Long-term neuronal plasticity is known to be dependent on rapid de novo synthesis of mRNA and protein, and recent studies provide insight into the molecules involved in this response. Here, we demonstrate that mRNA encoding a member of the regulator of G-protein signaling (RGS) family, RGS2, is rapidly induced in neurons of the hippocampus, cortex, and striatum in response to stimuli that evoke plasticity. Although several members of the RGS family are expressed in brain with discrete neuronal localizations, RGS2 appears unique in that its expression is dynamically responsive to neuronal activity. In biochemical assays, RGS2 stimulates the GTPase activity of the alpha subunit of Gq and Gi1. The effect on Gi1 was observed only after reconstitution of the protein in phospholipid vesicles containing M2 muscarinic acetylcholine receptors. RGS2 also inhibits both Gq- and Gi-dependent responses in transfected cells. These studies suggest a novel mechanism linking neuronal activity and signal transduction.
Cell membranes contain various transporter proteins, some of which are responsible for transferring amino acids across membrane. In this study, we report another class of carrier proteins, termed Serinc1-5, that incorporates a polar amino acid serine into membranes and facilitates the synthesis of two serine-derived lipids, phosphatidylserine and sphingolipids. Serinc is a unique protein family that shows no amino acid homology to other proteins but is highly conserved among eukaryotes. The members contain 11 transmembrane domains, and rat Serinc1 protein co-localizes with lipid biosynthetic enzymes in endoplasmic reticulum membranes. A Serinc protein forms an intracellular complex with key enzymes involved in serine and sphingolipid biosyntheses, and both functions, serine synthesis and membrane incorporation, are linked to each other. In the rat brain, expression of Serinc1 and Serinc2 mRNA was rapidly up-regulated by kainate-induced seizures in neuronal cell layers of the hippocampus. In contrast, myelin throughout the brain is enriched with Serinc5, which was downregulated in the hippocampus by seizures. These results indicate a novel mechanism linking neural activity and lipid biosynthesis.
Carbon monoxide (CO) is an activator of soluble guanylyl cyclase and is implicated as a neuronal messenger. CO production, nitric oxide synthase (NOS) activity, and guanosine 3',5'-monophosphate (cGMP) levels were quantitated in cerebellar granule cell cultures. Metabolic labeling experiments enabled the direct measurement of neuronal CO production in vitro. CO production is significant, and peaked during early stages of culture. NOS activity and cGMP levels synchronously increased as cells matured. Whereas inhibition of NOS depleted cGMP in mature cultures, inhibitors of CO production potentiated the nitric oxide (NO)-mediated cGMP increase. Exogenous CO at similar concentrations to endogenous levels blocked the NO-mediated cGMP increase. These results directly demonstrate that endogenous neuronal CO production is high and indicate that while NO is the major regulator of cGMP in these neurons, CO may modulate the NO-cGMP signaling system.
Recent evidence suggests that, like nitric oxide (NO), carbon monoxide (CO), another activator of soluble guanylyl cyclase, may serve as an intercellular messenger in the brain. Heme oxygenase, which converts heme to biliverdin and CO, is abundantly expressed in the brain and is localized to discrete neuronal populations. However, evidence for the actual generation of CO by neurons is lacking. Heme oxygenase-2 immunoreactivity is abundantly present in olfactory receptor neurons where it essentially colocalizes with immunoreactivity to soluble guanylyl cyclase, the target of CO action. To examine the generation of CO by neurons, we measured CO production directly and determined its relationship to cyclic GMP levels in cultured rat olfactory receptor neurons. This system has the advantage of not having measurable NO production, which could confound results since NO is a more potent activator of guanylyl cyclase than CO. Metabolic labeling experiments permitted the direct measurement of 14CO production by neurons in vitro. CO release parallels endogenous cyclic GMP concentrations with its peak at the immature stage of neuronal differentiation in culture. Cyclic GMP production is inhibited by zinc protoporphyrin-9 and zinc deuteroporphyrin IX 2,4-bis glycol, inhibitors of heme oxygenase, indicating that CO is an endogenous regulator of soluble guanylyl cyclase activities in these cells. Transforming growth factor-beta 2, an olfactory neurogenic factor, specifically shows a negative effect on CO release in olfactory receptor neurons. These results indicate that CO may serve as a gaseous neuronal messenger linked to cyclic GMP production and suggests its involvement in developmental processes of the olfactory receptor neuron.
Heme oxygenase (HO) converts heme to carbon monoxide (CO) and biliverdin, which is metabolized rapidly to bilirubin. CO is implicated as an intercellular messenger, whereas bilirubin could function as an antioxidant. These cellular functions differ significantly from those of HO in peripheral tissues, in which it degrades heme from senescent erythrocytes, suggesting that the regulation of HO may differ in neurons from that in other tissues. Among neurons, olfactory receptor neurons have the highest level of HO activity. Metabolic labeling with [2-14C]glycine or delta-[3H]aminolevulinic acid ([3H]ALA) was used to investigate heme metabolic turnover and CO biosynthesis in primary cultures of olfactory receptor neurons. The production rates of heme precursors and metabolites from [14C]glycine over 6 hr were (in pmol/mg protein): 100 for ALA, 8.2 for heme, and 2.9 for CO. Taking into account endogenous heme content, the amount of total CO production was determined to be 1.6 nmol/mg protein per 6 hr. Heme biosynthesis usually is subject to end-product negative feedback at the level of ALA synthase. However, metabolic control in these neurons is different. Both heme concentration (heme formation) and HO activity (heme degradation) were enhanced significantly during immature stage of neuronal differentiation in culture. Neuronal maturation, which is accelerated by transforming growth factor-beta 2 (TGF-beta 2), suppressed the activities of both heme biosynthesis and degradation. To explore the physiological importance of this endogenous production of CO, we examined the potency of CO as a soluble guanylyl cyclase activator. Exogenous CO (10-30 microM), comparable to endogenous CO production, significantly activated guanylyl cyclase, suggesting that HO activity may regulate cGMP levels in the nervous system.
The abundant expression of RGS (regulator of G-protein signalling) proteins in neurons, together with their modulatory function on G-protein-dependent neurotransmission, provides the basis for cellular adaptation to sensory inputs. To identify the molecular mechanism involved in the sensory experience-induced neural development, we performed a systematic survey of the localization of mRNAs encoding three subtypes of the RGSs (RGS2, RGS4 and RGS7) in developing rat brains by in situ hybridization through postnatal day 2 (P2), P10 and P18 to adult. The most dramatic changes of expression patterns were observed in the discrete neuronal cell layers of the cerebral neocortex (for RGS2 and 4), the hippocampus (for RGS2, 4 and 7), the thalamus (for RGS4) and the cerebellum (for RGS2 and 7). In the neocortex, RGS2 mRNA was enriched in the superficial cortical plate at P2, in contrast to RGS4, which was enriched in more mature neurons of the deeper layer V and VI. In the hippocampus, the neuronal cell layer-specific expression pattern of RGS2 developed from P2 to P18. RGS4 expression was temporarily confined to the CA pyramidal cell layer and not detectable in the dentate gyrus at P10 and P18. Similarly, a high level of expression of RGS7 was observed in the CA area, but not in the dentate gyrus at P2 and P10. In the cerebellum, the maturation of laminar expression patterns for the three RGSs correlated with neuronal maturation and synaptogenesis at P18. The most characteristic temporal pattern among the three RGSs was observed for RGS4 mRNA, which was highly enriched in the thalamocortical regions. The peaks of RGS4 expression were seen in the following regions with distinct onset and duration: the neocortex (from P2 onward), the hippocampus (P10 and P18) and the thalamus (from P18 onward). The divergent temporal and spatial expression of RGS subtypes and their dynamic control in the cortex, the hippocampus and the thalamus suggest that the RGS family could play multiple distinct roles in experience-dependent brain development.
Neuronal activity is a requirement for the plasticity and normal development of the central nervous system. We have used differential cloning techniques to identify an immediate-early gene (IEG) that is rapidly induced in neurons by activity in both adult and developmental models of plasticity. Here we describe the key regulatory enzyme of polyamine catabolism, spermidine/spermine N1-acetyltransferase (SSAT), as a neuronal IEG. In the rat brain, kainate-induced seizures result in a 5.5-fold increase in the amount of SSAT mRNA above basal levels and the enzymatic activity is increased twofold. Expression of SSAT mRNA is rapidly and transiently upregulated in the cerebral cortex and hippocampus by seizure-induced neuronal activation. In hippocampal neurons, SSAT expression is dynamically responsive to synaptic activity in the long-term potentiation (LTP) paradigm. In developing brain, region-specific expression of SSAT mRNA is first detected at postnatal day 9 (P9) and subsequently increases through days P15, P20, before reaching maximal level in adult animals. This dynamic transcriptional and translational control suggests that SSAT may play a role in activity-dependent neuronal plasticity and development.
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