Víctor Borrell

BDNF regulates spontaneous correlated activity at early developmental stages by increasing synaptogenesis and expression of the K+/Cl- co-transporter KCC2

Spontaneous neural activity is a basic property of the developing brain, which regulates key developmental processes, including migration, neural differentiation and formation and refinement of connections. The mechanisms regulating spontaneous activity are not known. By using transgenic embryos that overexpress BDNF under the control of the nestin promoter, we show here that BDNF controls the emergence and robustness of spontaneous activity in embryonic hippocampal slices. Further, BDNF dramatically increases spontaneous co-active network activity, which is believed to synchronize gene expression and synaptogenesis in vast numbers of neurons. In fact, BDNF raises the spontaneous activity of E18 hippocampal neurons to levels that are typical of postnatal slices. We also show that BDNF overexpression increases the number of synapses at much earlier stages (E18) than those reported previously. Most of these synapses were GABAergic, and GABAergic interneurons showed hypertrophy and a 3-fold increase in GAD expression. Interestingly, whereas BDNF does not alter the expression of GABA and glutamate ionotropic receptors, it does raise the expression of the recently cloned K+/Cl- KCC2 co-transporter, which is responsible for the conversion of GABA responses from depolarizing to inhibitory, through the control of the Cl- potential. Together, results indicate that both the presynaptic and postsynaptic machineries of GABAergic circuits may be essential targets of BDNF actions to control spontaneous activity. The data indicate that BDNF is a potent regulator of spontaneous activity and co-active networks, which is a new level of regulation of neurotrophins. Given that BDNF itself is regulated by neuronal activity, we suggest that BDNF acts as a homeostatic factor controlling the emergence, complexity and networking properties of spontaneous networks.

Chemokine Signaling Controls Intracortical Migration and Final Distribution of GABAergic Interneurons

Functioning of the cerebral cortex requires the coordinated assembly of circuits involving glutamatergic projection neurons and GABAergic interneurons. Although much is known about the migration of interneurons from the subpallium to the cortex, our understanding of the mechanisms controlling their precise integration within the cortex is still limited. Here, we have investigated in detail the behavior of GABAergic interneurons as they first enter the developing cortex by using time-lapse videomicroscopy, slice culture, and in utero experimental manipulations and analysis of mouse mutants. We found that interneurons actively avoid the cortical plate for a period of ∼48 h after reaching the pallium; during this time, interneurons disperse tangentially through the marginal and subventricular zones. Perturbation of CXCL12/CXCR4 signaling causes premature cortical plate invasion by cortical interneurons and, in the long term, disrupts their laminar and regional distribution. These results suggest that regulation of cortical plate invasion by GABAergic interneurons is a key event in cortical development, because it directly influences the coordinated formation of appropriate glutamatergic and GABAergic neuronal assemblies.

Targeted gene delivery to telencephalic inhibitory neurons by directional in utero electroporation

Telencephalic inhibitory neurons originate in the ganglionic eminences and migrate to the cerebral cortex following a tangential trajectory, before they differentiate and integrate within the local circuitry. Current studies of interneuron development and function benefit from the use of knock-out and transgenic mice, whereas none take advantage of the versatility of in utero electroporation. Here, we show how in utero electroporation can be directed to the ganglionic eminences to specifically target gene expression to interneurons. Electroporation of GFP-encoding plasmids into the ganglionic eminences results in selective labeling of migrating interneurons during development. In the adult brain of electroporated animals, a wide variety of cortical, hippocampal and olfactory bulb interneurons are labeled. We also show that GFP-expressing interneurons can be visualized in living slices of adult cerebral cortex, where they display normal electrophysiological properties. Photostimulation studies using acute slices show that cortical GFP+ interneurons receive normal, layer-specific synaptic input, indicating that these neurons integrate within the local cortical circuitry. Ganglionic eminence-directed in utero electroporation is therefore an effective, rapid, and versatile method of selectively transfecting telencephalic interneurons, optimal for both developmental studies and adult functional studies.

Development of commissural connections in the hippocampus of reeler mice: evidence of an inhibitory influence of Cajal-Retzius cells.

Reelin is a large, extracellular matrix protein involved in neuronal migration and axonal growth. To analyze the contribution of Reelin to the development of the commissural projection in the hippocampus, we analyzed the ontogeny of this projection in the reeler mutant mouse. Injections of the lipophilic tracer DiI revealed many commissural fibers in the hippocampus of both reeler and control mice at P1-P2. At P5, at P12, and in the adult, the topography of commissural connections was normal in the CA1 region of reeler mice, with axons innervating the stratum radiatum and stratum oriens. In contrast, in the CA3/CA2 region, commissural fibers abnormally innervated the stratum lacunosum-moleculare and, in the dentate gyrus, some fibers were observed in the outer molecular layer. Next, we monitored the distribution of Cajal-Retzius cells in the hippocampus of reeler mutant mice and noted that the stratum lacunosum-moleculare of the CA3/CA2 region was largely devoid of Cajal-Retzius (CR) cells. Taken together, the above results indicate that in the absence of CR cells in the CA3/CA2, commissural axons abnormally grow to the stratum lacunosum-moleculare. To test this hypothesis a series of coculture experiments was performed in collagen gels, in which the CA3 axonal growth was monitored when confronted to the marginal zone. These experiments showed that the marginal zone containing CR cells exerts short-range inhibitory influences for commissural axonal growth.

Developmental Sculpting of Dendritic Morphology of Layer 4 Neurons in Visual Cortex: Influence of Retinal Input

Dendritic morphology determines the kinds of input a neuron receives, having a profound impact on neural information processing. In the mammalian cerebral cortex, excitatory neurons have been ascribed to one of two main dendritic morphologies, either pyramidal or stellate, which differ mainly on the extent of the apical dendrite. Developmental mechanisms regulating the emergence and refinement of dendritic morphologies have been studied for cortical pyramidal neurons, but little is known for spiny stellate neurons. Using biolistics to label single cells on acute brain slices of the ferret primary visual cortex, we show that neurons in layer 4 develop in a two-step process: initially, all neurons appear pyramidal, growing a prominent apical dendrite and few small basal dendrites. Later, a majority of these neurons show a change in the relative extent of basal and apical dendrites that results in a gradual sculpting into a stellate morphology. We also find that ∼22% of neurons maintain the proportionality of their dendritic arbors, remaining as pyramidal cells at maturity. When ferrets were deprived of retinal input at early stages of postnatal development by binocular enucleation, a significant proportion of layer 4 spiny neurons failed to remodel their apical dendrites, and ∼55% remained as pyramidal neurons. Our results demonstrate that cortical spiny stellate neurons emerge by differential sculpting of the dendritic arborizations of an initial pyramidal morphology and that sensory input plays a fundamental role in this process.

Reelin and mDab1 regulate the development of hippocampal connections

We analyze in this study the participation of Reelin and mDab1 in the development of hippocampal connections. We show that mDab1 is present in growth cones and axonal tracts of developing hippocampal afferents. mdab1-deficiency produces severe alterations in the entorhino-hippocampal and commissural connections identical to those described in reeler mice, including innervation of ectopic areas, formation of abnormal patches of fiber termination and a delay in the refinement of projections. Organotypic slice cultures combining tissue from mdab1-mutant and control mice demonstrate that the abnormalities observed in the mutant entorhino-hippocampal projection are caused by mdab1-deficiency in both the projecting neurons and target hippocampal cells. Axonal afferents that innervate the hippocampus react to Reelin by reducing axonal growth, and increasing growth cone collapse and axonal branching. Altogether these results indicate that Reelin and mDab1 participate in the development and refinement of hippocampal connections by regulating axonal extension, targeting and branching.

Involvement of Cajal–Retzius cells in robust and layer-specific regeneration of the entorhino-hippocampal pathways

Severed adult CNS axons can extend over long distances when a permissive ‘milieu’, such as grafted Schwann cells or ensheathing cells, is provided. Moreover, functional blocking of endogenous inhibitory factors, such as Nogo‐A or proteoglycans, enhances the regeneration of axotomized neurons. Here we examine whether guidance cues available during the development of axonal pathways could also potentiate the regeneration of lesioned adult circuits. The Cajal–Retzius cells in the hippocampus are transient pioneer neurons that guide entorhino‐hippocampal afferents to their target layers. By using an in vitro model of axotomy of the entorhino‐hippocampal pathway we show that Cajal–Retzius cells triggered the regeneration of the axotomized entorhino‐hippocampal pathway. Furthermore, the regrowth induced by Cajal–Retzius cells was robust and its pattern was indistinguishable from that of the unlesioned entorhino‐hippocampal pathway. Thus, regenerating axons regrew in a layer‐specific fashion towards the appropriate target layers, making synaptic contacts with target pyramidal neurons. Interestingly, the ability of lesioned entorhinal axons to regrow was maintained for at least 9 days after axotomy. These results show that the growth‐promoting cells controlling the development of neural circuits will be a relevant approach to promoting the regeneration of lesioned adult CNS pathways.