The accumulation of arc (an immediate early gene) mRNA by the inhibition of protein synthesis

Characterization and Transcriptional Activation of the Immediate Early Gene ARC During a Neural Correlate of Classical Conditioning

Plasticity and learning genes require regulatory mechanisms that have the flexibility to respond to a variety of sensory stimuli to generate adaptive behavioral responses. The immediate early gene (IEG) activity-regulated cytoskeleton-associated protein (ARC) is rapidly induced not only by neuronal stimulation but also during a variety of learning tasks. How ARC is regulated in response to complex stimuli during associative learning remains to be fully detailed. Here, we characterized the structure of the ARC gene in the pond turtle and mechanisms of its transcriptional activation during a neural correlate of eyeblink classical conditioning. The tARC gene is regulated in part by the presence of paused polymerase (RNAPII) that is poised at the promoter for rapid gene induction. Conditioning induces permissive chromatin modifications in the tARC promoter that allows binding by the transcription factor cAMP response element-binding protein (CREB) within 5 min of training. During learning acquisition, the pausing factor negative elongation factor (NELF) dissociates from the promoter thereby releasing RNAPII for active transcription. Data additionally suggest that the DNA insulator protein CCCTC-binding factor (CTCF) is required for transcription by mediating a learning-induced interaction of the ARC promoter with an enhancer element. Our study suggests that the learning-inducible IEG tARC utilizes both paused RNAPII and rapid chromatin modifications that allow for dynamic gene responsiveness required when an organism is presented with a variety of environmental stimuli.

Balancing Arc synthesis, mRNA decay, and proteasomal degradation: maximal protein expression triggered by rapid eye movement sleep-like bursts of muscarinic cholinergic receptor stimulation

Cholinergic signaling induces Arc/Arg3.1, an immediate early gene crucial for synaptic plasticity. However, the molecular mechanisms that dictate Arc mRNA and protein dynamics during and after cholinergic epochs are little understood. Using human SH-SY5Y neuroblastoma cells, we show that muscarinic cholinergic receptor (mAchR) stimulation triggers Arc synthesis, whereas translation-dependent RNA decay and proteasomal degradation strictly limit the amount and duration of Arc expression. Chronic application of the mAchR agonist, carbachol (Cch), induces Arc transcription via ERK signaling and release of calcium from IP(3)-sensitive stores. Arc translation requires ERK activation, but not changes in intracellular calcium. Proteasomal degradation of Arc (half-life ∼37 min) was enhanced by thapsigargin, an inhibitor of the endoplasmic calcium-ATPase pump. Similar mechanisms of Arc protein regulation were observed in cultured rat hippocampal slices. Functionally, we studied the impact of cholinergic epoch duration and temporal pattern on Arc protein expression. Acute Cch treatment (as short as 2 min) induces transient, moderate Arc expression, whereas continuous treatment of more than 30 min induces maximal expression, followed by rapid decline. Cholinergic activity associated with rapid eye movement sleep may function to facilitate long term synaptic plasticity and memory. Employing a paradigm designed to mimic intermittent rapid eye movement sleep epochs, we show that application of Cch in a series of short bursts generates persistent and maximal Arc protein expression. The results demonstrate dynamic, multifaceted control of Arc synthesis during mAchR signaling, and implicate cholinergic epoch duration and repetition as critical determinants of Arc expression and function in synaptic plasticity and behavior.

p38 mitogen-activated protein kinase and PI3-kinase are involved in up-regulation of mu opioid receptor transcription induced by cycloheximide

Despite several decades of efforts to develop safer, efficacious, and non-addictive opioids for pain treatment, morphine remains the most valuable painkiller in contemporary medicine. Morphine and endogenous mu opioid peptides exert their pharmacological actions mainly through the mu opioid receptor (MOR). Analgesic effects of opioids in animals are dependent on the MOR expression levels, as demonstrated by studies of MOR-knockout mice (homo/heterozygotes) and MOR-less expressing mice. Surprisingly, in the course of our investigation to understand the mechanisms involved in the regulation of MOR gene expression, cycloheximide (CHX), a known protein synthesis inhibitor, markedly induced accumulation of MOR mRNAs in both MOR-negative and -positive cells. This induction was blocked by inhibitors of phosphoinositide 3-kinase (PI3-K) and p38 MAPK, but not by a p42/44 MAPK inhibitor. In vitro, CHX was found to activate the MOR promoter and this activation was suppressed by inhibition of PI3-K. The transcriptional activator Sox18 was recruited to the MOR promoter in CHX-treated cells and this recruitment was also inhibited by the PI3-K and p38 MAPK inhibitors, Ly294002 and SB203580, respectively. Consistently, acetylation of histone H3 and induction of H3-K4 methylation were detected while reductions of histone deacetylase 2 binding and H3-K9 methylation were observed on the promoter. Furthermore, the MOR mRNA accumulation was almost completely inhibited in the presence of actinomycin-D, indicating that this effect occurs mainly through activation of the transcriptional machinery. These observations suggest that CHX directly induces MOR gene transcription by recruiting the active transcription factor Sox18 to the MOR promoter through PI3- and/or p38 MAPK pathways.

The serum response factor and a putative novel transcription factor regulate expression of the immediate-early gene Arc/Arg3.1 in neurons

The immediate-early effector gene Arc/Arg3.1 is robustly upregulated by synaptic activity associated with learning and memory. Here we show in primary cortical neuron culture that diverse stimuli induce Arc expression through new transcription. Searching for regulatory regions important for Arc transcription, we found nine DNaseI-sensitive nucleosome-depleted sites at this genomic locus. A reporter gene encompassing these sites responded to synaptic activity in an NMDA receptor-dependent manner, consistent with endogenous Arc mRNA. Responsiveness mapped to two enhancer regions approximately 6.5 kb and approximately 1.4 kb upstream of Arc. We dissected these regions further and found that the proximal enhancer contains a functional and conserved "Zeste-like" response element that binds a putative novel nuclear protein in neurons. Therefore, activity regulates Arc transcription partly by a novel signaling pathway. We also found that the distal enhancer has a functional and highly conserved serum response element. This element binds serum response factor, which is recruited by synaptic activity to regulate Arc. Thus, Arc is the first target of serum response factor that functions at synapses to mediate plasticity.

The EJC factor eIF4AIII modulates synaptic strength and neuronal protein expression

Proper neuronal function and several forms of synaptic plasticity are highly dependent on precise control of mRNA translation, particularly in dendrites. We find that eIF4AIII, a core exon junction complex (EJC) component loaded onto mRNAs by pre-mRNA splicing, is associated with neuronal mRNA granules and dendritic mRNAs. eIF4AIII knockdown markedly increases both synaptic strength and GLUR1 AMPA receptor abundance at synapses. eIF4AIII depletion also increases ARC, a protein required for maintenance of long-term potentiation; arc mRNA, one of the most abundant in dendrites, is a natural target for nonsense-mediated decay (NMD). Numerous new NMD candidates, some with potential to affect synaptic activity, were also identified computationally. Two models are presented for how translation-dependent decay pathways such as NMD might advantageously function as critical brakes for protein synthesis in cells such as neurons that are highly dependent on spatially and temporally restricted protein expression.

Corticostriatal up-regulation of activity-regulated cytoskeletal-associated protein expression after repeated exposure to cocaine

We provide evidence that cocaine evokes short- and long-lasting increases in activity-regulated cytoskeletal-associated protein (Arc) expression after a finely tuned, time-dependent and regional-selective expression profile. Acute experiments revealed that cocaine up-regulates Arc expression primarily in striatum and prefrontal cortex through a dopamine D1-dependent mechanism and a combination of D1- and D2-dependent mechanisms, respectively. Aside from cocaine-dependent Arc elevation, we show for the first time that D1 and D2 receptors tonically regulate basal Arc expression following a regional-selective profile. As opposed to the effects of a single cocaine injection on Arc expression, which dissipate within 24 h, subchronic (five daily injections) or chronic (14 daily injections) cocaine administration, with animals sacrificed hours or days after the last treatment, demonstrated that Arc expression is still up-regulated long after treatment cessation, suggesting that adaptive changes have been set in motion by the prolonged administration of the psychostimulant. In summary, our findings are the first to demonstrate that repeated exposure to cocaine leads to long-lasting dysregulation of Arc expression in the corticostriatal network, thus establishing a molecular basis to explain, at least partially, the impaired synaptic transmission caused by cocaine abuse at this level. Furthermore, given the role exerted by Arc in cytoarchitectural rearrangements, it is conceivable to speculate that it mediates changes in synaptic connectivity brought about by cocaine. Our findings thus pinpoint this molecule as a neuropathological underpinning and molecular bridge that connects short- and long-term neuronal modifications associated with cocaine abuse.

Cycloheximide treatment to identify components of the transitional transcriptome in PACAP-induced PC12 cell differentiation

Pituitary adenylate cyclase-activating polypeptide (PACAP) promotes neurite outgrowth, reduces proliferation and inhibits apoptosis of PC12 cells. We have partially characterized the transcriptome changes induced by PACAP after 6 h of treatment, when commitment to differentiation has occurred. Here, we have investigated the effects of a 6-h treatment with PACAP (10(-7) m) in the presence of cycloheximide (5 microm) to identify, via superinduction, components of the transitional transcriptome initially induced by PACAP and potentially participating in the regulation of late-response genes required for differentiation. Approximately 100 new transcripts were identified in this screen, i.e. as many individual genes as make up the 6-h PACAP differentiation transcriptome itself. Six known transcripts in this cohort were then measured at several time points between 0 and 6 h by real-time PCR to determine whether these transcripts are induced early following PACAP treatment in the absence of cycloheximide, and therefore may be of functional importance in differentiation. Five out of the six transcripts were indeed induced by PACAP alone soon (between 30 min and 3 h) after cell treatment. beta-Cell translocation gene 2, antiproliferative (Btg2), serum/glucocorticoid-regulated kinase (Sgk), nuclear factor for the kappa chain of B-cells (NFkappaB), seven in absentia homologue 2 (Siah2) and FBJ osteosarcoma related oncogene (Fos) showed a 2.5-200-fold induction by PACAP between 15 min and 3 h, and mRNA levels returned either to baseline or near baseline after 6 h. This work provides new information concerning genes whose transient regulation early after PACAP exposure may contribute to the expression of the differentiated transcriptome in PC12 cells, and should help to elucidate the molecular mechanisms involved in the control of nerve cell survival and differentiation.

Identification of a cis-acting element required for dendritic targeting of activity-regulated cytoskeleton-associated protein mRNA

The mRNA encoding activity-regulated cytoskeleton-associated protein (Arc) is known to be targeted to dendritic regions that have received strong synaptic inputs. However, the cis-acting elements in Arc mRNA that mediate dendritic targeting have not been identified. To identify the dendritic targeting element (DTE) in rat Arc mRNA, we expressed reporter mRNAs containing various regions of Arc in primary hippocampal neurones and analysed their subcellular distribution by in situ hybridization. Here, we report that the 3'-untranslated region of rat Arc mRNA contains a 350-nucleotide DTE with strong dendritic targeting activity and another 370-nucleotide sequence with weaker dendritic targeting activity. The 350-nucleotide DTE does not share any obvious sequence similarity with other known DTEs previously reported.