Adult neurogenesis: from canaries to the clinic

Neuronal precursor cells persist in the adult vertebrate forebrain, residing primarily in the ventricular/subventricular zone (SZ). In vivo, SZ precursors yield progeny which may die or give rise to glia. Yet they may also generate neurons, which are recruited to restricted regions such as the avian telencephalon and mammalian olfactory bulb. The survival of neurons arising from adult progenitors is dictated by both the availability of a permissive pathway for migration and the environment into which migration occurs. In the songbird higher vocal center (HVC), both humoral and contact-mediated signals modulate the migration and survival of new neurons, through an orchestrated set of hormonally regulated paracrine interactions. New neurons of the songbird brain depart the SZ to enter the brain parenchyma by migrating upon radial guide fibers, which emanate from cell bodies in the ventricular epithelium. The radial guide cells coderive with new neurons from a common progenitor, which is widespread throughout the songbird SZ. Neural precursors are also widely distributed in the adult mammalian SZ, although it is unclear whether avian and mammalian progenitor cells are homologous: Whereas neuronal recruitment persists throughout much of the songbird forebrain, in mammals it is limited to the olfactory bulb. In humans, the adult SZ appears to largely cease neurogenesis in vivo, although it, too, can produce neurons in vitro. In both rats and humans, the differentiation and survival of neurons arising from the postnatal SZ may be regulated by access to postmitotic trophic factors. Indeed, serial application of fibroblast growth factor-2 (FGF-2) and brain-derived neurotrophic factor (BDNF) has allowed the generation and maintenance of neurons from the adult human SZ. This suggests the feasibility of inducing neurogenesis in the human brain, both in situ and through implanted progenitors. In this regard, using cell-specific neural promoters coupled to fluorescent reporters, defined progenitor phenotypes may now be isolated by fluorescence-activated cell sorting. Together, these findings give hope that structural brain repair through induced neurogenesis and neurogenic implants will soon be a clinical reality.     

Lyme disease (Lyme borreliosis)

Unlike the peripheral nervous system (PNS), the mammalian central nervous system (CNS) clearly lacks the robust regenerative characteristics and capacity of the former. Despite this fact, two unique regions of the adult mammalian CNS possess such regenerative potential and are capable of active regeneration following injury or structural compromise. These unique areas are the olfactory system and the neurohypophyseal system of the endocrine hypothalamus. Furthermore, it has been clearly demonstrated that primordial neuroblasts regarded as stem cells emerge from the subependymal parenchyma of the walls and floor of the third cerebral ventricle, migrate to the ventricular surface and undergo compensatory synaptogenesis within one week following hypophysectomy. In situ hybridization studies have unequivocally demonstrated that the up-regulation of nitric oxide synthase (NOS) is essential for neural (axonal) regeneration and neuronal (stem cell) migration to occur. Moreover, neuronal migration is reliably inhibited following the administration of the NO antagonist, nitroarginine. The current investigation serves to confirm a remarkable degree of plasticity and regeneration in the adult mammalian neurohypophyseal system coupled with the emergence of primordial neuroblasts that undergo apparent differentiation, migration and compensatory synaptogenesis in response to the up-regulation of NO that occurs following the trauma of hypophysectomy. Evidence from the current investigation appears to confirm that specialized glia of the neurohypophyseal system, the so-called pituicyte, proliferate following hypophysectomy and may serve as a growth matrix or structural template that may target and direct regenerating Supraoptic (SON) and Paraventricular (PVN) axons toward endothelial primordia in the regenerating neural stem and lobe.     

Inappropriate apoptosis of salivary and lacrimal gland epithelium of immunodeficient NOD-scid mice

Reactive gliosis, which occurs in response to any damage or disturbance to the central nervous system, has been recognized for many years, but is still not completely understood. The hallmark is the increased expression of glial fibrillary acidic protein (GFAP), yet studies in GFAP knockout mice suggest that GFAP may not be required for an astrocyte to become hypertrophic. In this review, we describe a series of tissue culture models that have been established in order to address: 1) the biochemical phenotype of reactive astrocytes; 2) the factor and/or cell responsible for induction of gliosis; 3) the mechanisms by which one might block the induction. These models range from cultures of astrocytes, both neonatal and adult, to co-cultures of astrocytes with either neurons or microglia, to organ cultures. None is ideal: each addresses a different set of questions, but taken together, they are beginning to provide useful information which should allow a better understanding of the plasticity response of astrocytes to brain injury.     

Effects of basic fibroblast growth factor on hippocampal neurons after axonal injury

OBJECTIVE: Axons of adult central nervous system neurons fail to regenerate after diffuse axonal injury in head trauma. Basic fibroblast growth factor (bFGF) has been reported to enhance neuritic extensions after neuronal injury in immature nerve cells. To investigate the effects of bFGF on adult neurons and axonal reoutgrowth, differentiated nerve cells were axonally transected and bFGF was applied. DESIGN: Cell culture study with primary rat hippocampal neurons. MATERIALS AND METHODS: After axotomy, hippocampal cultures were maintained untreated or in the presence of 0.5, 1, 10, or 20 ng/mL bFGF and evaluated over a 7-day period after injury. MEASUREMENTS AND MAIN RESULTS: Seven days after injury, axotomy decreased cell survival to 65%, increased [3H]arachidonic acid release 1.8-fold from prelabeled cells, and showed negligible effects on neuronal dendrites. bFGF reduced this neurodegeneration at all doses applied. bFGF at 10 ng/mL most efficiently increased live cells to 85% and decreased [3H]arachidonic acid release from prelabeled cells to control values (p < 0.01, vs. damaged cells). Furthermore, 10 ng/mL bFGF induced axonal branching and the longest axonal re-extensions from 60 +/- 8 to 377 +/- 10 microns 7 days after injury (p < 0.01, vs. damaged cells). CONCLUSIONS: bFGF increased cell survival and supported axonal re-elongations in adult hippocampal neurons in vitro when applied after axotomy. bFGF may play a role in new therapeutic concepts for the management of axonal injury after head trauma.     

Development and regeneration of the nervous system: a role for neurosteroids

Several steroids, termed 'neurosteroids', are synthesized from cholesterol within both the central and peripheral nervous systems. These include pregnenolone and its sulfate ester, progesterone and its 5 alpha-reduced metabolites. Dehydroepiandrosterone, mainly in its sulfated form, also remains present in the brain long after removal of the steroidogenic endocrine glands. Its biosynthesis in brain remains an open possibility, but the pathways involved are unknown. Little information is available concerning the role of neurosteroids during the maturation of the nervous system, although they are already synthesized by glial cells and by some populations of neurons during embryonic life. Cell culture experiments suggest that neurosteroids may increase the survival and differentiation of both neurons and glial cells. In the adult nervous system, neurosteroids modulate neurotransmission by acting directly on the neuronal membrane and also produce structural changes in neurons and in astrocytes. Studies of neurosteroid levels are currently conducted to examine their possible role during aging. We have recently reported that progesterone, synthesized by Schwann cells, promotes the formation of new myelin sheaths after lesion of the mouse sciatic nerve. Thus, neurosteroids may also play an important role during regeneration of the nervous system.     

Central nervous system stem cells in the embryo and adult

The central nervous system is generated from neural stem cells during embryonic development. These cells are multipotent and generate neurons, astrocytes and oligodendrocytes. The last few years it has been found that there are populations of stem cells also in the adult mammalian brain and spinal cord. In this paper, we review the recent development in the field of embryonic and adult neural stem cells.     

bHLH transcription factors and mammalian neuronal differentiation

The basic helix-loop-helix (bHLH) factor Mash1 is expressed in the developing nervous system. Null mutation of Mash1 results in loss of olfactory and autonomic neurons and delays differentiation of retinal neurons, indicating that Mash1 promotes neuronal differentiation. Other bHLH genes, Math/NeuroD/Neurogenin, all expressed in the developing nervous system, have also been suggested to promote neuronal differentiation. In contrast, another bHLH factor, HES1, which is expressed by neural precursor cells but not by neurons, represses Mash1 expression and antagonizes Mash1 activity in a dominant negative manner. Forced expression of HES1 in precursor cells blocks neuronal differentiation in the brain and retina, indicating that HES1 is a negative regulator of neuronal differentiation. Conversely, null mutation of HES1 up-regulates Mash1 expression, accelerates neuronal differentiation, and causes severe defects of the brain and eyes. Thus, HES1 regulates brain and eye morphogenesis by inhibiting premature neuronal differentiation, and the down-regulation of HES1 expression at the right time is required for normal development of the nervous system. Interestingly, HES1 can repress its own expression by binding to its promoter, suggesting that negative autoregulation may contribute to down-regulation of HES1 expression during neural development. Recent studies indicate that HES1 expression is also controlled by RBP-J, a mammalian homologue of Suppressor of Hairless [Su(H)], and Notch, a key membrane protein that may regulate lateral specification through RBP-J during neural development. Thus, the Notch-->RBP-J-->HES1-Mash1 pathway may play a critical role in neuronal differentiation.     

Phytochrome controls the number of endoreduplication cycles in the Arabidopsis thaliana hypocotyl

In contrast to mammals, all teleost fish examined thus far exhibit an enormous potential to regenerate not only neuronal processes (axonal regeneration), but even whole neurons (neuronal regeneration) after injuries in the central nervous system. By application of lesions to one subdivision of the cerebellum, the corpus cerebelli, the role of apoptosis in neuronal regeneration was examined in the gymnotiform fish, Apteronotus leptorhynchus. Apoptotic cells were identified by examination of cryosections with the terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick end labelling (TUNEL) reaction, an in situ technique employed for detection of nuclear DNA fragmentation. Additional evidence for the apoptotic nature of dying cells was obtained through analysis of morphologies displayed at both the light microscopic and the ultrastructural level. The first TUNEL-positive cells at the site of the lesion appeared as rapidly as 5 min following mechanical damage of the tissue. Thirty minutes after stab wound lesion, their number reached maximum levels. Starting with 2 days of postlesioning survival time, a gradual decline in the number of TUNEL-positive cells was evident, until this process reached background levels 20 days after the lesion. We hypothesize that apoptosis is used in A. leptorhynchus as an efficient mechanism for the removal of cells damaged through injury in the central nervous system. Since apoptosis is not accompanied by the side-effects known from necrosis (which is predominant after injuries in the mammalian central nervous system), this "clean" type of cell death may, at least partially, explain the tremendous regenerative capability of teleosts.     

Anisotropic Heisenberg ferromagnetic model in two dimensions

Transformation of normal resting astrocytes to reactive astrocytes after injury is a well-known phenomenon. Using immunofluorescent labelling methods, astrocytes in the ischemically and retrogradely/anterogradely damaged adult forebrain nuclei were shown to express substance-P immunoreactivity. In contrast, astrocytes were not immunostained for substance-P in the normal brain or undamaged areas. Since substance-P has been shown to regulate inflammatory, wound-healing and immune responses in the peripheral tissues, it is likely that this aberrant expression of substance-P immunoreactivity in reactive astrocytes may relate to similar functions in the central nervous system as in the peripheral tissues after injury.     

A peptide derived from a neurite outgrowth-promoting domain on the gamma 1 chain of laminin modulates the electrical properties of neocortical neurons

Laminins form a family of large multidomain glycoproteins of the extracellular matrix. The cellular distribution of laminin immunoreactivity in the adult mammalian central nervous system suggests an important role for laminins in mature brain function in addition to their role during brain development. To characterize the effects of this group of extracellular matrix molecules on mature brain function, intracellular recording techniques were applied to in vitro slice preparations of the rat neocortex. The experiments show that a peptide homologous to the C-terminal part of the gamma 1 chain of laminin modulates the electrical activity of pyramidal neurons in the adult neocortex of the rat. The peptide is part of the neurite outgrowth-promoting domain of the gamma 1 chain on the E8 fragment of laminin and it displays the neurite outgrowth-promoting activity of the native laminin molecule. Perfusion of in vitro brain slices with the peptide increased the input resistance of the neuronal membrane. In addition, a rise in inward rectification could be observed. These events were accompanied by a strong increase in direct excitability of the treated neurons. Immunohistochemistry techniques were applied to sections of the adult rat neocortex and hippocampus to demonstrate the presence of both the neurite outgrowth-promoting domain and the native laminin in the adult brain. An antiserum raised against the neurite outgrowth-promoting domain on the gamma 1 chain of laminin, which also recognized the free synthetic peptide, showed immunoreactivity on neurons. In addition, a population of glial fibrillary acidic protein-positive astrocytes in the hippocampus displayed immunoreactivity for this antibody. These results were confirmed by using several antibodies directed against the whole laminin-1 molecule. Neurons in the neocortex and hippocampus, as well as astrocytes in the hippocampus, demonstrated immunoreactivity for antibodies directed against the whole laminin-1 molecule. The results suggest that laminins containing the gamma 1 chain have the potential to modulate neuronal activity. This effect may be mediated either by direct cell-cell contact from surrounding cells, or through the neuronal expression of laminin or laminin-like molecules which are inserted into the neuronal cell membrane.     

Beta-galactosidase-labelled relay neurons of homotopic olfactory bulb transplants establish proper afferent and efferent synaptic connections with host neurons

The vertebrate olfactory system has long been an attractive model for studying neuronal regeneration and adaptive plasticity due to the continuous neurogenesis and synaptic remodelling throughout adult life in primary and secondary olfactory centres, its precisely ordered synaptic network and accessibility for manipulation. After homotopic transplantation of fetal olfactory bulbs in bulbectomized neonatal rodents, newly regenerated olfactory neurons form glomeruli within the graft, and the efferent mitral/tufted cells of the transplant innervate the host brain, terminating in higher olfactory centres. However, the synaptic connections of the transplanted relay neurons within the graft and/or host's olfactory centres could not be characterized mainly because of lack of suitable cell-specific markers for these neurons. In this study, we have used olfactory bulbs from transgenic fetuses, in which the majority of the mitral/tufted cells express the bacterial enzyme beta-galactosidase, for homotopic olfactory bulb transplantation following complete unilateral bulbectomy. In the transplants, the cell bodies and terminals of the donor mitral/tufted cells were identified by beta-galactosidase histochemistry and immunocytochemistry at both light and electron microscope levels. We demonstrate that transplanted relay neurons re-establish specific synaptic connections with host neurons of the periphery, source of the primary signal and central nervous system, thereby providing the basis for a functional recovery in the lesioned olfactory system.     

Neurodegeneration in excitotoxicity, global cerebral ischemia, and target deprivation: A perspective on the contributions of apoptosis and necrosis

In the human brain and spinal cord, neurons degenerate after acute insults (e.g., stroke, cardiac arrest, trauma) and during progressive, adult-onset diseases [e.g., amyotrophic lateral sclerosis, Alzheimer's disease]. Glutamate receptor-mediated excitotoxicity has been implicated in all of these neurological conditions. Nevertheless, effective approaches to prevent or limit neuronal damage in these disorders remain elusive, primarily because of an incomplete understanding of the mechanisms of neuronal death in in vivo settings. Therefore, animal models of neurodegeneration are crucial for improving our understanding of the mechanisms of neuronal death. In this review, we evaluate experimental data on the general characteristics of cell death and, in particular, neuronal death in the central nervous system (CNS) following injury. We focus on the ongoing controversy of the contributions of apoptosis and necrosis in neurodegeneration and summarize new data from this laboratory on the classification of neuronal death using a variety of animal models of neurodegeneration in the immature or adult brain following excitotoxic injury, global cerebral ischemia, and axotomy/target deprivation. In these different models of brain injury, we determined whether the process of neuronal death has uniformly similar morphological characteristics or whether the features of neurodegeneration induced by different insults are distinct. We classified neurodegeneration in each of these models with respect to whether it resembles apoptosis, necrosis, or an intermediate form of cell death falling along an apoptosis-necrosis continuum. We found that N-methyl-D-aspartate (NMDA) receptor- and non-NMDA receptor-mediated excitotoxic injury results in neurodegeneration along an apoptosis-necrosis continuum, in which neuronal death (appearing as apoptotic, necrotic, or intermediate between the two extremes) is influenced by the degree of brain maturity and the subtype of glutamate receptor that is stimulated. Global cerebral ischemia produces neuronal death that has commonalities with excitotoxicity and target deprivation. Degeneration of selectively vulnerable populations of neurons after ischemia is morphologically nonapoptotic and is indistinguishable from NMDA receptor-mediated excitotoxic death of mature neurons. However, prominent apoptotic cell death occurs following global ischemia in neuronal groups that are interconnected with selectively vulnerable populations of neurons and also in nonneuronal cells. This apoptotic neuronal death is similar to some forms of retrograde neuronal apoptosis that occur following target deprivation. We conclude that cell death in the CNS following injury can coexist as apoptosis, necrosis, and hybrid forms along an apoptosis-necrosis continuum. These different forms of cell death have varying contributions to the neuropathology resulting from excitotoxicity, cerebral ischemia, and target deprivation/axotomy. Degeneration of different populations of cells (neurons and nonneuronal cells) may be mediated by distinct or common causal mechanisms that can temporally overlap and perhaps differ mechanistically in the rate of progression of cell death.     

Transmitting transmitter phenotypes in brain development

Little is known about the transmitter choice of neurons in the central nervous system. Recent evidence suggests that precursor cells in the mammalian neocortex are multipotential and generate GABAergic as well as glutamatergic neurons. Environmental interactions within the proliferative zone seem to specify the transmitter phenotype of the neurons generated by the multipotential precursor cells. Precursor cells are restricted in the ventricular zone of a given region in the forebrain and do not intermingle with precursor cells from the adjacent regions. They are thus exposed to distinct region-specific environmental influences that instruct the different neuronal phenotypes found in different regions of the adult brain. Amongst the factors that influence the transmitter choice of early neuroblasts are transmitters themselves. Activity-dependent mechanisms mediated by a variety of neurotransmitters and their receptors could be the key players in specifying neuronal phenotypes at early developmental stages in the ventricular zone.     

Synthesis and expression of a DNA encoding the Fv domain of an anti-lysozyme monoclonal antibody, HyHEL10, in Streptomyces lividans

The effect of peripheral axotomy on the expression of the class III beta-tubulin gene in adult dorsal root ganglion (DRG) neurons was examined. Of the 5 isotypic classes of beta-tubulin expressed in the mammalian nervous system, only the class III beta-tubulin is neuron specific. While information about the expression of several of the tubulin genes during neuronal development and regeneration has become available recently, very little is known about the expression of beta III-tubulin during axonal regeneration. To explore this issue, we examined axotomy-induced changes in beta III-tubulin mRNA levels in adult rat lumbar dorsal root ganglion (DRG) neurons at different times (1-28 days) after unilateral sciatic nerve crush using northern blotting of total RNA and quantitative in situ hybridization. These studies showed an initial decrease in beta III-tubulin mRNA levels in axotomized DRG neurons as compared to contralateral controls at 1 day after injury followed by robust increases in beta III-tubulin mRNA levels relative to contralateral controls from 1 to 4 weeks after injury. We postulate that beta III-tubulin may play an essential role in axonal growth because of its unique neuron-specific pattern of expression and its substantial increase in neurons that have been stimulated to regrow their axons.     

Brain macrophages stimulate neurite growth and regeneration by secreting thrombospondin

The presence of macrophages in the developing or lesioned central nervous system (CNS) led us to study the influence of these cells on neuronal growth. Macrophages were isolated from embryonic rat brain and we observed that factors released in vitro by these cells stimulate neurite growth and regeneration of cultured CNS neurons. This effect was inhibited by antibodies directed against thrombospondin, an extracellular matrix protein that we found to be synthesized and released by brain macrophages. Immunodetection of thrombospondin in the adult rat brain lesioned by kainic acid confirmed the production of this protein by brain macrophages and indicated an early intraparenchymal accumulation of thrombospondin following injury. These results suggest that brain macrophages contribute actively to neurite growth or regeneration during the development or in pathological contexts.