Mechanisms of roof plate formation in the vertebrate CNS

The roof plate is an embryonic organizing centre that occupies the dorsal midline of the vertebrate neural tube. During early CNS development, the roof plate produces secreted factors, which control the specification and differentiation of dorsal neuronal cell types. An appreciation of the signalling properties of the roof plate has prompted an enhanced interest in this important organizing centre, and several recent studies have begun to illuminate the molecular mechanisms of roof plate development.     

Intermediate filament proteins in the developing chick spinal cord

The distribution of different intermediate filament (IF) proteins in the embryonic chick spinal cord was examined at several stages of development using immunohistochemical techniques, analytic gel electrophoresis, and electron microscopy. We have found that: (1) the fibroblast-type IF protein (vimentin) is present in virtually all of the replicating neuroepithelial cells of the early neural tube, as well as in radial glia, astrocytes, and Schwann cells in later stages of development; (2) the fibroblast-type IF protein is not detectable in definitive neurons; (3) the neurofilament proteins are first detectable in postmitotic neuroblasts at about the time of initial axon formation and they are restricted to neurons; (4) the astrocyte-type IF protein (glial fibrillary acidic protein) is in definitive astrocytes, but not in radial glia; (5) the prekeratin proteins are restricted to cells of the leptomeninges; and (6) the muscle-type IF protein (desmin) is restricted to vascular tissue in and around the developing spinal cord. These findings suggest that the fibroblast-type IF protein is the only IF protein in the early neuroepithelial cells and that the progeny of these cells will follow one of three different patterns of IF protein expression: (1) continued expression of only the fibroblast-type IF protein (radial glia); (2) expression of both the fibroblast-type IF protein and the astrocyte-type IF protein (astrocytes); or (3) expression of only the neurofilament proteins (neurons).     

VEGF modulates synaptic activity in the developing spinal cord

Although it has been documented that the nervous and the vascular systems share numerous analogies and are closely intermingled during development and pathological processes, interactions between the two systems are still poorly described. In this study, we investigated whether vascular endothelial growth factor (VEGF), which is a key regulator of vascular development, also modulates neuronal developmental processes. We report that VEGF enhances the gamma‐aminobutyric acid (GABA)/glycinergic but not glutamatergic synaptic activity in embryonic spinal motoneurons (MNs), without affecting MNs excitability. In response to VEGF, the frequency of these synaptic events but not their amplitude was increased. Blocking endogenous VEGF led to an opposite effect by decreasing frequency of synaptic events. We found that this effect occurred specifically at early developmental stages (E13.5 and E15.5) and vanished at the prenatal stage E17.5. Furthermore, VEGF was able to increase vesicular inhibitory amino acid transporter density at the MN membrane. Inhibition of single VEGF receptors did not modify electrophysiological parameters indicating receptor combinations or an alternative pathway. Altogether, our findings identify VEGF as a modulator of the neuronal activity during synapse formation and highlight a new ontogenic role for this angiogenic factor in the nervous system. © 2014 Wiley Periodicals, Inc. Develop Neurobiol 74: 1110–1122, 2014     

PiggyBac transgenic strategies in the developing chicken spinal cord

The chicken spinal cord is an excellent model for the study of early neural development in vertebrates. However, the lack of robust, stable and versatile transgenic methods has limited the usefulness of chick embryos for the study of later neurodevelopmental events. Here we describe a new transgenic approach utilizing the PiggyBac (PB) transposon to facilitate analysis of late-stage neural development such as axon targeting and synaptic connection in the chicken embryo. Using PB transgenic approaches we achieved temporal and spatial regulation of transgene expression and performed stable RNA interference (RNAi). With these new capabilities, we mapped axon projection patterns of V2b subset of spinal interneurons and visualized maturation of the neuromuscular junction (NMJ). Furthermore, PB-mediated RNAi in the chick recapitulated the phenotype of loss of agrin function in the mouse NMJ. The simplicity and versatility of PB-mediated transgenic strategies hold great promise for large-scale genetic analysis of neuronal connectivity in the chick.     

Distinct neural precursors in the developing human spinal cord

Both embryonic and adult central nervous system have been shown to contain multipotent neural stem cells, but it is not yet clear whether they consist of a single or distinct populations of neural precursors. Since embryonic human neural precursors, particularly in the spinal cord, have not been extensively characterized, we have studied their behaviour at different days of gestation and in different culture conditions. Depending on dissociation and culture conditions, neurospheres which contain nestin- and vimentin-positive or only vimentin-positive neural precursors can be isolated. Whereas the former can be isolated only at early developmental stages, the latter appear to be present at all the stages examined, between 45 and 89 days of gestation. Furthermore, comparison of the effect of FGF, EGF and the two factors in combination on colony formation shows an additive effect of the two growth factors, indicating the existence of more than one type of neural precursor. Overall our results suggest that the human spinal cord contains distinct and dynamic populations of neural precursors which are developmentally regulated.     

PlexinA1 signaling directs the segregation of proprioceptive sensory axons in the developing spinal cord

As different classes of sensory neurons project into the CNS, their axons segregate and establish distinct trajectories and target zones. One striking instance of axonal segregation is the projection of sensory neurons into the spinal cord, where proprioceptive axons avoid the superficial dorsal horn-the target zone of many cutaneous afferent fibers. PlexinA1 is a proprioceptive sensory axon-specific receptor for sema6C and sema6D, which are expressed in a dynamic pattern in the dorsal horn. The loss of plexinA1 signaling causes the shafts of proprioceptive axons to invade the superficial dorsal horn, disrupting the organization of cutaneous afferents. This disruptive influence appears to involve the intermediary action of oligodendrocytes, which accompany displaced proprioceptive axon shafts into the dorsal horn. Our findings reveal a dedicated program of axonal shaft positioning in the mammalian CNS and establish a role for plexinA1-mediated axonal exclusion in organizing the projection pattern of spinal sensory afferents.     

Calcium imaging of network function in the developing spinal cord

We have used calcium imaging to visualize the spatiotemporal organization of activity generated by in vitro spinal cord preparations of the developing chick embryo and the neonatal mouse. During each episode of spontaneous activity, we found that chick spinal neurons were activated rhythmically and synchronously throughout the transverse extent of the spinal cord. At the onset of a spontaneous episode, optical activity originated in the ventrolateral part of the cord. Back-labeling of spinal interneurons with calcium dyes suggested that this ventrolateral initiation was mediated by activation of a class of interneurons, located dorsomedial to the motor nucleus, that receive direct monosynaptic input from motoneurons. Studies of locomotor-like activity in the anterior lumbar segments of the neonatal mouse cord revealed the existence of a rostrocaudal wave in the oscillatory component of each cycle of rhythmic motoneuron activity. This finding raises the possibility that the activation of mammalian motoneurons during locomotion may share some of the same rostrocaudally organized mechanisms that evolved to control swimming in fishes.     

Triphosphopyridine nucleotide-dependent enzymes in the developing spinal cord of the rabbit

Abstract— Total lipid and the activity of five enzymes closely related to the generation of NADPH have been measured in the anterior horn region and dorsal columns of rabbit spinal cord during the period of rapid myelination. Lipid deposition progressed to a much greater extent in the dorsal columns than in the anterior horn region; however, the age at which one-half of the total adult level of lipid accumulated in both regions was the same, i.e. 19-20 days after birth. During the first 15 days of postnatal development of the dorsal columns, glucose-6-phosphate dehydrogenase changed in parallel with lipid content; however, in the anterior horn region changes in lipid were not accompanied by increases in glucose-6-phosphate dehydrogenase. In contrast to changes in glucose-6-phosphate dehydrogenase, the activity of malic enzyme increased in the anterior horn region but remained relatively constant in the dorsal columns during development. The activities of two other enzymes of the pentose phosphate pathway, 6-phosphogluconate dehydrogenase and transketolase, measured at various intervals after birth, did not directly parallel changes in the activity of glucose-6-phosphate dehydrogenase in the dorsal columns. In both areas of the developing spinal cord the activity of NADP⁺-dependent isocitrate dehydrogenase was greater than the activities of the other three dehydrogenases but it did not parallel changes in lipid content of either region. A relationship between the requirements for reducing equivalents and the activities of the four NADP⁺-dependent dehydrogenases is suggested by the finding that both areas of the adult spinal cord contained lower activities of these enzymes than those observed during the initial 26 days of development. The differences noted in the two areas of the spinal cord during development suggest that mechanisms for the generation of NADPH differ in gray and white matter.     

Region-specific cell clones in the developing spinal cord of the zebrafish

 To analyse the proliferative abilities of cells within particular regions of the zebrafish neural plate, injections of fluorescein-dextran were made into single cells at either medial or intermediary positions in the neural plate region of two-somite stage embryos. The resulting cell clones were analysed in 3.5-day-old embryos. Clones with similar compositions were found among those derived from injections in both regions, and these were grouped into classes. 78 clones 29 obtained following injections in the medial region, and 22 of 59 cell clones derived from injections in the intermediary region, were classifiable into 9 and 10 different classes, respectively, each comprising a variable number of clones. Several identified cell types, as well as each of the clone classes themselves, were specific for the regions of the neural plate from which they derived, i.e. they were not represented among the clones derived from the other region. These results suggest that the composition of the lineages derived from particular cells is constant in different animals. Received: 13 July 1998 / Accepted: 20 October 1998     

Specific and integrated roles of Lmx1a, Lmx1b and Phox2a in ventral midbrain development

The severe disorders associated with a loss or dysfunction of midbrain dopamine neurons (DNs) have intensified research aimed at deciphering developmental programs controlling midbrain development. The homeodomain proteins Lmx1a and Lmx1b are important for the specification of DNs during embryogenesis, but it is unclear to what degree they may mediate redundant or specific functions. Here, we provide evidence showing that DN progenitors in the ventral midbrain can be subdivided into molecularly distinct medial and lateral domains, and these subgroups show different sensitivity to the loss of Lmx1a and Lmx1b. Lmx1a is specifically required for converting non-neuronal floor-plate cells into neuronal DN progenitors, a process that involves the establishment of Notch signaling in ventral midline cells. On the other hand, lateral DN progenitors that do not appear to originate from the floor plate are selectively ablated in Lmx1b mutants. In addition, we also reveal an unanticipated role for Lmx1b in regulating Phox2a expression and the sequential specification of ocular motor neurons (OMNs) and red nucleus neurons (RNNs) from progenitors located lateral to DNs in the midbrain. Our data therefore establish that Lmx1b influences the differentiation of multiple neuronal subtypes in the ventral midbrain, whereas Lmx1a appears to be exclusively devoted to the differentiation of the DN lineage.     

Growth cone guidance by floor plate cells in the spinal cord of zebrafish embryos.

The spinal cord of early zebrafish embryos contains a small number of neuronal classes whose growth cones all follow stereotyped, cell-specific pathways to their targets. Two classes of spinal neurons make cell-specific turns at or near the ventral midline of the spinal cord, which is occupied by a single row of midline floor plate cells. We tested whether these cells guide the growth cones by examining embryos missing the midline floor plate cells due either to laser ablation of the cells or to a mutation (cyc-1). In these embryos the growth cones followed both normal and aberrant pathways once near the ventral midline. This suggests that normally the midline floor plate cells do provide guidance cues, but that these cues are not obligatory.