biosynthetic enzymes, receptors and transporters) in adult non-neurogenic brain regions. The effects of targeted mutations in genes relevant for GABAergic functions and how they influence specific neuronal circuits and pathological states are presented. We then review GABA actions on neuronal differentiation. During brain development, GABA has depolarizing activity in cerebrocortical neural precursors, controlling cell division and contributing to neuronal migration and maturation. In the adult forebrain there are two neurogenic regions exposed to synaptic and non-synaptic GABA release. Neural stem cells and neuronal progenitors express GABA receptors in subventricular and subgranular zones. GABA effects in these cells are very similar to those found in embryonic cortical precursor cells, and therefore it is possible that this amino acid has important roles during adult brain plasticity. Special issue article in honor of Dr. Ricardo Tapia.     

Towards brain repair: Insights from teleost fish

In the adult mammalian brain, the ability to minimize secondary cell death after injury, and to repair nervous tissue through generation of new neurons, is severely compromised. By contrast, certain taxa of non-mammalian vertebrates possess an enormous potential for regeneration. Examination of one of these taxa, teleost fish, has revealed a close link between this phenomenon and constitutive adult neurogenesis. Key factors mediating successful regeneration appear to be: elimination of damaged cells by apoptosis, instead of necrosis; activation of mechanisms that prevent the occurrence of secondary cell death; increased production of new neurons that replace neurons lost to injury; and activation of developmental mechanisms that mediate directed migration of the new cells to the site of injury, the differentiation of the young cells, and their integration into the existing neural network. Comparative analysis has suggested that constitutive adult neurogenesis is a primitive vertebrate trait, the main function of which has been to ensure a numerical matching between muscle fibers/sensory receptor cells and central elements involved in motor control/processing of sensory information associated with these peripheral elements. It is hypothesized that, when in the course of the evolution of mammals a major shift in the growth pattern from hyperplasia to hypertrophy took place, the number of neurogenic brain regions and new neurons markedly decreased. As a consequence, the potential for neuronal regeneration was greatly reduced, but remnants of neurogenic areas have persisted in the adult mammalian brain in form of quiescent stem cells. It is likely that the study of regeneration-competent taxa will provide important information on how to activate intrinsic mechanisms for successful brain regeneration in humans.     

Neural stem cells: involvement in adult neurogenesis and CNS repair

Recent advances in stem cell research, including the selective expansion of neural stem cells (NSCs) in vitro, the induction of particular neural cells from embryonic stem cells in vitro, the identification of NSCs or NSC-like cells in the adult brain and the detection of neurogenesis in the adult brain (adult neurogenesis), have laid the groundwork for the development of novel therapies aimed at inducing regeneration in the damaged central nervous system (CNS). There are two major strategies for inducing regeneration in the damaged CNS: (i) activation of the endogenous regenerative capacity and (ii) cell transplantation therapy. In this review, we summarize the recent findings from our group and others on NSCs, with respect to their role in insult-induced neurogenesis (activation of adult NSCs, proliferation of transit-amplifying cells, migration of neuroblasts and survival and maturation of the newborn neurons), and implications for therapeutic interventions, together with tactics for using cell transplantation therapy to treat the damaged CNS.     

Midkine, a heparin-binding growth factor, is expressed in neural precursor cells and promotes their growth

Midkine, a heparin-binding growth factor, was found to be expressed in neural precursor cells, which consist of neural stem cells and the progenitor cells. When embryonic brain cells were allowed to form neurospheres enriched in neural precursor cells, numbers were significantly smaller from the midkine-deficient brain than from the wild-type brain. Dissociated neurosphere cells yielded nestin-positive neural precursor cells and differentiated neuronal cells upon culture on a substratum. Neural precursor cells from the midkine-deficient brain spread poorly and grew less effectively on a substratum coated with poly-l-lysine than the cells on midkine-coated substratum. Neural precursor cells from the wild-type brain spread and grew well on both the substrata. Differentiation to neurons and glia cells was not affected by the absence of midkine. Heparitinase digestion of dissociated neurosphere cells resulted in poor growth of neural precursor cells, while chondroitinase digestion had no effect. These results indicate that midkine is involved in the growth of neural precursor cells and suggest that the interaction with heparan sulfate proteoglycans is important in midkine action to these cells.