Guangnan Li

Wnt Signaling Regulates Neuronal Differentiation of Cortical Intermediate Progenitors

Cortical intermediate progenitors (IPs) comprise a secondary neuronal progenitor pool that arises from radial glia (RG). IPs are essential for generating the correct number of cortical neurons, but the factors that regulate the expansion and differentiation of IPs in the embryonic cortex are essentially unknown. In this study, we show that the Wnt–β-catenin pathway (canonical Wnt pathway) regulates IP differentiation into neurons. Upregulation of Wnt–β-catenin signaling by overexpression of Wnt3a in the neocortex induced early differentiation of IPs into neurons and the accumulation of these newly born neurons at the subventricular zone/intermediate zone border. Long-term overexpression of Wnt3a led to cortical dysplasia associated with the formation of large neuronal heterotopias. Conversely, downregulation of Wnt–β-catenin signaling with Dkk1 during mid and late stages of neurogenesis inhibited neuronal production. Consistent with previous reports, we show that Wnt–β-catenin signaling also promotes RG self-renewal. Thus, our findings show differential effects of the Wnt–β-catenin pathway on distinct groups of cortical neuronal progenitors: RG self-renewal and IP differentiation. Moreover, our findings suggest that dysregulation of Wnt signaling can lead to developmental defects similar to human cortical malformation disorders.

Regional Distribution of Cortical Interneurons and Development of Inhibitory Tone Are Regulated by Cxcl12/Cxcr4 Signaling

Interneurons are born in subcortical germinative zones and tangentially migrate in multiple streams above and below the developing cortex, and then, at the appropriate developmental stage, migrate radially into the cortex. The factors that control the formation of and the timing of exit from the streams remain obscure; moreover, the rationale for this complicated developmental plan is unclear. We show that a chemokine, Cxcl12, is an attractant for interneurons during the stage of stream formation and tangential migration. Furthermore, the timing of exit from the migratory streams accompanies loss of responsiveness to Cxcl12 as an attractant. Mice with mutations in Cxcr4 have disorganized migratory streams and deletion of Cxcr4 after the streams have formed precipitates premature entry into the cortical plate. In addition, constitutive deletion of Cxcr4 specifically in interneurons alters the regional distribution of interneurons within the cortex and leads to interneuron laminar positioning defects in the postnatal cortex. To examine the role of interneuron distribution on the development of cortical circuitry, we generated mice with focal defects in interneuron distribution and studied the density of postnatal inhibitory innervation in areas with too many and too few interneurons. Interestingly, alterations in IPSC frequency and amplitude in areas with excess interneurons tend toward normalization of inhibitory tone, but in areas with reduced interneuron density this system fails. Thus, the processes controlling interneuron sorting, migration, regional distribution, and laminar positioning can have significant consequences for the development of cortical circuitry and may have important implications for a range of neurodevelopmental disorders.

Morphogenesis of the Dentate Gyrus: What We Are Learning from Mouse Mutants

The dentate gyrus is one of two locations with continuing neurogenesis in adult mammals. While the function of adult neurogenesis is unknown, it is believed that it is involved in learning and memory. For adult neurogenesis to occur, the dentate gyrus must maintain the appropriate precursor cell niche in the subgranular zone, which is likely to be dependent on the developmental mechanisms at play in forming the dentate gyrus. In this review, we graft a molecular framework onto the known neuroanatomic developmental plan by considering the phenotypes of several mouse mutants that have well characterized dentate gyrus developmental abnormalities. This effort reveals that there are at least six distinct developmental steps that need to occur in the formation of the dentate gyrus, which can be associated with specific gene defects: (1) defining the dentate neuroepithelium; (2) forming the primary radial glial scaffolding; (3) radial migration of granule neurons to form the primordial granule cell layer; (4) establishing the precursor pool in the hilus; (5) radial transformation of the tertiary matrix, and (6) differentiation of dentate granule cells. From this analysis, it is clear that some molecular pathways control multiple steps in the development of the dentate gyrus. For example the Wnt pathway (steps 1, 2, 4) and the chemokine receptor CXCR4 (steps 3, 4) are involved in multiple developmental steps, while the neuronal differentiation gene NeuroD (step 6) and the integrin signaling pathway (step 5) are involved only in discrete stages of the dentate gyrus morphogenesis.

NMDA receptors inhibit synapse unsilencing during brain development

How the billions of synapses in the adult mammalian brain are precisely specified remains one of the fundamental questions of neuroscience. Although a genetic program is likely to encode the basic neural blueprint, much evidence suggests that experience-driven activity through NMDA receptors wires up neuronal circuits by inducing a process similar to long-term potentiation. To test this notion directly, we eliminated NMDA receptors before and during synaptogenesis in single cells in vitro and in vivo. Although the prevailing model would predict that NMDA receptor deletion should strongly inhibit the maturation of excitatory circuits, we find that genetic ablation of NMDA receptor function profoundly increases the number of functional synapses between neurons. Conversely, reintroduction of NMDA receptors into NR1-deficient neurons reduces the number of functional inputs, a process requiring network activity and NMDA receptor function. Although NMDA receptor deletion increases the strength of unitary connections, it does not alter neuronal morphology, suggesting that basal NMDA receptor activation blocks the recruitment of AMPA receptors to silent synapses. Based on these results we suggest a new model for the maturation of excitatory synapses in which ongoing activation of NMDA receptors prevents premature synaptic maturation by ensuring that only punctuated bursts of activity lead to the induction of a functional synapse for the activity-dependent wiring of neural circuitry.

Stromal-Derived Factor-1 (CXCL12) Regulates Laminar Position of Cajal-Retzius Cells in Normal and Dysplastic Brains

Normal brain development requires a series of highly complex and interrelated steps. This process presents many opportunities for errors to occur, which could result in developmental defects in the brain, clinically referred to as malformations of cortical development. The marginal zone and Cajal-Retzius cells are key players in cortical development and are established early, yet there is little understanding of the factors resulting in the disruption of the marginal zone in many types of cortical malformation syndromes. We showed previously that treatment with methylazoxymethanol in rats causes marginal zone dysplasia with displacement of Cajal-Retzius cells to deeper cortical layers. Here we establish that loss of activity of the chemokine stromal-derived factor-1 (SDF1) (CXCL12), which is expressed by the leptomeninges, is necessary and sufficient to cause marginal zone disorganization in this widely used teratogenic animal model. We also found that mice with mutations in the main receptor for SDF1 (CXCR4) have Cajal-Retzius cells displaced to deeper cortical layers. Furthermore, by inhibiting SDF1 signaling in utero by intraventricular injection of a receptor antagonist, we establish that SDF1 signaling is required for the maintenance of Cajal-Retzius cell position in the marginal zone during normal cortical development. Our data imply that cortical layering is not a static process, but rather requires input from locally produced molecular cues for maintenance, and that complex syndromes of cortical malformation as a result of environmental insults may still be amenable to explanation by interruption of specific molecular signaling pathways.

Identification of a transient subpial neurogenic zone in the developing dentate gyrus and its regulation by Cxcl12 and reelin signaling.

One striking feature of dentate gyrus development, distinct from the other cortical structures, is the relocation of neural precursors from the ventricular zone to the forming dentate pole to produce a lifelong neurogenic subgranular zone (SGZ). In this study, we demonstrate that dentate progenitors first dwell for up to 1 week in a previously unrecognized neurogenic zone intimately associated with the pial meningeal surface lining the outer edge of the forming dentate. This zone also serves as the organizational matrix for the initial formation of the dentate glial scaffolding. Timely clearance of neural precursors from their transient location depends on reelin, whereas initial formation of this transient stem cell niche requires Cxcl12-Cxcr4 signaling. The final settlement of the neural precursors at the subgranular zone relies on a pertussis toxin-sensitive pathway independent of Cxcl12-Cxcr4 signaling. Furthermore, genetic fate-mapping analysis suggests that subpial precursors contribute to the SGZ formation. These results demonstrate that the relocation of neural precursors in the dentate gyrus consists of discrete steps regulated by multiple pathways.

Expression of SDF-1 and CXCR4 during Reorganization of the Postnatal Dentate Gyrus

Previous studies have demonstrated that stromal cell-derived factor 1 (SDF-1) is crucial for early dentate development; however, the mouse mutants for this chemokine and its only receptor, CXCR4, are neonatally lethal, making conclusions about the role of these molecules in postnatal development difficult to sustain. Previous expression analyses have used single labeling, but the distribution of CXCR4 is complex and to determine the cell types expressing CXCR4 requires multiple marker labeling. In this study, we examined the distribution of SDF-1 and CXCR4 mRNAs during the first postnatal weeks, combining these markers with several other cell-type-specific markers. We found that SDF-1 has three sites of expression: (1) continuation of prenatal expression in the meninges; (2) expression in Cajal-Retzius cells occupying the molecular layer of the upper and lower blades of the dentate, and (3) the maturing dentate granule neurons themselves. The timing of expression in these three sites corresponds to alterations in the distribution of the primary cell types expressing CXCR4 during the same periods, notably the expression of CXCR4 in radial-glial-like GFAP-expressing dentate precursors and immature dentate granule neurons. Taken together, our data suggest potential ongoing roles for SDF-1/CXCR4 signaling in the dentate gyrus during the early postnatal period that will be tested in the future with more precise genetic approaches.

Genetic regulation of dentate gyrus morphogenesis

The dentate gyrus is one of the small number of forebrain areas that have continued adult neurogenesis. During development the dentate gyrus acquires the capacity for neurogenesis by generating a new neurogenic stem cell niche at the border between the hilus and dentate granule cell layer. This is in distinction to the other prominent zone of continued neurogenesis in the subventricular zone where neurons are born in a structure directly descended from the mid-gestation subventricular zone. The ability to generate this newly formed dentate neurogenic niche is controlled by the action of a number of genes during prenatal and early postnatal development that regulate the fate, survival, migration, expansion, and differentiation of the cellular components of the dentate neurogenic niche. In this review, we provide an updated framework discussing the molecular steps and genes involved in these early stages of dentate gyrus formation. We previously described a molecular framework for dentate gyrus morphogenesis that can be associated with specific gene defects (Li, G., Pleasure, S.J. (2005). Dev. Neurosci., 27, 93-99), and here we add additional recently described molecular players and discuss this framework.

Ongoing interplay between the neural network and neurogenesis in the adult hippocampus

As a unique form of structural plasticity in the central nervous system, adult neurogenesis in the hippocampus alters network functions by continuously adding new neurons to the mature network, while at the same time is subjected to regulation by surrounding network activity. Here, we review the recently identified mechanisms through which network activity exerts its impacts on multiple steps of adult neurogenesis in rodents and culminates in the selective recruitment of new neurons. We also review recent progress on the study of cellular connectivity modified by new neurons in the dentate gyrus and its physiological functions in rodents. We believe that understanding these processes will allow eventual elucidation of the mechanisms controlling the development of balanced inputs and outputs for the adult-born neurons and reveal important insights into the cellular organization of learning and memory.

Hilar Mossy Cells Share Developmental Influences with Dentate Granule Neurons

Mossy cells are the major class of excitatory neurons in the dentate hilus. Although mossy cells are involved in a range of physiological and pathological conditions, very little is known about their ontogeny. To gain insight into this issue, we first determined the developmental stage at which mossy cells can be reliably identified with the molecular markers calretinin and GluR2/3 and found that hilar mossy cells were first identifiable around the end of the 1st postnatal week. Birthdating studies combined with staining for these markers revealed that the appearance of mossy cells coincided with the first wave of dentate granule cell production during mid-gestation. Since mossy cells are born as the first granule cells are produced and it is believed that mossy cells originate from the neuroepithelium adjacent to the dentate progenitor zone, we examined to what extent the development of mossy cells is controlled by the same molecular pathways as that of granule cells. To do this, we analyzed the production of mossy cells in Lef1 and NeuroD mutant animals, in which granule cell production is disrupted during precursor proliferation or neuronal differentiation, respectively. The production of mossy cells was almost entirely lost in both mutants. Collectively, these data suggests that hilar mossy cells, unlike CA subfield pyramidal cells, are influenced by many of the same developmental cues as dentate granule cells.