Nobuyuki Kuramoto

Molecular mechanisms associated with long-term consolidation of the NMDA signals.

The N-methyl-D-aspartate (NMDA) subtype of glutamate receptors in the mammalian brain plays a central role in synaptic plasticity underlying refinement of neuronal connections during development, or processes like long-term potentiation (LTP), learning and memory. On the other hand, over-activation of glutamate receptors leading to neurodegeneration has been implicated in major areas of brain pathology. Any sustained effect of a transient NMDA receptor activation is likely to involve signaling to the nucleus and coordinated changes in gene expression. Classically, a set of immediate-early genes is induced first; some of them are themselves transcription factors that control expression of other target genes. This review deals with the induction of Fos, Jun and Egr (Krox) transcription factors in response to NMDA or non-NMDA (AMPA/kainate) ionotropic receptor agonists in vivo or in neuronal cultures in vitro. In addition, the mechanism of induction of a model immediate-early gene c-fos in response to Ca2+ influx through activated NMDA receptors or voltage-sensitive calcium channels is discussed. Both modes of calcium entry induce c-fos via activation of multiple signaling pathways that converge on constitutive transcription factors cAMP-response element-binding protein (CREB), serum response factor (SRF) and a ternary complex factor (TCF), such as Elk-1. In contrast to the traditional view of the NMDA receptor as a ligand-gated calcium channel, whose activation leads to calcium influx and activation of Ca2+/calmodulin-dependent kinases, recent evidence highlights involvement of the Ras/ mitogen-activated protein kinase (MAPK) pathway in the NMDA signaling to the nucleus.

Chronic vitamin D3 treatment protects against neurotoxicity by glutamate in association with upregulation of vitamin D receptor mRNA expression in cultured rat cortical neurons

The vitamin D receptor (VDR) is believed to mediate different biologic actions of vitamin D3, an active metabolite of vitamin D, through regulation of gene expression after binding to specific DNA‐response element (VDRE) on target genes. To further understand roles of both vitamin D3 and VDR in the central nervous system, we examined VDRE binding in nuclear extracts prepared from discrete rat brain regions and cultured rat cortical neurons by electrophoretic mobility shift assay. The highest activity of VDRE binding was found in the cerebellum among other brain regions examined, but sequence specific by taking into consideration the efficient competition with excess unlabeled VDRE but not with mutated VDRE. On in situ hybridization analysis, cells stained for VDR mRNA were abundant in neuron‐enriched areas of cerebral cortex, hippocampus and cerebellar cortex in the mouse brain. Chronic treatment of vitamin D3 increased the expression of microtubule‐associated protein‐2, growth‐associated protein‐43 and synapsin‐1 in cultured rat cortical neurons, suggesting a trophic role of vitamin D3 in differentiation and maturation of neurons. Neuronal cell death by brief glutamate exposure was significantly protected in cultured cortical neurons chronically treated with vitamin D3. Parallel studies showed that VDR mRNA was significantly upregulated 12–24 hr after brief glutamate exposure in cultured neurons chronically treated with vitamin D3, but not in those with vehicle alone. Our results suggest that vitamin D3 may play a role in mechanisms relevant to protective properties against the neurotoxicity of glutamate through upregulation of VDR expression in cultured rat cortical neurons.

Consolidation of transient ionotropic glutamate signals through nuclear transcription factors in the brain.

Long-lasting alterations of neuronal functions could involve mechanisms associated with consolidation of transient extracellular signals through modulation of de novo synthesis of particular functional proteins in the brain. In eukaryotes, protein de novo synthesis is mainly under the control at the level of gene transcription by transcription factors in the cell nucleus. Transcription factors are nuclear proteins with an ability to recognize particular core nucleotides at the upstream and/or downstream of target genes, and thereby to modulate the activity of RNA polymerase II that is responsible for the formation of mRNA from double stranded DNA. Gel retardation electrophoresis is widely employed for conventional detection of DNA binding activities of a variety of transcription factors with different protein motifs. Extracellular ionotropic glutamate (Glu) signals lead to rapid and selective potentiation of DNA binding of the nuclear transcription factor activator protein-1 (AP1) that is a homo- and heterodimeric complex between Jun and Fos family members, in addition to inducing expression of the corresponding proteins, in a manner unique to each Glu signal in murine hippocampus. Therefore, extracellular Glu signals may be differentially transduced into the nucleus to express AP1 with different assemblies between Jun and Fos family members, and thereby to modulate de novo synthesis of the individual target proteins at the level of gene transcription in the hippocampus. Such mechanisms may be operative on synaptic plasticity as well as delayed neuronal death through consolidation of alterations of a variety of cellular functions induced by transient extracellular signals in the brain.

Blockade by ferrous iron of Ca2+ influx through N-methyl-d-aspartate receptor channels in immature cultured rat cortical neurons

Rat cortical neurons cultured for 3u2003days in vitro were loaded with the fluorescent indicator fluo‐3 for assessment of intracellular free calcium ion (Ca2+) concentrations with the aid of a confocal laser‐scanning microscope. In the absence of added MgCl2, the addition of NMDA induced a rapid but sustained increase in the number of fluorescent neurons in a concentration‐dependent manner at a concentration range of 1–100u2003µm with the increase by KCl being transient. The addition of FeCl2, but not FeCl3, markedly inhibited the increase by NMDA in a reversible manner at concentrations of 10–200u2003µm, without affecting that by KCl. Extensive analyses revealed clear differentiation between inhibitions by ferrous iron and other channel blockers known to date. The inhibition by FeCl2 was completely prevented by the addition of two different iron chelators. Exposure to NMDA alone did not lead to cell death in immature cultured neurons, however, while further addition of FeCl2 invariably induced neuronal cell death 24 h after exposure. These results give support to our previous proposal that NMDA receptor complex may contain a novel site sensitive to blockade by ferrous iron in rat brain.

Dual mechanisms of Ca2+ increases elicited by N‐methyl‐D‐aspartate in immature and mature cultured cortical neurons

Cortical primary cultures were loaded with the fluorescent indicator fluo‐3 for assessment of intracellular‐free Ca2+ ions with the aid of a confocal laser‐scanning microscope. The addition of N‐methyl‐D‐aspartic acid (NMDA) markedly increased the number of fluorescent cells in a manner sensitive to prevention by both an NMDA channel blocker and MgCl2. In the absence of added MgCl2, NMDA induced a sustained increase in the number of fluorescent cells with a transient increase by KCl in cells cultured for 3 days in vitro (DIV). Both nifedipine and dantrolene were more potent in preventing the increase by NMDA in cortical preparations cultured for 9 DIV than those for 3 DIV. These results suggest that activation of NMDA receptors may lead to a sustained increase in intracellular‐free Ca2+ concentrations in immature cultured neurons, in a manner less dependent on the influx through L‐type voltage‐dependent channels as well as the release from intracellular stores than in mature neurons.

Nuclear transcription factors in the hippocampus

In the mammalian hippocampus, there is a trisynaptic loop that has been often referred to in studies on learning and memory mechanisms and their physiological correlate, the long-term potentiation (LTP). The three sets of synapses are formed by the fibers of perforant pathway terminating on granule cells and by the mossy fibers and Schaeffer collaterals making connections with the pyramidal cells. Each of the three types of synapses can develop LTP. LTP is accompanied by changes in gene expression and it is the nuclear transcription, involving specific transcription factors, that is the starting point for the series of biological amplifications and consolidations both necessary for such sustained changes. The transcription factors are proteins that control gene expression, development and functional formation in every eukaryotic cell. Two categories of transcription factors have been defined to date: general factors that comprise at least 20 proteins to form multiple preinitiation complex at the TATA box (TATA rich sequence) or regulatory factors that bind to promoter or enhancer regions at specific sites on the DNA close to, or distant from, the TATA box. Transcription factors have been divided into five different major classes according to unique protein motifs. These include basic domain, zinc-finger, helix-turn-helix, beta-Scaffold factors with minor groove contacts and other transcription factors not specifically classified. Much evidence has been accumulating in favor of the participation of several transcription factors in the consolidation of memory in the mammalian hippocampus following a spatial memory task. It is, therefore, of great importance that the involvement of transcription factors in de novo protein synthesis relevant to the synaptic mechanisms that mediate the formation of long-term memory should be summarized and discussed. No specific correlation between transduction of extracellular signals and expression of nuclear transcription factors, however, has been demonstrated to date.

Apparent presence of Ser133-phosphorylated cyclic AMP response element binding protein (pCREB) in brain mitochondria is due to cross-reactivity of pCREB antibodies with pyruvate dehydrogenase

Cyclic AMP response element binding protein (CREB) is a constitutive transcription factor that activates transcription following stimulus‐dependent phosphorylation at Ser133, implicated in synaptic plasticity and neuronal survival pathways. The prevailing view that CREB is exclusively nuclear has been questioned by several studies, and, for example, mitochondrial localization has been reported. Using subcellular fractionation of rat brain cortex coupled with western immunoblotting with Ser133‐phospho‐CREB (pCREB) antibodies, we found a robust pCREB immunoreactivity (IR) in mitochondria‐enriched fractions. The pCREB antibodies also stained the mitochondria, in addition to nuclei, of glial cells in primary cortical cultures. However, two CREB antibodies against different epitopes and gel shift assay detected the CREB protein mainly in the nuclear fraction. The two‐dimensional electrophoretic mobility of mitochondrial pCREB IR differed markedly from the nuclear CREB/pCREB IR, indicating that the pCREB antibody cross‐reacts with another mitochondrial protein. Immunoprecipitation of the mitochondrial pCREB IR produced three bands on sodium dodecyl sulfate–polyacrylamide gel electrophoresis, which were identified by matrix‐assisted laser desorption/ionization time‐of‐flight mass spectrometry as E2, E1 α‐subunit, and E1 β‐subunit of pyruvate dehydrogenase complex. The cross‐reacting epitope was identified as phospho‐Ser300 of the α‐subunit. In conclusion, this study confirms the presence of pCREB‐like IR in brain mitochondria that, after careful scrutiny, turned out to be pyruvate dehydrogenase rather than authentic CREB.

Xenobiotic response element binding enriched in both nuclear and microsomal fractions of rat cerebellum

Xenobiotic response element (XRE) is a core nucleotide sequence at the upstream of inducible target genes for the transcription factor aryl hydrocarbon receptor (AhR) that is responsible for signal transduction of exogenous environmental pollutants in eukaryotic cells. Immunoblotting analysis revealed the constitutive expression of AhR‐related proteins in rat liver and brain, while specific binding of a radiolabelled probe containing XRE was detected in nuclear preparations of both liver and brain on gel retardation electrophoresis. Among discrete rat brain structures examined, cerebellum exhibited the highest XRE binding with less potent binding in hypothalamus, midbrain, medulla‐oblongata, hippocampus, cerebral cortex and striatum. In contrast to liver and hippocampus, cerebellum also contained unusually higher XRE binding in microsomal fractions than that in either nuclear or mitochondrial fractions. Limited proteolysis by V8 protease did not markedly affect XRE binding in cerebellar nuclear extracts, with concomitant diminution of that in hepatic and hippocampal nuclear extracts. In primary cultured cerebellar neurons, indigo was effective in significantly increasing XRE binding only when determined immediately after sustained exposure for 120u2003min in the presence of high potassium chloride. These results suggest the abundance of as‐yet unidentified proteins with high affinity for XRE and responsiveness to indigo in both nuclear and microsomal fractions of rat cerebellum.

Modulation of DNA binding of nuclear transcription factors with leucine-zipper motifs by particular endogenous polyamines in murine central and peripheral excitable tissues

Transcriptional regulation is one of the most important functions of polyamines in the nucleus of eukaryotic cells. The addition of the endogenous polyamines spermine and spermidine markedly increased DNA binding activity of the transcription factor activator protein-1 (AP1) in a concentration-dependent manner at a concentration range of 50 to 500 microM in nuclear extracts of murine whole brain when determined in the absence of added MgCl(2) on gel retardation electrophoresis. Similar but less potent potentiation was seen with DNA binding of cAMP responsive element binding protein (CREB), while both polyamines were ineffective in affecting that of c-Myc irrespective of the addition of MgCl(2). Unlabeled AP1 probe was invariably more potent in competing for AP1 binding than unlabeled CREB probe in either the presence or absence of spermine and spermidine. In addition to whole brain, both polyamines significantly increased AP1 binding in retina, adrenal and pituitary, without significantly affecting that in spleen. Moreover, ultraviolet and circular dichroism spectra analyses revealed that these two polyamines induced DNA topological transition of AP1 probe under the conditions favorable for the increase in AP1 binding. These results suggest that both spermine and spermidine may modulate gene transcription through cis- and trans-actions on AP1 binding in the nucleus in murine central and peripheral structures with high excitability.

Degradation of c-Fos protein expressed by N-methyl-D-aspartic acid in nuclear fractions of murine hippocampus

In both nuclear and cytosolic fractions of murine hippocampus, constitutive expression was seen with Fra-2 protein, but not with other Fos family members tested including c-Fos, Fos-B and Fra-1 proteins. Fos-B protein was only detected in nuclear fractions. The systemic administration of N-methyl-D-aspartic acid (NMDA) induced marked and transient expression of c-Fos protein, but not other family members, in both hippocampal fractions 2 h later. In vitro incubation at 30 degrees C led to more rapid degradation of inducible c-Fos protein than constitutive Fra-2 protein in nuclear fractions obtained 2 h after the administration of NMDA, without significantly affecting that of both member proteins in cytosolic fractions. The addition of phosphatase inhibitors significantly delayed the initial degradation rate of inducible c-Fos protein, with concomitant facilitation of that of constitutive Fra-2 protein, in nuclear fractions. The addition of protease inhibitors also delayed the initial degradation of constitutive Fra-2 protein, without markedly altering that of inducible c-Fos protein, in nuclear fractions. Immunoprecipitation analysis revealed that NMDA induced phosphorylation of c-Fos protein on tyrosine residues in nuclear fractions to a lesser extent than that on serine residues 2 h after administration. These results suggest that NMDA signals may be propagated to the nucleus to induce both expression and degradation of c-Fos protein through a molecular mechanism associated with phosphorylation on serine and/or tyrosine residues in murine hippocampus.