Serotonin Activates S6 Kinase in a Rapamycin-Sensitive Manner in Aplysia Synaptosomes

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The Journal of Neuroscience, January 15, 2001, 21(2):382-391

Serotonin Activates S6 Kinase in a Rapamycin-Sensitive Manner in Aplysia Synaptosomes
Asad Khan, Antonio M. Pepio, and Wayne S. Sossin
Department of Neurology and Neurosurgery, Montreal Neurological Institute, McGill University, Montreal, Quebec H3A 2B4, Canada

  ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The identification of tags that can specifically mark activated synapses is important for understanding how long-term synapticchanges can be restricted to specific synapses. The maintenanceof synapse-specific facilitation in Aplysia sensory to motor neuroncultures can be blocked by inhibitors of translation and by thedrug rapamycin, which specifically blocks a signaling pathwaythat regulates phosphorylation of translational regulators. Oneimportant target of rapamycin is the phosphorylation and subsequentactivation of S6 kinase. To test whether S6 kinase is the targetfor the ability of rapamycin to block synapse-specific facilitationin Aplysia, we cloned Aplysia S6 kinase, its substrate S6, andthe S6 kinase kinase phosphoinositide-dependent kinase 1 (PDK-1).Serotonin, which induces synapse-specific facilitation, increasedphosphorylation of Aplysia S6 kinase at threonine 399 in a rapamycin-sensitivemanner in Aplysia synaptosomes. The phosphorylation of threonine399 by 5-HT was independent of phosphoinositide-3 kinase, dependenton PKA and PKC, and occluded by the phosphatase inhibitor calyculin-A.5-HT also increased S6 kinase activity and led to increased phosphorylationof S6 in synaptosomes. 5-HT increased levels of S6 in synaptosomesbecause of a rapamycin-sensitive increase in translation-stabilizationof S6. Aplysia PDK-1 bound to and phosphorylated Aplysia S6 kinasebut only modulated phosphorylation of threonine 399 indirectly.These results suggest a mechanism by which the levels of translationfactors can be increased specifically at activated synapses generatinga long-lasting synaptictag.

Key words: synaptic plasticity; S6 kinase; Aplysia; synaptic tagging; rapamycin; serotonin; phosphoinositide-dependent protein kinase; S6; translation

  INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The ability to regulate translation locally at synaptic contacts is an attractive mechanism for limiting global changes inneuronal gene expression to specific synapses (Steward and Banker,1992; Sossin, 1996; Schuman, 1997; Wells et al., 2000). In themarine mollusk Aplysia californica, the retention of long-termfacilitation after addition of serotonin (5-HT) is dependent onlocal translation and is blocked by local application of rapamycinto the synapse (Casadio et al., 1999). Addition of 5-HT also leadsto increases in the rate of translation that are sensitive torapamycin (Yanow et al., 1998; Casadio et al., 1999), suggestingthat the increase in the translation rate may be important forthe retention of long-termfacilitation.

The major target for rapamycin in cells is the FKPB-12 and rapamycin-associated protein FRAP (Brown and Schreiber, 1996).Activation of FRAP leads to increased S6 kinase activity (Brownet al., 1995), which in turn leads to phosphorylation of S6 andincreased translation of a set of proteins, including ribosomalproteins and translation factors (Jefferies et al., 1997; Petersonand Schreiber, 1998; Dufner and Thomas, 1999). Disruption of S6kinase leads to growth defects in both mammals and invertebrates(Shima et al., 1998; Montagne et al., 1999).

S6 kinase activation requires multiple phosphorylation events that are regulated in a complex manner (Dufner and Thomas, 1999).Important sites in the inhibitory C terminus (Han et al., 1995)are similar to those phosphorylated by FRAP in eukaryotic initiationfactor 4E binding protein (eIF4E-BP) and may be direct targetsof FRAP (Gingras et al., 1998; Isotani et al., 1999). Phosphorylationof a threonine in the activation loop of S6 kinase is criticalfor activation; this site is phosphorylated by phosphoinositide-dependentkinase 1 (PDK-1) (Alessi et al., 1998; Pullen et al., 1998; Wenget al., 1998). Phosphorylation of another site, often called thePDK-2 site, is also required for S6 kinase activation (Pearsonet al., 1995). Phosphorylation at this site is the most tightlylinked with activation of the kinase and is the most sensitiveto rapamycin (Pearson et al., 1995; Weng et al., 1998). Althoughthere is some evidence that this site is phosphorylated by FRAP(Burnett et al., 1998a; Isotani et al., 1999), rapamycin sensitivitymay also occur through FRAP-mediated inhibition of a calyculin-sensitivephosphatase (Dennis et al., 1996; Peterson et al., 1999; Westphalet al., 1999). These regulatory steps have been examined in celllines; however, there is little data regarding the mechanism ofactivation of S6 kinase inneurons.

We have cloned S6 kinase in Aplysia to determine whether it may play a role in the rapamycin-sensitivity of long-term facilitation.We find that 5-HT increased S6 kinase phosphorylation at the PDK-2site in synaptosomes and that this activation is blocked by rapamycinbut not by PI-3 kinase inhibitors. Activation of S6 kinase leadsto an increase in phosphorylation and levels of the S6 protein,suggesting that 5-HT may induce a synapse-specific increase inthe production of translation factors in Aplysia through activationof S6kinase.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Materials. Aplysia californica (75-125 gm) were obtained from Marine Specimens Unlimited (Pacific Palisades, CA) or Universityof Miami National Institutes of Health Aplysia resource facility(Miami, FL) and maintained in an aquarium for at least 3 d beforeexperimentation. The animals were first placed in a bath of isotonicMgCl₂-artificial seawater (1:1, v/v) and then anesthetized byinjection with isotonic MgCl₂ solution. The pharmacological agentsLY294002, Chelerythrine, KT5720, calyculin-A, and rapamycin werepurchased from Calbiochem (La Jolla,CA).

Cloning of S6 kinase, PDK, and S6. To create Aplysia nervous system cDNA, pleural, pedal, and abdominal ganglia were dissectedfrom the animals, immediately frozen in liquid nitrogen, and thenprocessed using the Qiagen RNEasy Minikit (Qiagen, Santa Clara,CA) to obtain total RNA. cDNA template was made using SuperscriptII reverse transcriptase (Life Technologies, Gaithersburg, MD).Finally, cDNA product was used as a template in PCR to amplifyfragments of S6, S6 kinase, and PDK-1 using degenerate primers(see below). These fragments were cloned using the TOPO TA cloningkit (Invitrogen, Carlsbad, CA). The cloned fragments were labeledwith [³²P]ATP using PCR and used to screen a $lambda$ -ZAP cDNA library (giftof Dr. J. H. Schwartz, Columbia University College of Physiciansand Surgeons, New York, NY). From this screen, cDNAs containingthe full coding region of S6 and S6 kinase were isolated, butfor PDK-1, the longest clone isolated was missing a small fragmentof the 3' end and this fragment could not be cloned from thislibrary. To isolate the 3' end, we used 3' rapid amplificationof cDNA ends (RACE) using nested primers from the sequenced cloneand nested primers from the vector sequences of a plasmid cDNAlibrary (Bartsch et al., 1995). This screen resulted in isolationof the 3' stop codon and additional PDK-1 3'untranslated region.All sequencing was done on both strands using the services ofThe W. M. Keck Biotechnology Resource Laboratory (Yale University,New Haven, CT) and Bio S&T Inc. (Montreal, Quebec, Canada). Thesequences have been submitted to the GenBank database with accessionnumbers AF294916 (S6 kinase), AF294917 (PDK), and AF29418(S6). The following primers were used: S6 kinase degenerate 5'primer (YAFQT), 5-TAYGCNTTYCARAC; S6 kinase degenerate 3' primer(KPENI), 5'-ATRTTYTCNGGYTT; S6 degenerate 5' primer (KQGFPM),5'-AARCARGGNTTYCCNATG; S6 degenerate 3' primer (KEDDV), 5'-ACRTCRTCYTCYTT;PDK-1 degenerate 5' primer (KGLFA), 5'-AARGGNYTNTTYGC; PDK-1 degenerate3' primer (KGEIPW), 5'-CCANGGDATYTCNCCYTT; PDK-1 5' primer 1 3'RACE, 5'-TTGTGGAGGACAACCTGAT; PDK-1 5'primer 2 3' RACE, 5'-CGCCAGA-GGCCAAGAAC;PDK-1 (K-N) O5, 5'-CCACAAGCTCAGGGCA-CAG; PDK-1 (K-N) I5, 5'-GCAATTAATGTGTGTGACAAGAA-GCAC;PDK-1 (K-N) I3, 5'-ACACCATTAATTGCAAATTCTTT-TTGAGT; and PDK (K-N)O3, 5'-CGTATTCTGCGGTGCCGAC.

Construction of plasmids. To make a baculovirus transfer vector for S6 kinase, we cut the cDNA clone with PstI and XhoI andinserted it into BB4 (Invitrogen) cut with the same enzymes. Togenerate a baculovirus for myristylated (constitutively active)phosphoinositide-3 (PI-3) kinase, a clone was generously providedby Dr. David Kaplan (Montreal Neurological Institute), and weinserted it into BB4 at the BamHI site. To generate a baculovirusfor PDK-1, we used a triple ligation cutting the long PDK-1 clonewith BamHI and DraI, the clone containing the 3' fragment withDraI and KpnI, and inserting these two fragments into BB4 cutwith BamHI and KpnI. Mutating the catalytic lysine in PDK-1 wasdone with a two-step mutagenic procedure using PCR. First-roundPCR used PDK-1 in BB4 as a template and either the outside 5'primer (O5) and the inside 3' primer (I3) or the inside 5' primer(I5) and the outside 3' primer (O3) (see above for primers). Theproducts from the first-round synthesis were combined and usedas the template for second-round synthesis using O5 and O3. Theresultant product was cut with BstEII and DraIII and insertedinto PDK-1 in the BB4 vector. A new AseI was formed by the mutagenesisand was used to confirm the cloning. A fragment of PDK-1 containingthe kinase domain, the PH domain, and ~75% of the unconserved5' domain (starting at residue 130) was used to make a glutathioneS-transferase (GST) fusion protein by cutting out both PDK-1 andPDK-1 (K-N) from the BB4 vector with NcoI and NheI, filling inthe ends with Klenow, and inserting the fragments into the pGEX5x-1 (Amersham Pharmacia Biotech, Arlington Heights, IL) vectorcut with SmaI. A GST-S6 fusion protein was made by cutting S6out of the cDNA clone with EcoRI and inserting it into pGEX 3.1(Amersham Pharmacia Biotech) cut with EcoRI.

Production of antibodies. A peptide from S6 kinase (CNGYDTSAQEDMT-NH₂) or PDK-1 (CIQEVWKKYYDADS-COOH) containing a cysteineresidue added to the N terminal was synthesized and then coupledto both BSA maleimide and SulfoLink columns (Pierce, Rockford,IL). The coupled peptides were injected into rabbits with Titer-Max(CytRx, Norcross, GA) adjuvant four times at intervals of 1 month.The resultant sera were affinity purified over the SulfoLink columnsand concentrated to at least 1 mg/ml. For S6, the antigen wasthe S6 fusion protein. The resultant sera recognized only theS6 doublet on Western blots and was not additionallypurified.

Immunoblots. Western blots were performed as described previously (Dyer et al., 1996) with the S6 kinase antibody at 2 µg/mldilution, the S6 antibody at a 1:3000 dilution of serum, the PDKantibody at 2 µg/ml, the phosphopeptide antibody to the PDK-2site (1 µg/ml; New England Biolabs, Beverly, MA), and goat anti-rabbit,horseradish peroxidase-conjugated secondary antibody at 1 µg/ml.The New England Biolabs antibody was incubated overnight at 4°C,whereas all other primaries were incubated at room temperaturefor 2 hr. Blots were then developed with ECL (Amersham PharmaciaBiotech).

Expression of S6 kinase, PDK, and PI-3 kinase in SF9 cells. Transfer vectors for S6 kinase, PDK, and PDK (K-N) and PI-3 kinasewere recombined with wild-type baculovirus (Invitrogen), and hightiter stocks were generated. For infections, a multiplicity ofinfection (MOI) of 5 for each virus was used. When multiple viruseswere used in a single experiment, the same MOI was used, but double(or triple for three virus infections) amounts of protein wasloaded onto gels forquantitation.

PI-3 kinase assays. Supernatant and membrane fractions from SF9 cells were incubated with mixed phosphoinositides (Sigma,St. Louis, MO) and 10 µM ATP (1 µCi of [ $gamma$ -³²P]ATP) in 10 mM HEPES buffer. The lipids were extracted with chloroformand separated by thin layer chromatography next to markers generatedusing purified PI-3 kinase. Infection with the activated formof PI-3 kinase led to a 10- to 50-fold increase in levels of phosphoinositide(3,4,5) P3 generated from membranes of SF9 cells (data notshown).

Phosphorylation of S6 and S6 kinase in synaptosomes. Synaptosomes were prepared as described previously (Chin et al., 1989).This protocol gives a P1 pellet containing particulate proteins,two soluble fractions (S2 and S3), and two synaptosome-containingfractions, P3, which contains the purest synaptosomes, and P2,which contains the greatest amount of synaptosomes but of lesserpurity (Chin et al., 1989). Initially, P2 and P3 fractions weretested separately but, because no differences were observed inthe amount of S6 or S6 kinase phosphorylated (data not shown),later experiments used a combination of P2 and P3. Synaptosomes,prepared from four to five nervous systems were used for singleexperiments, usually aliquoted into 8-12 individual tubes. Allconditions were done in duplicate. An initial time course with5-HT suggested that a 20 min incubation was optimal for increasedthreonine 399 (Thr 399) phosphorylation and 25 min for S6 phosphorylation(data not shown). All experiments for S6 kinase phosphorylationused a 20 min incubation with 5-HT, and all experiments with S6used 25 min incubations. We have only used one concentration of5-HT (20 µM). We have previously used this concentration to inducerapamycin-sensitive translational changes in Aplysia ganglia (Yanowet al., 1998), and it is similar to concentrations used to inducethe rapamycin-sensitive change at Aplysia synapses (Casadio etal., 1999). Pharmacological inhibitors were applied at the sametime as 5-HT. At the end of the time period, sample buffer wasadded to the synaptosomes, and they were boiled at 90°C for 5min. Nine percent SDS-page gels were run until the 46 kDa markerwas at the bottom of the gel to optimize separation of the post-translationallymodified S6 kinase. Blots were first probed with the anti-phosphopeptideantibody and then reprobed for S6 kinase. Twelve percent SDS gelswere run until the dye reached the end of the gel for quantitationof S6 because we were unable to resolve both post-translationalmodifications in the same gelsystem.

Quantitation of synaptosome phosphorylation. All gels were scanned and quantitated using NIH Image using the uncalibratedoptical density function. We have found that this leads to a broadrange in which results are linear (Nakhost et al., 1999). We standardizedthe phosphopeptide immunoreactivity with the S6 kinase immunoreactivityfor each lane. Duplicates for each condition were then averaged,and the percentage change from control was calculated: ((experimental $-$ control)/control) * 100. To calculate the effect of 5-HT, thepercentage change from pharmacological agent alone was calculated.For S6, the percentage of upper band was calculated from the twowell separated bands. Total S6 was standardized to ponceau stainsof total protein to ensure gels were equally loaded with protein.Duplicates for each condition were then averaged, and the percentagechange from control was calculated: ((experimental $-$ control)/control)* 100. All statistical tests were paired t tests between controland experimentalvalues.

S6 kinase assays. Synaptosomes were treated with low Ca²⁺-seawater or low Ca²⁺-seawater and 20 µM 5-HT for 20 min. The synaptosomes were lysedwith immunoprecipitation buffer (1% Triton X-100, 150 mM NaCl,0.5 mM 2-mercaptoethanol, 20 mg/ml aprotinin, 5 mM benzamadine,0.1 mM leupeptin, 50 mM NaF, 5 mM sodium pyrophosphate, pH 8.5,1 µM microcystin, and 50 mM Tris, pH 7.8). Nonsolubilized proteinswere spun out at 100,000 × g, and the supernatant was incubatedwith anti-S6 kinase serum (5 µl) or preimmune serum (5 µl) thathad been precoupled to protein-A beads. The beads were then spundown and washed extensively, and buffer was changed to kinasebuffer (50 mM Tris, pH 7.5, and 10 mM MgCl₂). Substrate peptidesderived from the Aplysia S6 sequence (see below) were added (20µM), and the reaction was started with [³²P]ATP (1 µCi, 50 µM final concentration). Supernatants were placedon phosphocellulose filters and washed with 1% cold ATP and thenfour times with 0.25% phosphoric acid before scintillationcounting.

S6 peptides for assay. We synthesized two peptides based on the two putative S6 kinase sites (R/KxR/KxxS/T) in Aplysia S6(RKRANSRA and RRAKGDSIA). These peptides were slightly modifiedfrom the S6 sequences (RKRSNSRS and RSKGDSIA). We added positivecharges at the N terminus of the second peptide to ensure bindingto phosphocellulose papers. We also converted serines outsidethe S6 kinase site to alanine to reduce cross-reactivity withotherkinases.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cloning of Aplysia S6, S6 kinase, and PDK-1

To determine whether phosphorylation of S6 is a target for the rapamycin-sensitive pathway in Aplysia, we cloned Aplysia S6,S6 kinase, and the S6 kinase kinase PDK-1 (Alessi et al., 1998;Pullen et al., 1998). Using degenerate primers based on sequencehomology between vertebrate and invertebrates, we isolated fragmentsof the proteins and then used these fragments as a probe to screenan Aplysia cDNA library. Several clones were isolated for eachprotein and, based on mapping, the longest isolate was completelysequenced on both strands. For S6 and S6 kinase, the entire openreading frame was encoded on the sequenced clone (Figs. 1, 2).For PDK-1, this clone was lacking the 3' end of the PH domainand the stop codon, and further screening of the library did notresult in longer clones. Therefore, we used 3' RACE to isolatean additional fragment that contained a stop codon to give theentire open reading frame (Fig. 3).

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Figure 1. Cloning of S6 kinase. A comparison of the Aplysia S6 kinase and rat S6 kinase is shown. Identical residues are shaded. Known phosphorylation sites in rat S6 kinase and putative sites in Aplysia are in a darker shade. In particular, the positions of the PDK-1, PDK-2, and C-terminal sites are outlined. Also shown are the region required for rapamycin sensitivity and the boundaries of the kinase domain.

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Figure 2. Cloning of Aplysia S6. A comparison of Aplysia and rat S6 sequences. Identical residues are shaded. Sites matching the S6 kinase consensus sequence are in bold.

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Figure 3. Cloning of Aplysia PDK-1. The sequence of Aplysia PDK-1 is shown compared with human PDK-1. Identical residues are shaded. The boundaries of the kinase domain and the PH domain are indicated.

The sequence of S6 kinase contained an initiator methionine with a classic Kozak sequence preceded by a stop codon in frame,identifying it as the initiator methionine (data not shown). Thissequence is clearly an S6 kinase based on strong homology to vertebrateand invertebrate S6 kinases (47% identity to rat S6 kinase) (Fig.1). The S6 kinase sequence contains many of the conserved phosphorylationsites that have been identified in S6 kinase, including the PDK-1site, the PDK-2 site, a site preceding the PDK-2 site that isan autophosphorylation site in PKCs, and a serine-proline sitein the autoinhibitory domain (Fig. 1). There is also conservationof an acidic region in the N-terminal domain thought to be importantfor rapamycin sensitivity (Fig. 1). One difference between theAplysia S6 kinase and the vertebrate forms is the number of C-terminalphosphorylation sites; Aplysia has only one, whereas vertebrateshave more than four sites in this region (Fig. 1). Also, the bindingsite for the PDZ-containing protein neurabin in the C terminalof S6 kinase (Burnett et al., 1998b) is not conserved in Aplysia.Drosophila and Caenorhabditis elegans S6 kinases also have fewerS/T-P sites in the C terminus and also lack the neurabin-bindingsite (Stewart et al., 1996; The C. elegans Sequencing Consortium,1998).

The sequence of S6 stopped shortly after the initiating methionine. However, the high homology to other S6 proteins allowedfor tentative assignment of the initial methionine (Fig. 2). Thereis very high conservation of S6 over evolution (76% sequence identitybetween mouse and Aplysia), except in the region of phosphorylation,in which phosphorylation sites are always present but the absolutesequence conservation is lower (Fig. 2).

The sequence of PDK-1 contained an initiator methionine with a classic Kozak sequence preceded by a stop codon in frame, identifyingit as the initiator methionine (data not shown). This clone ishighly homologous to human PDK-1 in both the PH (72%) and thekinase domain (53%), but contains a long N-terminal domain thatis not conserved (Fig. 3).

Characterization of S6 kinase

An antibody was raised to a C-terminal peptide from the nonconserved C-terminal domain of S6 kinase. The antibody recognizeda single band migrating at ~60 kDa in both SF9 cells expressingAplysia S6 kinase and Aplysia ganglia (Fig. 4A). Because the physiologicalresponse to rapamycin was seen in Aplysia synapses, we next determinedwhether S6 kinase was detected in synaptosomes. Indeed, we foundthat S6 kinase was present in synaptosomes (Fig. 4B), similarto the distribution of vertebrate S6 kinase (Burnett et al., 1998b).Using gels optimized for separation in this region, there aremultiple bands recognized by this antibody in Aplysia ganglia(Fig. 4C). These multiple bands probably consist of differentiallyphosphorylated forms of S6 kinase, similar to vertebrate S6 kinase(Dufner and Thomas, 1999). S6 kinase expressed in SF9 cells comigrateswith the lower bands, consistent with reduced phosphorylationof the protein when overexpressed in SF9 cells (Fig. 4C).

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Figure 4. Characterization of the Aplysia S6 kinase. A, The antibody to S6 kinase recognizes an ~60 kDa protein in both Aplysia nervous system (20 µg of homogenate) and SF9 cells infected with a baculovirus encoding Aplysia S6 kinase. No immunoreactivity is seen in uninfected SF9 cells. B, S6 kinase is enriched in synaptosomes; 10 µg from each fraction of a synaptosome preparation (H, homogenate; P1, P2, P3, and S2) were loaded on a gel and blotted for S6 kinase. The fraction most enriched for synaptosomes (P3) contained the highest levels of S6 kinase. C, Optimizing gel separation and running time reveals multiple immunoreactive bands in ganglia (20 µg of homogenate) and band(s) in SF9 cells that comigrate with the faster migrating band(s) from nervous system.

5-HT increases phosphorylation of threonine 399 in a rapamycin-sensitive, PI-3 kinase-insensitive manner

To determine whether 5-HT could activate S6 kinase, we used a commercial anti-phosphopeptide antibody to the mammalian PDK-2site Thr 399 in Aplysia, because this site is highly conserved(Fig. 1) and studies have suggested that it is most closely linkedwith S6 kinase activity (Weng et al., 1998). Indeed, this antibodyrecognized a band that corresponded to the size of the highestband observed with the total S6 kinase antibody (Fig. 5A). Treatingsynaptosomes with 5-HT induced a specific increase in the bandrecognized by the anti-phosphopeptide antibody (Figs. 5A, quantitatedin 6A). Importantly, rapamycin significantly reduced immunoreactivitywith the anti-phosphopeptide antibody (Figs. 5A, quantitated in6A). Rapamycin also blocked the ability of 5-HT to increase phosphorylationof S6 kinase at Thr 399 (Figs. 5A, quantitated in 6B).

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Figure 5. 5-HT increases Thr 399 phosphorylation. A, Synaptosomes were treated with low Ca²⁺-seawater or low Ca²⁺-seawater and 20 µM 5-HT for 20 min in the presence or absence of pharmacological inhibitors. Samples were immediately put in Laemmli's buffer, boiled and separated on SDS-PAGE gels, transferred to nitrocellulose, and blotted with a commercial antibody to the PDK-2 site (Anti-p-Thr399). The blots were then stripped and reprobed with the antibody to S6 kinase (Anti-S6 kinase). The antibody to the PDK-2 site only reacts with the slowest migrating S6 kinase band (arrow). 5-HT increases both Thr 399 phosphorylation and the amount of protein running in the slowest migrating band (arrow). Rapamycin (Rap; 20 nM) strongly decreases Thr 399 phosphorylation and blocks the effect of 5-HT. B, Twenty micromolar LY294002 (LY) does not prevent 5-HT increases in Thr 399 phosphorylation. C, Inhibitors of PKA [KT5720 (KT), 5 µM] and PKC [chelerythrine (Ch) 10 µM] both block the effects of 5-HT on Thr 399 phosphorylation. D, Calyculin-A (Calyc; 100 nM), a phosphatase inhibitor, greatly increases Thr 399 phosphorylation and occludes the effect of 5-HT. E, Rapamycin does not block the effects of calyculin-A.

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Figure 6. Quantitation of Thr 399 phosphorylation. A, The percentage change in Thr 399 phosphorylation ((experimental $-$ control)/control) * 100) was calculated with the control being aliquots of synaptosomes from the same preparation treated only with low Ca²⁺-seawater. White bars represent changes with pharmacological agent alone, and shaded bars represent changes in the presence of both serotonin and the pharmacological agent [5-HT, n = 20; rapamycin (Rap), n = 6; rapamycin plus 5-HT, n = 6; LY294002 (LY), n = 6; LY294002 plus 5-HT, n = 6; KT5720 (KT), n = 5; KT5720 plus 5-HT, n = 5; chelerythrine (Ch), n = 4; chelerythrine plus 5-HT, n = 4; calyculin-A (Calyc), n = 7; calyculin-A plus 5-HT, n = 4; error bars represent SEM). *p < 0.05, comparisons between control and treatment; Student's paired t test. B, Percentage change in Thr 399 treatment was calculated as above, but now the control was the presence of pharmacological agent as opposed to low Ca²⁺-free seawater. The experimental value was 5-HT in the presence of the pharmacological agent. Results from 5-HT alone from A are shown for comparison. Rapamycin, n = 6; LY294002, n = 6; KT5720, n = 5; chelerythrine, n = 4; calyculin-A, n = 4. *p < 0.05, comparisons between pharmacological agent and pharmacological agent plus 5-HT; Student's paired t test.

We conducted a series of experiments to determine the mechanism by which 5-HT increases phosphorylation of Thr 399 in synaptosomes.In vertebrates activation of S6 kinase by multiple pathways dependson PI-3 kinase activation (Dufner and Thomas, 1999).To determinewhether 5-HT activated Thr 399 phosphorylation through PI-3 kinase,we examined the effects of a PI-3 kinase inhibitor (LY294002).LY294002 significantly decreased phosphorylation of S6 kinaseat Thr 399 (Figs. 5C, quantitated in 6A). However, the effectof 5-HT on LY294002-treated synaptosomes was not blocked, because5-HT increased Thr 399 phosphorylation, even in the presence ofLY294002 (Figs. 5B, quantitated in 6B). Thus, 5-HT does not activatephosphorylation of S6 kinase through activation of PI-3kinase.

An increase in translation mediated by 5-HT in pleural ganglia was blocked by rapamycin (Yanow et al., 1998). This increasewas also blocked by inhibitors of PKA and PKC (Yanow et al., 1998).To determine whether this inhibition could be attributable toinhibition of S6 kinase, we determined the effect of PKA and PKCinhibitors on 5-HT-mediated phosphorylation of Thr 399. Both inhibitorsblocked the ability of 5-HT to increase S6 kinase phosphorylation(Figs. 5C, quantitated in 6A,B).

One model of S6 kinase activation is that the rapamycin-sensitive protein FRAP acts to inhibit a constitutively active phosphatase(Weng et al., 1995b; Peterson et al., 1999). Thus, a phosphataseinhibitor should mimic the actions of FRAP. This phosphatase hasbeen reported to be particularly sensitive to the phosphataseinhibitor calyculin-A (Parrott and Templeton, 1999), and indeed,the calyculin-A-sensitive phosphatase 2A has been reported toassociate with S6 kinase (Peterson et al., 1999). We found thattreating synaptosomes with calyculin-A led to a large increasein Thr 399 phosphorylation (Figs. 5D, quantitated in 6A). Thisincrease occluded the ability of 5-HT to further increase Thr399 phosphorylation. Indeed, in the presence of calyculin-A, 5-HTnow led to a decrease in Thr 399 phosphorylation (Figs. 5D, quantitatedin 6B).

To determine whether the phosphatase was upstream or downstream of FRAP, we determined whether the effect of calyculin-A couldbe blocked by rapamycin. The effect of calyculin-A was insensitiveto treatment with rapamycin (10 ± 12%, effect of rapamycin oncalyculin-treated synaptosomes; n = 3; SEM) (Fig. 5E); thus, theevidence suggests that a calyculin-A-sensitive phosphatase isdownstream of FRAP in Aplysiasynaptosomes.

5-HT increases S6 kinase activity

Although phosphorylation of the PDK-2 site is very closely linked with activation of the kinase (Weng et al., 1998), we wantedto confirm that 5-HT increased S6 kinase activity in synaptosomes.The consensus site for S6 kinase is R/KxR/KxxS (Flotow and Thomas,1992), and there are two sites in Aplysia S6 that match this consensus(Fig. 2). To determine whether 5-HT increased S6 kinase activity,in vitro kinase assays using peptides derived from the AplysiaS6 sequence were accomplished after immunoprecipitation of S6kinase from synaptosomes. These assays revealed a low level ofbasal S6 kinase activity that was significantly increased by 5-HT(Fig. 7). This increase was specific to S6 kinase because 5-HTdid not increase kinase activity if preimmune serum was used forthe immunoprecipitation (Fig. 7).

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Figure 7. 5-HT increases S6 kinase activity. Batches of synaptosomes from five animals were split into two aliquots. One aliquot was treated with Ca²⁺-free seawater ( $-$ ), and the other with Ca²⁺-free seawater containing 20 µM 5-HT (+). The synaptosomes were homogenized, split into two equal fractions, and immunoprecipitated with either preimmune serum or serum for S6 kinase. The immunoprecipitates were then assayed for S6 kinase activity measuring incorporation of [³²P]ATP into peptides derived from the Aplysia S6 kinase. Error bars represent SEM from three independent experiments.

5-HT increases the level of S6 and S6 phosphorylation in synaptosomes

To observe whether activation of S6 kinase led to an increase in phosphorylation of endogenous S6, we raised an antibody toS6. This antibody recognized multiple bands migrating around theexpected molecular weight of 31 kDa (Fig. 8A). It is well knownthat phosphorylation of S6 causes a shift in the migration ofthe protein (Thomas et al., 1979; Martin-Perez and Thomas, 1983).Treatment of synaptosomes with 5-HT increased the percentage ofslower migrating S6, consistent with an increase in S6 phosphorylation(Fig. 8A). This increase was not seen in the presence of rapamycin(Fig. 8A, quantitated in C). Strikingly, in many experiments,5-HT also induced a large rapamycin-sensitive increase in thelevels of S6 in synaptosomes (Fig. 8B, quantitated in D). Interestingly,the two effects of 5-HT were inversely correlated (Fig. 8E). Whena large increase in phosphorylation was seen, there was littlechange in the abundance of S6 (Fig. 8A), and similarly, when therewas a large increase in abundance, there was a smaller increasein the relative level of the upper band (Fig. 8B). This is consistentwith 5-HT-induced production or stabilization of unphosphorylatedS6.

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Figure 8. 5-HT increase S6 phosphorylation and the amount of S6 in synaptosomes. Synaptosomes were treated with Ca²⁺-free seawater or Ca²⁺-free seawater and 20 µM 5-HT for 25 min in the presence or absence of 20 nM rapamycin. Samples were immediately put in Laemmli's buffer, boiled, separated on SDS-PAGE gels, transferred to nitrocellulose, and blotted with the antibody to Aplysia S6. Two experiments are shown, one to illustrate the increase in the percentage in the upper band (A) and the other to illustrate the increase in S6 levels (B). C, Quantitation of the percentage change ((experimental $-$ control)/control) * 100) in the amount of S6 phosphorylated. The amount of phosphorylation was determined by dividing the immunoreactivity in the upper band by the total immunoreactivity (upper plus lower band). This was then compared with the synaptosomes from the same preparation treated with only Ca²⁺-free seawater (control); n = 6; SEM. *p < 0.05, comparisons between the control and the experimental condition; Student's paired t test . D, Quantitation of changes in the level of S6 in synaptosomes. Levels of S6 were first standardized to the total protein loaded in the lane measured using ponceau staining. Because all lanes from one preparation are aliquots, there was never more than a 20% difference between total levels of proteins in lanes from the same experiment. Each experimental value was then compared with the synaptosomes from the same preparation treated with only Ca²⁺-free seawater (control); n = 6; SEM. *p < 0.05, comparisons between the control and the experimental condition; Student's paired t test. E, The change in level of S6 and the change in the phosphorylation of S6 from each preparation of synaptosomes were compared. The increase in phosphorylation and increase in amounts were inversely correlated, suggesting a specific increase in nonphosphorylated S6.

Aplysia PDK-1 binds to and phosphorylates Aplysia S6 kinase

We were interested in determining whether Aplysia PDK-1 was the primary regulator of Thr 399 phosphorylation. It has beensuggested that PDK-1 not only phosphorylates the PDK-1 site (AplysiaThr 239) but also phosphorylates the PDK-2 site (Aplysia 399)(Balendran et al., 1999). First, we determined whether AplysiaS6 kinase could bind to Aplysia PDK-1, because PDK-1 binds tomany of its substrates (Belham et al., 1999). Indeed, GST fusionproteins of either PDK-1 or a mutant in which the catalytic lysinewas converted to asparagine [PDK-1 (K-N)] bound to baculovirus-expressedS6 kinase, whereas no binding was seen with GST alone (Fig. 9A).However, we were unable to detect kinase activity from these GSTfusion proteins. Therefore, to determine whether PDK could phosphorylateS6 kinase, we took advantage of the fact that, in SF9 cells, overexpressedS6 kinase was primarily unphosphorylated (Fig. 4C) Thus, we constructedbaculovirus vectors for both PDK and PDK (K-N) and expressed PDKin SF9 cells (Fig. 9B).

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Figure 9. Characterization of Aplysia PDK-1. A, GST-PDK-1 binds to S6 kinase. Extracts from SF9 cells expressing S6 kinase were incubated with glutathionine beads containing equal amounts of GST-PDK-1, GST-PDK-1 (K-N), and 10 times higher levels of GST. Glutathione beads were washed and then eluted with sample buffer, and the eluate were separated on a SDS-polyacrylamide gel, transferred to nitrocellulose, and blotted with the antibody to S6-kinase. Ten percent of the starting material was loaded in lane 1 (Start). B, Expression of PDK-1 and PDK-1 (K-N) in SF9 cells. Extracts of SF9 cells infected with PDK, PDK (K-N), or uninfected cells were separated on SDS-polyacrylamide gels, transferred to nitrocellulose, and blotted with the antibody to PDK-1.

Coexpression of Aplysia PDK with Aplysia S6 kinase in baculovirus was sufficient to cause a quantitative shift in the molecularweight of S6 kinase (Fig. 10A, quantitated in C). The mobilityshift required active PDK because no shift was seen after expressionwith PDK (K-N) (Fig. 10A, quantitated in C). Because PDK phosphorylationin cells may require PI-3 kinase activity (Alessi et al., 1998;Pullen et al., 1998), we also tested overexpression of a baculovirusencoding constitutively active PI-3 kinase. This construct increasedPI-3 kinase activity at least 10-fold in SF9 cell membranes (datanot shown). There was no additional shift in S6 kinase when PI-3kinase was expressed with PDK (Fig. 10A, quantitated in C).

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Figure 10. Aplysia PDK-1 phosphorylates Aplysia S6 kinase in SF9 cells. A, Coexpression of PDK-1 with S6 kinase in SF9 cells led to a quantitative shift in S6 kinase migration. Extracts from SF9 cells infected with the viruses shown were separated on SDS-polyacrylamide gels, transferred to nitrocellulose, and blotted for S6 kinase. B, The blot displayed in A was stripped and reprobed with the phospho-specific antibody to Thr 399 (B). When multiple infections are done, less of each virus is expressed as they all use the same promoter. Thus, we attempted to equalize the levels of S6 kinase by loading increasing levels of SF9 cell extract for multiple infections (10 µl, single infections; 20 µl, double infections; 30 µl, triple infections). Although only partially successful, neither of our quantitative results rely on equal loading of the gels. C, Quantitation of the shift in migration. The percentage of kinase in the slower migrating band was divided by the total immunoreactivity. SEM; n = 4. D, The immunoreactivity to the p-Thr-399 antibody was standardized by the immunoreactivity to the total S6 kinase antibody. All results are standardized to the coinfection with PDK-1 and S6 kinase run on the same gel. SEM; n = 4

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Figure 11. A model for S6 knase activation in Aplysia. Steps involved in phosphorylation of Thr 239 (PDK-1 site) are shown. Arrows indicate positive modulation. Lines with bars are negative modulations. The place which pharmacological agents act is indicated. Multiple arrows indicate missing steps. The dashed arrow between PDK-1 and the PDK-2 site indicates an indirect modulation, and the dashed arrow between FRAP and the PDK-2 site indicates the possibility that FRAP directly phosphorylates this site.

PDK-1 modulates threonine 399 phosphorylation in SF9 cells

To determine whether the shift in migration was attributable to phosphorylation at Thr 399, we reprobed experiments examiningcoexpression of PDK and S6 kinase with the phospho-specific antibodyto the PDK-2 site. Coinfection with PDK led to an increase inphosphorylation at Thr 399, and this was associated with an additionalshift in migration (Fig. 10B, quantitated in D). Thus, the initialquantitative shift in migration was probably attributable to phosphorylationof the PDK-1 site, Thr 239. Coinfection with a constitutivelyactive PI-3 kinase virus further increased Thr 399 phosphorylation(Fig. 10B, quantitated in D) and led to some additional immunoreactivitythat migrated at a lower position that may represent S6 kinasephosphorylated only at Thr 399. However, even under these conditions,very little protein was phosphorylated at Thr 399, because immunoreactivitywith the S6 kinase antibody could only be seen comigrating withanti-phospho-Thr 399 immunoreactivity with very long exposures(data not shown). This is in contrast to the quantitative shiftin mobility seem with the total antibody to S6 kinase, presumablyby complete phosphorylation of Thr 239 (Fig. 10A). Moreover, coinfectionwith the kinase-inactive PDK also increased Thr 399 phosphorylationin the presence of PI-3 kinase (Fig. 10B, quantitated in D). However,in this case, all of the Thr 399 phosphorylation was seen in afaster migrating band, consistent with the lack of phosphorylationat the PDK-1 site. This faster migrating Thr 399-phosphorylatedband was never seen in the nervous system, in which Thr 399 phosphorylationwas only observed in the slowest migratingband.

These results suggest that PDK can phosphorylate S6 kinase. PDK also increases phosphorylation at the PDK-2 site, but thisis indirect and does not require kinase activity. The increasedphosphorylation of Thr 399 may be attributable to modulating theavailability of S6 kinase to an endogenous kinase because of bindingof S6 kinase to PDK-1.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Activation of S6 kinase in Aplysia

Our results suggest a model for S6 kinase activation by 5-HT in Aplysia (Fig. 11). Application of 5-HT, through activationof PKA and PKC, increases FRAP activity. FRAP then inactivatesa phosphatase that had been constitutively dephosphorylating Thr399. This leads to increased phosphorylation of Thr 399 and increasedactivity of S6 kinase. This pathway does not require PI-3 kinaseactivity. Similarly, phorbol ester-induced activation of S6 kinasephosphorylation is rapamycin-sensitive but PI-3 kinase-independentin HEK 293 cells (Herbert et al., 2000).

Thr 399 phosphorylation may also requires previous phosphorylation at the Thr 239 (PDK-1 site), because in synaptosomes, onlya single Thr 399 phosphorylated band was seen that comigrateswith the slowest migrating band. This is consistent with resultsfrom vertebrate S6 kinase (Weng et al., 1998). LY249002, an inhibitorof PI-3 kinase, decreased Thr 399 phosphorylation, possibly throughinhibition of Thr 239 phosphorylation or through inhibition ofthe PDK-2 kinase. Phosphorylation at Thr 239 is probably attributableto phosphorylation by Aplysia PDK-1 because, in SF9 cells, coinfectionof PDK-1 was sufficient to quantitatively shift the migrationof S6kinase.

The PDK-2 kinase is still unidentified, although there is some data suggesting that it is FRAP itself (Burnett et al., 1998a;Isotani et al., 1999). It is unlikely that 5-HT activates S6 kinaseby stimulating this kinase. Indeed, in the presence of calyculin-A,5-HT decreased Thr 399 phosphorylation, consistent with a possible5-HT-mediated inhibition of the kinase that phosphorylates thePDK-2 site. We have not yet monitored phosphorylation of otherimportant phosphorylation sites in S6 kinase (Fig. 1), and itis possible that 5-HT modifies phosphorylation of these sitesaswell.

The regulation of S6 kinase in Aplysia synaptosomes shares similarities with its activation in cell lines. Similar to ourresults, phosphorylation of the PDK-2 site is only seen in theslowest migrating form of S6 kinase (Weng et al., 1998). Thr 399phosphorylation is highly rapamycin-sensitive in both systems(Weng et al., 1998), and there appear to be an important rolefor phosphatase regulation in both systems (Peterson et al., 1999).Also, PDK appears to be an upstream kinase in both Aplysia andvertebrates (Alessi et al., 1998; Pullen et al., 1998). The majordifference is that activation of PI-3 kinase is not rate-limitingfor Thr 399 phosphorylation (Weng et al., 1995a; Gingras et al.,1998; Balendran et al., 1999; Nave et al., 1999). There are anumber of plausible explanations for this difference, includingdifferent basal levels of PI-3 kinase levels in synaptosomes,alternative pathways of activating FRAP, or alternative regulationof the PDK-2kinase.

The target of rapamycin

Our results are consistent with the rapamycin-sensitive step required for the retention of long-term facilitation correspondingto activation of S6 kinase. However, there are other targets forthe rapamycin-sensitive enzyme FRAP that also may play a rolein the retention of long-term facilitation. Phosphorylation ofeIF4E-BPs is mediated by FRAP (Brunn et al., 1997). This phosphorylationreleases free eIF4E (Lin et al., 1994; Pause et al., 1994), whichthen can translocate mRNAs to the ribosome. A specific set ofmRNAs that have structured 5' untranslated regions are particularlysensitive to the levels of free eIF4E (Rosenwald et al., 1995;Rousseau et al., 1996). Recently, phosphorylation of a site equivalentto the PDK-2 site in Ca²⁺-independent PKCs was reported to also be rapamycin-sensitive(Parekh et al., 1999). This site is conserved in the Ca²⁺-independent PKC Apl II in Aplysia. It will be interesting todetermine whether these proteins are also regulated in a rapamycin-sensitivemanner in Aplysianeurons.

There are also important aspects of translational regulation at synapses that are independent of rapamycin (Yanow et al.,1998; Casadio et al., 1999). Regulation of translation at synapsesis likely to involve multiple independent mechanisms. These includeregulation of poly-A addition to mRNAs (Wu et al., 1998), increasesin translation initiation (Weiler et al., 1994), and regulationof translation elongation (Scheetz et al., 1997, 2000).

Role for an increase in the presence of translation factors

5-HT increased S6 kinase activity. We observed both an increase in S6 kinase activity and the percentage of more slowly migratingS6 after addition of 5-HT. We also observed an increase in thelevels of S6. Although this may be partially attributable to newsynthesis of S6 (S6 is a protein whose translation is normallyunder regulation of S6 phosphorylation), it may also be that S6is labile in our preparation, and 5-HT induces change in the conformationor localization of S6 that protects it fromdegradation.

Activation of the S6 kinase pathway leads to increases in translation of ribosomal proteins and translation factors (Dufnerand Thomas, 1999). The increase in ribosomal proteins, such asS6, is unlikely to play an important role in synapse-specificplasticity, because ribosomes are assembled in the nucleus, andany protein made at a synapse would have to translocate back tothe nucleus to have any effect on ribosome synthesis. However,the increase in translation factors, such as eIF1 $alpha$ and eIF2 $alpha$ ,could play an important role in the rapamycin sensitivity of long-termmemory. Indeed, preliminary evidence suggests that eIF1 $alpha$ mRNAis translocated to processes, and antibodies against eIF1 $alpha$ blockthe retention of long-term facilitation (Hegde et al., 1999).This is consistent with a model in which rapamycin-sensitive translationof translation factors at synapses is crucial for retention oflong-term facilitation. This increase in translation factors couldlead to a sustained increase in the translational capacity ofthe synapse, and this may be responsible for the retention ofnew varicosities by both increasing translation of RNAs that areat the synapse and RNAs that are emanating from the nucleus. Mutationof S6 kinase leads to small cells and small organisms (Shima etal., 1998; Montagne et al., 1999); we suggest it may also leadto smallersynapses.

  FOOTNOTES

Received Sept. 8, 2000; revised Oct. 20, 2000; accepted Oct. 30, 2000.

This work was supported by Medical Research Council of Canada (MRC) Grant MT-15121 to W.S.S. A.K. is supported by an MRC MD-PhDStudentship, and A.M.P is supported by an MRC PhD Studentship.W.S.S. is a recipient of a Chercheur-Boursier from Fonds de laRecherche en Sante du Quebec. We thank Xiaotang Fan for technicalassistance. We thank Phil Barker and Peter McPherson for commentson thismanuscript.
Correspondence should be addressed to Wayne Sossin, Montreal Neurological Institute, 3801 University Street, Montreal, QuebecH3A 2B4, Canada. E-mail: mdws{at}musica.mcgill.ca.

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