Amyloid {beta} Prevents Activation of Calcium/Calmodulin-Dependent Protein Kinase II and AMPA Receptor Phosphorylation During Hippocampal Long-Term Potentiation

doi:10.1152/jn.00485.2004

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Amyloid ${beta}$ Prevents Activation of Calcium/Calmodulin-Dependent Protein Kinase II and AMPA Receptor Phosphorylation During Hippocampal Long-Term Potentiation

Danyun Zhao, Joseph B. Watson and Cui-Wei Xie

Department of Psychiatry and Biobehavioral Sciences, David Geffen School of Medicine and Neuropsychiatric Institute, University of California, Los Angeles, California 90024

Submitted 9 May 2004; accepted in final form 10 June 2004

ABSTRACT

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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
REFERENCES

Accumulation of amyloid ${beta}$ -peptides (A ${beta}$ ) in the brain has beenlinked with memory loss in Alzheimer's disease and its animalmodels. However, the synaptic mechanism by which A ${beta}$ causes memorydeficits remains unclear. We previously showed that acute applicationof A ${beta}$ inhibited long-term potentiation (LTP) in the hippocampalperforant path via activation of calcineurin, a Ca²⁺-dependentprotein phosphatase. This study examined whether A ${beta}$ could alsoinhibit Ca²⁺/calmodulin dependent protein kinase II (CaMKII),further disrupting the dynamic balance between protein kinaseand phosphatase during synaptic plasticity. Immunoblot analysiswas conducted to measure autophosphorylation of CaMKII at Thr²⁸⁶and phosphorylation of the GluR1 subunit of AMPA receptors insingle rat hippocampal slices. A high-frequency tetanus appliedto the perforant path significantly increased CaMKII autophosphorylationand subsequent phosphorylation of GluR1 at Ser⁸³¹, a CaMKII-dependentsite, in the dentate area. Acute application of A ${beta}$ _1–42inhibited dentate LTP and associated phosphorylation processes,but was without effect on phosphorylation of GluR1 at Ser⁸⁴⁵,a protein kinase A-dependent site. These results suggest thatactivity-dependent CaMKII autophosphorylation and AMPA receptorphosphorylation are essential for dentate LTP. Disruption ofsuch mechanisms could directly contribute to A ${beta}$ -induced deficitsin hippocampal synaptic plasticity and memory.

INTRODUCTION

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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
REFERENCES

Alzheimer's disease (AD) is a neurodegenerative disease characterizedby progressive memory loss. Amyloid ${beta}$ peptides (A ${beta}$ ), the majorconstituents of senile plaques in AD brain, have long been implicatedin the pathogenesis of the disease. The exact cellular mechanismsfor A ${beta}$ action in AD, however, remain to be clarified. Earlierstudies supported the hypothesis that amyloid fibrils, generatedby self-aggregation of A ${beta}$ , drive the neurodegeneration cascadein AD (Hardy and Higgins 1992; Hardy and Selkoe 2002). Morerecent evidence indicates that soluble forms of A ${beta}$ , such as smalloligomers and protofibrils, also have potent toxic effect onneurons (Klein et al. 2001; Walsh et al. 2002). This may explainwhy AD-like neurological deficits can occur in the absence ofamyloid deposits in some strains of transgenic mice overexpressinghuman amyloid precursor protein (APP) (Van Dam et al. 2003;Yamaguchi et al. 1991). In other APP transgenic mice, impairedhippocampal long-term potentiation (LTP) and behavioral deficitsare correlated with elevated brain A ${beta}$ level and plaques, butfew have shown neuronal cell death or synaptic loss (Chapmanet al. 1999; Giacchino et al. 2000; Larson et al. 1999). Thesefindings suggest that early accumulation of A ${beta}$ , likely in itssoluble forms, causes synaptic dysfunction that initiates cognitivedecline prior to synapse loss and cell death. A key questionto be answered is how A ${beta}$ at this stage affects synaptic plasticityin neuronal networks where memories are formed and stored. Understandingsuch mechanisms may provide important clues for therapeuticintervention of AD at its early stages.

We and others have shown inhibition of LTP in area CA1 or dentategyrus of rat hippocampus by acute application of synthetic A ${beta}$ (Chen et al. 2000, 2002; Kim et al. 2001; Wang et al. 2002)or conditioned culture medium containing A ${beta}$ species secretedby cells transfected with human APP (Walsh et al. 2002). Subsequentstudies have focused on elucidating the pivotal signaling mechanismsunderlying A ${beta}$ disruption of synaptic plasticity (Mattson andChan 2003; Rowan et al. 2003). For example, we showed in thedentate gyrus that A ${beta}$ inhibition of LTP was blocked by specificinhibitors for calcineurin, a Ca²⁺- and calmodulin-dependentprotein phosphatase (Chen et al. 2002). This result indicatesthat increased calcineurin activity contributes to A ${beta}$ -inducedLTP deficits. It also gives rise to a new question as to whetherA ${beta}$ can also alter protein kinase activity thus further disruptingthe dynamic balance between protein phosphorylation and dephosphorylationduring LTP. This study examined, in the hippocampal dentategyrus, the effect of A ${beta}$ _1–42 on Ca²⁺ and calmodulin-dependentprotein kinase II (CaMKII). Activation of this enzyme is essentialfor LTP generation (Malinow et al. 1989; Silva et al. 1992)and is under the negative control of a calcineurin-dependentphosphatase pathway (Blitzer et al. 1995; Lisman 1994). CaMKII-mediatedphosphorylation of ${alpha}$ -amino-3-hydroxy-5-methyl-4-isoxazloe proprionicacid (AMPA) type of glutamate receptors, a crucial step in LTPexpression (Lee et al. 2000), was also measured following LTPand A ${beta}$ treatments. Our results show that A ${beta}$ _1–42 attenuatesLTP-induced activation of CaMKII and subsequent phosphorylationof AMPA receptors in the dentate gyrus.

METHODS

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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
REFERENCES

Slice preparation

Hippocampal slices were prepared from 30- to 60-day-old maleSprague-Dawley rats as described (Chen et al. 2000). Briefly,rats were decapitated under halothane anesthesia. The brainwas removed and sectioned into 500-µm-thick slices usinga vibroslicer. The slices were maintained at room temperaturein a holding chamber containing oxygenated artificial cerebrospinalfluid (ACSF; in mM: 120 NaCl, 25 NaHCO₃, 3.3 KCl, 1.23 NaH₂PO₄,2 CaCl₂, 1.0 MgSO₄, and 10 D-glucose, at pH 7.4). After at least1 h equilibration, slices were transferred into a submergedrecording chamber and continuously perfused with 29–30°Coxygenated ACSF at 2–3 ml/min throughout the experiments.All protocols were in accordance with PHS Guidelines and werereviewed and approved by the Chancellor’s Animal ResearchCommittee of the University of California at Los Angeles.

Electrophysiological recordings

Field excitatory postsynaptic potentials (fEPSPs) were recordedin dentate gyrus using standard extracellular recording techniquesas previously described (Chen et al. 2000). Briefly, fEPSPswere evoked by stimulating the medial perforant path in themiddle third of the dentate molecular layer with 0.1-ms pulsesdelivered via a sharpened monopolar tungsten electrode and recordedfrom the same layer with a glass microelectrode filled with2 M NaCl. Baseline responses were collected using 0.008-Hz testpulses that yielded 40–50% of the maximal fEPSP slopein ACSF. LTP was induced by a single high-frequency stimulation(HFS) of 100 Hz for 1 s at the same stimulus intensity usedfor baseline. After HFS, the stimulation was returned to thebaseline frequency, and slices were harvested at different time-pointsas described. The amount of LTP was expressed as percent changesof fEPSP slopes from baseline after HFS.

A ${beta}$ application and experimental design

A ${beta}$ _1–42 (Bachem, Torrance, CA) was prepared as 1 mM stocksolution in H₂O, stored in small aliquots at –20°C,and diluted with ACSF to 200 nM immediately before use. Samplesof applied peptide solutions were visually inspected under a400x phase-contrast microscope. No evident fibrillar or sheetlikeaggregates were observed at this concentration. The A ${beta}$ solutionwas bath-applied to slices during the field potential recordings,starting 20 min before and ending immediately after the HFS.To measure A ${beta}$ -induced changes in protein phosphorylation, fourslices from the same animal were used for different treatments:two receiving HFS with or without A ${beta}$ _1–42 treatment (HFS,A ${beta}$ +HFS) and the other two as paired controls receiving matchingtreatment except no HFS (control, A ${beta}$ ). The order in which thesetreatments were given to a set of slices was randomly decidedat the beginning and rotated daily across animals. The dentateregion of slices was rapidly dissected out after treatment.The mini-slices were frozen on dry ice and kept at –70°Cuntil further processing for immunoblotting.

Immunoblot analysis

CaMKII or GluR1 phosphorylation was measured in the dentatemini-slices using immunoblot analysis as described previouslywith some modifications (Makhinson et al. 1999). Individualdentate slices were homogenized in 70 µl of ice-cold buffercontaining 50 mM HEPES, 10 mM MgCl₂, 1 mM EDTA, 1 mM EGTA, 10mM benzamide, 100 ng/ml leupeptin, 100 ng/ml aprotinin, 0.01%TritonX-100, 0.08 mM sodium molybdate, and 2 mM sodium pyrophosphateat pH 7.4. Aliquots of the homogenate were taken to determineprotein concentration using Protein Assay Reagent (Bio-Rad,Hercules, CA). A cold denaturing loading buffer was added immediatelyinto the remaining homogenate to stop protein kinase and phosphataseactivity. Samples were boiled for 5 min, and aliquots of 30µg protein were electrophoresed on a SDS/PAGE gel containing4% stacking and 12% resolving acrylamide. The proteins weretransferred onto nitrocellulose membranes, blocked for 1 h withphosphate-buffered saline containing 4% nonfat dried milk (Blotto),and probed overnight at room temperature with primary antibodies.A monoclonal antibody against the ${alpha}$ subunit of CaMKII phosphorylatedat Thr²⁸⁶ (ABR, Golden, CO) was used at 1:1,000 to detect autophosphorylationof the kinase. Two polyclonal antibodies (Upstate, Lake Placid,NY) were used at 1:500 to recognize GluR1 phosphorylated atSer⁸³¹ or Ser⁸⁴⁵, respectively. Antibodies for total CaMKII(Chemicon International, Temecula, CA) and total GluR1 (Upstate)were used at 1:2,500. All primary antibodies were diluted inBlotto. Nitrocellulose membranes were further incubated for1 h with horseradish peroxidase-conjugated secondary antibodiesat 1:10,000. The proteins were visualized with enhanced chemiluminescence(Amersham ECL Western Blotting Analysis System). Densitometricdata were obtained by processing the exposed films with a MolecularDynamics Personal Densitometer SI (Sunnyvale, CA) using ImageQuantSoftware. For the loading control, membranes were stripped andreprobed with an antibody for ${beta}$ -actin (1:2,000; Sigma, St. Louis,MO). Values of phosphorylated and total proteins for eitherCaMKII or GluR1, measured with aliquots from the same slicesample, were normalized to ${beta}$ -actin.

Statistical analysis

Data are presented as group means ± SE. Percent changesin the protein bands due to A ${beta}$ or HFS treatments were calculatedrelative to the control band (ACSF alone) run in the same experimentusing slices from the same animal. One-way ANOVA was appliedto test for overall statistical significance across multiplegroup means, followed by Bonferroni post hoc test for pairwisemean comparisons. Student's t-test were used in LTP experimentsfor two-group comparisons. Statistical significance was definedas P < 0.05.

RESULTS

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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
REFERENCES

LTP-inducing stimulation increases ${alpha}$ CaMKII autophosphorylation in dentate gyrus

A single HFS to the media perforant path induced significantLTP in the dentate gyrus of hippocampal slices, increasing fEPSPslopes to 132 ± 3% of the baseline level at 30 min afterHFS (n = 17, P < 0.01). To determine LTP-associated changesin CaMKII autophosphorylation, slices were harvested at differenttime-points after HFS and measured for their phospho-CaMKIIand total CaMKII levels. Along with the potentiation of fEPSP(Fig. 1D), the phospho-CaMKII level increased rapidly, reaching131 ± 15, 158 ± 13, and 155 ± 14% of thecontrol level at 5, 15, and 30 min after the HFS, respectively(n = 8 for each time-point, P = 0.01 at 15 and 30 min comparedwith unstimulated controls; Fig. 1, A and B). In contrast, thetotal CaMKII protein was not significantly altered by HFS duringthe same period of time (Fig. 1, A and C).

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FIG. 1. Long-term potentiation (LTP)-inducing high-frequency stimulation (HFS, 100 Hz, 1 s) increases the level of phospho-Thr²⁸⁶-Ca²⁺/calmodulin–dependent protein kinase II (P-CaMKII) in the dentate area of rat hippocampal slices. A set of 4 dentate slices from each animal was harvested for immunoblotting at different time-points after HFS (n = 8 rats). Slices receiving no HFS served as the controls. Note the significant increases in the P-CaMKII level at 15 and 30 min after HFS (B) and lack of changes in the total CaMKII level measured in the same slices (C). Representative immunoblot images are shown in A in this figure and the following. Electrophysiological data collected at the corresponding time-points are shown in D. **P < 0.01 compared with the control slices.

A ${beta}$ _1–42 inhibits dentate LTP and HFS-induced CaMKII autophosphorylation

As reported previously (Chen et al. 2000), acute applicationof A ${beta}$ _1–42 during HFS reduced LTP in the dentate gyrus (Fig.2D). At 30 min after HFS, the fEPSP slope in A ${beta}$ -treated slicesdecayed to 100 ± 3% of baseline (n = 16), significantlysmaller than that in the control slices (132 ± 3%, n= 17, P < 0.01). In parallel, immunoblot analysis revealedsignificant changes in dentate phospho-CaMKII levels followingexperimental treatments [F(3, 60) = 5.2, P < 0.01, one-wayANOVA]. Although A ${beta}$ treatment alone caused no evident changein the basal phosphorylation level of CaMKII (98 ± 9%of the controls, n = 16, P > 0.05), the peptide clearly reducedLTP-induced CaMKII phosphorylation when applied with HFS (Fig.2, A and B). The phospho-CaMKII level in the A ${beta}$ + HFS group at15 min after HFS was 107 ± 8% (n = 16) of the controls,significantly lower than the level in the HFS alone group (135± 10%, n = 16, P < 0.05) and indistinguishable fromthat in the A ${beta}$ alone group (P > 0.05). The total CaMKII proteinlevel did not differ among all groups (Fig. 2C).

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FIG. 2. A ${beta}$ _1–42 inhibits dentate LTP and HFS-induced CaMKII autophosphorylation. A–C: slices were stimulated with the tetanus alone (HFS) or in the presence of 0.2 µM A ${beta}$ _1–42 (A ${beta}$ + HFS) and were harvested 15 min after HFS for immunoblotting. Paired control slices from the same animals received the matching treatment except no HFS (control or A ${beta}$ ). Note significantly reduced P-CaMKII level in the A ${beta}$ + HFS group compared with HFS alone (B, n = 16) and unaltered total CaMKII levels following HFS and A ${beta}$ treatment (C, n = 11). **P < 0.01 compared with the controls. #P < 0.05 compared with the HFS alone group. D: electrophysiological data show impairment of dentate LTP in A ${beta}$ -treated slices (n = 16) compared with untreated controls (n = 17). Both group received a single HFS (100 Hz, 1 s) indicated by the arrow. A ${beta}$ application is indicated by the solid bar. Insets: representative field excitatory postsynaptic potentials (fEPSPs) recorded before (1) and after (2) HFS in control and A ${beta}$ -treated slices.

A ${beta}$ _1–42 blocks HFS-induced GluR1 phosphorylation at a CaMKII-dependent site

Studies show that LTP is associated with an increase in CaMKII-mediatedphosphorylation of GluR1 subunits of AMPA receptors (Barriaet al. 1997b). We therefore further determined whether A ${beta}$ inhibitionof CaMKII led to reduction in GluR1 phosphorylation. Using twophosphorylation site-specific antibodies, we distinguished GluR1phosphorylation at a CaMKII site (Ser⁸³¹) or a protein kinaseA (PKA) site (Ser⁸⁴⁵). As shown in Fig. 3, HFS induced significantincreases in Ser⁸³¹ phosphorylation in the absence of A ${beta}$ (142± 12% of the control level at 15 min after HFS, n = 22,P < 0.01). In A ${beta}$ -treated slices, however, the HFS failed toincrease Ser⁸³¹ phosphorylation. At 15 min after HFS, the phospho-Ser⁸³¹level in the A ${beta}$ + HFS group did not differ from the A ${beta}$ alone group(108 ± 9 vs. 99 ± 7%, n = 22 for each group, P> 0.05) and was significantly lowered than the HFS only groupmentioned above (P < 0.05). Furthermore, the effect of HFSand A ${beta}$ _1–42 on GluR1 phosphorylation appeared to be specificfor the CaMKII site, because phosphorylation at Ser⁸⁴⁵ was notsignificantly affected by A ${beta}$ (108 ± 18%, n = 13) or HFStreatment (115 ± 15%, n = 13; Fig. 4 ).

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FIG. 3. A ${beta}$ _1–42 prevents LTP-induced AMPA receptor phosphorylation at a CaMKII-dependent site. Slices were treated with HFS or/and A ${beta}$ as described in Fig. 2. GluR1 phosphorylation at Ser⁸³¹ following HFS was blocked by A ${beta}$ (n = 22). No significant changes in total GluR1 expression were observed (n = 13). **P < 0.01 compared with the controls. #P < 0.05 compared with the HFS alone group.

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FIG. 4. A ${beta}$ _1–42 and HFS do not affect GluR1 phosphorylation at Ser⁸⁴⁵, a protein kinase A (PKA)-dependent site. HFS and A ${beta}$ were applied as described above. n = 13 for each group.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION GRANTS REFERENCES

This study showed activity-dependent increases in CaMKII autophosphorylationand subsequent phosphorylation of AMPA receptor GluR1 subunitsat a CaMKII-dependent site in the dentate gyrus of rat hippocampalslices. Both phosphorylation processes along with dentate early-phaseLTP were blocked by acute application of A ${beta}$ _1–42. Theseresults suggest that inhibition of CaMKII-dependent proteinphosphorylation may play a major role in A ${beta}$ -induced LTP and memorydeficits. It is well established that generation of N-methyl-D-aspartate(NMDA) receptor-dependent forms of LTP in the hippocampus requiresan initial postsynaptic Ca²⁺ influx and subsequent conversionof this transient signal into long-lasting enhancement in synapticstrength (Malenka and Nicoll 1999

). CaMKII, a kinase highlyconcentrated at postsynaptic density and activated by Ca²⁺/calmodulin(Bennett et al. 1983

; Kelly et al. 1984

), is thought to havea key role in this conversion. In the CA1 region of hippocampalslices, NMDA receptor–mediated Ca²⁺ transients lead toautophosphorylation of CaMKII and its accumulation in the dendritesof pyramidal neurons after LTP induction (Fukunaga et al. 1995

;Ouyang et al. 1997

). Autophosphorylation at Thr²⁸⁶ enables Ca²⁺/calmodulin-independent,persistent CaMKII activity (Miller and Kennedy 1986

; Soderlinget al. 2001

), which has been proposed to serve as a molecularswitch to convert transient NMDA receptor activation into long-lastingbiochemical changes underlying synaptic plasticity (Lisman etal. 2002

). In support of this view, genetic or pharmacologicalmanipulations that prevent CaMKII autophosphorylation blockLTP induction in the Schaffer collateral-CA1 pathway (Gieseet al. 1998

; Malinow et al. 1989

; Silva et al. 1992

). It wasunclear, however, whether synaptic plasticity induced in otherhippocampal regions uses similar, CaMKII-dependent mechanisms.Here we show for the first time that CaMKII autophosphorylationmay be necessary for LTP induction or expression in the perforantpath–dentate gyrus pathway. The LTP-inducing tetanus triggeredsignificant increases in CaMKII autophosphorylation in dentatearea. The increase became evident within 5 min, peaked around15 min, and lasted for $≥$ 30 min after HFS, resembling the timecourse of CaMKII autophosphorylation following LTP in the CA1region (Banke et al. 2000

; Barria et al. 1997b

; Giovannini etal. 2001

). This rapid change in the phospho-CaMKII level wasnot accompanied by a significant increase in the level of totalCaMKII protein. Thus the single HFS protocol we used to induceearly LTP appeared to promote phosphorylation of preexistingCaMKII proteins rather than to induce synthesis of new kinases.There is in vivo evidence that levels of synaptically associatedCaMKII mRNA and protein can be increased following LTP in thedentate gyrus (Davis et al. 2000

; Havik et al. 2003

; Robertset al. 1998

). However, these increases are restricted in thedendritic spines without parallel upregulation in the soma,indicating translocation of preexisting CaMKII mRNA to synapsesrather than an overall increase of CaMKII expression in thewhole tissue. Furthermore, dendritic CaMKII expression occursat a much slower rate than protein phosphorylation, often taking2–3 h to develop after LTP induction (Davis et al. 2000

;Roberts et al. 1998

) and therefore being more relevant to thelate phase rather than the early phase of LTP (Miller et al.2002

). Based on the above, it is not surprising that we didnot observe significant increases in the total CaMKII levelwhen measuring the whole tissue homogenates at 15–30 minafter induction of early LTP.

Application of A ${beta}$ _1–42 attenuated both LTP and associatedCaMKII phosphorylation in the dentate gyrus. These results indicatethat preventing CaMKII autophosphorylation/activation couldlead to impairment of long-term synaptic plasticity in thishippocampal subregion. Several distinct mechanisms may havecontributed to A ${beta}$ inhibition of CaMKII activity (Fig. 5). First,at the concentrations effective for LTP blockade, A ${beta}$ _1–42inhibits NMDA receptor–mediated synaptic currents (Chenet al. 2002). This effect can reduce Ca²⁺ influx through theNMDA receptor and thus prevent activation of CaMKII. Second,CaMKII activity is regulated by a balance between PKA and calcineurin(phosphatase 2B). These two enzymes antagonistically regulatethe activity of protein phosphatase 1 (PP1), which in turn servesas a gate controlling the phosphorylation state of CaMKII andhence synaptic strength (Blitzer et al. 1998; Lisman 1994).Blocking calcineurin activity reverses A ${beta}$ -induced deficits inthe late-phase LTP in dentate gyrus, suggesting activation ofcalcineurin by A ${beta}$ (Chen et al. 2002). It is thus likely thatenhanced calcineurin activity creates an imbalance between calcineurinand PKA activity, leading to activation of PP1 and thereby dephosphorylationof CaMKII.

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FIG. 5. Proposed mechanisms for A ${beta}$ -induced impairment in dentate LTP. The LTP at the perforant path synapse is initiated by Ca²⁺ influx through postsynaptic N-methyl-D-aspartate (NMDA) receptors and subsequent activation of CaMKII. Phosphorylation of AMPA receptors at Ser⁸³¹ of GluR1 subunits by CaMKII increases the conductance of AMPA receptor channels, contributing to LTP expression. We have shown that A ${beta}$ suppresses NMDA receptor channels and activates calcineurin (CN). Both effects are likely to reduce CaMKII autophosphorylation/activation, leading to deficits in dynamic regulation of AMPA receptors, and hence, inhibition of LTP.

How changes in CaMKII activity affect long-lasting synapticpotentiation in the hippocampus has been the subject of intenseinvestigation. A major postsynaptic target of CaMKII activityis the AMPA type of glutamate receptors. AMPA receptors areheterooligomeric complexes assembled from GluR1-4 subunits.The most common subunit combinations of AMPA receptors in hippocampalneurons are GluR1/2 and GluR2/3 (Craig et al. 1993

). LTP inCA1 neurons is associated with phosphorylation of GluR1 subunitat Ser⁸³¹ by CaMKII (Barria et al. 1997a

; Lee et al. 2000

).This phosphorylation increases the single-channel conductanceof AMPA receptors (Benke et al. 1998

; Derkach et al. 1999

),which can directly contribute to LTP expression at CA1 glutamatergicsynapses. This study showed an increase in Ser⁸³¹ phosphorylationfollowing dentate LTP and attenuation of such changes by A ${beta}$ _1–42.The peptide did not affect the basal phosphorylation level ofSer⁸³¹, consistent with the earlier finding that A ${beta}$ _1–42was without effect on AMPA receptor-mediated baseline synapticcurrents in dentate granule cells (Chen et al. 2002

). LTP-inducedSer⁸³¹ phosphorylation, however, was clearly blocked by A ${beta}$ , inparallel with the reduction of HFS-triggered CaMKII autophosphorylation.Studies show that the efficacy of CaMKII-mediated substratephosphorylation is regulated by its autophosphorylation at Thr²⁸⁶.The autophosphorylated kinase translocates to the postsynapticdensity (PSD) (Strack et al. 1997

), where it binds directlyto the NMDA receptor (Leonard et al. 1999

; Strack and Colbran1998

). This process places the kinase at an ideal site to controlsynaptic function and provides a positive feedback for its furtherautophosphorylation (Lisman et al. 2002

). Thus inhibition ofthe initial autophosphorylation of CaMKII could impede its translocationand synaptic targeting, leading to reduced AMPA receptor phosphorylationand impaired synaptic plasticity.

The effect of A ${beta}$ and LTP on GluR1 phosphorylation appeared tobe specific for the CaMKII-dependent site, because another phosphorylationsite on the GluR1 subunit, Ser⁸⁴⁵, was not altered by eitherHFS stimulation or A ${beta}$ _1–42 application. Phosphorylationof Ser⁸⁴⁵ by PKA is known to increase the peak open probabilityof AMPA receptor channels (Banke et al. 2000). This mechanismis important for maintaining the strength of basal synaptictransmission, because dephosphorylation of Ser⁸⁴⁵ leads to long-termdepression (LTD), a depressive form of synaptic plasticity (Leeet al. 2000). Calcineurin, a Ca²⁺-dependent serine/threoninephosphatase, is required for LTD induction (Mulkey et al. 1994)and thus likely mediates Ser⁸⁴⁵ dephosphorylation. Interestingly,acute application of A ${beta}$ _1–42 facilitates hippocampal LTD(Kim et al. 2001). Whether under LTD conditions A ${beta}$ could facilitateSer⁸⁴⁵ dephosphorylation via calcineurin is an interesting issueto be further investigated.

GRANTS

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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
REFERENCES

This work is supported by National Institutes of Health GrantsP50DA-05010 and R01AG-17542 to C.-W. Xie and by State of California,Department of Health Service/Alzheimer's Disease Program (Agreement01–15944) to J. B. Watson.

FOOTNOTES

The costs of publication of this article were defrayed in partby the payment of page charges. The article must therefore behereby marked "advertisement" in accordance with 18 U.S.C. Section1734 solely to indicate this fact.

Address for reprint requests and other correspondence: C.-W. Xie, Dept. of Psychiatry and Biobehavioral Sciences, Neuropsychiatric Inst., Univ. of California-Los Angeles, Los Angeles, CA 90024 (E-mail: cxie{at}mednet.ucla.edu).

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