Brain-type fatty acid-binding protein (B-FABP) belongs to a family of intracellular lipid-binding proteins. B-FABP exhibits a binding affinity to long-chain fatty acids (FAs) whose effects on brain functions including development, emotion, learning and memory have been proposed. B-FABP is localized in the ventricular germinal cells in embryonic brain and astrocytes in developing and mature brain of rodents. In the present study we generated the mouse harboring a null mutation in the B-FABP gene and studied its phenotype. B-FABP mutant mice exhibited the enhanced anxiety and increased fear memory as well as the decreased content of docosahexaenoic acid (DHA) in their brain during the neonatal period without detection of any histological changes in the brain. In the adult brain, B-FABP was localized more numerously to the astrocytes in the amygdala and septal area than to those in the hippocampal area. Analysis of FA content in the amygdala of adult brain revealed that arachidonic and palmitic acids increased significantly in the mutant mice compared with wild-type. Furthermore, the response of N-methyl-d-aspartate receptor-mediated current to DHA in isolated neurons from B-FABP mutant brain was significantly decreased compared with that of wild-type, while no significant differences were detected in behavioral responses related to the spatial learning/memory or in the hippocampal long-term potentiation. These data indicate that B-FABP is crucially involved in the fear memory and anxiety through its binding with FAs and/or its own direct effects on pertinent metabolism/signaling of FAs.
The striatum is a heterogeneous mosaic of two neurochemically, developmentally, and functionally distinct compartments: the -opioid receptor (MOR)-enriched striosomes and the matrix. Preferential activation of the striosomes and persistent suppression of the matrix have recently been suggested to represent neural correlates of motor stereotypy. However, little is known concerning the physiological properties of the striosomes. We made patch-clamp recordings from medium spiny neurons in identified MOR-immunoreactive "dopamine islands" as striosomes in a slice preparation taken from transgenic mice expressing green fluorescent protein in tyrosine hydroxylase mRNA-containing neurons. Striosomal neurons differed electrophysiologically from cells in the matrix in having significantly less hyperpolarized resting membrane potentials and larger input resistances, suggesting developmental differences between the two types of cells. Moreover, corticostriatal EPSCs were inhibited by MOR activation to similar extents in the two compartments, although inhibition of IPSCs was observed only in the striosomes. This MOR-induced inhibition of IPSCs was presynaptically mediated, because MOR agonist invariably decreased IPSC amplitudes when postsynaptic G-protein was inactivated, significantly increased the paired-pulse ratio of the IPSCs, and decreased the frequency but not the amplitude of miniature IPSCs. These effects of MOR were mediated principally by 4-aminopyridine-sensitive K ϩ conductance via a cAMP-dependent pathway, which was further augmented by previous blockade of the protein kinase C cascade. These findings suggest that MOR activation by endogenous and/or exogenous MOR-selective opioid substances differentially regulates the activities of the striosome and matrix compartments and thus plays an important role in motivated behavior and learning.
Olfactory bulb (OB) interneurons are derived primarily postnatally from progenitors in the anterior subventricular zone (SVZa) and migrate to the OB in the rostral migratory stream (RMS). Progenitors differentiate into phenotypically diverse granule and periglomerular cells by as yet undefined mechanisms. To visualize spatiotemporal aspects of periglomerular dopamine (DA) neuron differentiation, two independently derived transgenic mouse lines were analyzed with a 9-kb tyrosine hydroxylase (TH) promoter to drive either a LacZ or an enhanced green fluorescent protein (EGFP) reporter gene. Both reporters showed similar neonatal expression that varied from low levels in RMS, to moderate in the superficial granule cell layer, to strong in relatively large cells, possibly external tufted cells, in the periglomerular region. TH mRNA and protein were not detected in the RMS but were colocalized with the transgenes in neonatal superficial granule and periglomerular cells. By comparison, TH protein in adults was further limited to periglomerular cells. To demonstrate that transcriptional regulation was the same for EGFP and TH, expression was shown to decline similarly in the OB ipsilateral to odor deprivation produced by adult unilateral naris closure. Of two genes previously hypothesized to regulate OB DA expression, only regulated expression of the orphan receptor Nurr1, but not the homeobox-containing genes Dlx-1 and -2, was consistent with a role in regulation of the DA phenotype. These data demonstrate for the first time that DA phenotypic differentiation in neonates begins with low-level transcription in migrating progenitors in the RMS and culminates with activity-dependent protein expression in periglomerular cells innervated by olfactory receptor cells.
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