Prolonged local neurotrophin-3 infusion reduces ipsilateral collateral sprouting of spared corticospinal axons in adult rats.

The corticospinal tract is widely used to study regeneration and is essential for voluntary movements in humans. In young rats, corticospinal axons on the uninjured side sprout and grow into the denervated side. Neurotrophin-3 (NT-3) induces such crossed collateral sprouting in adults. We investigated whether local intraspinal NT-3 infusions would promote collateral sprouting of spared corticospinal terminals from within a partially denervated side, as this would be more appropriate for enhancing function of unilateral and specific movements. Adult rats received a partial bilateral transection of the pyramids, leaving approximately 40% of each tract intact. Vehicle or vehicle plus NT-3 (3 or 10 microg/day) was infused for 14 days into the left side of the cervical (C5/6) or lumbar (L2) cord. The corticospinal processes on the left side were anterogradely traced with cholera toxin B (CTB; which labeled gray matter processes more robustly than biotinylated dextran amine) injected into the front or hind limb area of the right sensorimotor cortex, respectively, 3 days before analysis. Unexpectedly, approximately 40% fewer CTB-labeled corticospinal processes were detectable in the cervical or lumbar gray matter of NT-3-treated rats than in vehicle-infused ones. Vehicle-infused injured rats had more corticospinal processes in the center of the cord than normal rats, evidence for lesion-induced collateral sprouting. NT-3 caused sprouting of local calcitonin gene-related peptide-positive fibers. These results suggest that NT-3 reduces collateral sprouting of spared corticospinal axons from within the denervated regions, possibly because of the injury environment or by increasing sprouting of local afferents. They identify an unexpected context-dependent outgrowth inhibitory effect of NT-3.

alpha6beta1 integrin directs migration of neuronal precursors in adult mouse forebrain.

New neuroblasts are constantly generated in the adult mammalian subventricular zone (SVZ) and migrate via the very-restricted rostral migratory stream (RMS) to the olfactory bulb, where they differentiate into functional neurons. Several facilitating and repulsive molecules for this migration have been identified, but little is known about chemoattractive molecules involved in the directed nature of this migration in vivo. Here, we investigated the role of the alpha6beta1 integrin, and its ligand, laminin, in controlling guidance of the migrating neuroblasts in adult mice. Immunostaining for the alpha6beta1 integrin was present in neuroblasts and their processes in the anterior/rostral SVZ and the RMS. Inhibition of the endogenous alpha6 or beta1 subunit with locally injected antibodies disrupted the cohesive nature of the RMS, but did not kill the neuroblasts. Infusion of a 15 a.a. peptide, representing the E8 domain of the laminin alpha chains that bind alpha6beta1 integrin, into the neostriatum redirected the neuroblasts away from the RMS towards the site of infusion. Injection of a narrow tract of intact laminin also drew the neuroblasts away from the RMS, but in a more restricted localization. These results suggest a critical role for integrins and laminins in adult SVZ-derived neuroblast migration. They also suggest that integrin-based strategies could be used to direct or restrict neuroblasts to CNS regions where they are needed for cell replacement therapies in the nervous system.

Endogenous and exogenous ciliary neurotrophic factor enhances forebrain neurogenesis in adult mice.

Neurogenesis in the adult mammalian CNS occurs in the subventricular zone (SVZ) and dentate gyrus. The receptor for ciliary neurotrophic factor (CNTF), CNTFRalpha, is expressed in the adult subventricular zone. Because the in vitro effects of CNTF on neural precursors have been varied, including proliferation and differentiation into neurons or glia, we investigated its role in vivo. Injection of CNTF in the adult C57BL/6 mice forebrain increased the number of cells labeled with ip BrdU in both neurogenic regions. In the dentate gyrus, CNTF also appeared to enhance differentiation of precursors into neurons, i.e., increased the proportion of NeuN+/BrdU+ cells from approximately 14 to approximately 29%, but did not affect differentiation into astrocytes (GFAP+) or oligodendrocytes (CNPase+). In the SVZ, CNTF increased the proportion of GFAP+/BrdU+ cells from approximately 1 to approximately 2%. CNTF enhanced the distance of migration of new neurons into the granule cell layer. Intraventricular injection of neutralizing anti-CNTF antibodies reduced the number of BrdU-labeled cells in the SVZ. These results suggest that endogenous CNTF regulates adult neurogenesis by increasing proliferation of neural stem cells and/or precursors. Alternatively, CNTF could maintain cells longer in the S-phase, resulting in increased BrdU labeling. In the neurogenic region of the SVZ, CNTFRalpha was exclusively present in GFAP-positive process-bearing cells, suggesting that CNTF affects neurogenesis indirectly via neighboring astroglia. Alternatively, these cells may be part of the neural precursor lineage. The restricted expression of CNTF within the nervous system makes it a potential selective drug target for cell replacement strategies.

Marked differences in olfactory sensitivity and apparent speed of forebrain neuroblast migration in three inbred strains of mice.

In the adult forebrain, new neuroblasts constantly migrate from the subventricular zone along the rostral migratory stream to the olfactory bulb, where many become neurons. It is unclear whether this process is different in commonly used mouse strains and whether it is related to olfactory function. Adult male BALB/c, C57BL/6, and 129/S1 (formerly 129SV) mice were tested for olfactory sensitivity plus discrimination, using male mouse urine from the two other strains. BALB/c mice had the greatest olfactory sensitivity, followed by 129/S1, and C57BL/6 mice, by an order of magnitude each. Newly formed cells were pulse-labeled for 3 h with i.p. 5-bromo-2'-deoxyuridine (BrdU) injections and the animals analyzed 24 h later. In 129/S1 mice, a greater proportion of neuroblasts were present closer to the olfactory bulb than in BALB/c mice, followed by C57BL/6 mice. The total number of BrdU-labeled cells did not differ, suggesting differences in migration and not proliferation. The impaired olfactory function in C57BL/6 mice might be caused by the reduced number of neuroblasts that reach the olfactory bulbs. However, olfactory function in BALB/c and 129/S1 mice did not correlate with their putative migration speed, suggesting a more complex nature of cellular processes that contribute to olfactory function. These results caution against comparing studies of olfactory function or neural precursors that use different strains of mice, and question the use of C57BL/6 mice as a "normal" strain or as transgenic background. Perhaps more importantly, the results point to an opportunity to identify genes that regulate olfactory function and neuroblast behavior.

Administration of brain-derived neurotrophic factor suppresses the expression of heat shock protein 27 in rat retinal ganglion cells following axotomy.

Optic nerve transection results in the apoptotic cell death of the majority of retinal ganglion cells by 14 days. The neurotrophin brain-derived neurotrophic factor (BDNF) enhances survival of retinal ganglion cells. In addition, the small heat shock protein Hsp27, with its anti-apoptotic effects, may be important for neuron survival following axotomy or trophic factor withdrawal. We recently reported the induction and expression of Hsp27 in a subset of retinal ganglion cells following axotomy. Here we have examined the effect of BDNF administration on the expression of Hsp27 in axotomized adult rodent retinal ganglion cells. Retinal ganglion cells were pre-labeled with Fluorogold prior to optic nerve transection and concomitant intraocular injection of BDNF or vehicle. Hsp27 immunofluorescence was examined in retinal sections from 4 to 28 days following injury. Consistent with previous survival studies, the number of Fluorogold-labeled retinal ganglion cells declined from 100% at 4 days to approximately 15% by 14 days following axotomy and vehicle injection. In contrast, with BDNF administration, retinal ganglion cell survival was maintained at 100% to 7 days following axotomy. We report that the number of Hsp27-positive injured retinal ganglion cells, as detected by immunohistochemical staining, was decreased by 50% in BDNF-treated retinas, when compared with vehicle-treated controls. This decreased expression of Hsp27 in response to BDNF treatment was seen both at early (4 days) and delayed (14 days) times. BDNF following optic nerve transection significantly reduced the expression of Hsp27 in retinal ganglion cells. These results indicate that BDNF may down-regulate alternate cell survival pathways, including the stress-induced expression of Hsp27, and may help to explain the failure of chronic neurotrophin treatment to maintain long-term retinal ganglion cell survival.

Injury to retinal ganglion cells induces expression of the small heat shock protein Hsp27 in the rat visual system.

Optic nerve transection results in apoptotic cell death of most adult rat retinal ganglion cells that begins at 4 days and leaves few surviving neurons at 14 days post-injury [Berkelaar et al. (1994) J. Neurosci. 14, 4368-4374]. The small heat shock protein Hsp27 has recently been shown to play a role in sensory neuron survival following peripheral nerve axotomy [Lewis et al. (1999) J. Neurosci. 19, 8945-8953]. To investigate the role of Hsp27 in injured CNS sensory neurons, we have studied the induction and cell-specific expression of Hsp27 in rat retinal ganglion cells 1-28 days after optic nerve transection. Immunohistochemical results indicate that Hsp27 is not present at detectable levels in the ganglion cell layer of control (uninjured) or sham-operated control rats. In contrast, Hsp27 is detected in retinal ganglion cells from 4 to 28 days following axotomy. Furthermore, the percentage of surviving retinal ganglion cells that are Hsp27-positive increased over the same time period. Hsp27 is also detected in glial fibrillary acidic protein-positive astrocytes in the optic layer of the superior colliculus from 4 to 28 days after optic nerve transection. These experiments demonstrate that transection of the optic nerve results in the expression of Hsp27 in three distinct regions of the rat visual system: sensory retinal ganglion cells in the eye, glial cells of the optic tract, and astrocytes in the optic layer of the superior colliculus. Hsp27 may be associated with enhanced survival of a subset of retinal ganglion cells, providing evidence of a protective role for Hsp27 in CNS neuronal injury.

Partial unilateral absence of the trapezius muscle in a human cadaver.

We report here the partial unilateral absence of the trapezius muscle found during dissection. The left trapezius was significantly reduced in size when compared to the right trapezius, especially in its inferior third. Moreover, the existing fibers of the left trapezius inferior to the scapula were only one-third to two-thirds as thick as those on the right. The vertebral attachment of the inferior fibers of the left trapezius was also notably higher than that on the right. Morphometric analysis indicated that the surface area of the left trapezius was approximately 50% that of the right trapezius. Fiber orientation along the left and right trapezius muscles was also markedly different. An examination of nerve supply yielded no apparent anomalies, therefore suggesting that the absence of trapezius has a developmental etiology.

Retrograde tracing techniques influence reported death rates of adult rat nigrostriatal neurons.

Injury often causes loss of neuronal markers and prior retrograde labeling can circumvent this problem of identification. We have previously used a time-consuming protocol for labeling all dopaminergic substantia nigra pars compacta neurons in adult rats by injecting the fluorescent tracer DiI into six sites throughout each neostriatum. Here, 2 weeks after injection of DiI into two central locations, only half of these nigrostriatal neurons were labeled. With six sites, more medial and lateral neurons were labeled, and also more in the midportion along the medial-lateral extent of the pars compacta. Less than 0.5% of the contralateral neurons were labeled. Two injections of Fluorogold also labeled fewer neurons, but their morphology was clearer. Two to 4 weeks after injection of the neurotoxin 6-OHDA into the two neostriatal sites, the total number of surviving neurons appeared greater with six sites of DiI than with two. However, within the middle region of the nigra, survival was lower with the six sites. This suggests that neurons that project outside the two central striatal tracer and 6-OHDA injection regions may be spared initially, but that those in the midportion that project to the central region are more vulnerable with the six-site protocol. Some reports suggest that Fluorogold prelabeling increases neuronal death. Here, survival after 6-OHDA or axotomy was similar with DiI or Fluorogold. These results suggest that because of a complex projection pattern of the nigrostriatal neurons, detailed quantification of neuronal survival should rely on extensive labeling. However, for drug screening purposes, faster labeling with Fluorogold using two sites is more suitable and should provide reliable data.

Developmental anatomy of the Drosophila brain: neuroanatomy is gene expression.

On-line databases of anatomical information are being compiled for a number of genetically manipulable organisms, including the fruit fly, Drosophila melanogaster. Based on the success of the molecular databases that preceded them, they face formidable problems in data cataloguing, storage, and retrieval. The prospect for such databases, which is apparent already, is to alter permanently the approach to neuroanatomy in such species. Experience with Drosophila indicates the possibility to arbitrate controversies over and, in some cases, to redefine the borders drawn in the brain by conventional neuroanatomical methods. Two publications in this issue of Journal of Comparative Neurology by Nassif et al. and by Hartenstein et al. highlight one of the first demonstrations of a further opportunity in Drosophila. In some cases, it is already possible to suggest how individual cellular elements--neurons, tracts, and neuropil regions--might be traced from the time when they first express a precocious marker, such as the product of the fasciclin-II gene, through the metamorphic pupal stage, and into the adult. In this way, it becomes possible to identify the structures of the adult brain from the time of their first emergence in the embryo and to follow their transitional positions throughout the course of development. Critical in this process is the neuroanatomical organization of the larval brain, which contains not only the fully functional central nervous system of the larva but also the developing elements of the adult brain, because this holds the key to understanding both the cellular elements that are inherited from the embryo and the elements that are in the process of forming the adult nervous system.