Epoxygenase metabolites

Cytochrome P450 (CYP450) epoxygenase enzymes demonstrate organ and cell specific expression and each CYP450 enzyme isoform produces a distinct pattern of epoxyeicosatrienoic acids (EETs). Investigations are beginning to describe the regulation of specific tissue CYP450 epoxygenase isoforms that may be associated with alterations in organ function that occur during various physiological and pathophysiological states. The main biological actions of EETs are their ability to affect epithelial ion transport and vascular smooth muscle cell function. This chapter focuses on the organ localization and production of EETs and the action of EETs on epithelial and vascular smooth muscle cells.     

Wnt/β‐catenin signaling during early vertebrate neural development

The vertebrate central nervous system (CNS) is comprised of vast number of distinct cell types arranged in a highly organized manner. This high degree of complexity is achieved by cellular communication, including direct cell‐cell contact, cell‐matrix interactions, and cell‐growth factor signaling. Among the several developmental signals controlling the development of the CNS, Wnt proteins have emerged as particularly critical and, hence, have captivated the attention of many researchers. With Wnts' evolutionarily conserved function as primordial symmetry breaking signals, these proteins and their downstream effects are responsible for simultaneously establishing cellular diversity and tissue organization. With their expansive repertoire of secreted agonists and antagonists, cell surface receptors, signaling cascades and downstream biological effects, Wnts are ideally suited to control the complex processes underlying vertebrate neural development. In this review, we will describe the mechanisms by which Wnts exert their potent effects on cells and tissues and highlight the many roles of Wnt signaling during neural development, starting from the initial induction of the neural plate, the subsequent patterning along the embryonic axes, to the intricately organized structure of the CNS. © 2017 Wiley Periodicals, Inc. Develop Neurobiol 77: 1239–1259, 2017     

对比不同类型干细胞对于缺血性脑卒中治疗的研究进展

成人中枢神经系统存在着一定量的神经干细胞,其具有两大关键能力;自我更新和多向分化潜能。缺血性脑卒中是一种由于由脑血流的缺失或减少引起的脑动脉闭塞,进而导致脑组织梗死的脑血管疾病。虽然对于脑损伤的药物治疗已经取得了一定的成果,但目前以干细胞为基础的治疗方法仍成为了研究热点。无论是内源性神经干细胞还是外源性神经干细胞移植均可在脑损伤后向远端损伤区迁移并分化成新的神经细胞,从而在中枢神经系统疾病尤其是脑梗死后进行组织修复和功能恢复。因此在这篇综述中,我们主要探讨不同类型的干细胞对脑梗死介导的脑损伤的应用潜能,对比不同类型干细胞对缺血性脑卒中的治疗优缺点。     

Notch signaling is involved in nervous system formation in ascidian embryos

Notch signaling plays crucial roles during embryogenesis in various metazoans. HrNotch, a Notch homologue in the ascidian Halocynthia roretzi, has been previously cloned, and its expression pattern suggests that HrNotch signaling is involved in nervous system formation. To determine the function of HrNotch signaling, in the present study we examined the effects of the constitutively activated forms of HrNotch. Overexpression resulted in larvae with defects in neural tube closure and brain vesicle formation. In embryos expressing the activated HrNotch, the expression of a neural marker gene, HrETR-1, was enhanced and expanded in the central nervous system, although ectopic expression decreased during the tailbud stage. The activated HrNotch also suppressed the formation of the adhesive organ (palps) and the peripheral nervous system, which consists of ciliary mechanosensory neurons, whereas it promoted epidermal differentiation. The suppression and promotion of the formation of these respective cell types were confirmed by examination of the expression of relevant tissue-specific markers. We also cloned Hrdelta, an ascidian homologue of DSL family genes, which encode ligands for which Notch acts as a receptor. The expression of Hrdelta was observed in the precursors of palps and peripheral neurons in addition to the CNS. These results suggest that Notch signaling is important for ascidian nervous system formation and that it affects the fate choice between palps and epidermis and between peripheral neurons and epidermis within the neurogenic regions of the surface ectoderm by suppressing the formations of palps and peripheral neurons and promoting epidermal differentiation.     

Notch: from neural development to neurological disorders

Notch is an integral membrane protein that functions as receptor for ligands such as jagged and delta that are associated with the surface of neighboring cells. Upon ligand binding, notch is proteolytically cleaved within its transmembrane domain by presenilin‐1 (the enzymatic component of the γ‐secretase complex) resulting in the release of a notch intracellular domain which translocates to the nucleus where it regulates gene expression. Notch signaling plays multiple roles in the development of the CNS including regulating neural stem cell (NSC) proliferation, survival, self‐renewal and differentiation. Notch is also present in post‐mitotic neurons in the adult CNS wherein its activation influences structural and functional plasticity including processes involved in learning and memory. Recent findings suggest that notch signaling in neurons, glia, and NSCs may be involved in pathological changes that occur in disorders such as stroke, Alzheimer’s disease and CNS tumors. Studies of animal models suggest the potential of agents that target notch signaling as therapeutic interventions for several different CNS disorders.     

Integrin-mediated regulation of neurovascular development,physiology and disease

The mammalian central nervous system (CNS) is comprised of billions of neurons and glia that are intertwined with an elaborate network of blood vessels. These various neural and vascular cell types actively converse with one another to form integrated, multifunctional complexes, termed neurovascular units. Cell-cell communication within neurovascular units promotes normal CNS development and homeostasis, and abnormal regulation of these events leads to a variety of debilitating CNS diseases. This review will summarize (i) cellular and molecular mechanisms that regulate physiological assembly and maintenance of neurovascular units; and (ii) signaling events that induce pathological alterations in neurovascular unit formation and function. An emphasis will be placed on neural-vascular cell adhesion events mediated by integrins and their extracellular matrix (ECM) ligands. I will highlight the role of a specific adhesion and signaling axis involving αvβ8 integrin, latent transforming growth factor β’s (TGFβ’s), and canonical TGFβ receptors. Possible functional links between components of this axis and other signal transduction cascades implicated in neurovascular development and disease will be discussed. In summary, comprehensively understanding the pathways that regulate bidirectional neural-vascular cell contact and communication will provide new insights into the mechanisms of neurovascular unit development, physiology and disease.     

急性脑缺血诱导的Sirt3蛋白表达下调通过破坏线粒体功能导致神经元损伤

本文旨在观察急性脑缺血对神经元沉默信息调节因子2相关酶类3(silent mating type information regulator 2 homolog 3,Sirt3)蛋白表达水平的影响,并阐明Sirt3在急性脑缺血中的病理意义.建立小鼠大脑中动脉栓塞(middle cerebral artery occlu...     

The role of the insulin-like growth factors in the central nervous system

Increasing evidence strongly supports a role for insulin-like growth factor-I (IGF-I) in central nervous system (CNS) development. IGF-I, IGF-II, the type IIGF receptor (the cell surface tyrosine kinase receptor that mediates IGF signals), and some IGF binding proteins (IGFBPs; secreted proteins that modulate IGF actions) are expressed in many regions of the CNS beginningin utero. The expression pattern of IGF system proteins during brain growth suggests highly regulated and developmentally timed IGF actions on specific neural cell populations. IGF-I expression is predominantly in neurons and, in many brain regions, peaks in a fashion temporally coincident with periods in development when neuron progenitor proliferation and/or neuritic outgrowth occurs. In contrast, IGF-II expression is confined mainly to cells of mesenchymal and neural crest origin. While expression of type I IGF receptors appears ubiquitous, that of IGFBPs is characterized by regional and developmental specificity, and often occurs coordinately with peaks of IGF expression. In vitro IGF-I has been shown to stimulate the proliferation of neuron progenitors and/or the survival of neurons and oligodendrocytes, and in some cultured neurons, to stimulate function. Transgenic (Tg) mice that overexpress IGF-I in the brain exhibit postnatal brain overgrowth without anatomic abnormality (20–85% increases in weight, depending on the magnitude of expression). In contrast, Tg mice that exhibit ectopic brain expression of IGFBP-1, an inhibitor of IGF action when present in molar excess, manifest postnatal brain growth retardation, and mice with ablated IGF-I gene expression, accomplished by homologous recombination, have brains that are 60% of normal size as adults. Taken together, these in vivo studies indicate that IGF-I can influence the development of most, if not all, brain regions, and suggest that the cerebral cortex and cerebellum are especially sensitive to IGF-I actions. IGF-I’s growth-promoting in vivo actions result from its capacity to increase neuron number, at least in certain populations, and from its potent stimulation of myelination. These IGF-I actions, taken together with its neuroprotective effects following CNS and peripheral nerve injury, suggest that it may be of therapeutic benefit in a wide variety of disorders affecting the nervous system.     

Wnt/��-catenin signaling in cerebral cortical development

The cerebral cortex is the multilayered sheet of neurons that underlies our highest cognitive abilities. Canonical Wnt/β-catenin signaling has well-known activities in tissue patterning in regulating rostral-caudal and medial-lateral patterning in the developing cortex. In addition, recent studies suggest that Wnt/β-catenin signaling also plays important roles in establishing the radial inside to outside organization of the cerebral cortex. Different Wnts, Wnt receptors and inhibitors are expressed in overlapping radial compartments of the cerebral cortex, and in vivo functional studies have provided evidence for Wnt/β-catenin regulation of neural precursor self-renewal, laminar fate determination and establishing or stabilizing the patterns of neuronal communication of cortical neurons. Wnt/β-catenin alterations have been observed in human brain tumors, and understanding its many diverse functions during normal neural development may provide greater insight into the mechanisms underlying the development and progression of neural tumors.Key words: cerebral cortex, neural stem cell, neural precursor, ventricular zone, laminar fate, regional specification, radial patterning     

Rejection of fetal neocortical neural transplants by H-2 incompatible mice

In order to examine questions concerning immunologic privilege of the central nervous system, we placed neocortical transplants into cerebral ventricles of mice. We compared the fates of transplants between fully H-2 compatible (isografts) and H-2 incompatible (allografts) animals. Histologic evaluation comparing animals from iso- and allograft groups revealed significant differences in the number of inflammatory cells and in the degree of necrosis within the grafts. Response to allografted tissue within the brain mimics that seen in several immune-mediated diseases of the nervous system in that neurons appear to be selectively spared. Only upon subsequent stimulation of the host's immune system with an orthotopic skin graft bearing the major histocompatibility complex antigens of the neural graft are neurons destroyed. Immunohistochemical evaluation revealed that the inflammatory cell infiltrates in and around the allografts were composed of Lyt-2+, L3T4+, and Mac-1+ cells. In addition, Ia+ endothelial cells as well as Ia+ parenchymal CNS cells were found in both donor and host tissue of allografted animals. Hence, H-2 incompatible neural tissue transplanted to the CNS is recognized and rejected by the immune system of the recipient animal. The cellular infiltrates seen within the first weeks to months following transplantation of allogeneic CNS tissue resemble those seen in other allografts undergoing rejection. We conclude that the CNS is not unconditionally privileged as either a transplant site or as a source of transplanted tissue.     

活性氮自由基:脑缺血再灌注损伤过程中引起血脑屏障破坏及调节神经修复的双刃剑(英文)

在脑缺血再灌注损伤中,自由基发挥着重要作用。脑缺血及再灌注可产生大量的自由基,随着这些自由基的聚集,会引发一系列的分子级联反应,从而增加血脑屏障的通透性,诱发脑水肿、出血、炎症反应及细胞死亡。以一氧化氮(NO)及过氧亚硝基阴离子(ONOO-)为代表的活性氮(reactive nitrogen species,RNS),是自由基的重要组成部分,它们在脑缺血再灌注损伤中作用显著。一方面,活性氮能激活基质金属蛋白酶(MMPs),破坏血脑屏障。MMPs作为一大类含2价锌离子的水解酶,其激活可以降解脑血管及神经元细胞外基质。脑缺血再灌注损伤产生NO和ONOO-,它们均可以通过激活MMPs,降解紧密连接蛋白,从而破坏血脑屏障。另一方面,近期研究发现,活性氮也参与了脑缺血后神经再生及修复的调节过程。因此,了解这些活性小分子在血脑屏障破坏及神经再生中的复杂生物活性将很有意义。小窝蛋白1(Caveolin-1)就是活性氮自由基的重要靶分子,它是一种细胞表面的穴样内陷(caveolae)中的膜蛋白,可以通过抑制MMPs的激活保护血脑屏障的完整性。下调Caveolin-1的表达将引起血脑屏障的破坏。脑缺血所产生的NO能下调Caveolin-1的表达,而Caveolin-1的下调,能引起NO合酶的增加,促进生成更多的NO。活性氮与Caveolin-1互相作用,形成了一个反馈回路,通过激活MMPs而造成血脑屏障的不断破坏。此外,Caveolin-1通过调节不同的信号通路,抑制神经干细胞的增长及向神经元分化。因此,活性氮也很可能通过调节Caveolin-1及其他信号通路调控神经再生。在这篇文章中,我们对活性氮在血脑屏障及神经再生中的近期研究进展进行了综述。我们认为,活性氮可能在脑缺血再灌注中起双重作用,既是细胞毒性分子,亦可能是神经再生中的重要信号分子,其作用与其在神经元、内皮细胞及其微环境中产生的量有重要的关系。     

Role of morphogens in neural crest cell determination

The neural crest is a transient, migratory cell population found in all vertebrate embryos that generate a diverse range of cell and tissue derivatives including, but not limited, to the neurons and glia of the peripheral nervous system, smooth muscle, connective tissue, melanocytes, craniofacial cartilage, and bone. Over the past few years, many studies have provided tremendous insights into understanding the mechanisms regulating the induction and migration of neural crest cell development. This review highlights the surprising and perhaps unexpected roles for morphogens in these distinct processes. A comparison of studies performed in several different vertebrates emphasizes the requirement for coordination between multiple signaling pathways in the induction and migration of neural crest cells in the developing embryo.     

Astrocyte Mitochondria in In Vitro Models of Ischemia

There is growing evidence that preservation of mitochondrial respiratory function during cerebral ischemia-reperfusion predicts the ultimate extent of tissue injury. Because neurons are selectively vulnerable to ischemic injury, many studies have focused on neuronal mitochondrial dysfunction in ischemia. However, positron emission tomography (PET) studies in animals and humans suggest that non-neuronal cells such as astrocytes may also experience mitochondrial metabolic compromise that contributes to ischemic necrosis. Astrocytes carry out a number of functions that are critical to normal nervous system function, including uptake of neurotransmitters, regulation of pH and ion concentrations, and metabolic support of neurons. Mitochondria are important for many of these actions. We have used a cell culture model of stroke, oxygen-glucose deprivation (OGD), to study the response of astrocyte mitochondria to ischemia, and to evaluate how changes in astrocyte mitochondrial function might affect neuronal survival and recovery after ischemia.     

The O-GlcNAc Modification of CDK5 Involved in Neuronal Apoptosis Following In Vitro Intracerebral Hemorrhage

Contrary to cell cycle-associated cyclin-dependent kinases, CDK5 is best known for its regulation of signaling processes in regulating mammalian CNS development. Studies of CDK5 have focused on its phosphorylation, although the diversity of CDK5 functions in the brain suggests additional forms of regulation. Here we expanded on the functional roles of CDK5 glycosylation in neurons. We showed that CDK5 was dynamically modified with O-GlcNAc in response to neuronal activity and that glycosylation represses CDK5-dependent apoptosis by impairing its association with p53 pathway. Blocking glycosylation of CDK5 alters cellular function and increases neuronal apoptosis in the cell model of the ICH. Our findings demonstrated a new role for O-glycosylation in neuronal apoptosis and provided a mechanistic understanding of how glycosylation contributes to critical neuronal functions. Moreover, we identified a previously unknown mechanism for the regulation of activity-dependent gene expression, neural development, and apoptosis.     

Nerve Growth Factor as a Mitogen for a Pancreatic Carcinoid Cell Line

Abstract: Carcinoid tumors are a group of neuroendocrine neoplasms distributed widely throughout the body but most commonly occurring in the gut. These tumors retain many characteristics of their neural crest origin, including secretion of neuroactive peptides and responsiveness to neurotrophic substances. Nerve growth factor (NGF), a neurotrophic protein involved in maintenance and differentiation of peripheral sympathetic and sensory neurons, regulates growth of several neural tumor cells by inducing a differentiated phenotype and subsequent inhibition of cell growth rate. We examined the actions of NGF in a functioning human pancreatic carcinoid cell line (termed BON). NGF has no effect on the cytoarchitecture or constitutive secretion of bioamines in this carcinoid cell line. NGF, however, stimulates the in vitro cellular proliferation of BON cells. BON cells possess mRNA for the NGF receptors (p75^LNGFR and p140^trkA) and membrane-associated tyrosine kinase activity is increased in response to NGF. Both the mitogenic activity of NGF, as well as the receptor-linked tyrosine kinase activity, can be abrogated in BON cells by the trkA inhibitor K-252a and specific anti-NGF antibody. Our studies demonstrate that NGF is a mitogen for this carcinoid cell line without effect on cellular phenotype or cytoarchitecture. NGF may play a role in the development and progression of human carcinoid tumors.     

TGF-β in the central nervous system: Potential roles in ischemic injury and neurodegenerative diseases

The Transforming Growth Factor-βs (TGF-β) are a group of multifunctional proteins whose cellular sites of production and action are widely distributed throughout the body, including the central nervous system (CNS). Within the CNS, various isoforms of TGF-β are produced by both glial and neural cells. When evaluated in either cell culture or in vivo models, the various isoforms of TGF-β have been shown to have potent effects on the proliferation, function, or survival of both neurons and all three glial cell types, astrocytes, microglia and oligodendrocytes. TGF-β has also been shown to play a role in several forms of acute CNS pathology including ischemia, excitotoxicity and several forms of neurodegenerative diseases including multiple sclerosis, Parkinson's disease, AIDS dementia and Alzheimer's disease.     

Regeneration of the central nervous system using endogenous repair mechanisms

Recent advances in developmental and stem cell biology have made regeneration-based therapies feasible as therapeutic strategies for patients with damaged central nervous systems (CNSs), including those with spinal cord injuries, Parkinson disease, or stroke. These strategies can be classified into two approaches: (i) the replenishment of lost neural cells and (ii) the induction of axonal regeneration. The first approach includes the activation of endogenous neural stem cells (NSCs) in the adult CNS and cell transplantation therapy. Endogenous NSCs have been shown to give rise to new neurons after insults, including ischemia, have been sustained; this form of neurogenesis followed by the migration and functional maturation of neuronal cells, as well as the responses of glial cells and the vascular system play crucial roles in endogenous repair mechanisms in damaged CNS tissue. In this review, we will summarize the recent advances in regeneration-based therapeutic approaches using endogenous NSCs, including the results of our own collaborative groups.     

Distribution and Expression of Protein Kinase C Interactive Protein (PKCI/HINT1) in Mouse Central Nervous System (CNS)

Protein kinase C interactive protein (PKCI; also known as histidine triad protein, HINT1) is a small intracellular protein widely expressed in tissues from both the peripheral and CNS. Although the structure of this protein is well characterized, the functional aspect and cellular distribution of the protein remain unknown, especially in CNS. To analyze the expression pattern of PKCI/HINT1 we used antibodies against either the whole recombinant protein or a peptide epitope of PKCI/HINT1. We find widespread of PKCI/HINT1 expression in the mouse CNS by Western blot and immunostaining. Our data indicates that PKCI/HINT1 is present broadly throughout the regions of CNS with relatively high abundance in olfactory system, cerebral cortex, hippocampus and part of thalamus, hypothalamus, midbrain, pons and medulla. On the cellular level, PKCI/HINT1 immunoreactivity is primarily located in neurons and neuronal processes. This study provides the anatomical evidence for the potential roles of PKCI/HINT1 in neuronal function.     

Administration of anti-c-kit antibody into the cerebrospinal fluid leads to increased cell death in the developing cerebral cortex

It is generally believed that during development, neurons are usually produced in excess. Cell death occurs in the developing nervous system. The survival of the developing neurons depends on many factors derived from the target sites, of which the neuronal trophic factors are by far the best known. Stem cell factor (SCF) and its receptor, c-kit, is expressed in cells of nervous system during development and adulthood. Although the role of SCF/c-kit in the nervous system is so far not clear, in vitro studies indicate that SCF/c-kit is trophic to certain neurons derived from neural crest and cerebral cortex. In this study the effects of anti-c-kit antibody on cell death in the newborn chick cerebral cortex have been investigated. Injection of anti-c-kit antibody into the cisterna magnum increased the number of cell death and resulted in thinning of the cerebral cortex as compared to that from the control group. It is concluded that SCF/c-kit is essential for cortical progenitor cell survival in the cerebral cortex. Moreover, this method may be applied to the other factors and different CNS regions, allowing identification of factors involved in cell death. It additionally re-emphasizes the importance of further investigations into the potential roles of SCF/c-kit signaling in neurodegenerative diseases.     

Cell fate control in the developing central nervous system

The principal neural cell types forming the mature central nervous system (CNS) are now understood to be diverse. This cellular subtype diversity originates to a large extent from the specification of the earlier proliferating progenitor populations during development. Here, we review the processes governing the differentiation of a common neuroepithelial cell progenitor pool into mature neurons, astrocytes, oligodendrocytes, ependymal cells and adult stem cells. We focus on studies performed in mice and involving two distinct CNS structures: the spinal cord and the cerebral cortex. Understanding the origin, specification and developmental regulators of neural cells will ultimately impact comprehension and treatments of neurological disorders and diseases.