Protein kinase C phosphorylates a 47 Mr protein (F1) directly related to synaptic plasticity

Ca²⁺-phospholipid-dependent protein kinase C, and activators of protein kinase C (phosphatidylserine, phorbol esters) stimulate the in vitro phosphorylation of a 47 kdalton phosphoprotein (protein F1) previously shown (Routtenberg, Lovinger and Steward,Behav. neural Biol., 43 (1985) 3–11) to be directly related to the plasticity of long-term potentiation. These data indicate that protein F1 serves as a protein kinase C substrate, and suggest the hypothesis that protein kinase C is involved in processes of long-term potentiation.     

NMDA receptor blockade prevents the increase in protein kinase C substrate (protein F1) phosphorylation produced by long-term potentiation

Recent evidence has implicated activation of the N-methyl-D-aspartate (NMDA) class of glutamate receptor in the initiation of hippocampal long-term potentiation (LTP), an electrophysiological model of information storage in the brain. A separate line of evidence has suggested that activation of protein kinase C (PKC) and the consequent phosphorylation of its substrates is necessary for the maintenance of the LTP response. To determine if PKC activation is a consequence of NMDA receptor activation during LTP, we applied the NMDA receptor antagonist drug, DL-aminophosphonovalerate (APV) both immediately prior to and following high frequency stimulation, resulting in successful and unsuccessful blockade of LTP initiation, respectively. We then measured the phosphorylation of a PKC substrate (protein F1) in hippocampal tissue dissected from these animals. Only successful blockade of LTP initiation by prior application of APV was seen to block the LTP-associated increase in protein F1 phosphorylation measured in vitro (P less than 0.001 by ANOVA). This suggests that NMDA receptor-mediated initiation triggers maintenance processes that are, at least in part, mediated by protein F1 phosphorylation. These data provide the first evidence linking two mechanisms associated with LTP, NMDA receptor activation and PKC substrate phosphorylation.     

Characterization of protein F1 (47 kDa, 4.5 pI): a kinase C substrate directly related to neural plasticity

We recently demonstrated that long-term potentiation in rat hippocampal formation leads to a selective increase in the phosphorylation of a 47-kDa protein band (F1). The present report provided evidence, using two-dimensional gel electrophoresis, that only one major phosphoprotein in rat is found at 47 kDa under conditions identical to those used in that earlier study. This protein, which we also term F1, has an isoelectric point of 4.5 and is increased in phosphorylation after long-term potentiation. In addition to this identification, we demonstrated in two-dimensional gels that protein F1 is a membrane-enriched kinase C substrate whose phosphorylation is stimulated by Ca2+ and phosphatidylserine. Protein F1 may be equivalent to several reported proteins: a brain-specific, synaptically enriched protein (B-50), a major membrane-bound growth cone protein (pp46), and a fast axonally transported "growth-associated protein" (GAP43; 44- to 49-kDa goldfish optic nerve protein). Protein F1 participation in neural plasticity may thus involve growth occurring at synaptic loci.     

Direct relation of long-term synaptic potentiation to phosphorylation of membrane protein F1, a substrate for membrane protein kinase C

One hour after long-term potentiation (LTP) in the intact hippocampus, a selective increase in protein F₁ in vitro phosphorylation was observed in homogenate prepared from dorsal hippocampus. Protein F₁ phosphorylation was directly related to the magnitude and persistence of potentiation. No other phosphoprotein studied exhibited a relationship with synaptic enhancement. Low-frequency, non-potentiating stimulation did not increase protein F₁ phosphorylation, and phosphorylation of F₁ was not elevated when high-frequency stimulation did not produce potentiation. We also confirmed our earlier demonstration of a similar pattern of results 5 min after LTP. In related work we have previously observed: (1) that protein F₁ is a substrate for protein kinase C (PKC); (2) that membrane PKC activity was increased by translocation from the cytosol following LTP; and (3) that membrane PKC activity was directly related to the persistence of enhancement. We therefore predicted in the present study that protein F₁ phosphorylation in a dorsal hippocampal membrane fraction would be related to LTP. Hippocampal membrane protein F₁ was found to be directly related to both the magnitude and persistence of response enhancement. Thus the molecular events leading to prolonged potentiation may involve increased PKC/protein F₁ association. Persistence of potentiation may be related to synaptic growth processes involving the growth-associated function of protein F₁.     

A selective increase in phosphorylation of protein F1, a protein kinase C substrate, directly related to three day growth of long term synaptic enhancement

Increased in vitro phosphorylation of the 47 kdalton, 4.5 pI protein F1 was observed in dorsal hippocampal tissue from animals exhibiting long term enhancement (LTE) three days after high frequency stimulation of the perforant pathway, as compared to tissue from low frequency stimulated controls or from unoperated animals. The increase in protein F1 phosphorylation was related to LTE rather than simple activation of perforant path-dentate gyrus synapses. This is the first report of a change in brain protein phosphorylation accompanying synaptic enhancement lasting days. The extent of growth of LTE over the three days following stimulation was directly related (r = +0.66, P < 0.05) to protein F1 phosphorylation. Among the phosphorylation. Among the phosphoproteins studied this relationship between LTE and phosphorylation was selective for protein F1. This suggests that protein F1 may regulate growth of synaptic plasticity for at least a three day period. The mechanism for the LTE-related increase in protein F1 phosphorylation has not been established. However, recent evidence from this laboratory indicates: (1) that protein F1 is phosphorylated by the calcium/phospholipid-dependent protein kinase C; and (2) that kinase C is activated 1 h after LTE. Therefore, the increase in protein F1 phosphorylation following LTE may result from long term activation of protein C kinase.     

Phosphoprotein F1: purification and characterization of a brain kinase C substrate related to plasticity

To study the role of protein kinase C (PKC) and its substrates in neuronal function, we have investigated the in vitro endogenous phosphorylation of the neuronal phosphoprotein F1 after induction of synaptic plasticity by long-term potentiation (LTP). The protein F1 phosphorylation was found to increase 5 min (Routtenberg et al., 1985), 1 hr (Lovinger et al., 1986) and 3 d (Lovinger et al., 1985) after LTP. The characteristics of this protein bear close similarities to a number of proteins characterized in various neuronal systems, such as B50 (brain specific, synaptosome-enriched protein), pp46 (a growth cone protein), and GAP 43 (nerve growth and regeneration-associated protein). A positive identification of the purified protein F1 with these proteins would link protein F1 to the developmental growth of axons, nerve regeneration, and polyphosphoinositide metabolism, as well as adult plasticity. We have therefore purified and partially characterized native protein F1 so that a meaningful comparison among the properties of these proteins can be made. Using synaptosomal plasma membrane (P2') as starting material, subsequent purification involved pH extraction, 40-80% ammonium sulfate precipitation, hydroxylapatite, and phenyl-Sepharose column chromatography. This procedure achieved greater than 800-fold purification and about 45% yield relative to P2'. Purified protein F1 (Mr = 47,000, pI = 4.5) was found to be a hydrophilic molecule and was phosphorylated by 1000-fold purified PKC in the presence of phosphatidylserine (PS) and Ca2+. The Ka of PS activation is about 15 micrograms/ml (approximately 20 microM), and that of Ca2+ is about 25 microM. Diolein and DiC:8 (a synthetic diacylglycerol) lowered the requirement of Ca2+ for maximal stimulation from 100 to 5 microM. Ca2+-calmodulin kinases type I and II did not phosphorylate protein F1. The phosphoamino acid analysis showed that 97% of the total incorporated 32P-phosphate was on the serine residue. Phosphopeptide mapping using V8-protease generated 2 phospho-fragments having apparent Mr of 13,000 and 11,000. Calmodulin at 3.6 microM inhibited 95% of protein F1 phosphorylation by PKC. The availability of purified native protein F1 should facilitate investigation of the physiological role of this protein in the nervous system and its functional regulation by PKC.     

Activation of metabotropic glutamate receptors increases endogenous protein kinase C substrate phosphorylation in adult hippocampal slices

We previously reported (Staak, S., Behnisch, T. and Angenstein, F., Hippocampal long-term potentiation: transient increase but no persistent translocation of protein kinase C (PKC) isoenzymes α and β, Brain Res., 682 (1995) 55–62) that Ca²⁺-dependent PKC isoenzymes α/β and γ are not translocated between subcellular compartments after stimulation of glutamate receptor subtypes in hippocampal slices. Extending our previous work in this study in situ phosphorylation of endogenous PKC substrates and the translocation of novel PKC isoenzymes δ and ε was analysed to detect PKC activation. Two proteins of approximately 94 kDa and 18 kDa were first characterised to be specific PKC substrates. As control of the technique carbachol was shown to increase in situ phosphorylation of the two substrates without any measurable translocation of PKC protein. Activation of metabotropic glutamate receptors by 50 μM DHPG also increased the in situ-phosphorylation by 43.9% (94 kDa) and 32.8% (18 kDa) compared to controls but did not induce a measurable subcellular redistribution of conventional and novel PKC isoenzymes. Stimulation by 50 μM trans-ACPD or 0.1 mM quisqualate enhanced the in situ phosphorylation in the same range, whereas 0.1 mM NMDA was ineffective. To our knowledge this is the first report showing a direct link between metabotropic glutamate receptor activation and increased endogenous PKC substrate phosphorylation in adult hippocampal slices. This PKC activation was not detectable by a redistribution of enzyme protein between subcellular compartments. We, therefore, conclude, that the failure to detect PKC translocation in physiological experiments is not an indicator for unchanged enzyme activity.     

A selective increase in phosporylation of protein F1, a protein kinase C substrate, directly related to three day growth of long term synaptic enhancement

Increased in vitro phosphorylation of the 47 kdalton, 4.5 pI protein F1 was observed in dorsal hippocampal tissue from animals exhibiting long term enhancement (LTE) three days after high frequency stimulation of the perforant pathway, as compared to tissue from low frequency stimulated controls or from unoperated animals. The increase in protein F1 phosphorylation was related to LTE rather than simple activation of perforant path-dentate gyrus synapses. This is the first report of a change in brain protein phosphorylation accompanying synaptic enhancement lasting days. The extent of growth of LTE over the three days following stimulation was directly related (r = +0.66, P less than 0.05) to protein F1 phosphorylation. Among the phosphoproteins studied this relationship between LTE and phosphorylation was selective for protein F1. This suggests that protein F1 may regulate growth of synaptic plasticity for at least a three day period. The mechanism for the LTE-related increase in protein F1 phosphorylation has not been established. However, recent evidence from this laboratory indicates: that protein F1 is phosphorylated by the calcium/phospholipid-dependent protein kinase C; and that kinase C is activated 1 h after LTE. Therefore, the increase in protein F1 phosphorylation following LTE may result from long term activation of protein C kinase.     

Effect of myristoylated alanine-rich C kinase substrate (MARCKS) overexpression on hippocampus-dependent learning and hippocampal synaptic plasticity in MARCKS transgenic mice

The myristoylated alanine-rich C kinase substrate (MARCKS) is a primary substrate of protein kinase C (PKC) thought to regulate membrane-filamentous actin cytoskeletal plasticity in response to PKC activity in the regulation of synaptic efficacy. We have recently reported that MARCKS expression is significantly elevated (45%) in the hippocampus of DBA/2J mice, which exhibit impaired hippocampus-dependent learning and hippocampal long-term potentiation (LTP), compared with C57BL/6J mice. The latter finding led us to hypothesize that elevations in MARCKS expression are detrimental to hippocampal plasticity and function. To assess this more directly, we examined hippocampal (CA1) paired-pulse facilitation and LTP, and hippocampus-dependent learning in mice overexpressing MARCKS through the expression of a human MARCKS transgene (Tg+). The human MARCKS protein was confirmed to be expressed in the hippocampus of Tg+ mice but not in Tg- mice. Schaffer collateral paired-pulse facilitation, input-output responses, and LTP did not differ between Tg+ and Tg- mice, indicating that neurotransmitter release, short-term, and long-term synaptic plasticity are not impaired by MARCKS overexpression. In the Morris water maze, Tg+ mice exhibited a mild but significant spatial learning impairment during initial acquisition, and a more severe impairment during reversal training. Tg+ did not exhibit impaired swim speed or visible platform performance relative to Tg- mice, indicating the absence of gross sensorimotor deficits. Fear conditioning to either context or cue was not impaired in Tg+ mice. Behavioral deficits could not be attributed to differences in hippocampal PKC isozyme (alpha beta(II), gamma, epsilon, zeta) or calmodulin expression, or alterations in hippocampal cytoarchitecture or infrapyramidal mossy fiber limb length. Collectively, these results indicate that elevations in MARCKS expression are detrimental to specific aspects of hippocampal function.     

Acidosis enhances translocation of protein kinase C but not Ca(2+)/calmodulin-dependent protein kinase II to cell membranes during complete cerebral ischemia

Systemic hyperglycemia and hypercapnia severely aggravate ischemic brain damage when instituted prior to cerebral ischemia. An aberrant cell signaling following ischemia has been proposed to be involved in ischemic cell death, affecting protein kinase C (PKC) and the calcium calmodulin kinase II (CaMKII). Using a cardiac arrest model of global brain ischemia of 10 min duration, we investigated the effect of hyperglycemia (20 mM) and hypercapnia (pCO(2) 300 mmHg) on the subcellular redistribution of PKC (alpha, beta, gamma) and CaMKII to synaptic membranes and to the microsomes, as well as the effect on PKC activity. We confirmed the marked translocation of PKC and CaMKII to cell membranes induced by ischemia, concomitantly with a decrease in the PKC activity in both the membrane fraction and cytosol. Hyperglycemia and hypercapnia markedly enhanced the translocation of PKC-gamma to cell membranes while other PKC isoforms were less affected. There was no effect of acidosis on PKC activity, or on translocation of CaMKII to cell membranes. Our data strongly suggest that the enhanced translocation of PKC to cell membranes induced by hyperglycemia and hypercapnia may contribute to the detrimental effect of tissue acidosis on the outcome following ischemia.     

Acidosis enhances translocation of protein kinase C but not Ca/calmodulin-dependent protein kinase II to cell membranes during complete cerebral ischemia

Systemic hyperglycemia and hypercapnia severely aggravate ischemic brain damage when instituted prior to cerebral ischemia. An aberrant cell signaling following ischemia has been proposed to be involved in ischemic cell death, affecting protein kinase C (PKC) and the calcium calmodulin kinase II (CaMKII). Using a cardiac arrest model of global brain ischemia of 10 min duration, we investigated the effect of hyperglycemia (20 mM) and hypercapnia (pCO₂ 300 mmHg) on the subcellular redistribution of PKC (α, β, γ) and CaMKII to synaptic membranes and to the microsomes, as well as the effect on PKC activity. We confirmed the marked translocation of PKC and CaMKII to cell membranes induced by ischemia, concomitantly with a decrease in the PKC activity in both the membrane fraction and cytosol. Hyperglycemia and hypercapnia markedly enhanced the translocation of PKC-γ to cell membranes while other PKC isoforms were less affected. There was no effect of acidosis on PKC activity, or on translocation of CaMKII to cell membranes. Our data strongly suggest that the enhanced translocation of PKC to cell membranes induced by hyperglycemia and hypercapnia may contribute to the detrimental effect of tissue acidosis on the outcome following ischemia.     

Enhanced phosphorylation of the postsynaptic protein kinase C substrate RC3/neurogranin during long-term potentiation

Long-term potentiation (LTP) is a sustained strengthening of synaptic connections that occurs in the mammalian hippocampus, and is a cellular mechanism likely to contribute to memory formation. One question of current interest is whether the biochemical mechanisms responsible for the maintenance of LTP have a presynaptic or postsynaptic locus. We have determined that the phosphorylation of the postsynaptic protein kinase (PKC) substrate RC3/neurogranin is increased in the maintenance phase of LTP, and that the induction of this effect is dependent on activation of the N-methyl-d-aspartate (NMDA) subtype of glutamate receptors. The sustained increase in RC3/neurogranin phosphorylation requires ongoing protein kinase activity, as application of the protein kinase inhibitor H-7 after LTP induction can reverse the increased RC3/neurogranin phosphorylation. Overall, these data are evidence for postsynaptic biochemical changes in the maintenance of LTP. They also implicate RC3/neurogranin as a downstream effector of PKC activity in LTP that could contribute to physiologic expression of LTP.     

Effects of arginine vasopressin on protein phosphorylation in rat hippocampal synaptic membranes

Our laboratory has reported previously the characteristics of specific AVP binding to rat hippocampal synaptic membranes (SPM) in the presence of Ni2+ [Costantini MG, Pearlmutter AF: J Biol Chem 259: 11739-11745, 1984]. We extended our investigation to determine the effects of Ni2+, (AVP), and AVP analogs on SPM protein phosphorylation. Ni2+ (5 mM) caused a dramatic reduction in phosphorylation of most SPM phosphoproteins. The most prominent protein which is phosphorylated in SPM has a molecular weight of 48 kilodaltons (KDa) and has been named B50 or F1; this protein shows altered phosphorylation in vitro in response to long-term potentiation in vivo as well as changes induced by exposure of SPM to ACTH (1-24), dopamine, and somatostatin. AVP and related peptides reduced phosphorylation of this pre-synaptic phosphoprotein in the following order of potency: AVP = oxytocin greater than DG-AVP greater than dDAVP greater than d(CH2)5Tyr(Me)AVP = [pGlu4,Cyt6]AVP-(4-9). Except for the pressor antagonist d(CH2)5Tyr(Me)AVP, this corresponds to their relative efficacy in displacing 3H-AVP from high-affinity specific binding sites on rat hippocampal synaptic membranes. Ni2+ did not alter the degree of inhibition caused by the peptides. When SPM were treated with AVP after the attainment of maximum 32P incorporation, AVP inhibited dephosphorylation over a 30-min period. Our results show that AVP can alter both phosphorylation and dephosphorylation of hippocampal SPM phosphoproteins in vitro; the direction of these effects depends upon experimental conditions. Since B50/F1 is known to be a substrate for protein kinase C, AVP may act by inhibition of protein kinase C activity, either directly or indirectly.     

Contrasting patterns of protein phosphorylation in human normal and Alzheimer brain: focus on protein kinase C and protein F1/GAP-43.

We introduce a new procedure to study kinase substrates in postmortem human brain. By adding purified exogenous protein kinase C (PKC) and the phospholipid phosphatidylserine to brain homogenates in vitro we are able to analyze PKC substrates. A human 53-kDa phosphoprotein is described that appears to be homologous to rat and monkey protein F1 (GAP-43). This identity is based on molecular weight, isoelectric point, phosphorylation by exogenous protein kinase C, enhancement of its phosphorylation by three activators (phospholipids, calcium and phorbol esters), phosphopeptide maps, and cross-reactivity with an antibody raised against rat protein F1. Protein F1 is a PKC substrate associated with synaptic plasticity and nerve growth. Its phosphorylation in rat brain has been correlated with long-term potentiation, an electrophysiological model of memory. In the present study of normal brain, human protein F1 shows an occipitotemporal in vitro phosphorylation gradient. This is consistent with previous observations in nonhuman primates. This gradient is less pronounced in Alzheimer's disease (AD). Changes in the in vitro phosphorylation pattern of three other non-PKC substrates in Alzheimer's disease, including one with characteristics similar to microtubule-associated protein tau, are also reported. These results suggest that protein phosphorylation can be studied in postmortem human brain and that PKC-mediated phosphorylation of protein F1, already linked to synaptic plasticity and memory, may be altered in AD.     

Identification of protein phosphatase 1 in synaptic junctions: dephosphorylation of endogenous calmodulin-dependent kinase II and synapse-enriched phosphoproteins

A calcium/calmodulin-dependent protein kinase termed CaM-kinase II is a major component of synaptic junctions from forebrain and constitutes approximately 12% of total synaptic junction protein. CaM-kinase II phosphorylates at least seven polypeptides that are enriched in synaptic junctions, of which two represent the 50- and 60-kilodalton subunits of the protein kinase. In this report the nature of endogenous protein phosphatases which dephosphorylate each of the seven synaptic junction phosphoproteins was examined. Assays of synaptic junctions and other subcellular fractions from rat forebrain for type-1 and type-2 protein phosphatases revealed that protein phosphatase 1 (PrP-1) was specifically enriched in synaptic junctions with respect to cytosolic fractions. The activity of type-2 protein phosphatases was very low in synaptic junctions. Homogeneous PrP-1 from rabbit skeletal muscle was found to dephosphorylate each of the seven phosphoproteins in synaptic junctions. Inhibitors-1 and -2 were found to inhibit endogenous protein phosphatase activity by 70 to 80%. Since inhibitors-1 and -2 are specific inhibitors of PrP-1, these results indicate that this enzyme accounts for the majority of endogenous protein phosphatase activity in synaptic junctions. Approximately 15% of the protein phosphatase activity in synaptic junctions was type 2A, whereas PrP-2B and PrP-2C accounted for little, if any, of the activity toward endogenous or exogenous phosphoproteins. These results indicate that PrP-1 may be important in controlling the state of phosphorylation of synaptic junction proteins.     

Presynaptic localization of B-50 phosphoprotein: the (ACTH)-sensitive protein kinase substrate involved in rat brain polyphosphoinositide metabolism

This study describes the ultrastructural localization in rat hippocampal tissue in situ and in isolated synaptosomes of the brain-specific phosphoprotein B-50, using affinity purified anti-B-50 immunoglobulins (IgGs). Evidence is presented for the presynaptic localization of B-50 in rat brain. Given this specific localization a model is presented outlining the presumed function of the B-50 protein in the membrane and describing possible neuromodulation by adrenocorticotropin hormone (ACTH)-like peptides.     

Neurogranin: immunocytochemical localization of a brain-specific protein kinase C substrate

The developmental expression and the cellular localization of neurogranin (formerly designated p17), a brain-specific protein kinase C (PKC) substrate, were investigated. The developmental expression of neurogranin was studied by immunoblotting of rat brain and neuronal cell-culture extracts using neurogranin polyclonal antibodies. Neurogranin synthesis was found to be developmentally regulated, with no expression in the embryonic and neonatal period and an abrupt increase between 2 and 3 weeks of age. By immunohistochemistry, neurogranin was found essentially in the adult rat telencephalon, specifically located in the cell bodies and dendritic processes of neurons of the cerebral cortex, hippocampus, striatum, and a few other discreet areas. Neurogranin immunoreactivity was nearly absent in the thalamus, cerebellum, and brain stem. The late developmental expression and the dendritic localization of neurogranin in neurons are 2 features that also characterize the type I PKC isozyme. The specific localization of the protein in integrative areas of the rat brain suggests a highly specialized function of neurogranin in the CNS. A possible role for neurogranin in the transduction of the PKC activation signals at the postsynaptic level is suggested.     

Comparative distribution of myristoylated alanine-rich C kinase substrate (MARCKS) and F1/GAP-43 gene expression in the adult rat brain

Myristoylated alanine-rich C-kinase substrate (MARCKS) and F1/GAP-43 (B-50/neuromodulin) are both major specific substrates for protein kinase C (PKC) and appear to play an important role in the regulation of neuroplastic events during development and in the adult brain. Since PKC isozymes are differentially expressed in brain and the expression of F1/GAP-43 and MARCKS mRNAs are differentially regulated by PKC through posttranslational mechanisms, the present study examined the relative distribution of both mRNAs in the adult rat brain by using in situ hybridization histochemistry. MARCKS hybridization was most pronounced in the olfactory bulb, piriform cortex (layer II), medial habenular nucleus, subregions of the amygdala, specific hypothalamic nuclei, hippocampal granule cells, neocortex, and cerebellar cortex, intermediate in the superior colliculus, hippocampal CA1, and certain brainstem nuclei including the locus coeruleus, and low-absent in regions of the caudate-putamen, geniculate nuclei, thalamic nuclei, lateral habenular nucleus, and hippocampal CA3 pyramidal and hilar neurons. Consistent with previous reports, prominent F1/GAP-43 hybridization was observed in neocortex, medial geniculate, piriform cortex (layer II), substantia nigra pars compacta, hippocampal CA3 pyramidal cells, thalamic and hypothalamic nuclei, lateral habenular nucleus, locus coeruleus, raphe nuclei, and cerebellar granule cells, intermediate in regions of the thalamus, hypothalamus, and amygdala, and low-absent in regions of the olfactory bulb, caudate-putamen, medial habenular nucleus, hippocampal granule cells, and superior colliculus. Overall, F1/GAP-43 was highly expressed in a greater number of regions compared to MARCKS and, in a number of regions, including the hippocampus, habenular complex, ventral tegmentum, geniculate, and certain brain stem nuclei, a striking inverse pattern of expression was observed. These results indicate that MARCKS gene expression, like that of F1/GAP-43, remains elevated in select regions of the adult rat brain which are associated with a high degree of retained plasticity. The potential role of PKC in the regulation of MARCKS and F1/GAP-43 gene expression in brain is assessed. J. Comp. Neurol. 379:48-71, 1997. © 1997 Wiley-Liss, Inc.     

Intra-spaced stimulation and protein phosphatase 1 dictate the direction of synaptic plasticity

Changes in the strength of synapses in the hippocampus that occur with long-term potentiation (LTP) or long-term depression (LTD) are thought to underlie the cellular basis of learning and memory. Memory formation is known to be regulated by spacing intervals between training episodes. Using paired whole-cell recordings to record from synapses connecting two CA3 pyramidal neurons, we now show that stimulation frequency and spacing between LTP and LTD induction protocols alter the expression of synaptic plasticity. These effects were found to be dependent on protein phosphatase 1 (PP1), an essential protein serine/threonine phosphatase involved in synaptic plasticity, learning and memory. We also show for the first time that PP1 not only regulates the expression of synaptic plasticity, but also has the ability to depress synaptic transmission at basal activity levels. Moreover, PP1 can sort two consecutive messages received by the postsynaptic neuron and control the direction of change in synaptic strength. This study highlights new roles of PP1 in regulating timing-dependent constraints on the expression of synaptic plasticity that may correlate with memory processes, and together PP1 and the spacing of stimulation protocols provide mechanisms to regulate the expression of synaptic plasticity at CNS synapses.