Zic1 promotes the expansion of dorsal neural progenitors in spinal cord by inhibiting neuronal differentiation

The role of Zic1 was investigated by altering its expression status in developing spinal cords. Zic genes encode zinc finger proteins homologous to Drosophila Odd-paired. In vertebrate neural development, they are generally expressed in the dorsal neural tube. Chick Zic1 was initially expressed evenly along the dorsoventral axis and its expression became increasingly restricted dorsally during the course of neurulation. The dorsal expression of Zic1 was regulated by Sonic hedgehog, BMP4, and BMP7, as revealed by their overexpressions in the spinal cord. When Zic1 was misexpressed on the ventral side of the chick spinal cord, neuronal differentiation was inhibited irrespective of the dorsoventral position. In addition, dorsoventral properties were not grossly affected as revealed by molecular markers. Concordantly, when Zic1 was overexpressed in the dorsal spinal cord in transgenic mice, we observed hypercellularity in the dorsal spinal cord. The transgene-expressing cells were increased in comparison to those of truncated mutant Zic1-bearing mice. Conversely, we observed a significant cell number reduction without loss of dorsal properties in the dorsal spinal cords of Zic1-deficient mice. Taken together, these findings suggest that Zic1 controls the expansion of neuronal precursors by inhibiting the progression of neuronal differentiation. Notch-mediated inhibition of neuronal differentiation is likely to act downstream of Zic genes since Notch1 is upregulated in Zic1-overexpressing spinal cords in both the mouse and the chick.     

Fractalkine and minocycline alter neuronal activity in the spinal cord dorsal horn

Fractalkine (FKN) evokes nociceptive behavior in nai ve rats, whereas minocycline attenuates pain acutely after neuronal injury. We show that, in nai ve rats, FKN causes hyperresponsiveness of lumbar wide dynamic range neurons to brush, pressure and pinch applied to the hindpaw. One day after spinal nerve ligation (SNL), minocycline attenuates after-discharge and responses to brush and pressure. In contrast, minocycline does not alter evoked neuronal responses 10 days after SNL or sciatic constriction, but increases spontaneous discharge. We speculate that microglia rapidly alter sensory neuronal activity in nai ve and neuropathic rats acutely, but not chronically, after injury.     

Mimicking the neurotrophic factor profile of embryonic spinal cord controls the differentiation potential of spinal progenitors into neuronal cells

Recent studies have indicated that the choice of lineage of neural progenitor cells is determined, at least in part, by environmental factors, such as neurotrophic factors. Despite extensive studies using exogenous neurotrophic factors, the effect of endogenous neurotrophic factors on the differentiation of progenitor cells remains obscure. Here we show that embryonic spinal cord derived-progenitor cells express both ciliary neurotrophic factor (CNTF) and brain-derived neurotrophic factor (BDNF) mRNA before differentiation. BDNF gene expression significantly decreases with their differentiation into the specific lineage, whereas CNTF gene expression significantly increases. The temporal pattern of neurotrophic factor gene expression in progenitor cells is similar to that of the spinal cord during postnatal development. Approximately 50% of spinal progenitor cells differentiated into astrocytes. To determine the effect of endogenous CNTF on their differentiation, we neutralized endogenous CNTF by administration of its polyclonal antibody. Neutralization of endogenous CNTF inhibited the differentiation of progenitor cells into astrocytes, but did not affect the numbers of neurons or oligodendrocytes. Furthermore, to mimic the profile of neurotrophic factors in the spinal cord during embryonic development, we applied BDNF or neurotrophin (NT)-3 exogenously in combination with the anti-CNTF antibody. The exogenous application of BDNF or NT-3 promoted the differentiation of these cells into neurons or oligodendrocytes, respectively. These findings suggest that endogenous CNTF and exogenous BDNF and NT-3 play roles in the differentiation of embryonic spinal cord derived progenitor cells into astrocytes, neurons and oligodendrocytes, respectively.     

The neuronal differentiation microenvironment is essential for spinal cord injury repair

Spinal cord injury (SCI) often leads to substantial disability due to loss of motor function and sensation below the lesion. Neural stem cells (NSCs) are a promising strategy for SCI repair. However, NSCs rarely differentiate into neurons; they mostly differentiate into astrocytes because of the adverse microenvironment present after SCI. We have shown that myelin-associated inhibitors (MAIs) inhibited neuronal differentiation of NSCs. Given that MAIs activate epidermal growth factor receptor (EGFR) signaling, we used a collagen scaffold-tethered anti-EGFR antibody to attenuate the inhibitory effects of MAIs and create a neuronal differentiation microenvironment for SCI repair. The collagen scaffold modified with anti-EGFR antibody prevented the inhibition of NSC neuronal differentiation by myelin. After transplantation into completely transected SCI animals, the scaffold-linked antibodies induced production of nascent neurons from endogenous and transplanted NSCs, which rebuilt the neuronal relay by forming connections with each other or host neurons to transmit electrophysiological signals and promote functional recovery. Thus, a scaffold-based strategy for rebuilding the neuronal differentiation microenvironment could be useful for SCI repair.     

Ptf1a determines GABAergic over glutamatergic neuronal cell fate in the spinal cord dorsal horn

Mutations in the human and mouse PTF1A/Ptf1a genes result in permanent diabetes mellitus and cerebellar agenesis. We show that Ptf1a is present in precursors to GABAergic neurons in spinal cord dorsal horn as well as the cerebellum. A null mutation in Ptf1a reveals its requirement for the dorsal horn GABAergic neurons. Specifically, Ptf1a is required for the generation of early-born (dI4, E10.5) and late-born (dIL(A), E12.5) dorsal interneuron populations identified by homeodomain factors Lhx1/5 and Pax2. Furthermore, in the absence of Ptf1a, the dI4 dorsal interneurons trans-fate to dI5 (Lmx1b(+)), and the dIL(A) to dIL(B) (Lmx1b(+);Tlx3(+)). This mis-specification of neurons results in a complete loss of inhibitory GABAergic neurons and an increase in the excitatory glutamatergic neurons in the dorsal horn of the spinal cord by E16.5. Thus, Ptf1a function is essential for GABAergic over glutamatergic neuronal cell fates in the developing spinal cord, and provides an important genetic link between inhibitory and excitatory interneuron development.     

Requirement of N-myc protein down-regulation for neuronal differentiation in the spinal cord

Previous work has indicated that N-myc expression occurs widely in the developing central nervous system, but its level changes dynamically with region- and stage-specificities. We show in the present report that in the developing spinal cord of the mouse, N-myc protein expression takes place in the ventricular zone and reaches its maximum at the outermost layer, but is extinct in the intermediate zone, indicating that N-myc protein is not expressed in mature neurons. We examined the effect of forced, persistent N-myc expression in development of the spinal cord in order to understand the functional significance of N-myc down-regulation. We made embryonic stem (ES) cell lines that constitutively expressed N-myc at a high level, then produced mouse embryo chimeras with a high contribution of the ES cells. The majority of the chimeras developed to day 12 with normal gross morphology, but in these chimeras neuronal differentiation in the spinal cord was perturbed at the histological level. Intermediate zones and ventral horns were formed, but the expression of N-CAM and neurofilaments was diminished. Chimeras using β-galactosidase-expressing recipient embryos indicated that inhibition of the neuronal differentiation was a cell-autonomous effect of persistent N-myc expression. These observations indicate that N-myc down-regulation in individual cells is required for full differentiation of neurons.     

Oxytocin prevents neuronal network pain-related changes on spinal cord dorsal horn in vitro

Recently, oxytocin (OT) has been studied as a potential modulator of endogenous analgesia by acting upon pain circuits at the spinal cord and supraspinal levels. Yet the detailed action mechanisms of OT are still undetermined. The present study aimed to evaluate the action of OT in the spinal cord dorsal horn network under nociceptive-like conditions induced by the activation of the N-methyl-d-aspartate (NMDA) receptor and formalin injection, using calcium imaging techniques. Results demonstrate that the spontaneous Ca²⁺-dependent activity of the dorsal horn cells was scarce, and the coactivity of cells was mainly absent. When NMDA was applied, high rates of activity and coactivity occurred in the dorsal horn cells; these rates of high activity mimicked the activity dynamics evoked by a neuropathic pain condition. In addition, although OT treatment increased activity rates, it was also capable of disrupting the conformation of coordinated activity previously consolidated by NMDA treatment, without showing any effect by itself. Altogether, our results suggest that OT globally prevents the formation of coordinated patterns previously generated by nociceptive-like conditions on dorsal horn cells by NMDA application, which supports previous evidence showing that OT represents a potential therapeutic alternative for the treatment of chronic neuropathic pain.     

A dorsal elaboration in the spinal cord

Functionally distinct types of neurons develop in stereotypical positions in the vertebrate spinal cord. The mechanisms that generate this diversity have been well studied in the ventral and intermediate regions of the spinal cord, while dorsal cells have received less attention. In this issue of Neuron, two papers focusing on dorsal interneuron development level the playing field.     

Notch1 control of oligodendrocyte differentiation in the spinal cord

We have selectively inhibited Notch1 signaling in oligodendrocyte precursors (OPCs) using the Cre/loxP system in transgenic mice to investigate the role of Notch1 in oligodendrocyte (OL) development and differentiation. Early development of OPCs appeared normal in the spinal cord. However, at embryonic day 17.5, premature OL differentiation was observed and ectopic immature OLs were present in the gray matter. At birth, OL apoptosis was strongly increased in Notch1 mutant animals. Premature OL differentiation was also observed in the cerebrum, indicating that Notch1 is required for the correct spatial and temporal regulation of OL differentiation in various regions of the central nervous system. These findings establish a widespread function of Notch1 in the late steps of mammalian OPC development in vivo.     

Modulation of dorsal horn neuronal activity by spinal cord stimulation in a rat model of neuropathy: The role of the dorsal funicles

We recorded the spike activity from spinal neurons In rats with a model of neuropathy after ligation of then. ishiadicus. A significantly increased frequency of background discharges and responsiveness to nonnoxious stimuli were observed in dorsal horn wide-dynamic range (convergent) neurons in a group of allodynic rats, as compared with non-allodynic and intact rats. Spinal cord stimulation (SCS) Induced a significant depression of both the principal responses and afterdischarges in allodynic rats. The frequency of background discharges was markedly decreased in approximately one third of the neurons. These effects outlasted SCS by about 10 rain. The moderating effect of SCS is considered a result of activation of distinctly different and complementary mechanisms: segmental and transsupraspinal. The former appears to be the most important in allodynic animals.     

The cholinergic neuronal differentiation factor from heart cell conditioned medium is different from the cholinergic factors in sciatic nerve and spinal cord

Environmental cues play an important role in determining the transmitter phenotype of developing sympathetic neurons. Several factors have been described which can induce cholinergic function in cultured sympathetic neurons. We have compared certain biological and immunological properties of three of them, cholinergic differentiation factor (CDF), membrane-associated neurotransmitter-stimulating factor (MANS), and ciliary neurotrophic factor (CNTF), to determine whether they are different. As previously reported, all three increased acetylcholine synthesis in cultured sympathetic neurons. In addition, MANS as well as CNTF and CDF decreased catecholamine synthesis. CNTF and MANS, but not CDF, promoted the survival of embryonic chick ciliary neurons. Affinity-purified antibodies raised against a synthetic peptide corresponding to the N-terminal sequence of CDF immunoprecipitated CDF, but not MANS or CNTF. These results indicate that although CDF, MANS, and CNTF have similar effects on transmitter synthesis by cultured sympathetic neurons, CDF lacks the ciliary neurotrophic activity of MANS and CNTF. Further, CDF possesses an N-terminal epitope which is absent from both MANS and CNTF. Thus, CDF is distinct from MANS and CNTF, and at least two factors exist which can alter the transmitter phenotype of sympathetic neurons in vitro.     

Ultrastructure of orexin-1 receptor immunoreactivities in the spinal cord dorsal horn

The ultrastructural properties of orexin 1-receptor-like immunoreactive (OX1R-LI) neurons in the dorsal horn of the rat spinal cord were examined using light and electron microscopy techniques. At the light microscopy level, the most heavily immunostained OX1R-LI neurons were found in the ventral horn of the spinal cord, while some immunostained profiles, including nerve fibers and small neurons, were also found in the dorsal horn. At the electron microscopy level, OX1R-LI perikarya were identified containing numerous dense-cored vesicles which were more heavily immunostained than any other organelles. Similar vesicles were also found within the axon terminals of the OX1R-LI neurons. The perikarya and dendrites of some of the OX1R-LI neurons could be seen receiving synapses from immunonegative axon terminals. These synapses were found mostly asymmetric in shape. Occasionally, some OX1R-LI axon terminals were found making synapses on dendrites that were OX1R-LI in some cases and immunonegative in others. The synapses made by OX1R-LI axon terminals were found both asymmetric and symmetric in appearance. The results provide solid morphological evidence that OX1R is transported in the dense-cored vesicles from the perikarya to axon terminals and that OX1R-LI neurons in the dorsal horn of the spinal cord have complex synaptic relationships both with other OX1R-LI neurons as well as other neuron types.     

Notch3 is necessary for neuronal differentiation and maturation in the adult spinal cord

Notch receptors are key regulators of nervous system development and promoters of neural stem cells renewal and proliferation. Defects in the expression of Notch genes result in severe, often lethal developmental abnormalities. Notch3 is generally thought to have a similar proliferative, anti‐differentiation and gliogenic role to Notch1. However, in some cases, Notch3 has an opposite, pro‐differentiation effect. Here, we show that Notch3 segregates from Notch1 and is transiently expressed in adult rat and mouse spinal cord neuron precursors and immature neurons. This suggests that during the differentiation of adult neural progenitor cells, Notch signalling may follow a modified version of the classical lateral inhibition model, involving the segregation of individual Notch receptors. Notch3 knockout mice, otherwise neurologically normal, are characterized by a reduced number of mature inhibitory interneurons and an increased number of highly excitable immature neurons in spinal cord laminae I–II. As a result, these mice have permanently lower nociceptive thresholds, similar to chronic pain. These results suggest that defective neuronal differentiation, for example as a result of reduced Notch3 expression or activation, may underlie human cases of intractable chronic pain, such as fibromyalgia and neuropathic pain.     

The on/off of Pax6 controls the tempo of neuronal differentiation in the developing spinal cord

During neurogenesis, complex networks of genes act sequentially to control neuronal differentiation. In the neural tube, the expression of Pax6, a paired-box-containing gene, just precedes the appearance of the first post-mitotic neurons. So far, its only reported function in the spinal cord is in specifying subsets of neurons. Here we address its possible function in controlling the balance between proliferation and commitment of neural progenitors. We report that increasing Pax6 level is sufficient to push neural progenitors toward cell cycle exit and neuronal commitment via Neurogenin 2 (Ngn2) upregulation. However, neuronal precursors maintaining Pax6(On) fail to perform neuronal differentiation. Conversely, turning off Pax6 function in these precursors is sufficient to provoke premature differentiation and the number of differentiated neurons depends of the amount of Pax6 protein. Moreover, we found that Pax6 expression involves negative feedback regulation by Ngn2 and this repression is critical for the proneural activity of Ngn2. We present a model in which the level of Pax6 activity first conditions the moment when a given progenitor will leave the cell cycle and second, the moment when a selected neuronal precursor will irreversibly differentiate.