Chasing fate and function of new neurons in adult brains

Neuron production, migration and differentiation are major developmental events that continue, on a smaller scale, into adult life in a wide range of species from insects to mammals. Recent reports of adult neurogenesis in primates, including humans, have led to explosive scientific and public attention. During the last two years, significant discoveries have revealed that the generation, recruitment and survival of new neurons in adult brains are governed by principles similar to those that shape the developing brain, such as neuronal death, sensory experience, activity levels, and learning. Similarly, many factors implicated in embryonic neurogenesis are increasingly found to regulate adult neurogenesis and survival as well. These findings now allow the first manipulations of the numbers of adult-generated neurons to address their potential behavioral function.     

成年哺乳动物脑内神经元的增殖

成年哺乳动物的齿状回中仍保有一群具有增生能力并能分化成神经元的前体细胞 ,增生后分化成的神经元移入颗粒细胞层并发出轴突到苔藓纤维通路组成突触连接。在正常生理条件下这些细胞的再生能力很低 ,但在特殊环境或某些病理条件下增殖水平急剧升高 ,产生大量新生神经元。本文综述迄今为止有关这一类神经元前体细胞的研究结果。     

Neurogenesis in the adult mammalian brain

The concept of the CNS cell composition stability has recently undergone significant changes. It was earlier believed that neurogenesis in the mammalian CNS took place only during embryonic and early postnatal development. New approaches make it possible to obtain new results overriding the dogma that neurogenesis is impossible in the adult brain. The present review summarizes the information about the neural stem cell. It has been demonstrated that new neurons are constantly formed in adult mammals, including man. In two brain zones, subventricular zone and denate gyrus, neurogenesis appears proceed throughout the entire life of mammals, including man. The newly arising neurons are essential for some important processes, such as memory and learning. Stem cells were found in the subependymal and/or ependymal layer. They express nestin, and have a low mitotic activity. During embryogenesis, the stem cell divides asymmetrically: one daughter cell resides as the stem cell in the ependymal layer and another migrates to the subventricular zone. There it gives rise very fast to a pool of dividing precursors, from which neural and glial cells differentiate and migrate to the sites of final localization. The epidermal and fibroblast growth factors act as mitogens for the neural stem cell. The neural stem cell gives rise to the cells of all germ layers in vitro and has a wide potential for differentiation in the adult organism. Hence, it can be used as a source of various cell types of the nervous tissue necessary for cellular transplantation therapy.     

Interplay of KNDy and nNOS neurons: A new possible mechanism of GnRH secretion in the adult brain

Reproduction in mammals is favoured when there is sufficient energy available to permit the survival of offspring. Neuronal nitric oxide synthase expressing neurons produce nitric oxide in the proximity of the gonadotropin-releasing hormone neurons in the preoptic region. nNOS neurons are an integral part of the neuronal network controlling ovarian cyclicity and ovulation. Nitric oxide can directly regulate the activity of the GnRH neurons and play a vital role neuroendocrine axis. Kisspeptin neurons are essential for the GnRH pulse and surge generation. The anteroventral periventricular nucleus (AVPV), kisspeptin neurons are essential for GnRH surge generation. KNDy neurons are present in the hypothalamus's arcuate nucleus (ARC), co-express NKB and dynorphin, essential for GnRH pulse generation. Kisspeptin-neurokinin B-dynorphin (KNDy) neuroendocrine molecules of the hypothalamus are key components in the central control of GnRH secretion. The hypothalamic neurons kisspeptin, KNDy, nitric oxide synthase (NOS), and other mediators such as leptin, adiponectin, and ghrelin, play an active role in attaining puberty. Kisspeptin signalling is mediated by NOS, which further results in the secretion of GnRH. Neuronal nitric oxide is critical for attaining puberty, but its direct role in adult GnRH secretion is poorly understood. This review mainly focuses on the role of nNOS and its interplay with KNDy neurons in the hormonal regulation of reproduction.     

The scalable mammalian brain: emergent distributions of glia and neurons

In this paper, we demonstrate that two characteristic properties of mammalian brains emerge when scaling-up modular, cortical structures. Firstly, the glia-to-neuron ratio is not constant across brains of different sizes: large mammalian brains have more glia per neuron than smaller brains. Our analyses suggest that if one assumes that glia number is proportional to wiring, a particular quantitative relationship emerges between brain size and glia-to-neuron ratio that fits the empirical data. Secondly, many authors have reported that the number of neurons underlying one mm² of mammalian cortex is remarkably constant, across both areas and species. Here, we will show that such a constancy emerges when enlarging modular, cortical brain structures. Our analyses thus corroborate recent studies on the mammalian brain as a scalable architecture, providing a possible mechanism to explain some of the principles, constancies and rules that hold across brains of different size.     

Brain micro-ecologies: neural stem cell niches in the adult mammalian brain

Neurogenesis persists in two germinal regions in the adult mammalian brain, the subventricular zone of the lateral ventricles and the subgranular zone in the hippocampal formation. Within these two neurogenic niches, specialized astrocytes are neural stem cells, capable of self-renewing and generating neurons and glia. Cues within the niche, from cell-cell interactions to diffusible factors, are spatially and temporally coordinated to regulate proliferation and neurogenesis, ultimately affecting stem cell fate choices. Here, we review the components of adult neural stem cell niches and how they act to regulate neurogenesis in these regions.     

BDNF mediates the effects of testosterone on the survival of new neurons in an adult brain

New neurons are incorporated into the high vocal center (HVC), a nucleus of the adult canary (Serinus canaria) brain that plays a critical role in the acquisition and production of learned song. Recruitment of new neurons in the HVC is seasonally regulated and depends upon testosterone levels. We show here that brain-derived neurotrophic factor (BDNF) is present in the HVC of adult males but is not detectable in that of females, though the HVC of both sexes has BDNF receptors (TrkB). Testosterone treatment increases the levels of BDNF protein in the female HVC, and BDNF infused into the HVC of adult females triples the number of new neurons. Infusion of a neutralizing antibody to BDNF blocks the testosterone-induced increase in new neurons. Our results demonstrate that BDNF is involved in the regulation of neuronal replacement in the adult canary brain and suggest that the effects of testosterone are mediated through BDNF.     

Intranuclear localization of iron in neurons of mammalian brain

Using Perls’ histochemical method, iron was revealed in the brain structures of human and rat. Iron accumulation was observed in perivascular areas and neuropil of substantia nigra as well as in white matter of cerebellum. After diaminobenzidine enhancement of histochemical reaction, the iron was revealed in nucleoli of many neurons, which is described for the first time in animal cells.     

Neurosteroids: a new function in the brain

"Neurosteroids" accumulate in the central nervous system independently of supply by peripheral endocrine glands. Dehydroepiandrosterone (DHA) and pregnenolone (delta 5P) were first found in the rat brain. Then, a steroid biosynthetic pathway was demonstrated in oligodendrocytes, mostly by enzyme immunocytochemistry and biochemical studies in primary cultures of glial cells, where the formation, from appropriate radioactive precursors, of delta 5P, delta 5-pregn-3 beta, 20 alpha-diol (20 alpha-DH delta 5P), progesterone (P), 5 alpha-pregnane-3,20-dione (5 alpha-DHP) and 3 alpha-hydroxy-5 alpha-pregnane-20-one (3 alpha, 5 alpha-THP), as well as estrogen-induced nuclear progesterone receptor (PR) was observed. Several biological effects of neurosteroids have been observed, such as electrical stimulation of neurones, involvement in behaviorial activities, modulation of GABAA-receptor (GABAA-R) function (potentiated by 3 alpha, 5 alpha-THP and its 21-hydroxyderivative, antagonized by delta 5P- and DHA-sulfates) and growth/differentiation of glial cells in vitro. Preliminary findings suggest that the neurosteroid concept applies to all mammalian species, including man. Further investigations should assess the pathophysiological significance of the synthesis of neurosteroids and decipher their mechanisms of action via nuclear and membrane receptors.     

Genetically targeting new neurons in the adult hippocampus

Neurogenesis, the birth of new neu-rons from neural stem cells, is known to occur throughout life in two specific regions of the adult mammalian brain, the sub...     

Neural function: metabolism and actions of inositol metabolites in mammalian brain

In the nervous system, a variety of cell types respond to external stimuli through the inositol lipid signalling pathways. The stimulus-coupled sequence of intracellular events has been investigated in a homogeneous model system, the cloned mammalian neural cell line NG115-401L. The neural peptide bradykinin stimulates a rapid production of identified inositol phosphate isomers and an intracellular Ca2+ discharge followed by a persistent plasma membrane influx. The temporal sequence suggests that Ins(1,4,5)P3 or Ins(1,3,4,5)P4 or both may coordinate these events in a neuronal cell, as has been suggested in other cell types. Thapsigargin, an irritant and tumour-promoting plant product, produces calcium transients in the absence of inositol phosphate production, and may provide a new tool for investigating the interactions between inositol phosphates and changes in cellular calcium homeostasis. In the 401L line, high levels of radiolabelled InsP5 and InsP6 have been detected, which has led to the evaluation of their possible occurrence and actions in normal brain. Both InsP5 and InsP6 are produced from a radiolabelled myo-inositol precursor in intact mature brain in a region-specific manner. This suggests that both inositol polyphosphates may be end products of regionally regulated biosynthetic pathways. When microinjected into a nucleus of the brainstem, or iontophoretically applied to the dorsal horn of the spinal cord, both InsP5 and InsP6, but not Ins(1,3,4,5)P4 isomers, appear to be potent neural stimulants. These results suggest that the inositol lipid signalling pathways may generate both intracellular and extracellular signals in brain.     

Hormonal control of neural function in the adult brain

Although the mechanisms by which peripheral hormones modulate complex behaviors are far from being well understood, recent advances in deciphering the mechanisms of hormone action in the brain are promising. Current areas of interest include the molecular mechanisms of steroid receptor action, the steroid modulation of synaptic function, and the mediation of steroid-regulated neuronal and glial plasticity by growth factors or proteins associated with brain development.     

Blind patch clamp recordings in embryonic and adult mammalian brain slices

To obtain electrophysiological recordings in brain slices, sophisticated and expensive pieces of equipment can be used. However, costly microscope equipment with infrared differential interference contrast optics is not always necessary or even desirable. For instance, obtaining a randomized unbiased sample in a given preparation would be better accomplished if cells were not directly visualized before recording. In addition, some preparations require thick slices, and direct visualization is not possible. Here we describe a protocol for the 'blind patch clamp method' that we developed several years ago to perform electrophysiological recordings in mammalian brain slices using a standard patch clamp amplifier, dissecting microscope and recording chamber. Overall, it takes approximately 3-4 h to set up this procedure.     

Transplanted neurons form both normal and ectopic projections in the adult brain

Transplantation of embryonic or stem cell derived neurons has been proposed as a potential therapy for several neurological diseases. Previous studies reported that transplanted embryonic neurons extended long-distance projections through the adult brain exclusively to appropriate targets. We transplanted E14 lateral ganglionic eminence (LGE) and E15 cortical precursors from embryonic mice into the intact adult brain and analyzed the projections formed by transplanted neurons. In contrast to previous studies, we found that transplanted embryonic neurons formed distinct long-distance projections to both appropriate and ectopic targets. LGE neurons transplanted into the adult striatum formed projections not only to the substantia nigra, a normal target, but also to the claustrum and through all layers of fronto-orbital cortex, regions that do not normally receive striatal input. In some cases, inappropriate projections outnumbered appropriate projections. To examine the relationship between the donor cells and host brain in establishing the pattern of projections, we transplanted cortical precursors into the adult striatum. Despite their heterotopic location, cortical precursors not only predominantly formed projections appropriate for cortical neurons, but they also formed projections to inappropriate targets. Transplantation of GFP-expressing cells into beta-galactosidase-expressing mice confirmed that the axonal projections were not created by the fusion of donor and host cells. These results suggest that repairing the brain using transplantation may be more complicated than previously expected, because exuberant ectopic projections could result in brain dysfunction. Understanding the signals regulating axonal extension in the adult brain will be necessary to harness stem cells or embryonic neurons for effective neuronal-replacement therapies.     

Deviating from the well travelled path: precursor cell migration in the pathological adult mammalian brain

The presence of both neural and glial precursor cells in the adult central nervous system (CNS) and the capacity of these cells to migrate through this mature structure to areas of pathological damage and injury raises hope for the development of new therapeutic strategies to treat brain injury and disease. Although at present time, the compensatory neurogenesis described after various types of brain pathologies appears to be modest, the development of a strategy promoting the directed mobilization and phenotypic induction of endogenous precursor cells to areas of neural cell loss remains of high interest. The development of such a strategy however is currently thwarted by a limited understanding of the process and factors influencing precursor cell migration. In this review, we will discuss the current knowledge around precursor cell migration in the pathological adult brain with particular focus on the response and fate of precursor sub-populations to neural cell loss and the role of the inflammatory system in mediating precursor cell migration. Through this discussion we will identify particular areas in which further detailed research is required in order to expand our current understanding and aid in the eventual development of a novel therapeutic application.