Fates of the earliest generated cells in the developing murine neocortex

In mammalian species studied to date, the first-born neocortical cells normally form two layers, one above and one below the cortical plate, called the marginal zone (future layer 1) and the subplate. In primates and carnivores, many of these first-born cells die early in postnatal life. Whether this also occurs in rodents is highly controversial. In this study, we injected pregnant mice with bromodeoxyuridine on embryonic days (E) 11–14 to label the earliest generated neocortical cells, and examined their fates between birth and postnatal day 21. At birth, most cells born on embryonic day 11 were below the cortical plate, and a smaller proportion were above it. Very few of these cells remained by postnatal day 3 and there were none at any depth in the neocortex at older ages. At birth, the largest proportion of cells born on embryonic days 12 and 13 were in the subplate and smaller proportions were in the cortical plate and marginal zone. At older ages, almost all of these cells had disappeared from the marginal zone and from below the cortical plate, although some were retained in the cortical plate. The density of the remaining E12- and E13-born cells decreased more than could be explained by neocortical expansion alone. As a control, we studied cells born on embryonic day 14. These cells were restricted to the cortical plate at birth. By postnatal day 21, their density had decreased by an amount that could be explained by neocortical expansion alone. We conclude that, as in other species, many of the earliest generated cells of the murine neocortex die. J. Comp. Neurol. 377:414–422, 1997. © 1997 Wiley-Liss, Inc.     

Migration of transplanted neural progenitor cells in a ferret model of cortical dysplasia

Although altered gene expression clearly causes failure of the neocortex to form properly, many causes of neocortical dysplasia arise from environmental or unknown factors. Our lab studies a model of cortical dysplasia induced by injection of methylazoxymethanol (MAM) into pregnant ferrets on embryonic day 33 (E33), which shares many features of neocortical dysplasia in humans. E33 MAM treatment results in characteristic deficits that include dramatic reduction of layer 4 in somatosensory cortex, widespread termination of thalamic afferents, and altered distribution of GABAergic elements. We determined the ability of immature cells to migrate into MAM-treated cortex using ferret neural progenitor cells obtained at E27 and E33 and mouse neural progenitor cells obtained at E14. When these cells were transplanted into organotypic cultures obtained from normal and E33 MAM-treated ferret cortex prepared on postnatal day 0 (P0), all progenitor cells migrated similarly in both hosts, preferentially residing in the upper cortical plate. The site of transplantation was significant, however, so that injections into the ventricular zone were more likely to reach the cortical plate than transplants into the intermediate zone. When similar cells were transplanted into ferret kits, approximately P7-P9, and allowed to survive for 2-4 weeks, the donor cells migrated differently and also reached distinct destinations in normal and MAM-treated hosts. MAM-treated cortex was more permissive to invasion by donor cells as they migrated to widespread aspects of the cortex, whereas transplants in normal host cortex were more restricted. E27 neural progenitor cells populated more cortical layers than later born E33 neural progenitor cells, suggesting that the fate of transplanted cells is governed by a combination of extrinsic and intrinsic factors.     

Time of origin of corresponding cell classes in the cerebral cortex of normal and reeler mutant mice: An autoradiographic analysis

Reeler, a recessive mutation in mice, causes cytoarchitectonic abnormalities of the cerebral and cerebellar cortices. Although the relative positions of classes of cells in the cerebral cortex are markedly abnormal, the time of origin of cells in each class appears to be normal by autoradiographic criteria. In the retrohippocampal cortical structures and in the adjacent neocortex, the earliest generated cell class, the polymorphic, arises at the same embryonic time in normal and reeler littermates. Whereas these cells come to form the deepest stratum of the normal cortex, they lie in an immediately subpial position in the mutant, there being no cell-sparse external plexiform (molecular) layer. A population of larger cells is generated next; these normally come to lie in more superficial layers but instead lie deep to the polymorphic cells in the mutant. Granule cells of the neocortex arise last, simultaneously in normal and reeler; they form the most superficial neocortical cell stratum in the normal, but lie at a more restricted level within the large cell zone in the mutant. These data indicate that the cytoarchitectonic anomaly in reeler is independent of the spatiotemporal program of cell generation. It appears likely that the reeler genetic locus governs embryonic events, as yet undefined, that direct the postmitotic migrating young neuron to class-specific levels within the cortex.     

A radialization factor in normal cortical plate restores disorganized radial glia and disrupted migration in a model of cortical dysplasia

Treatment of pregnant ferrets on embryonic day 24 (E24) with the antimitotic methylazoxy methanol (MAM) leads to a specific constellation of effects in newborn kits, which include a very thin and poorly laminated neocortex, disruption of radial glial cell morphology with early differentiation into astrocytes, and abnormal positioning of Cajal-Retzius cells. We suggest that MAM treatment on E24 results in this model of cortical dysplasia by eliminating a population of cells that produce a factor capable of maintaining radial glia in their normal morphology. The abnormal radial glia, either alone or in combination with other abnormal features, are likely to prevent proper migration into the cortical plate. To test the possibility that normal cortex can provide the missing substance that influences radial glia, slices of E24 MAM-treated cortex were removed at postnatal day 0 (P0) and cultured adjacent to explants of P0 normal cortical plate. By labelling a small number of cells with injections of fluorescent dextrans into the cultured slices, we found that abnormal radial glia in MAM treated slices cocultured adjacent to normal cortical plate were restored toward normal, in comparison to E24 MAM treated slices cultured alone and in other control conditions. We also found that abnormally positioned Cajal-Retzius cells move into the marginal zone and that neurons are able to migrate into the cortical plate more effectively in the coculture condition. These data indicate that normal cortical plate of ferrets contains a factor causing radial glia to maintain their elongated morphology; the improved position of radial glia encourages repositioning of Cajal-Retzius cells and improved neuronal migration into the cortical plate.     

Laminar specific alterations of thalamocortical projections in organotypic cultures following layer 4 disruption in ferret somatosensory cortex

The developing neocortex influences the growth of thalamocortical projections. Layer 4 in particular receives the majority of input from the thalamus and is important in instructing thalamic afferents to terminate. Previous in vivo experiments demonstrated that disruption of layer 4 during corticogenesis in ferret somatosensory cortex by application of methylazoxy methanol acetate (MAM) prevents proper termination of thalamic afferents in appropriate cortical regions. To further explore the role of layer 4 in thalamocortical development, we prepared organotypic cocultures consisting of normal gestational day 0 (P0) ferret thalamus paired with normal, embryonic day 33 (E33), or E38 MAM-treated cortex obtained from ferrets at either P0 or P7. Injection of MAM on E33 disrupts layer 4 formation, whereas similar injections on E38 interfere with layer 2 formation. The cocultures grew together for a number of days, then discrete injections of either fluorescent dextrans or 1,1'-dioctadecyl-3,3,3',3'-tetramethyl-indocarbocyanine perchlorate (DiI) were made into the thalamic piece. The labeled thalamic afferents that grew into the cortical slice were analysed and the sites of their terminations quantified after 3, 5, or 7-10 days in culture (DIC). Our results varied somewhat with the amount of time in culture, but the preponderance of thalamic fibers in normal cortex terminated in layer 4, whereas their counterparts in E33 MAM-treated cortex grew beyond the cortical plate and many fibers terminated inappropriately within lower cortical layers or white matter. Terminal distribution of thalamic fibers in E38 MAM-treated cortex looked similar to normal. These results demonstrate that the cells of layer 4 provide thalamic afferents with important positional and termination cues.     

Neuronal migration disturbance and consequent cytoarchitecture in the cerebral cortex following transplacental administration of methylmercury

To understand the effects of methylmercury (MeHg) on neuronal migration in the developing cerebral cortex, we performed double administrations of MeHg and 5-bromo-2-deoxyuridine (BrdU) to pregnant rats on different embryonic days (E11, E13, E16 or E21). Histopathological examination of a proportion of the offspring on postnatal day 28 revealed no apparent cytoarchitectural abnormalities in the primary motor and primary somatosensory cortices of the cerebrum. Morphometric analysis revealed no significant differences in total neuron population in either of these areas, and no differences in subpopulations of cells in any of the cortical layers, between any of the MeHg-exposed groups and the control animals. However, BrdU immunohistochemistry revealed an abnormally widespread distribution of the labeled cells throughout cortical layers II-VI of offspring exposed to MeHg on E16 and E21, indicating disruption of the inside-out pattern of neuronal migration. We examined one aspect of cell-fate determination by applying immunohistochemistry with antibodies against calbindin, parvalbumin, calretinin, and gamma-aminobutyric acid, but found no differences in the topographic distributions of the antibody-labeled cells in the cortex between the controls and the MeHg-exposed offspring. These results suggest that it is the extrinsic circumstances - rather than the timing of neuron generation - that regulates the expression of these proteins.     

Localization and characterization of NPY/PYY receptors in rat frontoparietal cortex during development.

Neuropeptide Y (NPY) is present in most cerebrocortical areas during fetal and postnatal development. In the rat frontal cortex, a dense radial fiber network containing NPY immunoreactivity is observed transiently as early as embryonic day 17 (E17) and disappears at the end of the first postnatal week. We have investigated the distribution of NPY receptors in the frontoparietal cortex at 13 stages of development, from E15 fetuses to adults, by in vitro autoradiography, using (125)I-pPYY as a radioligand. Quantitative receptor density was measured through all cortical layers at each developmental stage. Pharmacological identification of (125)I-pPPY binding sites was made by competition experiments using pNPY or [Leu(31),Pro(34)]pNPY and pNPY(13-36), as selective competitors for Y1 and Y2 receptors, respectively. NPY receptors were first detected in the cerebral cortex at low densities at E19 in a thin layer of tissue corresponding to the inner half of the intermediate zone (IZ) and the upper ventricular zone (VZ). The neuroepithelium did not contain binding sites. High densities of sites were observed by E21 onward to P10 in the deep cortical layers corresponding to the IZ and layers V-VI. A decreasing gradient of receptor density was observed from layer VI to the marginal zone (layer I). The distribution of NPY receptors does not match with the perikarya of transient NPY-immunoreactive neurons located in the cortical plate but does coincide with their axonal extension. The receptor density decreased abruptly between P10 and P12 in deep layers, whereas a moderate expression of binding sites is detected from P10 to P12 in layers I-III. By P14, the binding level was the lowest observed in the postnatal period. From P21 onward, receptors were observed in superficial layers I-III, and their density rose by two- to threefold up to adulthood. Competition studies indicated that the NPY receptors located in the deep cortical layers of the E21 or P1 rat cortex exhibit Y2 receptor type characteristics. The binding sites detected in the superficial layers from P10 to P12 rats also show Y2 receptors characteristics, unlike the NPY receptors in layers II-III of the adult, which behave like Y1 receptors. These data show that different NPY receptor types are successively expressed in specific layers during late gestation and early postnatal life in the rat frontoparietal cortex.     

Autoradiographic study of beta 1-adrenergic receptor development in the mouse forebrain

The development of beta 1-adrenergic receptors has been studied in the mouse forebrain from embryonic day 14 (E14) to adulthood, using autoradiographic visualization of [125I]iodocyanopindolol (ICYP) binding sites. From E14, ICYP binding sites are detected in moderate amounts in the striatum and basal forebrain and in very low concentration in the cortical plate. At E17, binding sites have increased in number in the deep layers of the embryonic cortex and extend over the whole thickness of the cortical ribbon at birth. On postnatal day 4 (P4), ICYP binding sites are more abundant in the superficial than in the inner cortex. By P10 the adult pattern of ICYP binding site distribution is achieved, namely: a high concentration in ventral pallidum, striatum and cortical layers I, II and III, a moderate concentration in layers V and VI and a lower density in septal areas and in cortical layer IV. It is well established that norepinephrine fibers arrive in the embryonic cortex early in development. The present results show that the development of norepinephrine fiber and beta 1 receptor systems are coincident in the mouse.     

Topographic distribution of efferent fibers originating from homotopic or heterotopic transplants: heterotopically transplanted neurons retain some of the developmental characteristics corresponding to their site of origin

The present study was undertaken to determine whether the topographical distribution of cortical efferents is exclusively dependent on environmental cues or is also controlled by intrinsic factors. For that purpose, we used a sensitive tract tracing method (Phaseolus vulgaris leucoagglutinin) to compare the pattern of efferent fibers of homotopic and heterotopic transplants of embryonic (E16) neocortex. Our findings indicate that transplants of embryonic sensorimotor cortex placed homotopically in the sensorimotor cortex of newborn rats distribute a set of efferent projections not fundamentally different from that of normal sensorimotor cortex. The pattern of efferents arising from transplants of embryonic occipital cortex heterotopically placed in the sensorimotor cortex of newborns is strikingly different. Heterotopically transplanted neurons: (i) only rarely contact normal targets of the motor cortex; (ii) systematically project towards normal targets of the visual cortex (primary and secondary visual cortical areas, dorsal and ventral lateral geniculate nuclei, lateral dorsal and lateral posterior thalamic nuclei, anterior pretectal nucleus and superficial and intermediate layers of the superior colliculus); (iii) distribute fibers to structures normally receiving fibers from both motor and visual cortices (caudate-putamen, pontine nuclei), either exclusively into the visual cortico-recipient zone of the structure or into both visual and motor cortico-recipient zones. Taken together, these results seem to indicate that the heterotopically transplanted cells have retained certain anatomical characteristics of their locus of origin.     

Histogenesis of the cerebral cortex in rat fetuses with a mutation in the Pax-6 gene

The embryonic development of the cerebral cortex was histologically examined in rat homozygotes with a mutation of the Paired box (Pax)-6 gene, rat Small eye (rSey(2)/rSey(2)). Although the cerebral wall was thinner in rSey(2)/rSey(2) than in the wild type at embryonic day 16 (E16), cortical cells of mutants labeled with 5'-bromodeoxyuridine (BrdU) at E13 migrated as normal, settling in superficial layer at E16. Mitotic activity in the ventricular zone, estimated by immunoreactivity for proliferating cell nuclear antigen (PCNA), was also retained. On the other hand, after E20 cells were clustered in abnormally expanded ventricular and intermediate zones of the rSey(2)/rSey(2) cortex. Birthdating studies using BrdU revealed that most of these clustered cells were generated between E18 and E20. Most of clustered cells were immunoreactive for PCNA and highly polysialylated NCAM, while immunoreaction for neurofilament and microtubule-associated protein-2 (MAP-2) was hardly detected in the clusters. Furthermore, apoptosis detected with terminal deoxynucleotidyl transferase (TdT)-mediated dUTP-biotin nick end labeling (TUNEL) was rarely seen, suggesting that the clustered cells remain in an undifferentiating state, but not degenerated by the end of the gestational period. Considering that Pax-6 immunoreactivity was exclusively localized in the ventricular zone of the normal rat cortex throughout the fetal period, the present results suggest that Pax-6 is crucial for differentiation and migration of late-generated cortical neurons.     

An hypothesis on the early evolution of the development of the isocortex

We propose an hypothesis on the evolutionary origin of the unique inside-out developmental gradient of the isocortex, in which deep layers originate before superficial layers. This contrasts with the development of the reptilian cortex, which originates in an outside-in gradient. In mice, a mutated protein, reelin, produces the reeler phenotype, whose cortex has an outside-in neurogenetic gradient like in reptiles. Reelin is normally located in the marginal layer of the developing cerebral cortex, and its normal function has been proposed to be a stop signal that prevents radially migrating cells from moving into the marginal zone. Additionally, mutations on the kinase Cdk5, or in its neuronal-specific activator p35, produce a deficit similar to reeler in that the neurogenetic gradient is outside-in. However, contrary to reeler, in which no cell-sparse layer I is observed, in these mice, a well-defined layer I exists, which suggests that migrating cells respond normally to reelin. Apparently, Cdk5/p35 participate in permitting cortical cells to move across pre-existing (earlier produced) cortical layers, in order to be able to contact reelin once they reach the marginal zone. We suggest that the evolutionary advent of the mammalian cortical inside-out gradient became partly possible through the activation of the Cdk5/p35 pathway, which permitted migrating cells to move across layers of older cells. At about the same time, reelin became an important element in cortical development as it prevented neuronal migration into the marginal zone (cortical layer I) and facilitated the migration of neurons past postmigratory elements.     

Times of generation of glutamic acid decarboxylase immunoreactive neurons in mouse somatosensory cortex

The birth dates of neurons showing glutamic acid decarboxylase (GAD) immunoreactivity have been determined in mouse somatosensory cortex. Pregnant C57Bl mice received pulse injections of (3H)thymidine from E10 through E17 (E0 being the day of mating). The distributions of thymidine-labeled, GAD-positive and nonimmunoreactive (non-GAD) cells as a function of depth under the pial surface were recorded in adult animals. The maximum rate of generation of GAD-positive neurons occurred at E14, whereas the generation of non-GAD neurons reached its maximum rate at E13. Except for those in layer I, GAD-positive neurons followed an inside-out sequence of positioning. GAD-positive neurons born at E12 and E13 were located in layers VI-IV. GAD-positive neurons born at E14 were found throughout the cortical thickness, with a maximum in layer IV. The GAD-positive neurons labeled after pulses at E15 or E16 or E17 were limited to the superficial strata, forming a band that became narrower as it moved toward the pial surface with increase in age of pulse labeling. GAD-positive neurons in layer I were generated at a constant rate during the whole embryonic period analyzed. Non-GAD neurons also followed an inside-out spatiotemporal gradient. Two partially overlapping phases were distinguished in non-GAD neurogenesis. During the first phase (from E12 to E14) neurons populating adult layers VI and V originated, while neurons located in layers IV through I were generated during the second phase (from E13 to E17). Since GAD-immunoreactive neurons form a heterogeneous population, we envisage further studies in order to test whether differences exist in birth dates among the classes.     

Stage of specification of the spinal cord and tectal projections from cortical grafts

In order to determine the embryonic age at which the hodological phenotype developed by neocortical cells is specified, we have examined the spinal or tectal projections developed by embryonic (E) grafts of presumptive frontal or occipital neocortex placed into the frontal or occipital neocortex of newborn host rats. Grafts of E13, E14 and E16 cells of the frontal cortex transplanted into the occipital cortex of newborns are capable of developing and maintaining in adulthood a spinal cord axon. Grafts of E12 cells do not project to the spinal cord but send fibres to the superficial layers of the tectum. In addition, following transplantation into the frontal cortex, early embryonic (E12) cells from the presumptive occipital cortex are capable of differentiating into neurons with spinal cord projection but are practically incapable of developing a tectal projection. When grafted at E14 into the frontal cortex, occipital cells lose the capacity to project to the spinal cord but become able to send fibres to the tectum. Taken together, these findings indicate that young (E12) embryonic frontal and occipital cortical cells are competent to subsequently differentiate into neurons projecting to the spinal cord or tectum according to instructive signals available in the cortical territory where they complete their development. By E13/E14, some cortical cells are specified and their capacity to contact targets that are not appropriate to their embryonic origin is much reduced. These findings are consistent with the notion that cortical specification involves progressive restriction in cell multipotentiality and fate specification toward region-specific phenotypes.     

Direct and indirect effects on the lateral geniculate nucleus neurons of prenatal exposure to methylazoxymethanol acetate

In this study the morphology of the lateral geniculate nucleus and occipital cortex in rats with methylazoxymethanol acetate (MAM Ac)-induced micrencephaly was examined. The aim was to examine the relative contributions of (a) the direct cytotoxic action of the drug on precursors of dorsal lateral geniculate nucleus (dLGN) neurons in the fetal brain and, (b) the postnatal degeneration of the dLGN following prenatal destruction of target neurons in the occipital cortex, to the final extent of damage to the dLGN. Exposure to MAM Ac on E13 produced severe necrosis in the fetal thalamus and caused a 77% deficit in neuronal numbers in the mature dLGN. Exposure to MAM Ac on E15 did not cause necrosis in the fetal thalamus but when animals exposed at this time were examined at 5 weeks postnatal age there was an 87% deficit in neuronal numbers in the dLGN. The hypothesis that this deficit was the result of postnatal death of the dLGN neurons following the destruction by MAM Ac of their normal target population in laminae iii and iv of the occipital cortex was supported by the observation of severe postnatal degeneration in the dLGN of animals exposed to MAM Ac on E15. The significance of these direct and indirect effects of the cytotoxic teratogen, MAM Ac, for understanding the mechanisms by which brain abnormalities in human micrencephaly are produced is discussed.     

Transcranial electrical stimulation of cortico-cortical connections in anesthetized mice

We developed a technique of transcranial electrical stimulation (TES) to investigate cortico-cortical connections in mice. After the skull was shaved with the blade of a dental bar, a blunt tip of a needle was gently pushed onto the thinned skull. The skull was deformed by the force, and the subarachnoid space between the skull and the cortex was minimized around the needle tip. Under these conditions, stimulus currents applied to the needle directly flowed into the cortex through the thinned skull. Cortico-cortical functional connections stimulated by this method were visualized by transcranial flavoprotein fluorescence imaging. The cortical responses evoked by TES exhibited spatial and temporal activity patterns comparable to those elicited by a conventional method, in which an electrode is directly inserted into superficial cortical layers. A comparison of the two methods revealed that TES required a slightly stronger stimulus intensity and preferentially activated superficial layers of the cortex compared with the conventional method. Using the new method, we revealed the presence of reciprocal cortico-cortical functional connections between lateral and medial parts of higher visual cortices in mice. This new method combined with transcranial flavoprotein fluorescence imaging allowed us to activate cortico-cortical pathways arising from the primary sensory areas and investigate sensory information flow in the mouse cerebral cortex.     

Methylazoxymethanol acetate (MAM ac) effects on the ontogenesis of the mouse neocortex

Methylazoxymethanol acetate (MAM ac) injected prenatally affects development of neocortex in mice. Treatment at 13 days of gestation results in cortical hypoplasia that affects all the cortical layers except the first. Treatment at 15 days of gestation causes a statistically significant reduction in cell density in the superficial layers, while the deepest layers show no significant differences compared to the controls. Treatment at 17 days of gestation causes an alterated arrangement of the cortical layers, not easily separable since MAM ac in limiting perhaps glial cell proliferation, modifies the subsequent migration mechanisms. Fetal MAM exposure prevents proliferation of the various cortical laminae and there aren't subsequent compensatory phenomena.     

Vascularity and cytochrome oxidase distribution in the occipital cortex in MAM Ac-induced micrencephaly

The laminar distributions of cytochrome oxidase activity and vascularization of the occipital cortex of animals made micrencephalic by exposure to MAM Ac on E14 or E16 were examined and compared to control animals. Despite severe disruptions of the normal cytoarchitecture in MAM Ac exposed animals, the laminar distributions of vascular profiles, branch points and cytochrome oxidase activity in micrencephalic animals were similar to those in control animals.     

Telencephalic cytoarchitectonics in the brains of rats with graded degrees of micrencephaly

Summary Graded degrees of micrencephaly were produced in the progeny of rats given 0, 14, 22, or 30 mg methylazoxymethanol acetate (MAM Ac) per Kg b.wt. on gestation day (GD) 15. Brains of animals from five litters were examined at each dose level. Golgi-Cox-stained sections prepared from brains of progeny of rats given 25 mg MAM Ac/kg on GD 15 were also evaluated for four micrencephalic and four control animals. Each increase in dosage of MAM Ac resulted in significantly greater loss in brain weight in the progeny. The largest effect was on the telencephalon. In the low dose group the telencephalon, though noticeably smaller, was structurally normal. The two higher doses resulted in easily visualized neuropathologic lesions in both the cerebral cortex and hippocampus. The external layers of the cerebral cortex were most severely affected. Layers V and VI were much better preserved but measurements on pyramidal cells in layer VI in the Golgi-Cox-stained sections showed them to have significantly fewer dendrites and spines than the normal animals. In addition to an intrinsic disorganization of the neocortex, periventricular nodular heterotopias and hippocampal ectopias were common. All the structural anomalies were most severe at the highest dose, though they were also readily apparent at the intermediate dose. The findings suggest to us that MAM Ac treatment during gestation not only produces an acute lesion resulting in the destruction of many proliferating neuroblasts, but that many of the surviving neuroblasts may sustain a chronic lesion altering their subsequent development.     

Murine neocortical histogenesis is perturbed by prenatal exposure to low doses of Bisphenol A

Bisphenol A (BPA) has been shown to disrupt thyroid hormone function. We therefore studied whether prenatal exposure to low-doses of BPA affects the morphology and the expression of some genes related to brain development in the murine fetal neocortex. Pregnant mice were injected subcutaneously with 20 microg/kg of BPA daily from embryonic day 0 (E0). Control animals received vehicle alone. For evaluating cell proliferation, neuronal differentiation and migration, bromodeoxyuridine (BrdU) was injected intraperitoneally into pregnant mice with various regimens and the brains were processed for immunohistochemistry. The total RNA was extracted from the embryonic telencephalon at various embryonic stages. The BrdU-labeled cells examined 1 hour after BrdU injection showed no differences between the BPA-treated and control groups (n = 10, each), which indicated that the proliferation of precursor cells was not affected. The BrdU-labeled cells, analysed 2 days after BrdU injection, were decreased in the ventricular zone of BPA-treated mice at E14.5 and E16.5, whereas they were increased in the cortical plate at E14.5 as compared with those in control mice (n = 10, each). Furthermore, the expression of Math3, Ngn2, Hes1, LICAM, and THRalpha was significantly upregulated at E14.5 in the BPA-treated group. These results suggested that BPA might disrupt normal neocortical development by accelerating neuronal differentiation/migration.