Sox1-deficient mice suffer from epilepsy associated with abnormal ventral forebrain development and olfactory cortex hyperexcitability

Mutations in several classes of embryonically-expressed transcription factor genes are associated with behavioral disorders and epilepsies. However, there is little known about how such genetic and neurodevelopmental defects lead to brain dysfunction. Here we present the characterization of an epilepsy syndrome caused by the absence of the transcription factor SOX1 in mice. In vivo electroencephalographic recordings from SOX1 mutants established a correlation between behavioral changes and cortical output that was consistent with a seizure origin in the limbic forebrain. In vitro intracellular recordings from three major forebrain regions, neocortex, hippocampus and olfactory (piriform) cortex (OC) showed that only the OC exhibits abnormal enhanced synaptic excitability and spontaneous epileptiform discharges. Furthermore, the hyperexcitability of the OC neurons was present in mutants prior to the onset of seizures but was completely absent from both the hippocampus and neocortex of the same animals. The local inhibitory GABAergic neurotransmission remained normal in the OC of SOX1-deficient brains, but there was a severe developmental deficit of OC postsynaptic target neurons, mainly GABAergic projection neurons within the olfactory tubercle and the nucleus accumbens shell. Our data show that SOX1 is essential for ventral telencephalic development and suggest that the neurodevelopmental defect disrupts local neuronal circuits leading to epilepsy in the SOX1-deficient mice.

Roles of the mammalian subventricular zone in brain development

There has been enormous progress in uncovering the contributions of the subventricular zone (SVZ) to the developing brain. Here, we review the roles of four anatomically defined embryologic divisions of the SVZ of the mammalian brain: the lateral ganglionic eminence (LGE), the medial ganglionic eminence (MGE), the caudal ganglionic eminence (CGE), and the fetal neocortical SVZ (SVZn), as well as the roles of the two major anatomically defined regions of the postnatal SVZ, the anterior SVZ (SVZa) and the dorsolateral SVZ (SVZdl). We describe the types of cells within each subdivision of the SVZ, the types of brain cells that they generate during embryonic, fetal, and perinatal development, and when known the mechanisms that regulate their differentiation. This review provides a critical analysis of the literature, from which current and future studies on the SVZ can be formulated and evaluated.

Brain development, song learning and mate choice in birds: a review and experimental test of the "nutritional stress hypothesis"

The nutritional stress hypothesis explains how learned features of song, such as complexity and local dialect structure, can serve as indicators of male quality of interest to females in mate choice. The link between song and quality comes about because the brain structures underlying song learning largely develop during the first few months post-hatching. During this same period, songbirds are likely to be subject to nutritional and other stresses. Only individuals faring well in the face of stress are able to invest the resources in brain development necessary to optimize song learning. Learned features of song thus become reliable indicators of male quality, with reliability maintained by the developmental costs of song. We review the background and assumptions of the nutritional stress hypothesis, and present new experimental data demonstrating an effect of nestling nutrition on nestling growth, brain development, and song learning, providing support for a key prediction of the hypothesis.

Loss of the tailless gene affects forebrain development and emotional behavior

We are studying the role of the evolutionarily conserved tlx gene in forebrain development in mice. Tlx is expressed in the ventricular zone that gives rise to neurons and glia of the forebrain. We have shown by mutating the tlx gene in mice, that in the absence of this transcription factor, mutant animals survive, but suffer specific anatomical defects in the limbic system. Because of these developmentally induced structural changes, mice with a mutation in the tlx gene can function, but exhibit extreme behavioral pathology. Mice show heightened aggressiveness, excitability, and poor cognition. In this article, we present a summary of our findings on the cellular and behavioral changes in the forebrain of mutant animals. We show that absence of the tlx gene leads to abnormal proliferation and differentiation of progenitor cells (PCs) in the forebrain from embryonic day 9 (E9). These abnormalities lead to hypoplasia of superficial cortical layers and subsets of GABAergic interneurons in the neocortex. We examined the behavior of mutant animals in three tests for anxiety/fear: the open field, the elevated plus maze, and fear conditioning. Mutant animals are less anxious and less fearful when assessed in the elevated plus and open-field paradigm. In addition, mutant animals do not condition to either the tone or the context in the fear-conditioning paradigm. These animals, therefore, provide a genetic tool to delineate structure/function relationships in defined regions of the brain and decipher how their disruption leads to behavioral abnormalities.

Cloning and characterization of GRIPE, a novel interacting partner of the transcription factor E12 in developing mouse forebrain

The helix-loop-helix (HLH) family of transcription factors are key contributors to a wide array of developmental processes, including neurogenesis and hematopoiesis. These factors are thought to exert their regulatory influences by binding to cognate promoter-DNA sequences as dimers. Although studies in mice have convincingly demonstrated that neurogenic HLH proteins such as NeuroD are intimately involved in neuronal fate determination, the role of the ubiquitously expressed HLH protein, E12, in mammalian neurogenesis remains ambiguous. To address this, a yeast two-hybrid interaction screen was employed to identify dimerization partners to E12. Screening of an embryonic day 11.5 forebrain library resulted in the cloning of GRIPE, a novel GAP-related interacting protein to E12. GRIPE binds to the HLH region of E12 and may require E12 for nuclear import. Furthermore, GRIPE may negatively regulate E12-dependent target gene transcription. High levels of GRIPE and E12 mRNA were coincidentally detected during embryogenesis, but only GRIPE mRNA levels remained high in adult brain, particularly in neurons of the cortex and hippocampus. These observations were recapitulated through an in vitro model of neurogenesis. Taken together, these results indicate that GRIPE is a novel protein dimerization of which with E12 has important consequences for cells undergoing neuronal differentiation.

Wired for reproduction: organization and development of sexually dimorphic circuits in the mammalian forebrain

Mammalian reproduction depends on the coordinated expression of behavior with precisely timed physiological events that are fundamentally different in males and females. An improved understanding of the neuroanatomical relationships between sexually dimorphic parts of the forebrain has contributed to a significant paradigm shift in how functional neural systems are approached experimentally. This review focuses on the organization of interconnected limbic-hypothalamic pathways that participate in the neural control of reproduction and summarizes what is known about the developmental neurobiology of these pathways. Sex steroid hormones such as estrogen and testosterone have much in common with neurotrophins and regulate cell death, neuronal migration, neurogenesis, and neurotransmitter plasticity. In addition, these hormones direct formation of sexually dimorphic circuits by influencing axonal guidance and synaptogenesis. The signaling events underlying the developmental activities of sex steroids involve interactions between nuclear hormone receptors and other transcriptional regulators, as well as interactions at multiple levels with neurotrophin and neurotransmitter signal transduction pathways.

Expression pattern of the homeobox protein NKX2-1 in the developing Xenopus forebrain

Although morphological data suggest that the amphibian forebrain contains similar subdivisions to those observed in birds and mammals, it is presently unclear whether the same patterning mechanisms are conserved among all three classes of tetrapods. Here we report that NKX2-1, a transcription factor that is essential for the ventral patterning of the forebrain in birds and mammals, is expressed in corresponding (homologous) domains in the developing Xenopus forebrain. NKX2-1 expression is restricted to two domains in the amphibian forebrain: (1) a ventral diencephalic domain, with expression limited to hypothalamic structures; and (2) a telencephalic domain, with expression in the medial ganglionic eminence, preoptic area and part of the septum. Thus, the detailed analysis of the distribution of NKX2-1 provides the first unequivocal evidence for distinct progenitor zones within the amphibian forebrain through embryonic and larval development.

Reelin, Disabled 1, and beta 1 integrins are required for the formation of the radial glial scaffold in the hippocampus

The extracellular matrix molecule Reelin is required for the correct positioning of neurons during the development of the forebrain. However, the mechanism of Reelin action on neuronal migration is poorly understood. Reelin is assumed to act on neurons directly, but it may also affect the differentiation of glial cells necessary for neuronal migration. Here we show that a regular glial scaffold fails to form in vivo in the dentate gyrus of mice deficient of Reelin or Disabled 1, a neuronal adaptor protein in the Reelin signaling pathway. A subset of these defects is observed in mice that lack beta(1)-class integrins, known to bind Reelin. Moreover, recombinant Reelin induced branching of glial processes in vitro. Our data suggest that Reelin affects glial differentiation via Disabled 1 and beta(1)-class integrin-dependent signaling pathways.

BrdU-, neuroD (nrd)- and Hu-studies reveal unusual non-ventricular neurogenesis in the postembryonic zebrafish forebrain

In the postembryonic zebrafish forebrain, subpial locations of neurogenesis do exist in the early cerebellar external granular layer, and--unusually among vertebrates--in the primordial pretectal (M1) and preglomerular (M2) Anlagen as shown here with 5-bromo-2'-deoxyuridine (BrdU)/Hu-immunocytochemistry and in situ hybridization of neuroD. An intermediate BrdU incubation time of 12-16 h reveals in addition to proliferative ventricularly located cells those in M1 and M2. This BrdU saturation-labeling shows--in conjunction with a Hu-assay demonstrating earliest neuronal differentiation--that proliferating cells in M1 and M2 represent neuronal progenitors. This is demonstrated by single BrdU-labeled and double BrdU-/Hu-labeled cells in these aggregates. Further, expression of NeuroD--a marker for freshly determined neuronal cells--confirms this unusual subpial postembryonic forebrain neurogenesis.

The terminal nerve in turbot, Psetta maxima:

The ontogeny and organization of the terminal nerve (TN) during turbot development was studied using an antiserum to neuropeptide Y. First immunoreactive cells were detected in the olfactory placode at hatching time. At 1 day after hatching, a loose group of labeled neurons form an extracranial primordial ganglion of the TN. During the subsequent larval development, more perikarya displaying increased immunoreactivity were found along the course of the olfactory nerve. Moreover, labeled cells cross the meninx of the forebrain gathering in the olfactory bulb of larval turbot. Projections from these cells, directed both to the caudal brain and to the retina, develop when the cells become established in the olfactory bulb. The generation of immunoreactive cells in the olfactory organ extends into the metamorphic period, when a pronounced asymmetry affects the turbot morphology. At this time, the topological location of the immunoreactive cells in the TN becomes distorted. This developmental pattern was compared with those found in other teleosts and in other vertebrates. Preabsorption experiments of anti-neuropeptide Y serum with neuropeptide Y and FMRF-amide suggests that immunoreactive material observed in TN cells was not neuropeptide Y, and raises the possibility that other peptides, e.g. FMRF-amide-like peptides, exist in this neural system.

Role of adrenoceptor subtypes in memory consolidation

Noradrenaline release in areas within the forebrain occurs following activation of noradrenergic cells in the locus coeruleus (LoC). Release of noradrenaline by attentional/arousal/vigilance factors appears to be essential for learning and is responsible for the consolidation of memory. Noradrenaline can activate any of nine different adrenoceptor (AR) subtypes in the brain and selectivity of action may be achieved by the spatial location and relative density of the AR subtypes, by different affinities of the different subtypes and by temporal selectivity in terms of when the different ARs are activated in the memory formation process. This review examines the use of selective agonists and antagonists to determine the roles of the AR subtypes in the one-trial discriminated avoidance learning paradigm in the chick. A model is developed that integrates noradrenergic activity in basal ganglia (lobus parolfactorius (LPO)) and association cortex (intermediate medial hyperstriatum ventrale (IMHV)) leading to the consolidation of memory 30 min after training. There is evidence that beta(2)- and beta(3)-ARs are important in the association area but require input from alpha(2)-AR stimulated activity in the basal ganglia for consolidation. On the other hand, alpha(1)-AR activation in the IMHV is inhibitory and prevents consolidation. While there is no role for beta(1)-ARs in memory consolidation, they play a role in short-term memory (STM). The use of the precocial chick has clear advantages in having a temporally discrete learning task which allows for discrimination memory and whose development can be followed at discrete intervals after learning. These studies reveal clear roles for AR subtypes in the formation and consolidation of memory in the chick, which have allowed the development of a model that can now be tested in mammalian systems.

Presence of Ras guanyl nucleotide-releasing protein in striosomes of the mature and developing rat

Ras signal transduction pathways have been implicated as key regulators in neuroplasticity and synaptic transmission in the brain. These pathways can be modulated by Ras guanyl nucleotide exchange factors, (GEF) which activate Ras proteins by catalysing the exchange of GDP for GTP. Ras guanyl nucleotide-releasing protein (RasGRP), a recently discovered Ras GEF, that links diacylglycerol and probably calcium to Ras signaling pathways, is expressed in brain as well as in T-cells. Here, we have used a highly selective monoclonal antibody against RasGRP to localize this protein within the striatum and related forebrain structures of developing and adult rats. RasGRP immunolabeling was found to be widespread in the mature and developing rat forebrain. Most notably, it presented a prominent patchy distribution throughout the striatum at birth and at all postnatal ages examined. These patches were found to correspond with the striosomal compartment of the striatum, as identified by micro-opioid receptor labeling in the adult. RasGRP-immunoreactivity was also observed in the matrix-like compartment surrounding these patches/striosomes but appeared later in development and was always weaker than in the patches. In both striatal compartments, RasGRP was exclusively expressed by medium-sized spiny neurons and showed no preference for neurons that project either directly or indirectly to the substantia nigra. At the ultrastructural level, immunogold labeling of RasGRP was confined to the cell bodies and dendritic shafts of these output neurons. We conclude that the prominent expression of RasGRP in striosomes may be of significance for diacylglycerol signaling in the striatum, and could be of importance for the processing of limbic-related activity within the basal ganglia.

What songbirds teach us about learning

Bird fanciers have known for centuries that songbirds learn their songs. This learning has striking parallels to speech acquisition: like humans, birds must hear the sounds of adults during a sensitive period, and must hear their own voice while learning to vocalize. With the discovery and investigation of discrete brain structures required for singing, songbirds are now providing insights into neural mechanisms of learning. Aided by a wealth of behavioural observations and species diversity, studies in songbirds are addressing such basic issues in neuroscience as perceptual and sensorimotor learning, developmental regulation of plasticity, and the control and function of adult neurogenesis.

Ontogeny of gamma-aminobutyric acid-immunoreactive neuronal populations in the forebrain and midbrain of the sea lamprey

Although brain organization in lampreys is of great interest for understanding evolution in vertebrates, knowledge of early development is very scarce. Here, the development of the forebrain and midbrain gamma-aminobutyric acid (GABA)-ergic systems was studied in embryos, prolarvae, and small larvae of the sea lamprey using an anti-GABA antibody. Ancillary immunochemical markers, such as proliferating cell nuclear antigen (PCNA), calretinin, and serotonin, as well as general staining methods and semithin sections were used to characterize the territories containing GABA-immunoreactive (GABAir) neurons. Differentiation of GABAir neurons in the diencephalon begins in late embryos, whereas differentiation in the telencephalon and midbrain was delayed to posthatching stages. In lamprey prolarvae, the GABAir populations appear either as compact GABAir cell groups or as neurons interspersed among GABA-negative cells. In the telencephalon of prolarvae, a band of cerebrospinal fluid-contacting (CSF-c) GABAir neurons (septum) was separated from the major GABAir telencephalic band, the striatum (ganglionic eminence) primordium. The striatal primordium appears to give rise to most GABAir neurons observed in the olfactory bulb and striatum of early larval stages. GABAir populations in the dorsal telencephalon appear later, in 15-30-mm-long larvae. In the diencephalon, GABAir neurons appear in embryos, and the larval pattern of GABAir populations is recognizable in prolarvae. A small GABAir cluster consisting mainly of CSF-c neurons was observed in the caudal preoptic area, and a wide band of scattered CSF-c GABAir neurons extended from the preoptic region to the caudal infundibular recess. A mammillary GABAir population was also distinguished. Two compact GABAir clusters, one consisting of CSF-c neurons, were observed in the rostral (ventral) thalamus. In the caudal (dorsal) thalamus, a long band extended throughout the ventral tier. The nucleus of the medial longitudinal fascicle contained an early-appearing GABAir population. The paracommissural pretectum of prolarvae and larvae contained a large group of non-CSF-c GABAir neurons, although it was less compact than those of the thalamus, and a further group was found in the dorsal pretectum. In the midbrain of larvae, several groups of GABAir neurons were observed in the dorsal and ventral tegmentum and in the torus semicircularis. The development of GABAergic populations in the lamprey forebrain was similar to that observed in teleosts and in mouse, suggesting that GABA is a very useful marker for understanding evolution of forebrain regions. The possible relation between early GABAergic cell groups and the regions of the prosomeric map of the lamprey forebrain (Pombal and Puelles [ 1999] J. Comp. Neurol. 414:391-422) is discussed in view of these results and information obtained with ancillary markers.

A2B5+ and O4+ Cycling progenitors in the adult forebrain white matter respond differentially to PDGF-AA, FGF-2, and IGF-1

Cycling glial progenitors reside within subcortical white matter of the mammalian adult forebrain. Either A2B5 or O4 expression defines two of the major classes of cycling progenitors. We examined the growth factor receptor profiles of these progenitor populations and their capability to proliferate and differentiate in response to PDGF-AA, FGF-2, and IGF-1. FGF-2 and IGF-1 enhance the acquisition of O1 by the O4+ progenitors, but have no significant effect on the acquisition of O4 and/or O1 by the A2B5+ progenitors. In contrast, PDGF-AA enhances the acquisition of O1 by the A2B5+ progenitors, while having no significant affect on the acquisition of O1 by the O4+ progenitors unless combined with FGF-2. In addition, PDGF-AA and FGF-2 promote the proliferation of A2B5+ progenitors, while having no mitogenic effect on the O4+ progenitors unless the two factors are combined with IGF-1. Interestingly, not all of the progenitors within the A2B5 or O4 populations express the same growth factor receptors nor respond similarly to growth factors. Thus, there are substantial differences between the two populations and heterogeneity within each of these populations may exist.

Developmental and hormonal regulation of NR2A mRNA in forebrain regions controlling avian vocal learning

Developmental changes in the composition of NMDA receptors can alter receptor physiology as well as intracellular signal transduction cascades, potentially shifting thresholds for neural and behavioral plasticity. During song learning in zebra finches, NMDAR currents become faster, and transcripts for the modulatory NR2B subunit of this receptor decrease in lMAN, a region in which NMDAR activation is critical for vocal learning. Using in situ hybridization, we found that NR2A transcripts change reciprocally, increasing significantly in both lMAN (59%) and in another song region, Area X (38%), between posthatch day (PHD) 20 and 40, but not changing further at PHD60 or 80. In adjacent areas not associated with song learning, NR2A mRNA did not change between PHD20-80. Although early song deprivation (which extends the sensitive period for song learning) delays changes in NR2B gene expression and NMDAR physiology within the lMAN, it did not alter NR2A mRNA levels measured at PHD40, 45, or 60. Early testosterone (T) treatment, which disrupts vocal development and accelerates the maturation of both NR2B levels and NMDAR physiology in lMAN, also significantly increased NR2A transcripts measured at PHD35 in lMAN. In Area X, a similar effect of T approached significance. Together with our previous studies, these results show that in a pathway critical for vocal plasticity, the ratio of NR2A:NR2B mRNA rises abruptly early during the sensitive period for song learning. Furthermore, androgen regulation of NMDAR gene expression may alter thresholds for experience-dependent synaptic change.

Postnatal development of zinc-rich terminal fields in the brain of the rat

The appearance and distribution of zinc-rich terminal fields in the rat forebrain was analyzed at 12 stages of postnatal development using the selenium method. Zinc stain was detected in neonates in piriform, cingulate, and motor cortices, septal area, and hippocampal formation. In the neocortex, a laminar pattern appeared progressively following an inside-out gradient: layer VI at postnatal day 0 (P0), layer V at P1, layers Va and Vb at P5, layer II-III at P9, and layer IV at P12. In the hippocampal formation the layered pattern in the dentate molecular layer appeared at P1-P3, and in the hilus and mossy fibers the stain was observed at P5. Patches in the caudate-putamen were sharply delimited at P1-P3. At these ages, staining was observed in the amygdaloid complex. In the thalamic and hypothalamic nuclei, stain appeared at P5-P7. Thus, a general increase in vesicular zinc over different telencephalic areas was determined until P15-P21, which was followed by a slight decrease thereafter (at P41). The increased stain in zinc-rich terminal fields is consistent with the development of telencephalic circuits. The rise in zinc might be relevant for the establishment and maturation of these circuits. On the other hand, the decrease in staining for zinc at later stages might be due to methodological problems but it might also reflect pruning of supernumerary connections and programmed cell death affecting zinc-rich circuits.

The teleostean forebrain: a comparative and developmental view based on early proliferation, Pax6 activity and catecholaminergic organization

An improved comparative interpretation of the teleostean forebrain suggests that the dorsal tier (Vd,Vc) and ventral tier (Vv,Vl) nuclei of the ventral telencephalic area (subpallium) represent the striatum and septum, respectively. Among other arguments, a dopaminergic innervation originating in the diencephalic posterior tubercle reaches Vd and dense efferents of Vv project to the midline hypothalamus in the adult zebrafish subpallium. The adult area dorsalis telencephali represents the teleostean pallium. Regulatory genes typically expressed in the early amniote subpallium (e.g., Dlx-1) are also restricted to the presumptive zebrafish ventral telencephalic area. Further, early Pax6 protein distribution in the zebrafish telencephalon corresponds to the migrating stream noted at the pallial-subpallial boundary in amniotes, but a ventricular, radial glia-based expression in the pallium is absent. The peripherally migrated, adult diencephalic preglomerular complex of the basal plate posterior tubercle (early: M2) provides sensory inputs to the pallium. Early Pax6 protein distribution indicates that at least part of M2 may directly originate from alar plate ventral thalamic Pax6-expressing cells. Dopaminergic cells of the basal plate posterior zebrafish forebrain (P1-P3) are restricted to the ventral thalamic prosomere (P3), including those forming the adult ascending dopaminergic system. Moreover, the latter likely depend developmentally on the dorsally adjacent alar plate Pax6-expressing cells.

Sleep-waking states develop independently in the isolated forebrain and brain stem following early postnatal midbrain transection in cats

We report the effects of permanently separating the immature forebrain from the brain stem upon sleeping and waking development. Kittens ranging from postnatal 9 to 27 days of age sustained a mesencephalic transection and were maintained for up to 135 days. Prior to postnatal day 40, the electroencephalogram of the isolated forebrain and behavioral sleep-wakefulness of the decerebrate animal showed the immature patterns of normal young kittens. Thereafter, the isolated forebrain showed alternating sleep-wakefulness electrocortical rhythms similar to the corresponding normal patterns of intact, mature cats. Olfactory stimuli generally changed forebrain sleeping into waking activity, and in cats with the section behind the third nerve nuclei, normal correlates of eye movements-pupillary activity with electrocortical rhythms were present. Behind the transection, decerebrate animals showed wakefulness, and after 20 days of age displayed typical behavioral episodes of rapid eye movements sleep and, during these periods, the pontine recordings showed ponto-geniculo-occipital waves, which are markers for this sleep stage, together with muscle atonia and rapid lateral eye movements. Typically, but with remarkable exceptions suggesting humoral interactions, the sleep-waking patterns of the isolated forebrain were dissociated from those of the decerebrate animal. These results were very similar to our previous findings in midbrain-transected adult cats. However, subtle differences suggested greater functional plasticity in the developing versus the adult isolated forebrain. We conclude that behavioral and electroencephalographic patterns of non-rapid eye movement sleep and of rapid eye movement sleep states mature independently in the forebrain and the brain stem, respectively, after these structures are separated early postnatally. In terms of waking, the findings strengthen our concept that in higher mammals the rostral brain can independently support wakefulness/arousal and, hypothetically, perhaps even awareness. Therefore, these basic sleeping-waking functions are intrinsic properties of the forebrain/brain stem and as such can develop autochthonously. These data help our understanding of some normal/borderline sleep-waking dissociations as well as peculiar states of consciousness in long term patients with brain stem lesions.

Expression of R-cadherin and N-cadherin by cell groups and fiber tracts in the developing mouse forebrain: relation to the formation of functional circuits

The expression of R-cadherin and N-cadherin was mapped in the postnatal forebrain of the mouse by immunohistochemistry and in situ hybridization. Results show that the two molecules are expressed in specific and restricted patterns in numerous brain nuclei, gray matter areas and cortical layers that are widely distributed throughout the mouse forebrain at postnatal day 1. The expression pattern of R-cadherin is clearly distinct from that of N-cadherin, but overlap is observed in many areas. In many cortical areas, the two cadherins have a laminar-specific distribution that varies from region to region. In addition, immunohistochemical data revealed expression of R-cadherin protein and N-cadherin protein in the neuropil of many brain regions as well as in the axons that travel in fiber tracts such as the olfactory tract, the anterior commissure, the corpus callosum, the stria terminalis and the fornix. Often, subsets of axons within the same fiber tract differentially express R-cadherin and N-cadherin, with partial overlap of expression. The targets of the cadherin-immunoreactive fiber bundles often contain neuropil as well as cell bodies of neurons that also express the same type(s) of cadherin, suggesting that R-cadherin and N-cadherin may be involved in target recognition and the establishment of connections. Specifically, the expression of R-cadherin and N-cadherin is related to the maturation of thalamocortical sensory pathways, corticofugal pathways, and pathways associated with the hippocampal complex, the piriform cortex, and the amygdala. It is also related to the development of the cell groups associated with these pathways.Together, the results from the present study indicate the possibility that the selective adhesion of neural structures that express the same type(s) of cadherin contributes to the formation of gray matter areas, neural circuits and functional connections in the postnatal forebrain of the mouse.

Developmental sex differences in glutamic acid decarboxylase (GAD(65)) and the housekeeping gene, GAPDH

Previous work has demonstrated that the GABAergic system is involved in sexual differentiation of the rodent hypothalamus. The present study was designed to further examine this involvement by investigating developmental sex differences in GAD(65) protein levels in hypothalamic and extrahypothalamic brain regions known to be sexually dimorphic in adulthood. Brain nuclei were micro-dissected and GAD(65) protein levels were quantified using western immunoblotting. Sex differences in levels of GAD(65) were found in the dorsomedial nucleus and preoptic area of the hypothalamus and also the medial amygdaloid nucleus and CA1 subfield of the hippocampus. Unexpectedly, there were sex differences in protein levels of the housekeeping gene, GAPDH, cautioning against the use of GAPDH for standardizing protein samples during western immunoblotting.

Evidence for target preferences by cholinergic axons originating from different subdivisions of the basal forebrain

Possible target preferences of basal forebrain cholinergic neurons were studied in organotypic slice cultures. Cholinergic neurons in slices of medial septum or substantia innominata send axons into both hippocampus and neocortex when co-cultured together. However, septal cholinergic axons course through adjacent slices of neocortex to reach and branch densely in slices of hippocampus, but septal axons seldom grow beyond adjacent hippocampal tissue to reach neocortex. In contrast, cholinergic axons from substantia innominata commonly grow through hippocampus to reach neocortex, and also grow through neocortex to reach hippocampus, with similar branching densities in each target. The greater density of septal axonal branches in hippocampus than in neocortex suggests a preference of septal axons for the hippocampal target.