Regulators of A20 (TNFAIP3): new drug-able targets in inflammation.

Persistent activation of the transcription factor Nuclear factor-κB (NF-κB) is central to the pathogenesis of many inflammatory disorders, including those of the lung such as cystic fibrosis (CF), asthma, and chronic obstructive pulmonary disease (COPD). Despite recent advances in treatment, management of the inflammatory component of these diseases still remains suboptimal. A20 is an endogenous negative regulator of NF-κB signaling, which has been widely described in several autoimmune and inflammatory disorders and more recently in terms of chronic lung disorders. However, the underlying mechanism for the apparent lack of A20 in CF, COPD, and asthma has not been investigated. Transcriptional regulation of A20 is complex and requires coordination of different transcription factors. In this review we examine the existing body of research evidence on the regulation of A20, concentrating on pulmonary inflammation. Special focus is given to the repressor downstream regulatory element antagonist modulator (DREAM) and its nuclear and cytosolic action to regulate inflammation. We provide evidence that would suggest the A20-DREAM axis to be an important player in (airway) inflammatory responses and point to DREAM as a potential future therapeutic target for the modification of phenotypic changes in airway inflammatory disorders. A schematic summary describing the role of DREAM in inflammation with a focus on chronic lung diseases as well as the possible consequences of altered DREAM expression on immune responses is provided.

Dopaminergic regulation of olfactory type G-protein α subunit expression in the striatum.

BACKGROUND: In rodents, the olfactory type G-protein α subunit (Gαolf) couples the dopamine D1 receptor (D1R) to adenylyl cyclase, triggering intracellular signaling and neuronal activation. In the striatum, Gαolf is enriched in the striosomes. Changes in Gαolf protein levels have been observed after dopamine depletion. However, the regulation of Gαolf expression by dopamine and dopamine receptors is not fully understood. METHODS: To address this, Striatal Gαolf expression pattern was studied in wild-type and genetically engineered mice lacking D1R, D2R (D2 receptor), and downstream regulatory element antagonist modulator (DREAM) protein whose dopamine levels were manipulated. Dopamine depletion was accomplished by 6-hydroxydopamine (6-OHDA) or by Pitx3 ablation, and dopamine replacement by chronic levodopa (l-dopa). The Gαolf levels were analyzed by immunohistochemistry, Western blot, and real-time quantitative polymerase chain reaction (RT-qPCR). RESULTS: Our results demostrate that Dopamine depletion or inactivation of D1R abolished the striosomal pattern of Gαolf expression and increased Gαolf protein levels. Dopamine replacement in wild-type lesioned mice reestablished both the expression pattern and protein levels, but paradoxically increased Gαolf messenger RNA (mRNA). In D1R(-/-) mice, dopamine depletion decreased striatal Gαolf expression, whereas l-dopa did not restore either Gαolf levels or its expression pattern. Inactivation of D2R or changes in the cAMP/PKA signaling pathway downstream of Gαolf did not modify its expression. CONCLUSION: Our results show a homeostatic, negative regulation of Gαolf by dopamine and by D1R stimulation, which are also required for the striosomal Gαolf pattern. These results shed light on the regulation of Gαolf by dopamine signaling that could be involved in the pathophysiology of the maladaptive response to chronic l-dopa treatment in Parkinson's disease.

A neuroprotective phase precedes striatal degeneration upon nucleolar stress.

The nucleolus is implicated in sensing and responding to cellular stress by stabilizing p53. The pro-apoptotic effect of p53 is associated with several neurodegenerative disorders, including Huntington's disease (HD), which is characterized by the progressive loss of medium spiny neurons (MSNs) in the striatum. Here we show that disruption of nucleolar integrity and function causes nucleolar stress and is an early event in MSNs of R6/2 mice, a transgenic model of HD. Targeted perturbation of nucleolar function in MSNs by conditional knockout of the RNA polymerase I-specific transcription initiation factor IA (TIF-IA) leads to late progressive striatal degeneration, HD-like motor abnormalities and molecular signatures. Significantly, p53 prolongs neuronal survival in TIF-IA-deficient MSNs by transient upregulation of phosphatase and tensin homolog deleted on chromosome 10 (PTEN), a tumor suppressor that inhibits mammalian target of rapamycin signaling and induces autophagy. The results emphasize the initial role of nucleolar stress in neurodegeneration and uncover a p53/PTEN-dependent neuroprotective response.

Thyroid hormones, learning and memory.

Thyroid hormones (THs), T3 and T4, have many physiological actions and are essential for normal behavioral, intellectual and neurological development. THs have a broad spectrum of effects on the developing brain and mediate important effects within the CNS throughout life. Insufficient maternal iodine intake during gestation and TH deficiency during human development are associated to pathological alterations such as cretinism and mental retardation. In adulthood, thyroid dysfunction is related to neurological and behavioral abnormalities, including memory impairment. Analysis of different experimental models suggests that most of the effects on cognition as a result of thyroid dysfunction rely on hippocampal modifications. Insufficiency of THs during development thus alters hippocampal synaptic function and impairs behavioral performance of hippocampal-dependent learning and memory tasks that persist in euthyroid adult animals. In the present review, we summarize the current knowledge obtained by clinical observations and experimental models that shows the importance of THs in learning and mnemonic processes.

EEG dynamics of the frontoparietal network during reaching preparation in humans.

Visuomotor transformation processes are essential when accurate reaching movements towards a visual target have to be performed. In contrast, those transformations are not needed for similar, but non-visually guided, arm movements. According to previous studies, these transformations are carried out by neuronal populations located in the parietal and frontal cortical areas (the so-called "dorsal visual stream"). However, it is still debated whether these processes are mediated by the sequential and/or parallel activation of the frontoparietal areas. To investigate this issue, we designed a task where the same visual cue could represent either the target of a reaching/pointing movement or the go-signal for a similar but non-targeting arm movement. By subtracting the event-related potentials (ERPs) recorded from healthy subjects performing the two conditions, we identified the brain processes underlying the visuomotor transformations needed for accurate reaching/pointing movements. We then localized the generators by means of cortical current density (CCD) reconstruction and studied their dynamics from visual cue presentation to movement onset. The results showed simultaneous activation of the parietal and frontal areas from 140 to 260 ms. The results are interpreted as neural correlates of two critical phases of visuomotor integration, namely target selection and movement selection. Our findings suggest that the visuomotor transformation processes required for correct reaching/pointing movements do not rely on a purely sequential activation of the frontoparietal areas, but mainly on a parallel information processing system, where feedback circuits play an important role before movement onset.

Mechanisms of Ca(2+)-dependent transcription.

Ca(2+) has a central role in coupling synaptic activity and transcriptional responses. Recent studies have focused on Ca(2+)-dependent nuclear mechanisms that bring to the nucleosomal level cascades of events initiated in the submembranous space at the synapse. In addition, a new Ca(2+)-dependent interaction between a calcium sensor and DNA has been shown to regulate transcription directly.

Interleukin 3-dependent activation of DREAM is involved in transcriptional silencing of the apoptotic Hrk gene in hematopoietic progenitor cells.

The apoptotic protein Hrk is expressed in hematopoietic progenitors after growth factor deprivation. Here we identify a silencer sequence in the 3' untranslated region of the hrk gene that binds to the transcriptional repressor DREAM in interleukin-3 (IL-3)-dependent hematopoietic progenitor cells, and abrogates the expression of reporter genes when located downstream of the open reading frame. In addition, the binding of DREAM to the hrk gene is reduced or eliminated when cells are cultured in the absence of IL-3 or treated with a calcium ionophore or a phosphatidylinositol 3-kinase-specific inhibitor, suggesting that both calcium mobilization and phosphorylation can regulate the transcriptional activity of DREAM. Furthermore, we have shown that DREAM is phosphorylated by a phosphatidylinositol 3-kinase-dependent, but Akt-independent pathway. In all cases, loss of the DREAM-DNA binding complex was correlated with increased levels of Hrk and apoptosis. These data suggest that IL-3 may trigger the activation of DREAM through different signaling pathways, which in turn binds to a silencer sequence in the hrk gene and blocks transcription, avoiding inappropriate cell death in hematopoietic progenitors.

Ca2+-dependent transcriptional repression and derepression: DREAM, a direct effector.

Control of gene expression by Ca2+ is a well known phenomenon acting through three major pathways: (i) changes in the transactivating properties of transcription factors after induction of Ca2+-dependent kinases and phosphatases (ii) Ca2+-dependent interaction between calmodulin and S-100 proteins with basic helix-loop-helix (bHLH) transcription factors that prevents binding to DNA and (iii) direct interaction between Ca2+-free DREAM and DNA that represses transcription. Because the first mechanism has been extensively reviewed, (Gallin, W. J., Greenberg, M. E. (1995). Calcium regulation of gene expression in neurons: the mode of entry matters. Curr Opin Neurobiol 5: 367-374; Santella, L., Carafoli, E. (1997). Calcium signaling in the cell nucleus. FASEB J, 11: 1091-1109) this commentary will focus on the other two with special emphasis on DREAM, the first EF-hand protein known to specifically bind DNA and regulate transcription in a Ca2+-dependent manner (Carrion, A. M.; Link, W. A., Ledo, F., Mellstrom, B., Naranjo, J. R. (1999). DREAM is a Ca2+-regulated transcriptional repressor, Nature. 398: 80-84).

The DREAM-DRE interaction: key nucleotides and dominant negative mutants.

Transcriptional repressor DREAM, an EF-hand containing calcium-binding protein, blocks basal expression of target genes through specific interaction with DRE sites in the DNA. The sequence GTCA forms the central core of the DRE site, whereas flanking nucleotides contribute notably to the affinity for DREAM. Release of binding of DREAM from the DRE results in derepression, a process that is regulated by Ca(2+). Change of two amino acids within an EF-hand in DREAM blocks Ca(2+)-induced derepression and results in potent dominant negative mutants of endogenous DREAM.

DREAM-alphaCREM interaction via leucine-charged domains derepresses downstream regulatory element-dependent transcription.

Protein kinase A-dependent derepression of the human prodynorphin gene is regulated by the differential occupancy of the Dyn downstream regulatory element (DRE) site. Here, we show that a direct protein-protein interaction between DREAM and the CREM repressor isoform, alphaCREM, prevents binding of DREAM to the DRE and suggests a mechanism for cyclic AMP-dependent derepression of the prodynorphin gene in human neuroblastoma cells. Phosphorylation in the kinase-inducible domain of alphaCREM is not required for the interaction, but phospho-alphaCREM shows higher affinity for DREAM. The interaction with alphaCREM is independent of the Ca(2+)-binding properties of DREAM and is governed by leucine-charged residue-rich domains located in both alphaCREM and DREAM. Thus, our results propose a new mechanism for DREAM-mediated derepression that can operate independently of changes in nuclear Ca(2+).

Induction of glycerol phosphate dehydrogenase gene expression during seizure and analgesia.

Using mRNA differential display, we found that the gene for NAD(+)-dependent glycerol phosphate dehydrogenase (GPDH; EC 1.1.1.8) is induced in rat brain following seizure activity. Northern blot and in situ hybridization analysis confirmed the differential display results; they also showed, in a separate model of neuronal activation, that after thermal noxious stimulation of the hind-paws, a similar increase in GPDH mRNA occurs in the areas of somatotopic projection in the lumbar spinal cord. Surprisingly, administration of analgesic doses of morphine or the nonsteroidal antiinflammatory drugs aspirin, metamizol (dipyrone), and indomethacin also increased GPDH mRNA levels in rat spinal cord. The opioid receptor antagonist naloxone completely blocked morphine induction of GPDH but had no effect on GPDH induction by noxious heat stimulation or metamizol treatment, implicating different mechanisms of GPDH induction. Nevertheless, in all cases, induction of the GPDH gene requires adrenal steroids and new protein synthesis, as the induction was blocked in adrenalectomized rats and by cycloheximide treatment, respectively. Our results suggest that the induction of the GPDH gene upon peripheral noxious stimulation is related to the endogenous response to pain as it is mimicked by exogenously applied analgesic drugs.

DREAM is a Ca2+-regulated transcriptional repressor.

Fluxes in amounts of intracellular calcium ions are important determinants of gene expression. So far, Ca2+-regulated kinases and phosphatases have been implicated in changing the phosphorylation status of key transcription factors and thereby modulating their function. In addition, direct effectors of Ca2+-induced gene expression have been suggested to exist in the nucleus, although no such effectors have been identified yet. Expression of the human prodynorphin gene, which is involved in memory acquisition and pain, is regulated through its downstream regulatory element (DRE) sequence, which acts as a location-dependent gene silencer. Here we isolate a new transcriptional repressor, DRE-antagonist modulator (DREAM), which specifically binds to the DRE. DREAM contains four Ca2+-binding domains of the EF-hand type. Upon stimulation by Ca2+, DREAM's ability to bind to the DRE and its repressor function are prevented. Mutation of the EF-hands abolishes the response of DREAM to Ca2+. In addition to the prodynorphin promoter, DREAM represses transcription from the early response gene c-fos. Thus, DREAM represents the first known Ca2+-binding protein to function as a DNA-binding transcriptional regulator.

Protein kinase A-dependent derepression of the human prodynorphin gene via differential binding to an intragenic silencer element.

Induction of the prodynorphin gene has been implicated in medium and long-term adaptation during memory acquisition and pain. By 5' deletion mapping and site-directed mutagenesis of the human prodynorphin promoter, we demonstrate that both basal transcription and protein kinase A (PKA)-induced transcription in NB69 and SK-N-MC human neuroblastoma cells are regulated by the GAGTCAAGG sequence centered at position +40 in the 5' untranslated region of the gene (named the DRE, for downstream regulatory element). The DRE repressed basal transcription in an orientation-independent and cell-specific manner when placed downstream from the heterologous thymidine kinase promoter. Southwestern blotting and UV cross-linking experiments with nuclear extracts from human neuroblastoma cells or human brain revealed a protein complex of approximately 110 kDa that specifically bound to the DRE. Forskolin treatment reduced binding to the DRE, and the time course paralleled that for an increase in prodynorphin gene expression. Our results suggest that under basal conditions, expression of the prodynorphin gene is repressed by occupancy of the DRE site. Upon PKA stimulation, binding to the DRE is reduced and transcription increases. We propose a model for human prodynorphin activation through PKA-dependent derepression at the DRE site.

Metamizol potentiates morphine effects on visceral pain and evoked c-Fos immunoreactivity in spinal cord.

In a model of visceral pain consisting of intraperitoneal injection of acetic acid (writhing test), simultaneous administration of subanalgesic doses of metamizol (150 mg/kg) and morphine (0.2 mg/kg) resulted in a potent analgesia (19 +/- 1 vs. 2.3 +/- 0.8 writhes; P < 0.05). While the analgesic effect of morphine (2 mg/kg) was antagonized by naloxone (1 mg/kg), the opioid antagonist did not reverse the analgesia induced by the combination of metamizol and morphine. Potentiation by metamizol was also observed as a bilateral decrease in stimulus-evoked c-Fos induction in superficial laminas (I-II) of the dorsal spinal cord after drug combination compared to single administration (66.5 +/- 2.2 vs. 80.7 +/- 4.2; P < 0.05). Conversely, the number of nuclei immunostained with an antibody that recognizes all proteins of the Fos family was not modified by the same dose combination compared to single treatment (21.1 +/- 1.3 vs. 20.2 +/- 1.2). Furthermore, in a model of somatic pain consisting of peripheral thermal stimulation of the paws, simultaneous administration of metamizol (100-250 mg/kg) and morphine (0.5 mg/kg) failed to modify flexor reflex latency.

Stimulus-specific hierarchy of enhancer elements within the rat prodynorphin promoter.

Induction of the prodynorphin gene occurs in a tissue-specific manner following different physiological stimuli. Using electrophoretic mobility shift assays, we studied the relative activity of the five major regulatory sites in the rat prodynorphin promoter. Prodynorphin cyclic AMP-responsive element 2 (DynCRE2), DynCRE3, and the noncanonical prodynorphin AP-1 (ncDynAP-1) regulatory sites control, in a coordinated manner, prodynorphin induction in the spinal cord after noxious stimulation, whereas prodynorphin up-regulation in supraoptic neurons is regulated predominantly by the ncDynAP-1. Conversely, prodynorphin transactivation in the ovaries upon gonadotropin stimulation is controlled by DynCRE1 and DynCRE3. Our results support the idea that stimulus-specific changes in nuclear proteins establish a functional hierarchy among regulatory sites in the prodynorphin promoter and provide further insight in the molecular mechanisms that govern prodynorphin gene regulation.

Identification and functional characterization of a K+ channel alpha-subunit with regulatory properties specific to brain.

The physiological diversity of K+ channels mainly depends on the expression of several genes encoding different alpha-subunits. We have cloned a new K+ channel alpha-subunit (Kv2.3r) that is unable to form functional channels on its own but that has a major regulatory function. Kv2.3r can coassemble selectively with other alpha-subunits to form functional heteromultimeric K+ channels with kinetic properties that differ from those of the parent channels. Kv2.3r is expressed exclusively in the brain, being concentrated particularly in neocortical neurons. The functional expression of this regulatory alpha-subunit represents a novel mechanism without precedents in voltage-gated channels, which might contribute to further increase the functional diversity of K+ channels necessary to specify the intrinsic electrical properties of individual neurons.

Peripheral noxious stimulation induces CREM expression in dorsal horn: involvement of glutamate.

Peripheral noxious stimulation is known to trigger signalling cascades in neurons of the spinal cord. The response to pain and stress at the level of gene expression involves transcriptional activation of several cyclic AMP responsive genes. Here, we show induction of the CREM (cyclic-AMP responsive element modulator) gene in distinct subpopulations of spinal cord neurons upon thermal noxious stimulation. The addition of forskolin or glutamate to cultured spinal cord neurons results in the induction of the CREM isoform, ICER (Inducible cyclic-AMP Early Repressor), a powerful repressor of cAMP-induced transcription. Overexpression of ICER in cultured spinal cord neurons results in the repression of the c-fos and c-jun promoters induced by forskolin and glutamate. On this basis, we postulate that early activation of ICER in spinal cord participates in the attenuation of early gene induction following noxious stimulation.

Experimental brain glioma: growth arrest and destruction by a blood-group-related tetrasaccharide.

A synthetic tetrasaccharide (TS4), structurally related to blood groups, inhibited the proliferation of the C6 glioma cells in culture and the growth of tumors formed after intracerebral transplantation of C6 cells. TS4-treated tumors were substantially smaller than controls, as expected from TS4 cytostatic action on C6 glioma cells in culture. However, in vivo treatment also caused extensive tumor destruction. This effect appeared to be caused by indirectly, either by activation of natural killer cells, cytotoxic lymphocytes, or by inhibition of tumor vascularization. Enhanced antigenicity of TS4-treated glioma may be related to the increased expression of connexin 43 observed in glioma cell cultures treated with the oligosaccharide. Because concentrations of up to 20 mg/ml of TS4 were not toxic for normal neuronal or glial cells, specific oligosaccharides such as TS4 offer the possibility of selective tumor treatment.

Functional N-methyl-D-aspartate receptors in clonal rat phaeochromocytoma cells.

1. To characterize from a molecular and functional point of view the endogenous NMDA receptors expressed by phaeochromocytoma (PC12) cells, experiments involving polymerase chain reaction (PCR) amplification, Western blotting and patch-clamp analysis of undifferentiated and nerve growth factor (NGF)-differentiated PC12 cells were performed. 2. Analysis of PC12 mRNA demonstrated the presence of NMDAR1 and NMDAR2C transcripts. The NMDAR1 subunits lack the amino terminal insert of twenty-one amino acid residues, where as transcripts with and without deletions I and II at the 3' end of the coding region were detected. Thus, NMDA receptors of the PC12 cells might include NMDAR1A, NMDAR1E, NMDAR1C and NMDAR1D subunits. 3. Differentiation by NGF treatment of PC12 cells did not alter mRNA expression for NMDA receptor subunits significantly but induced an increase in both the NMDAR1 protein and the total amount of functional receptors that correlated well with a parallel increase in membrane area. 4. NMDA receptors in differentiated PC12 cells had a high affinity for both glutamate and glycine. These were estimated kinetically as 0.59 microM and 74 nM, respectively. Responses to glutamate or NMDA were non-desensitizing in the presence of saturating glycine, but slowly desensitized with low concentrations of glycine. Currents were completely blocked by D-aminophosphonovalerate (APV), 7-Cl-kynurenate and phencyclidine, and showed a voltage-dependent magnesium blockade. Spermine did not potentiate but inhibited NMDA receptor-mediated responses in a voltage-independent manner. 5. With 0.5 mM Ca2+, single-channel analysis revealed very brief openings (mean open time (t(o)) = 0.42 ms), with at least two conductive states, 55 and 33 pS, both having markedly low open probability. At 2 mM Ca2+, conductances were reduced to 39 and 19 pS, without an effect in open probability or mean open time. 6. The functional properties of NMDA receptors in PC12 cells were very similar to those described for NMDAR1A-NMDAR2C heteromers recombinantly expressed. The PC12 cell line provides a simple and reproducible system to analyse some specific NMDA receptor properties.