Protein Phosphatase-Mediated Regulation of Protein Kinase C during Long-Term Depression in the Adult Hippocampus In Vivo

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The Journal of Neuroscience, October 1, 2000, 20(19):7199-7207

Protein Phosphatase-Mediated Regulation of Protein Kinase C during Long-Term Depression in the Adult Hippocampus In Vivo
Edda Thiels, Beatriz I. Kanterewicz, Lauren T. Knapp, German Barrionuevo, and Eric Klann
Department of Neuroscience and Center for the Neural Basis of Cognition, University of Pittsburgh, Pittsburgh, Pennsylvania 15260

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The neural substrates of learning and memory are thought to involve use-dependent long-term changes in synaptic function,including long-term depression (LTD) of synaptic strength. Onebiochemical event hypothesized to contribute to the maintenanceand expression of LTD is decreased protein phosphorylation, causedby a decrease in protein kinase activity and/or an increase inprotein phosphatase activity. We tested whether the activity ofprotein kinase C (PKC) decreases after the induction of LTD inarea CA1 of the adult hippocampus in vivo, and then investigatedthe mechanism responsible for the LTD-associated alteration inPKC activity. We found that LTD was associated with a significantdecrease in both autonomous and cofactor-dependent PKC activity.The decrease in PKC activity was prevented by NMDA receptor blockadeand was not accompanied by a decrease in the level of either PKC $alpha$ , $beta$ , $gamma$ , or $zeta$ . Western blot analysis with phosphospecific antibodiesrevealed that phosphorylation of Ser-657 on the catalytic domainof PKC $alpha$ (Ser-660 on PKC $beta$ II) was decreased significantly afterthe induction of LTD, and that this dephosphorylation was preventedby the protein phosphatase inhibitor okadaic acid. The decreasein autonomous and cofactor-dependent PKC activity likewise wasprevented by okadaic acid. These findings suggest that LTD inthe adult hippocampus in vivo involves a decrease in PKC activitythat is mediated, at least in part, by dephosphorylation of thecatalytic domain of PKC by protein phosphatases activated afterLTD-inducing stimulation. Our findings are consistent with theidea that protein dephosphorylation contributes to the expressionofLTD.

Key words: long-term depression; protein kinase C; protein phosphatase; dephosphorylation; area CA1; learning and memory

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The neural substrates of information processing and storage most likely involve activity-dependent long-term changes in synapticstrength. Two forms of synaptic plasticity induced by patternedactivity in the afferent pathway and considered widely as modelsof learning and memory are long-term potentiation (LTP) and long-termdepression (LTD) of synaptic strength (Bliss and Collingridge,1993; Malenka, 1994; Martin et al., 2000). A critical elementin the events hypothesized to underlie the induction and earlyexpression of LTP and LTD is modification of protein phosphorylation(Bear and Malenka, 1994; Lisman, 1994; Schulman, 1994; Robersonet al., 1996). Specifically, LTP is thought to involve increasedprotein phosphorylation, an idea that is supported by findingsof (1) increased protein kinase activity during LTP in hippocampus(Charriaut-Marlangue et al., 1991; Fukunaga et al., 1993; Klannet al., 1993), a forebrain structure demonstrated to play a criticalrole in memory function (Squire, 1992), (2) increased glutamatereceptor phosphorylation in association with hippocampal LTP (Barriaet al., 1997; Lee et al., 2000), (3) blockade of the inductionand/or expression of hippocampal LTP by inhibition of basal proteinkinase activity (Malinow et al., 1988, 1989; Malenka et al., 1989),and (4) alterations of LTP in hippocampus of mice deficient forone of various protein kinase genes (c.f., Chen and Tonegawa,1997).

LTD, on the other hand, is thought to involve decreased protein phosphorylation, an idea supported by findings of (1) increasedprotein phosphatase activity during LTD in hippocampus (Thielset al., 1998), (2) decreased glutamate receptor phosphorylationin association with hippocampal LTD (Lee et al., 1998, 2000),and (3) blockade of the induction and/or expression of hippocampalLTD by inhibition of protein phosphatase activity (Mulkey et al.,1993, 1994). Interestingly, the protein phosphatases whose activitywas found to be increased during LTD, protein phosphatase 1 (PP1)and protein phosphatase 2A (PP2A) (Thiels et al., 1998), havebeen shown to dephosphorylate and regulate the activity of variousprotein kinases, including of protein kinases implicated in synapticplasticity (Anderson et al., 1990; Dutil et al., 1994; Stracket al., 1997). Reduction of protein kinase activity caused bymodification by protein phosphatases activated after LTD-inducingstimulation could contribute to and amplify proteindephosphorylation.

One of the protein kinases targeted by PP1 and PP2A and shown to play a role in synaptic plasticity is protein kinase C (PKC)(c.f., Roberson et al., 1996). Of particular relevance to theregulation of PKC during LTD are findings of proteolytic degradationof a permanently active isoform of PKC, PKM $zeta$ , after the inductionof LTD in the immature hippocampus in vitro (Hrabetova and Sacktor,1996). Our previous observations of an LTD-associated increasein PP1 and PP2A activity (Thiels et al., 1998), together withevidence for PKC regulation by these phosphatases (Dutil et al.,1994; Keranen et al., 1995; Bornancin and Parker, 1996, 1997;Lee et al., 1996; Sweatt et al., 1998) prompted us to investigatewhether LTD in the adult hippocampus in vivo is associated witha change in PKC activity, and if so, whether the change in PKCactivity results from dephosphorylation and/or proteolytic degradationof thekinase.

We herein report that LTD in the adult hippocampus in vivo is accompanied by a decrease in autonomous and cofactor-dependentPKC activity but not by a reduction in the level of either PKC $alpha$ , $beta$ , $gamma$ , or $zeta$ . Additional experiments revealed an LTD-associateddecrease in phosphorylation at Ser-657, an autophosphorylationsite on the C terminus of PKC $alpha$ (Ser-660 on PKC $beta$ II). The LTD-associateddecrease in autonomous and cofactor-dependent PKC activity aswell as in phosphorylation at the autophosphorylation site wereblocked by inhibition of okadaic acid (OA)-sensitive protein phosphatases.Taken together, these findings suggest that LTD in the adult hippocampusin vivo involves a decrease in PKC activity that is mediated,at least in part, by dephosphorylation of the catalytic domainof PKC by serine/threonine protein phosphatases activated afterLTD-inducingstimulation.

Some of the electrophysiological results have been reported previously (Norman et al. 2000).

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Electrophysiology. Electrophysiological methods described previously (Thiels et al., 1994) were used for recordings from thehippocampus of anesthetized adult rats (Sprague Dawley, 250-350gm). Briefly, field responses evoked by stimulation pulses (20-500µA; 100 µsec duration) delivered to the dorsal commissural pathwaywere recorded in either st. pyramidale or st. radiatum of areaCA1 of the right dorsal hippocampus. Series of 10 test pulses(0.1 Hz) were delivered at 5-10 min intervals before and afterpaired-pulse stimulation, which consisted of three trains of 200pairs of pulses with an interstimulus interval of 25 msec, aninterpair interval of 2 sec, and an intertrain interval of 15min. The stimulation intensity for test and train pulses was setto produce a CA1 population spike amplitude ~40% of maximum amplitude,as determined before the first series of test pulses. In someexperiments, either D-2-amino-5-phosphonovaleric acid (D-APV;100 µM, dissolved in 150 mM NaCl) or OA (5-10 µM, dissolved in0.1% dimethylsulfoxide) was administered by continuous pressure-ejectionfrom a micropipette placed near the recording electrode in st.radiatum. Recorded waveforms were amplified, filtered (0.1-10kHz), digitized (10 kHz), and stored on computer disk for lateranalysis of the amplitude of the CA1 population spike or the initialslope (1.0 msec after onset) of the populationEPSP.

To determine PKC activity at various times after the induction of LTD, animals were killed either 5, 35, or 65 min after terminationof the third train of paired-pulse stimulation, and their righthippocampus was dissected out in the presence of cooled artificialCSF (in mM: 124 NaCl, 5 KCl, 1.25 NaH₂PO₄, 26 NaHCO₃, 10 dextrose,1.5 MgCl₂, and 2.5 CaCl₂). A block of area CA1 (~1 mm³) was excised from each the dorsal and the ventral portion ofthe hippocampus and placed in individual, coded vials on dry ice,which then were stored at $-$ 70°C until biochemicalanalysis.

PKC assays. Tissue samples were homogenized in ice-cold buffer [50 mM Tris-HCl, pH 7.4, 1 mM EGTA, 1 mM EDTA, 10 µM benzamidine,aprotinin (100 ng/ml), leupeptin (250 ng/ml), 2 mM sodium pyrophosphate,4 mM p-nitrophenylphosphate, and 1 mM sodium orthovanadate]. Proteinconcentrations in homogenates were determined using the methodof Bradford (1976). Reaction mixtures (final volume, 50 µl) contained5 µl of homogenate, 20 mM Tris-HCl, pH 7.4, 10 mM MgCl₂, 2 mMsodium pyrophosphate, leupeptin (25 µg/ml), 10 µM of the specificPKC substrate NG_(28-43), and 100 µM [ $gamma$ -³²P]ATP. Assays were conducted in the presence of either EGTA (finalconcentration, 2.5 mM) for the determination of autonomous activityor Ca²⁺ (100 µM in the presence of 500 µM EGTA) and lipid cofactors (finalconcentrations: phosphatidylserine, 320 µg/ml; sn-1,2-dioctanoylglycerol,30 µg/ml) for the determination of total activity. Cofactor-dependentactivity was determined by subtracting autonomous activity fromtotal activity. Reactions were performed for 2 min at 37°C. ³²P incorporation into NG_(28-43) was determined by scintillationcounting after spotting onto strips of phosphocellulose filterpaper, as described previously (Klann et al., 1993).

Electrophoresis and Western blot analyses. Tissue samples were homogenized, and protein concentrations were determined asdescribed above. Equivalent amounts of protein for each samplewere resolved by 10% SDS-PAGE, blotted electrophoretically toImmobilon membranes, and probed with a rabbit polyclonal antibodyto either PKC $alpha$ , $beta$ , $gamma$ , or $zeta$ (Life Technologies, Gaithersburg, MD),phosphoT500-PKC $beta$ II (a generous gift from Drs. A. C. Newton andJ. Johnson, University of California, San Diego, CA), phosphoT634/641-PKC $beta$ II(a generous gift from Dr. J. D. Sweatt, Baylor College of Medicine,Houston, TX), or phosphoS657-PKC $alpha$ (Upstate Biotechnology, LakePlacid, NY) (1:500-1000 final dilution in each case). The blotsthen were exposed to a goat anti-rabbit IgG-peroxidase-linkedantibody, and developed using an enhanced chemiluminescence reagent.Densitometric analysis was conducted using NIH Imagesoftware.

Statistical analyses. Unless indicated otherwise, results from assays containing homogenate of dorsal CA1 tissue (experimental)were compared with those from assays containing homogenate ofventral CA1 tissue (control) derived from the same animals withStudent's t test for matched pairs. All tests were two-tailed,with the $alpha$ -level set to $<=$ 0.05.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

LTD in area CA1 of the adult hippocampus in vivo is accompanied by a decrease in autonomous and cofactor-dependent PKC activity

To induce LTD of the commissural input to area CA1 of the hippocampus, we delivered three trains of paired-pulse stimulation(200 pairs of pulses with a 25 msec interstimulus interval at0.5 Hz per train) to the commissural fibers of anesthetized adultrats. Figure 1A illustrates that paired-pulse stimulation produceda persistent depression of both the amplitude of the CA1 populationspike (mean change from baseline 30 min after termination of thethird train ± SEM: $-$ 4.0 ± 0.3 mV, n = 12; Fig. 1Aa) and the initialslope of the CA1 population EPSP ( $-$ 0.7 ± 0.1 mV/msec, n = 6; Fig.1Ab) evoked by test pulses before and after paired-pulse stimulation.We (Thiels et al., 1994) and others (Doyère et al., 1996) showedpreviously that LTD induced by paired-pulse stimulation in theadult hippocampus lasts for hours to days.

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Figure 1. LTD in the adult hippocampus in vivo is associated with decreased autonomous and cofactor-dependent PKC activity. Aa, Group data (mean ± SEM) of the amplitude of the CA1 pyramidal cell population spike evoked by stimulation of the commissural fibers before and after delivery of three trains of paired pulses (downward arrows) to these fibers. The data are expressed as a percentage of the average population spike amplitude before paired-pulse stimulation. Animals were killed either 5 min (circles; n = 6), 35 min (squares; n = 6), or 65 min (triangles; n = 6) after termination of the third train of pairs. Inset, Average of 10 waveforms of population spikes recorded in the same animal 5 min before onset of the first train (stippled line) and 30 min after termination of the third train of pairs (solid line). Calibration: 4 mV, 5 msec. Ab, Similar group data of the initial slope of the CA1 pyramidal cell population EPSP recorded in st. radiatum before and after three trains of paired-pulse stimulation (downward arrows). All animals were killed 35 min after termination of the third train of pairs (n = 6). Inset, Averaged waveforms of population EPSPs recorded before and after paired-pulse stimulation, as described above (calibration as above). Ba, Group data (mean ± SEM) of autonomous PKC activity in either ventral area CA1 homogenates (control; open bars) or dorsal area CA1 homogenates (baseline, striped bar; LTD, filled bars) for animals killed either 5 min after termination of baseline recording (base line; n = 6) or either 5 min (n = 6), 35 min (n = 12), or 65 min (n = 6) after termination of the final LTD-inducing train. Bb, Similar group data of cofactor-dependent PKC activity with the respective area CA1 homogenates. Asterisk indicates significant difference between control and LTD samples at the indicated time points (Student's t test for matched samples; *p < 0.05, **p < 0.01).

To examine whether LTD was accompanied by an alteration in PKC activity, we determined ³²P incorporation into NG_(28-43), an exogenous PKC substrate,in assays containing homogenates of tissue blocks excised fromdorsal area CA1 near the recording site either 5, 35, or 65 minafter termination of the third train of paired-pulse stimulation.³²P incorporation into NG_(28-43) in assays containing dorsalCA1 homogenates was compared to that of assays containing homogenateof ventral area CA1 excised from the same animals at the sametime (control homogenate). Ventral area CA1 is a cell field verysimilar to dorsal area CA1 with the important difference, however,that it is not innervated by the dorsal commissural pathway stimulatedin these experiments (Laurberg, 1979; Ishizuka et al., 1990).Figure 1B shows that PKC activity, as measured in terms of ³²P incorporation into NG_(28-43), was 25-40% lower for assayswith dorsal CA1 homogenate (LTD) compared to assays with ventralCA1 homogenate (control) after the induction of LTD. This effectwas observed with respect to autonomous PKC activity, i.e., enzymeactivity measured in the absence of exogenously applied cofactors(Fig. 1Ba), as well as cofactor-dependent PKC activity measuredin the presence of the cofactors diacylglycerol, Ca²⁺, and phosphotidylserine (Fig. 1Bb). The decrease in PKC activitywas present within 5 min after the final LTD-inducing stimulation(for both autonomous and cofactor-dependent activity, controlvs LTD, n = 6, p < 0.05) and lasted >35 min but <65 min afterthe final LTD-inducing stimulation (35 min after the third train:both n values = 12, both P values < 0.01; 65 min after the thirdtrain: both n values = 6, both P values > 0.1). Control experiments,also shown in Figure 1B, revealed that autonomous and cofactor-dependentPKC activity did not differ between dorsal and ventral area CA1before LTD-inducing stimulation, i.e., at the end of recordingof baseline responses (both n values = 6, both P values > 0.1).Collectively, these findings suggest that LTD in the adult hippocampusin vivo is accompanied by a transient decrease in PKC activitybelow baselinelevels.

We previously demonstrated that induction of LTD by paired-pulse stimulation requires activation of the NMDA receptor (Thielset al., 1994). Delivery of paired-pulse stimulation in the presenceof the specific NMDA receptor antagonist, D-APV, therefore enabledus to test the potential confound that the decrease in PKC activityresulted from patterned stimulation alone. Figure 2A shows thatthree trains of paired-pulse stimulation failed to induce LTDwhen NMDA receptors near the recording site were blocked (changefrom baseline in the amplitude of the evoked population spike5 min after the second train of pairs in the presence of D-APV:0.5 ± 0.2 mV, n = 5, vs in the absence of D-APV: $-$ 3.4 ± 0.2 mV,n = 6; t test for independent groups, p < 0.01). Figure 2B showsthat the decrease in both autonomous and cofactor-dependent PKCactivity observed immediately after paired-pulse stimulation inthe absence of NMDA receptor blockade (Fig. 1B) failed to occurwhen NMDA receptors were blocked (Fig. 2Ba: autonomous PKC activity,n = 5, p > 0.1; Fig. 2Bb: cofactor-dependent PKC activity, n =5, p > 0.1). These findings demonstrate that repeated paired-pulsestimulation alone is not sufficient to cause a significant decreasein PKC activity. Taken together with the findings reported inFigure 1, our observations indicate that NMDA receptor activationsufficient to induce LTD is necessary for a decrease in PKC activityafter paired-pulse stimulation.

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Figure 2. Blockade of the NMDA receptor prevents the induction of LTD as well as the associated decrease in autonomous and cofactor-dependent PKC activity. A, Group data (mean ± SEM) of the amplitude of the evoked CA1 population spike recorded before and after three trains of paired-pulse stimulation (downward arrows) during continuous administration of the specific NMDA receptor antagonist D-APV (100 µM in the drug pipette; closed circles, n = 5). For purposes of comparison, the effect of paired-pulse stimulation in the absence of D-APV is depicted as well (open circles, n = 6; data are taken from Fig. 1Aa). B, Group data (mean ± SEM) of autonomous PKC activity (a) and cofactor-dependent PKC activity (b) in ventral (open bars) and dorsal (filled bars) area CA1 homogenates for animals who received paired-pulse stimulation in the presence of D-APV and were killed 5 min after termination of the third train of pairs (n = 5).

LTD in the adult hippocampus in vivo is not associated with a loss of either PKC $alpha$ , $beta$ , $gamma$ , or $zeta$

The observed decrease in cofactor-dependent PKC activity suggests that LTD in the adult hippocampus in vivo is associatedwith either a loss of mature enzyme or a posttranslational modificationof the enzyme that renders it less able to become catalyticallycompetent. To test the possibility of an LTD-associated reductionof enzyme level, we compared the level of either PKC $alpha$ , $beta$ , $gamma$ , or $zeta$ in dorsal area CA1 to that in ventral area CA1 both before paired-pulsestimulation (baseline) and 5 min after the third train of LTD-inducingstimulation using specific antibodies against the respective isozymes.As illustrated in Figure 3, there was no significant differencein isozyme immunoreactivity between assays containing homogenateof dorsal versus ventral area CA1 during baseline or after theinduction of LTD with respect to PKC $alpha$ (Fig. 3a; both n values= 6; p > 0.1 and p > 0.05 for baseline and 5 min after LTD induction,respectively), PKC $gamma$ (Fig. 3c; both n values = 8; both P values> 0.1), or PKC $zeta$ (Fig. 3d; both n values = 8, both P values > 0.1).Because of previous observations of a delayed effect on the levelof persistently active PKC $zeta$ , PKM $zeta$ , during LTD in immature hippocampusin vitro (Hrabetova and Sacktor, 1996), we also compared PKC $zeta$ immunoreactivity between assays with homogenate from dorsal versusventral area CA1 excised 35 min after LTD induction. However,similar to the results observed immediately after LTD induction,there was no significant difference in PKC $zeta$ immunoreactivity fortissue collected at the later time point (immunoreactivity fordorsal area CA1, expressed as a percentage of control, 100 ± 4%,n = 6, p > 0.1). PKC $beta$ immunoreactivity did not differ betweenassays with dorsal versus ventral area CA1 homogenate during baseline(Fig. 3b; n = 6; p > 0.1) but, surprisingly, was increased significantlyin assays containing dorsal CA1 homogenate compared to those containingventral area CA1 homogenate after the induction of LTD (Fig. 3b;n = 6; p < 0.05). Control experiments with APV administrationduring paired-pulse stimulation, similar to those described above,revealed that the observed increase of PKC $beta$ did not depend onprior induction of LTD but developed after patterned stimulationin the absence of LTD induction (immunoreactivity for dorsal areaCA1, expressed as a percentage of control, 130 ± 12%; n = 4; p< 0.05).

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Figure 3. LTD in the adult hippocampus in vivo is not associated with a loss of either PKC $alpha$ , $beta$ , $gamma$ , or $zeta$ . A, Group data (mean ± SEM) of PKC $alpha$ immunoreactivity from dorsal area CA1 homogenate (baseline, striped bar; LTD, filled bar), expressed as a percentage of PKC $alpha$ immunoreactivity from ventral area CA1 homogenate (control; open bars), either 5 min after baseline stimulation (baseline; n = 6) or 5 min after termination of the final LTD-inducing stimulation (5 min; n = 6). The amplitude of the evoked CA1 population spike recorded shortly before the third LTD-inducing stimulation was, on average, 52 ± 9% of baseline level. Representative Western blots of PKC $alpha$ for ventral (V) and dorsal (D) area CA1 homog enate for baseline and 5 min after LTD-inducing stimulation. B, Similar group data of PKC $beta$ immunoreactivity and representative Western blots (baseline, n = 6; 5 min, n = 6). The amplitude of the evoked population spike recorded shortly before the third LTD-inducing stimulation was, on average, 52 ± 9% of baseline level. Asterisk indicates significant difference between control and LTD samples at the indicated time point (Student's t test for matched samples; *p < 0.05). C, Similar group data of PKC $gamma$ immunoreactivity and representative Western blots (baseline, n = 8; 5 min, n = 8). The amplitude of the evoked population spike recorded shortly before the third LTD-inducing stimulation was, on average, 42 ± 5% of baseline level. D, Similar group data of PKC $zeta$ immunoreactivity and representative Western blots (baseline, n = 8; 5 min, n = 8). The amplitude of the evoked population spike recorded shortly before the third LTD-inducing stimulation was, on average, 42 ± 5% of baseline level.

To test further the possibility that the observed decrease in PKC activity resulted from loss of enzyme, we compared the levelof the catalytic fragment of either PKC $alpha$ or $beta$ , the only two isozymeswhose catalytic fragment was clearly recognizable by the antibody,between dorsal and ventral area CA1 before and after LTD induction.We found no systematic differences in immunoreactivity betweenassays with dorsal and ventral area CA1 homogenate either beforeor after LTD induction (immunoreactivity in dorsal area CA1, expressedas a percentage of control, for PKC $alpha$ : baseline = 85 ± 8%, n =6, p > 0.1; 5 min after final stimulation train = 97 ± 13%, n= 6, p > 0.1; for PKC $beta$ : baseline = 87 ± 6%, n = 6, p > 0.1; 5min after final stimulation train = 93 ± 9%, n = 6, p > 0.1).Collectively, these findings do not support the idea that thedecrease in cofactor-dependent (and autonomous) PKC activity observedin association with LTD in the adult hippocampus in vivo resultsfrom decreased synthesis and/or increased proteolysis of one orseveral PKCisozymes.

LTD in the adult hippocampus in vivo is associated with a protein phosphatase-mediated reduction of phosphorylation at C-terminal autophosphorylation sites of PKC

An alternative explanation for the decrease in both types of PKC activity is dephosphorylation of the catalytic domain ofPKC by protein phosphatases. To address this possibility, we focusedon the transphosphorylation site Thr-500 on PKC $beta$ II (Thr-497 onPKC $alpha$ ) and the autophosphorylation sites Thr-634/Thr-641 on PKC $alpha$ / $beta$ IIand Ser-657 on PKC $alpha$ (Ser-660 on PKC $beta$ II). The transphosphorylationsite is located on the activation loop of the enzyme, and itsphosphorylation is required for maturation to the cofactor-sensitive,catalytically competent state (Orr and Newton, 1994; Bornancinand Parker, 1997). Both autophosphorylation sites are locatedon the C terminus, and their phosphorylation plays a criticalrole in the enzymatic function of PKC, although their relativeimportance to PKC activity is controversial (Dutil et al., 1994;Zhang et al., 1994; Keranen et al., 1995; Bornancin and Parker,1996, 1997; Gysin and Imber, 1996; Sweatt et al., 1998; Edwardset al., 1999). Using antibodies that selectively recognize PKC $beta$ IIwhen phosphorylated at Thr-500, PKC $alpha$ and $beta$ II when phosphorylatedat Thr-634/Thr-641, and PKC $alpha$ when phosphorylated at Ser-657, wecompared immunoreactivity in assays with dorsal versus ventralarea CA1 homogenate before paired-pulse stimulation and at varioustimes after termination of the final LTD-inducing stimulation.Figure 4 illustrates that there was no systematic difference betweendorsal and ventral area CA1 before LTD induction with respectto phosphorylation of Thr-500 (Fig. 4A; n = 6; p > 0.1), Thr-634/Thr-641on PKC $alpha$ / $beta$ II (Fig. 4B; n = 4; p > 0.1), or Ser-657 on PKC $alpha$ (Fig.4C; n = 6; p > 0.1). Five minutes after the induction of LTD,the phosphorylation level at the transphosphorylation site wasunchanged, relative to control levels (Fig. 4A; n = 6; p > 0.1),whereas at both autophosphorylation sites it was reduced, as indicatedby relatively lower immunoreactivity in assays with dorsal comparedto ventral area CA1 homogenate. With respect to Thr-634/Thr-641on PKC $alpha$ / $beta$ II, the reduction in phosphorylation level, albeit aclear trend immediately after LTD induction, failed to reach statisticalsignificance either 5 or 35 min after LTD induction (Fig, 4B;5 min after the final LTD-inducing stimulation: n = 6, 0.1 > p> 0.05; 35 min after the third stimulation train: n = 7, p > 0.1).However, with respect to Ser-657 on PKC $alpha$ , the reduction in phosphorylationlevel was pronounced and lasted at least 35 min after the finalLTD-inducing stimulation (Fig. 4C; 5 min after the third stimulationtrain: n = 6, p < 0.01; 35 min after the third train: n = 8, p< 0.01). Control experiments with APV administration during paired-pulsestimulation, similar to those described above, revealed that thedephosphorylation of the Ser-657 autophosphorylation site requiredprior induction of NMDA receptor-dependent LTD, because the differencein immunoreactivity in assays with dorsal versus ventral areaCA1 homogenates was abolished in experiments with the NMDA receptorantagonist (phosphoSer-657 immunoreactivity for dorsal area CA1,expressed as a percentage of control and corrected by total PKC $alpha$ ,99 ± 5%, n = 4, p > 0.1). Taken together, these findings suggestthat LTD in the adult hippocampus in vivo is accompanied by dephosphorylationof the catalytic domain of PKC, with the specific dephosphorylationtarget identified here being the Ser-657 autophosphorylation siteon the C terminus of PKC $alpha$ .

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Figure 4. LTD in the adult hippocampus in vivo is accompanied by a decrease in phosphorylation at Ser-657 on the C terminus of PKC $alpha$ . A, Group data (mean ± SEM) of phosphoT500-PKC $beta$ II immunoreactivity from dorsal area CA1 homogenate (baseline, striped bar; LTD, filled bar), expressed as a percentage of phosphoT500-PKC $beta$ II immunoreactivity from ventral area CA1 homogenate (control; open bars) and corrected by total PKC $beta$ , either 5 min after baseline stimulation (baseline; n = 6) or 5 min after termination of the final LTD-inducing stimulation (5 min; n = 6). The amplitude of the evoked CA1 population spike recorded shortly before the third LTD-inducing stimulation was, on average, 52 ± 9% of baseline level. Representative Western blots of phosphoT500-PKC $beta$ II and PKC $beta$ for ventral (V) and dorsal (D) area CA1 homogenate for baseline and 5 min after LTD-inducing stimulation. B, Similar group data of phosphoT634/T641-PKC $alpha$ / $beta$ II immunoreactivity and representative Western blots, except that data for 35 min after termination of the final LTD-inducing stimulation are depicted as well (baseline, n = 4; 5 min, n = 6; 35 min, n = 7). The amplitude of the evoked population spike recorded from animals in the 5 min group shortly before the third LTD-inducing stimulation was, on average, 47 ± 4% of baseline level; the amplitude of the evoked population spike recorded from animals in the 35 min group 30 min after the final LTD-inducing stimulation was, on average, 16 ± 10% of baseline level (n = 3), and the slope of the evoked population EPSP recorded from animals in the 35 min group at that time point was, on average, 79 ± 2% of baseline level (n = 4). C, Similar group data of phosphoS657-PKC $alpha$ immunoreactivity and representative Western blots (baseline, n = 6; 5 min, n = 6; 35 min, n = 8). The amplitude of the evoked population spike recorded from animals in the 5 min group shortly before the third LTD-inducing stimulation was, on average, 52 ± 9% of baseline level; the amplitude of the evoked population spike recorded from animals in the 35 min group 30 min after the final LTD-inducing stimulation was, on average, 16 ± 10% of baseline level (n = 3), and the slope of the evoked population EPSP recorded from animals in the 35 min group at that time point was, on average, 74 ± 2% of baseline level (n = 5). Asterisk indicates significant difference between control and LTD samples at the indicated time point (Student's t test for matched samples; **p < 0.01).

Previous studies showed that PKC activity (Dutil et al., 1994; Bornancin and Parker, 1996, 1997; Lee et al., 1996; Sweattet al., 1998) as well as phosphorylation at Ser-657 on PKC $alpha$ (Bornancinand Parker, 1997) are regulated negatively by PP1 and/or PP2A,protein phosphatases whose activity is increased after the inductionof LTD (Thiels et al., 1998). We therefore tested whether theLTD-associated decrease in autonomous and cofactor-dependent PKCactivity and dephosphorylation of Ser-657 on PKC $alpha$ could be blockedby the serine/threonine protein phosphatase inhibitor, okadaicacid. To that end, we delivered three trains of paired-pulse stimulationin the presence of okadaic acid (5-10 µM in the drug pipette)and then analyzed the tissue for both ³²P incorporation into NG_(28-43) and immunoreactivity to thephosphospecific antibody. Figure 5A illustrates that LTD was attenuatedmarkedly when paired-pulse stimulation was delivered in the presenceof the phosphatase inhibitor (change from baseline in the amplitudeof the evoked population spike 5 min after the second train ofpairs in the presence of okadaic acid: $-$ 0.8 ± 0.3 mV, n = 7, vsin the absence of okadaic acid: $-$ 3.4 ± 0.2 mV, n = 6; t test forindependent groups, p < 0.01). The effect of okadaic acid on LTD-associatedchanges in PKC activity are depicted in Figure 5B. Part a showsthat there was no difference in autonomous PKC activity betweenassays with dorsal versus ventral CA1 homogenate either beforeor after paired-pulse stimulation in the presence of okadaic acid(baseline, n = 4, p > 0.1; 5 min after the final stimulation train,n = 7, p > 0.1). Part b shows that there was a trend for cofactor-dependentPKC activity to be higher in assays with dorsal CA1 homogenatecompared to those with ventral CA1 homogenate both before andafter paired-pulse stimulation in the presence of okadaic acid(baseline, n = 4, 0.1 > p > 0.05; 5 min after the final stimulationtrain, n = 7, p < 0.05). Thus, the LTD-associated decrease inautonomous PKC activity (Fig. 1Ba) and that in cofactor-dependentPKC activity (Fig. 1Bb) both were abolished when okadaic acid-sensitiveprotein phosphatases were inhibited. The higher level of cofactor-dependentPKC activity in homogenate of dorsal area CA1, the site of okadaicacid administration, is likely to reflect higher levels of catalyticallycompetent PKC in the presence of the phosphatase inhibitor. Consistentwith this suggestion, probing the same homogenates with the anti-PKC $alpha$ antibody revealed slightly but systematically stronger immunoreactivityin assays with dorsal versus ventral area CA1 homogenate (dorsal,as a percentage of ventral; baseline: 137 ± 14%, n = 5, p < 0.05;5 min after the third stimulation train: 134 ± 6%, n = 7, p <0.01). The effect of okadaic acid on phosphorylation at Ser-657on PKC $alpha$ is depicted in Figure 5C. In the presence of okadaic acid,phosphorylation at this site was indistinguishable between assayswith dorsal versus ventral area CA1 homogenate both before andafter paired-pulse stimulation (baseline, n = 5, p > 0.1; 5 minafter the third stimulation train, n = 7, p > 0.1). Thus, similarto the pattern observed with respect to PKC activity, the LTD-associateddecrease in phosphorylation at Ser-657 on PKC $alpha$ (Fig. 4C) was abolishedcompletely when okadaic acid-sensitive protein phosphatases wereinhibited. Collectively, these findings indicate that increasedactivity of okadaic acid-sensitive protein phosphatases followingthe induction of LTD was responsible for both the decrease inphosphorylation at Ser-657 on PKC $alpha$ and the decrease in PKC activityobserved after LTD induction in adult hippocampus in vivo. A summaryof all the findings is presented in Table 1.

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Figure 5. The LTD-associated decrease in PKC activity and dephosphorylation of the Ser-657 autophosphorylation site on PKC $alpha$ are blocked by okadaic acid. A, Group data (mean ± SEM) of the amplitude of the evoked CA1 population spike recorded before and after three trains of paired-pulse stimulation (downward arrows) during continuous administration of okadaic acid (5-10 µM in the drug pipette; closed triangles, n = 7), a potent inhibitor of PP1 and PP2A. For purposes of comparison, the effect of paired-pulse stimulation in the absence of okadaic acid is depicted as well (open circles, n = 6; data are taken from Fig. 1Aa). B, Group data (mean ± SEM) of autonomous PKC activity (a) and cofactor-dependent PKC activity (b) in ventral (open bars) and dorsal (striped or filled bars) area CA1 homogenates for animals who received test pulse and paired-pulse stimulation in the presence of okadaic acid and were killed either 5 min after termination of baseline recording (baseline; n = 4) or 5 min after termination of the third train of pairs (n = 7). Asterisk indicates significant difference at the indicated time point between control samples and samples that received paired-pulse stimulation in the presence of OA (Student's t test for matched samples; *p < 0.05). C, Group data (mean ± SEM) of phosphoS657-PKC $alpha$ immunoreactivity from dorsal area CA1 homogenate (baseline, striped bar; LTD, filled bar), expressed as a percentage of phosphoS657-PKC $alpha$ immunoreactivity from ventral area CA1 homogenate (control; open bars) and corrected by total PKC $alpha$ , for animals who received test pulses and paired-pulse stimulation in the presence of okadaic acid and were killed either 5 min after baseline stimulation (baseline; n = 5) or 5 min after termination of the third train of pairs (5 min; n = 7). Representative Western blots of phosphoS657-PKC $alpha$ and PKC $alpha$ for ventral (V) and dorsal (D) area CA1 homogenate for baseline and 5 min after LTD-inducing stimulation.


View this table:
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Table 1. Summary of the electrophysiological and biochemical changes produced by LTD-inducing stimulation

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We examined the regulation of PKC activity during NMDA receptor-dependent LTD in area CA1 of the adult hippocampus in vivo.We found that autonomous PKC activity is reduced below basal levelsfor a period of 30-60 min after the final LTD-inducing stimulation.These findings are consistent with a previous report of reducedPKC activity during NMDA receptor-dependent LTD in area CA1 ofhippocampal slices from young animals (Hrabetova and Sacktor,1996). They also are consistent with a previous report that NMDAreceptor-dependent LTD is not affected by a PKC inhibitor (Olietet al., 1997; Nicoll et al., 1998). Interestingly, in that latterstudy it was found that metabotropic glutamate and GABA_A receptor-dependentLTD in area CA1 of hippocampal slices from young animals is blockedduring inhibition of PKC activity (Oliet et al., 1997), whichsuggests that this form of LTD involves an increase in PKC activity.Although the form of LTD studied here is GABA_A receptor-dependentas well (Thiels et al., 1994), the biochemical cascade that underliesGABA_A receptor-dependent LTD in the adult hippocampus in vivodoes not appear to resemble that of GABA_A receptor-dependent LTDinduced by prolonged low-frequency stimulation in hippocampalslices of preweaning-agedanimals.

In addition to the change in autonomous PKC activity, we observed an LTD-associated decrease in cofactor-dependent PKC activitywhose time course paralleled that of autonomous PKC activity.The change in cofactor-dependent activity suggested that duringLTD either PKC synthesis is decreased, its degradation is increased,or its catalytic competence is corrupted. To evaluate the firsttwo possibilities, we determined whether LTD was associated witha decrease in the level of PKC $alpha$ , $beta$ , $gamma$ , or $zeta$ . We found no evidencefor reduced levels of any of these isozymes at a time after LTDinduction at which PKC activity levels were decreased significantly.Thus, the LTD-associated change in PKC activity cannot readilybe explained in terms of downregulation or accelerated degradationof the kinase. This conclusion is supported further by our observedlack of an LTD effect on the level of the catalytic fragmentsof PKC $alpha$ or $beta$ . These results are not consistent with findings ofa significant, proteolysis-mediated decrease in PKC $gamma$ and PKM $zeta$ after the induction of LTD in area CA1 of hippocampal slices frompreweaning-aged rats (Hrabetova and Sacktor, 1996). This inconsistencyin outcome raises the interesting possibility of a developmentalchange in the regulation of PKC during synaptic plasticity. Alternatively,the type of LTD studied here, which was induced with paired-pulsestimulation, may differ from the type studied in the slice preparation,which was induced with prolonged low-frequency stimulation. Whereasblockade of GABA_A receptors prevents LTD induced by paired-pulsestimulation (Thiels et al., 1994), it does not affect or facilitateLTD induced by low-frequency stimulation (Wagner and Alger, 1995).

To evaluate the possibility that the observed reduction in PKC activity stems from a posttranslational modification that rendersthe enzyme less able to become activated, we determined whetherLTD was associated with dephosphorylation of a transphosphorylationsite implicated in the maturation of PKC to catalytic competence(Cazaubon et al., 1994; Orr and Newton, 1994) and/or two autophosphorylationsites implicated in the catalytic activity of PKC (Dutil et al.,1994; Zhang et al., 1994; Keranen et al., 1995; Gysin and Imber,1996; Bornancin and Parker, 1997; Sweatt et al., 1998; Edwardset al., 1999). Although phosphorylation of Thr-500 on PKC $beta$ II (Thr-497on PKC $alpha$ ) was found to not be essential for enzymatic functionprovided that the enzyme had progressed to the state of phosphorylationat Thr-641 (Keranen et al., 1995), we considered the possibilitythat PKC newly synthesized after LTD-inducing stimulation wasdephosphorylated by PP1 and/or PP2A (Dutil et al., 1994; Keranenet al., 1995) and thereby rendered inactivatable. We found thatphosphorylation at Thr-500 on PKC $beta$ II was not affected by LTD-inducingstimulation, which suggests that maturation of PKC proceeds normallyduring LTD in the adult hippocampus in vivo.

Phosphorylation of Thr-634/Thr-641 on PKC $alpha$ / $beta$ II has been shown to be increased after the induction of LTP in area CA1 (Sweattet al., 1998), coincident with elevated autonomous PKC activityafter LTP induction (Lovinger et al., 1985; Klann et al., 1991,1993; Gianotti et al., 1992; Sacktor et al., 1993; Osten et al.,1996). Recent work provides evidence for a direct link betweenphosphorylation of this site and catalytic activity of the enzyme(Sweatt et al., 1998; Edwards et al., 1999). In the present studywe found that, in contrast to LTP, during LTD the level of phosphorylationof Thr-634/Thr-641 on PKC $alpha$ / $beta$ II was not significantly changed fromcontrol or basal levels. Nevertheless, we observed a marked reductionof autonomous PKC activity that could not readily be attributedto a loss in the amount of enzyme. Thus, in hippocampal cellsin vivo, phosphorylation at Thr-634/Thr-641 on PKC $alpha$ / $beta$ II in theabsence of phosphorylation at Ser-657 on PKC $alpha$ (Ser-660 on PKC $beta$ II)does not appear to be sufficient for catalytic activity of theenzyme.

Phosphorylation of Ser-657 on PKC $alpha$ (Ser-660 on PKC $beta$ II) has been shown to play a role in the catalytic activity (Gysin andImber, 1996; Bornancin and Parker, 1997), the affinity to cofactorsand substrate (Edwards and Newton, 1997), the subcellular localization(Keranen et al., 1995; Gysin and Imber, 1996; Feng and Hannun,1998; Edwards et al., 1999), and the stabilization and phosphataseresistance (Gysin and Imber, 1996; Bornancin and Parker, 1997;Edwards and Newton, 1997) of PKC. Consistent with observationsthat this site is subject to dephosphorylation by PP1 and PP2A(Dutil et al., 1994; Bornancin and Parker, 1997) and our previousfindings of increased PP1 and PP2A activity during LTD (Thielset al., 1998), we found LTD to be associated with a decrease inphosphorylation at Ser-657 on PKC $alpha$ . Furthermore, we found thatthe LTD-associated dephosphorylation of this autophosphorylationsite as well as the LTD-associated decreases in autonomous andcofactor-dependent PKC activity were blocked when paired-pulsestimulation was delivered during inhibition of okadaic acid-sensitiveprotein phosphatases. In light of evidence that phosphorylationat the Ser-657 (Ser-660) autophosphorylation site regulates PKCactivity (Gysin and Imber, 1996; Bornancin and Parker, 1997) aswell as substrate and cofactor affinity (Edwards and Newton, 1997),the most parsimonious explanation of the decrease in both autonomousand cofactor-dependent PKC activity during LTD is that okadaicacid-sensitive phosphatases activated upon LTD-inducing stimulation,such as PP1 and PP2A, dephosphorylate the autophosphorylationsite on the C terminus of PKC and thereby render the enzyme lessactive and less capable of becoming activated bycofactors.

An interesting question that arises from our findings concerns the identity of the proteins that experience reduced PKC-mediatedphosphorylation during LTD. Recent evidence shows that NMDA-inducedLTD in hippocampus in vitro is not associated with a decreasein phosphorylation at the major PKC phosphorylation site on theAMPA receptor (Roche et al., 1996; Lee et al., 1998), althoughit remains to be determined whether phosphorylation at this PKCsite also is unaffected during the type of LTD studied here. Anotherpossible target is the ERK signaling cascade, because recent findingssuggest that PKC regulates this kinase cascade, including ERK-mediatedphosphorylation of the transcription factor cAMP responsive element-bindingprotein, during LTP in hippocampus in vitro (Roberson et al.,1999). Finally, based on our preparation, we cannot exclude thepossibility that the observed changes in PKC activity occur presynapticallyand affect presynaptic targets, as is suggested by the recentreport of reduced phosphorylation of growth-associated protein-43during LTD in juvenile hippocampus in vitro (Ramakers et al.,1999).

In conclusion, we have demonstrated that LTD in adult hippocampus in vivo is associated with a transient decrease in PKC activitythat is mediated by okadaic acid-sensitive protein phosphatases.In light of our previous findings of increased PP1 and PP2A activityduring the same form of LTD studied here, we hypothesize thatthe protein phosphatases responsible for the alteration in PKCactivity are PP1 and/or PP2A. The reduction in PKC activity doesnot appear to result from reduced synthesis or increased proteolyticdegradation of the kinase during LTD. Rather, it likely results,at least in part, from dephosphorylation of catalytically relevantautophosphorylation sites on the C terminus of PKC. Reduced PKCactivity during LTD is likely to contribute to a net dephosphorylationeffect that is believed to underlie the expression of early-phaseLTD (Bear and Malenka, 1994; Lisman, 1994; Malenka, 1994; Schulman,1994).

  FOOTNOTES

Received Feb. 18, 2000; revised June 16, 2000; accepted July 18, 2000.

This work was supported by National Institutes of Health Grants NS36180 (E.T.), NS34007 (E.K.), and NS24288 (G.B.). We thankDr. Alexandra C. Newton for helpfulsuggestions.
Correspondence should be addressed to Edda Thiels, Department of Neuroscience, 446 Crawford Hall, University of Pittsburgh,Pittsburgh, PA 15260. E-mail: thiels{at}bns.pitt.edu.

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PNAS, September 25, 2001; 98(20): 11725 - 11730.
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