Genetic Enhancement of Visual Learning by Activation of Protein Kinase C Pathways in Small Groups of Rat Cortical Neurons

doi:10.1523/JNEUROSCI.2271-05.2005

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The Journal of Neuroscience, September 14, 2005, 25(37):8468-8481; doi:10.1523/JNEUROSCI.2271-05.2005

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Behavioral/Systems/Cognitive
Genetic Enhancement of Visual Learning by Activation of Protein Kinase C Pathways in Small Groups of Rat Cortical Neurons
Guo-rong Zhang,¹ Xiaodan Wang,¹ Lingxin Kong,¹ Xiu-gui Lu,¹ Brian Lee,¹ Meng Liu,¹ Mei Sun,¹ Corinna Franklin,¹ Robert G. Cook,² and Alfred I. Geller¹
¹Department of Neurology, West Roxbury Veterans Affairs Hospital/Harvard Medical School, West Roxbury, Massachusetts 02132, and ²Department of Psychology, Tufts University, Medford, Massachusetts 02155

   Abstract

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Although learning and memory theories hypothesize that memoriesare encoded by specific circuits, it has proven difficult tolocalize learning within a cortical area. Neural network theoriespredict that activation of a small fraction of the neurons ina circuit can activate that circuit. Consequently, alteringthe physiology of a small group of neurons might potentiatea specific circuit and enhance learning, thereby localizinglearning to that circuit. In this study, we activated proteinkinase C (PKC) pathways in small groups of neurons in rat postrhinal(POR) cortex. We microinjected helper virus-free herpes simplexvirus vectors that expressed a constitutively active PKC intoPOR cortex. This PKC was expressed predominantly in glutamatergicand GABAergic neurons in POR cortex. This intervention increasedphosphorylation of five PKC substrates that play critical rolesin neurotransmitter release (GAP-43 and dynamin) or glutamatergicneurotransmission (specific subunits of AMPA or NMDA receptorsand myristoylated alanine-rich C kinase substrate). Additionally,activation of PKC pathways in cultured cortical neurons supportedactivation-dependent increases in release of glutamate and GABA.This intervention enhanced the learning rate and accuracy ofvisual object discriminations. In individual rats, the numbersof transfected neurons positively correlated with this learning.During learning, neuronal activity was increased in neuronsproximal to the transfected neurons. These results demonstratethat potentiating small groups of glutamatergic and GABAergicneurons in POR cortex enhances visual object learning. Moregenerally, these results suggest that learning can be mediatedby specific cortical circuits.

Key words: visual learning; postrhinal cortex; protein kinase C; neurotransmitter release; glutamate receptor; herpes simplex virus vector

   Introduction

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

Although learning theories hypothesize that memories are encodedby specific circuits (Dudai, 1989), it has proven difficultto localize learning to specific circuits within a forebrainarea. The most precise localization established that spatiallearning requires the dorsal quarter of hippocampus or NMDAreceptors throughout CA1 (using ablation, Moser et al., 1995;using transgenic mice, Tsien et al., 1996). Neural network theoriespredict that activating a small fraction of the neurons in acircuit can activate that circuit (Rumelhart et al., 1986).Consequently, altering the physiology of small groups of neuronscan potentiate a circuit and enhance learning, localizing learningto that circuit within a cortical area.
We hypothesized that activating protein kinase C (PKC) pathwaysin small groups of rat postrhinal (POR) cortex neurons can potentiatethe circuits containing these neurons, enhancing visual learningcapability. Rat POR cortex and analogous areas in monkeys arerequired for visual object discrimination learning (Mishkinand Murray, 1994; Mumby and Pinel, 1994). Lesions includingPOR cortex impair acquisition of visual learning tasks (Mumbyand Pinel, 1994; Bussey et al., 1999), POR cortex receives significantinputs from specific visual areas (Burwell and Amaral, 1998a),and POR cortex neurons are activated by visual stimuli (Wanet al., 1999) or stimulation of visual cortex (Naber et al.,2000).
PKC pathways are good candidates for causing changes in neuronalphysiology that mediate learning. Specific PKC substrates playcentral roles in neurotransmitter release, glutamatergic neurotransmission,and signal transduction. PKC pathways regulate specific neurophysiologicalprocesses (Tanaka and Nishizuka, 1994). Pharmacological activationof PKC enhances release from neurons throughout the nervoussystem (Nichols et al., 1987; Waters and Smith, 2000). PKC inhibitorsblock long-term potentiation (LTP) (Malenka and Nicoll, 1999),and long-term depression (LTD) requires PKC-mediated phosphorylationof specific AMPA receptor subunits (Chung et al., 2003; Seidenmanet al., 2003). Hippocampal PKC levels are altered during performanceof hippocampal-dependent learning tasks, including visual discriminationin a water maze (Olds et al., 1990). PKC ${gamma}$ knock-out mice displaymild deficits in selected learning paradigms (Abeliovich etal., 1993), although impaired cerebellar development and motorcoordination complicate interpretation (Chen et al., 1995; Kanoet al., 1995). PKC ${beta}$ knock-out mice display deficits in fear conditioning(Weeber et al., 2000).
Constitutively active PKCs have important roles in neuronalphysiology. PKCs are activated by calpain cleavage (Kishimotoet al., 1989), and levels are increased during LTP (Powell etal., 1994). Constitutively active PKC ${zeta}$ is transcribed from aninternal promoter (Hernandez et al., 2003) and is necessaryfor LTP (Ling et al., 2002). We reported a constitutively activecatalytic domain of rat PKC ${beta}$ II (Pkc ${Delta}$ ) and a point mutation (Pkc ${Delta}$ GG)lacking activity (Song et al., 1998). Pkc ${Delta}$ increased neurotransmitterrelease from cultured sympathetic neurons (Song et al., 1998).
We report that genetic activation of PKC pathways in small groupsof rat POR cortex neurons enhances visual object discriminationlearning. Pkc ${Delta}$ was expressed in several hundred predominantlyglutamatergic and GABAergic neurons in POR cortex (using a virusvector), increasing phosphorylation of five PKC substrates withcritical roles in neurotransmitter release and glutamatergicneurotransmission. This intervention enhanced accuracy on visualdiscriminations, and, during learning, neuronal activity wasincreased in neurons near the transfected neurons.

   Materials and Methods

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Herpes simplex virus vectors and packaging. pkc ${Delta}$ contains thecatalytic domain of rat PKC ${beta}$ II (nucleotide 994 to the 3' end),and the flag tag was fused to the 5' end of pkc ${Delta}$ (Song et al.,1998, their Fig. 1). Pkc ${Delta}$ GG contains a point mutation; a Glyreplaced an absolutely conserved Lys residue, required for phosphoryltransfer (Hanks et al., 1988; Song et al., 1998). We expressedthese constructs in the yeast Saccharomyces cerevisiae and usedcell extracts to show that Pkc ${Delta}$ exhibits a substrate specificitysimilar to rat brain PKC and that Pkc ${Delta}$ GG lacks protein kinaseactivity (Song et al., 1998, their Tables 1, 2).
A modified neurofilament promoter supported recombinant geneexpression (Zhang et al., 2000). An enhancer from the tyrosinehydroxylase promoter (TH) (–0.5 to –6.8 kb) wasfused to the 5' end of the neurofilament heavy gene promoter(NFH) (0.6 kb); and the chicken ${beta}$ -globin insulator (INS) (1.2kb) was fused to the 5' end of the TH enhancer (Zhang et al.,2000). This promoter (INS-TH-NFH promoter) supported expressionin forebrain neurons for 6 or 14 months, the longest times examined,and time courses in the striatum and the hippocampus documentedexpression in similar numbers of cells at times approximatingthe beginning and end of the testing of new object sets (Zhanget al., 2000; Sun et al., 2004) (supplemental Table S1, availableat www.jneurosci.org as supplemental material).
pINS-TH-NFHpkc ${Delta}$ \INS-TH-NFHlac (Wang et al., 2001) contains twotranscription units; one transcription unit contains pkc ${Delta}$ andthe other contains Lac Z, to facilitate detection of cells thatcontain the vector. This vector coexpresses ${beta}$ -galactosidase ( ${beta}$ -gal)and Pkc ${Delta}$ in POR cortex cells (Wang et al., 2001); 96% of thepositive cells costained for ${beta}$ -gal-immunoreactivity (IR) andflag-IR. pINS-TH-NFHpkc ${Delta}$ GG\INS-TH-NFHlac was constructed usingthe same strategy as for pINS-TH-NFHpkc ${Delta}$ \INS-TH-NFHlac (Wanget al., 2001), except pHSVpkc ${Delta}$ GG (Song et al., 1998) replacedpHSVpkc ${Delta}$ . pINS-TH-NFHlac (Zhang et al., 2000) is a control vectorthat expresses ${beta}$ -gal.
Helper virus-free herpes simplex virus (HSV-1) vector packagingwas performed as described previously (Fraefel et al., 1996),and the vector stocks were purified and titered (Zhang et al.,2000; Wang et al., 2001). The titers were 1.2 ± 0.1 x10⁷ (mean ± SEM) infectious vector particles per milliliter.In each experiment, the titers of the different vector stockswere matched by dilution. No HSV-1 (<10 pfu/ml) was detectedin any of these vector stocks.
Pkc ${Delta}$ is derived from the rat PKC ${beta}$ II isoform (Song et al., 1998),and PKC ${beta}$ knock-out mice display deficits in fear conditioning(Weeber et al., 2000). Pkc ${Delta}$ lacks the regulatory domain thatcontrols the activity of the PKC ${beta}$ isoforms and targets them tospecific subcellular locations (Tanaka and Nishizuka, 1994).Also, Pkc ${Delta}$ is expressed from a heterologous promoter, a modifiedneurofilament promoter (Zhang et al., 2000). Because of thesedifferences in cellular localization, subcellular localization,and regulation of activity, it is not surprising that the Pkc ${Delta}$ in POR cortex condition reported below and PKC ${beta}$ knock-out micedisplay different changes in neuronal physiology and learning.The catalytic domains of all of the PKC isoforms are highlyhomologous (Tanaka and Nishizuka, 1994), and Pkc ${Delta}$ has activityfor each of the eight PKC substrates that have been examined(Song et al., 1998; this study). Thus, use of a catalytic domainfrom a different PKC isoform in the paradigm reported here mightyield similar results.
Neurotransmitter release. Cultures of dissociated temporal cortexcells were prepared from embryonic day 17 Sprague Dawley rats(Dichter, 1978; Wang et al., 2002) and maintained in Neurobasalmedium with B-27 supplement (NB medium) (lacks Glu, Gln, andGABA; Invitrogen, Carlsbad, CA) and 0.5 mM Gln (omitted duringthe release procedure). Cultures were treated with 10 µMcytosine arabinoside (days 3–4) and infected (multiplicityof infection, 0.2) on day 8 or 9, and release of Glu (Feaseyet al., 1986; Di Iorio et al., 1996) and GABA (Snodgrass etal., 1980) was measured 24 h later. Cultures were incubated(15 min, 37°C) in NB medium containing [¹⁴C(U)]-L-Glu (0.73µM, 273 mCi/mmol; PerkinElmer, Shelton, CT) and [2,3-³H(N)]-GABA(0.03 µM, 27.6 Ci/mmol; PerkinElmer). Cultures were washedtwice (all subsequent incubations at room temperature), incubatedin NB medium (15 min, two times; then 3 min, five times; fractionalefflux was stable during the last four incubations), incubatedin NB medium containing 600 µM 4-aminopyridine (4-AP)[3 min, three times (Mitterdorfer and Bean, 2002); Sigma, St.Louis, MO], incubated in NB medium (3 min, three times), andlysed (10 mM EDTA, 1% SDS, and 10 mM Tris HCl, pH 8.0). Theno-calcium condition was NB medium containing 5.5 mM EGTA. Radioactivitywas quantified by liquid scintillation spectroscopy (<10%overlap between ¹⁴C and ³H channels), and fractional effluxwas calculated as the percentage of total radioactivity perwell. Basal efflux was calculated as the average fractionalefflux for the two incubations before 4-AP treatment. 4-AP-dependentrelease was calculated as the ratio of 4-AP treatment/basalefflux. With mock infection, the basal efflux for Glu and GABAwas 2.4 and 2.5%, respectively (similar before and after 4-APtreatment), and 4-AP-dependent release was 168 and 170%, respectively(relative to basal efflux). Each condition was in triplicateand the experiment was repeated twice (six wells per conditiontotal). As used within the context of 4-AP-stimulated effluxover a period of 3 min, "release" is not intended to representeither the initial rates of secretion or those processes underlyingthe rapid kinetics of synaptic transmission.
Gene transfer. Vector stocks were delivered into male Long–Evansrats (initially 100–125 gm; Charles River Laboratories,Wilmington MA) by stereotactic injection (two sites, one perhemisphere, 3 µl/site) into either POR cortex [anteroposterior(AP), –8.0; mediolateral (ML), ±6.0; dorsoventral(DV), –5.2] or primary somatosensory (SSp) cortex (AP,–2.3; ML, ± 1.5; DV, –2.0). AP is relativeto bregma, ML is relative to the sagittal suture, and DV isrelative to the bregma-lambda plane (Paxinos and Watson, 1986).These studies were approved by the West Roxbury Veterans AffairsHospital and Children's Hospital Institutional Animal Care andUse Committees.
Visual testing apparatus. Each of 12 operant chambers was enclosedwithin a 76 cm box (FIS units; Plas Labs, Lansing, MI) thatcontained an overhead fluorescent light and speaker locatedon the rear panel. A ventilation fan provided masking whitenoise. A computer located outside of each test box controlledand recorded experimental events. A touchscreen (IRFP-10.4;Elotouch Systems, Menlo Park, CA) was centered on one of thelong sides of a clear plastic rat cage (46 cm length x 20 cmheight x 24 cm depth) and placed directly in front of a computermonitor. A liquid feeder (ENV-110 and ENV-201A; Med Associates,Lafayette, IN) was mounted in the center of the wall oppositethe computer monitor. A lever (ENV-110; Med Associates) wasmounted underneath the feeder. For additional details, see Cooket al. (2004, their Methods).
Visual testing. For additional details, see Cook et al. (2004,their Methods). The rats were encoded at the beginning of eachexperiment, before the first training session. This blind codewas used to identify the rats to both the computer and the computeroperator throughout the experiment. The rats were maintainedon moderate food deprivation (8 gm/d per rat), and water wasavailable ad libitum (Cook et al., 2004).
As an overview, initial training was performed to familiarizethe rats with the apparatus (Cook et al., 2004); the rats werethen trained to discriminate between horizontal versus verticalbars ( ${equiv}$ vs ). Gene transferwas performed, the rats were retested on this orientation discrimination,and then the rats were tested on a new object set(s). For eachvisual discrimination trial, the rats pressed a lever to obtainan object set and pressed a touchscreen to choose an object,and correct responses were reinforced with both sound and food(Cook et al., 2004). Each experiment required $~$ 2 months: $~$ 1 monthfor the training before gene transfer, and $~$ 1 month for the genetransfer, recovery, and the visual testing after gene transfer.
For simultaneous two-object visual discrimination training,each trial was started by the rat depressing the lever, causingthe stimuli to appear on the screen. The location of a specificimage in an object set was pseudorandomly varied between theleft or right side of the display, with no more than three consecutivepresentations on one side and counterbalanced over blocks of20 presentations. Making contact with the correct stimulus inthe touchscreen resulted in the speaker emitting a sound (1s) and a milk reward (0.1 s; four consecutive correct responsescaused the reward amount to double until the next error). Anincorrect response caused the overhead house light to be turnedoff for 15 s, and a large (23.5 x 10.1 cm) solid rectangle flashedon the monitor three times (for only the initial acquisitionof ${equiv}$ vs , a timeout of3 s was used for the first two sessions only). A correctionprocedure was also used, with every fourth incorrect responsecausing a re-presentation of a trial. Each daily session consistedof 120 discrimination trials, and the rats were trained 7 d/week.For each object set, a specific object was always correct; becauseperformance with either object as correct is similar (Markhamet al., 1996), counterbalancing was not used. Objects were asfollows: ${equiv}$ and , describedpreviously (Cook et al., 2004); ${square}$ , 6.7 cm external side x 0.6cm wide; +, 6.4 x 1.3 cm for each bar; /and \, 8.3 x 1.0 cm(45° or 135° for long side); , ${top}$ , and ${bot}$ , 6.4 cm horizontalbar, 1.3 cm vertical bar, and 0.8 cm wide for both bars.
The experiments were designed to control for any differencesin learning ability among the rats. The rats were assigned tosets of three based on how quickly they acquired ${equiv}$ versus , and, within each set, they were randomlyassigned to one of three groups [Pkc ${Delta}$ , vector system control(Pkc ${Delta}$ GG or ${beta}$ -gal only), or no gene transfer (PBS or no surgery)].Rats received 4 d of food ad libitum, gene transfer, 4 d offood ad libitum, 2 d of moderate food deprivation, and thenvisual testing (Cook et al., 2004). Approximately three-quartersof the rats completed the protocol, and almost all subject attritionoccurred either during training before gene transfer or immediatelyafter the surgery. Twenty minutes before the start of selectedsessions, specific rats received dizocilpine (MK-801; 0.2 mg/kg,i.p.; Sigma).
Data analysis. The data collection and analysis was performedentirely by computer. Data analysis used macros in Excel (Microsoft,Seattle, WA). The data were exported from Excel into Sigma Stat(SPSS, Chicago, IL) for statistical analysis. Statistical analyseswere performed using between groups or repeated measures ANOVAs.Planned comparisons between the numbers of 5-bromo-4-chloro-3-indoyl- ${beta}$ -D-galactopyranoside(X-gal)-positive cells and the learning were evaluated usingPearson's product moment correlations. Each data set was analyzedat least two times to ensure correctness.
In the Pkc ${Delta}$ in POR cortex/ ${square}$ versus + group (n = 33 rats), datafrom five rats were excluded from the behavioral analyses becausethese rats had no needle tracks or X-gal-positive cells (onerat), injection sites outside of POR cortex (three rats), orsubstantial necrosis around the needle tracks (one rat). Includingthese rats in the Pkc ${Delta}$ in POR cortex group still results in astatistically significant enhancement in learning (sessions6–10, Pkc ${Delta}$ in POR cortex vs combined control group, p <0.01).
Immunohistochemistry. The rats were perfused with 50 ml of PBSand then 200 ml of 4% paraformaldehyde in PBS. The brains werepostfixed in 4% paraformaldehyde in PBS (4 h, 4°C) and cryoprotectedin 25% sucrose in PBS (2 d, 4°C), and 25 µm coronalsections were cut using a freezing microtome. Enzymatic stainingand immunohistochemistry were performed on free-floating sections.X-gal (Sigma) staining was performed as described previously(Zhang et al., 2000).
For immunohistochemistry, sections were incubated in PBS and0.3% H₂O₂ (10 min, room temperature) and then rinsed in PBS(three times, 5 min each). Sections were permeabilized by incubationin PBS, 2% normal goat serum, and 0.2% Triton X-100 (bufferA; 30 min, 37°C) and then incubated overnight (4°C)in buffer A with a primary antibody (listed below). The sectionswere rinsed in PBS and 0.2% Triton X-100 (buffer B; three times,10 min each, room temperature) and then incubated in bufferB with biotinylated goat anti-mouse IgG or goat anti-rabbitIgG (1:200 dilution; 2 h, room temperature; Vector Laboratories,Burlingame, CA). The sections were rinsed with buffer B (threetimes, 10 min each, room temperature), incubated with the ABCreagent (1 h, room temperature; Vector Laboratories), and rinsedwith PBS. Immunoreactivity was visualized with diaminobenzideneaccording to the instructions of the manufacturer (Vector Laboratories).
For immunofluorescent visualization, sections were permeabilizedas just described and then incubated with primary antibodies(listed below) in buffer A (overnight, 4°C; then 1 h, 37°C).Sections were washed with PBS (three times, 5 min each) andthen incubated with the appropriate combination of fluoresceinisothiocyanate- or rhodamine isothiocyanate-conjugated goatanti-rabbit IgG, or goat anti-mouse IgG, or rabbit anti-goatIgG (1:150 dilutions; Jackson ImmunoResearch, West Grove, PA)in buffer A (3 h, room temperature). Sections were washed withPBS (three times, 5 min each), mounted in PBS, and immediatelyexamined under the microscope.
The primary antibodies were as follows: rabbit anti- ${beta}$ -gal (1:1000dilution; ICN, Aurora, OH); mouse monoclonal anti- ${beta}$ -gal (1:500dilution; Sigma); mouse monoclonal anti-flag (1:500 dilution;Sigma); mouse monoclonal anti-neuronal-specific nuclear protein(NeuN) (1: 200 dilution; Chemicon, Pittsburg, PA); rabbit anti-phosphate-activatedglutaminase (1:200 dilution; gift from Dr. I. A. Torgner, Universityof Oslo, Oslo, Norway); rabbit anti-glutamic acid decarboxylase(GAD) (1:500 dilution; Chemicon); rabbit anti-choline acetyltransferase(ChAT) (1:300 dilution; gift from Dr. L. B. Hersh, Universityof Kentucky, Lexington, KY); mouse monoclonal anti-TH (1:500dilution; Roche, Indianapolis, IN); goat anti-GAP-43-Ser41-P,goat anti-GAP-43, rabbit anti-dynamin-Ser795-P, rabbit anti-dynamin,rabbit anti-NMDA receptor NR ${zeta}$ 1, rabbit anti-myristoylated alanine-richC kinase substrate (MARCKS)-Ser159/163-P, goat anti-MARCKS,and goat anti-calcium/calmodulin-dependent kinase II (CaMKII)-Thr286-P(1:200 dilutions; Santa Cruz Biotechnology, Santa Cruz, CA);rabbit anti-glutamate receptor subtype 2 (GluR2)-Ser880-P, rabbitanti-GluR2/3, and rabbit anti-NR1-Ser896-P (1:200 dilutions;Upstate Biotechnology, Lake Placid, NY); rabbit anti-c-fos (1:300dilution; Calbiochem, San Diego, CA); mouse monoclonal anti-c-fos(1:500 dilution; Oncogene, Cambridge, MA); goat anti-Arc (1:300dilution; Santa Cruz Biotechnology); and rabbit anti-Zif268(1:400 dilution; Santa Cruz Biotechnology).
Western blots. Western blots were performed as described previously(Oh et al., 2003). Protein extracts were prepared from the areasaround injection sites using CelLyticMT and protease inhibitorcocktail (Sigma), following the instructions of the manufacturer.Each sample was mixed with Laemmli's sample buffer (1:1) andtreated at 95°C for 5 min, and 10 µg was loaded ontoeach lane of a gel. SDS-PAGE was performed using a 10% gel underreducing conditions, and proteins were transferred to an Immuno-Blotpolyvinylidene difluoride membrane (Bio-Rad, Hercules, CA).The membrane was incubated with either rabbit anti-dynamin-Ser795-P(1:500 dilution) or rabbit anti-dynamin (1:1000 dilution), followedby an HRP-conjugated goat anti-rabbit IgG (1:5000 dilution),and visualized using ECL Western Blotting Detection Reagents(Amersham Biosciences, Piscataway, NJ). The bands were subjectedto densitometry scanning, and the density of the band from eachPkc ${Delta}$ or Pkc ${Delta}$ GG rat was divided by the density of the band froma no-surgery rat.
Vector DNA and recombinant RNA analyses. For PCR analysis ofvector DNAs, DNA was extracted (Song et al., 1998) from coronalsections that contained POR cortex and adjacent cortical areas.The PCR conditions and primers were as described previously(Song et al., 1998), except a primer from the mouse neurofilamentheavy gene promoter (nucleotides –297 to –271) replacedthe primer from the HSV-1 immediate early (IE) 4/5 intron; eachset of primers is specific for pkc ${Delta}$ -containing vector sequencesand does not support amplification of the endogenous rat PKC ${beta}$ gene. PCR products were visualized by Southern analysis.

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Figure 1. Recombinant gene expression was targeted to glutamatergic and GABAergic neurons in POR cortex. The rats were killed at 4 d after gene transfer. a, A low-power view shows X-gal-positive cells in POR cortex. The arrow indicates the rhinal sulcus. b, A high-power view shows X-gal-positive cells with neuronal morphology, including pyramidal cell bodies and apical dendrites (the boxed area from a is shown). c–e, Neuronal-specific expression: ${beta}$ -gal-IR (c), NeuN-IR (d), merged (e). Filled arrows, Costained cells; open arrows, ${beta}$ -gal-IR only; open arrowheads, cell marker-IR only. f–h, Glutamatergic neuron-specific expression: ${beta}$ -gal-IR (f), phosphate-activated glutaminase-IR (g), merged (h). i–k, GABAergic neuron-specific expression: ${beta}$ -gal-IR (i), GAD-IR (j), merged (k). l–p, Cholinergic neuron-specific expression: ${beta}$ -gal-IR (l), this field lacks ChAT-IR (m), and one ${beta}$ -gal-IR cell (n), ChAT-IR (o), merged (p). q, r, Catecholaminergic neuron-specific expression: ${beta}$ -gal-IR (q), TH-IR (r). s, Cell counts of the distribution of ${beta}$ -gal-IR in different cell types. PAG, Phosphate-activated glutaminase. Scale bars: a, 200µm; b,25 µm; (in c) c–k, q, r,25 µm; (in l) l, m,50 µm; (in n) n–p,25 µm.

For reverse transcriptase (RT)-PCR analysis of pkc ${Delta}$ RNA, RNAwas extracted from brain fragments that contained POR cortexand adjacent cortical areas (no hippocampus or subcortical areas)using the RNeasy Mini kit (Qiagen, Valencia, CA). RT-PCR wasperformed using the One Step RT-PCR kit (Qiagen) and the secondset of primers for PCR (Song et al., 1998). RT-PCR productswere visualized by Southern blot analysis. In situ hybridizationwas performed as described previously (Song et al., 1998).

   Results

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Gene transfer into neurons in POR cortex
Gene transfer was effected by using a helper virus-free HSV-1vector system (Fraefel et al., 1996) and a previously describedvector that coexpresses Pkc ${Delta}$ and ${beta}$ -gal (Wang et al., 2001). Thisvector uses a modified neurofilament heavy gene promoter thatsupports long-term expression in forebrain neurons (Zhang etal., 2000). This vector coexpresses ${beta}$ -gal and Pkc ${Delta}$ in POR cortexcells (Wang et al., 2001).
We determined the locations and types of transfected cells aftermicroinjection of this vector into POR cortex. Rats were killedat 4 d after gene transfer (one injection site per hemisphere),and positive cells were visualized using sensitive assays for ${beta}$ -gal. We observed groups of X-gal-positive cells proximal tothe injection sites in POR cortex (Fig. 1a). Many of these cellsdisplayed neuronal morphology, including pyramidal cell bodiesand apical dendrites (Fig. 1b). We identified the types of cellsthat were transfected by costaining sections for ${beta}$ -gal-IR andmarkers for specific types of cells. Recombinant gene expressionin neurons was assayed by costaining for ${beta}$ -gal and NeuN (Fig.1c–e). Expression in glutamatergic neurons was assayedby costaining for ${beta}$ -gal and phosphate-activated glutaminase (Kanekoet al., 1995) (Fig. 1f–h), and expression in GABAergicneurons was assayed by costaining for ${beta}$ -gal and GAD (Fig. 1i–k).Expression in cholinergic neurons was assayed by costainingfor ${beta}$ -gal and ChAT (Fig. 1l–p), and expression in catecholaminergicneurons was assayed by costaining for ${beta}$ -gal and TH (Fig. 1q,r).Cell counts (Fig. 1s) established that $~$ 91% of the transfectedcells were neurons, $~$ 52% were glutamatergic and $~$ 45% were GABAergic,<1% were cholinergic, and no TH-immunoreactive cells weredetected in POR cortex, consistent with previous reports (Hokfeltet al., 1984).
We were concerned that recombinant gene expression in otherbrain areas could potentially affect learning. Most previousstudies with HSV-1 vectors reported that the preponderance ofrecombinant gene expression was proximal to the injection site,with only low levels of expression at distant sites, attributableto retrograde transport of HSV-1 vectors through axons. Nonetheless,we directly addressed this concern by assaying for recombinantgene expression in specific cortical areas that project to PORcortex and in specific subcortical areas. Rats were killed at4 d after microinjection of vector into POR cortex, and $~$ 300 ${beta}$ -gal-immunoreactive cells were observed in each POR cortex (datanot shown). Small numbers (one to four) of ${beta}$ -gal-immunoreactivecells were observed in specific cortical areas with large projectionsto POR cortex (Fig. 2a–c). In particular, perirhinal cortex,which has a major projection to POR cortex (Burwell and Amaral,1998b), contained only $~$ 1% of the number of ${beta}$ -gal-immunoreactivecells as POR cortex. No ${beta}$ -gal-immunoreactive cells were observedin any of the subcortical areas examined, including the hippocampus,amygdala, specific cholinergic basal forebrain areas, and specificcatecholaminergic midbrain areas (Fig. 2d–j).
Together, these results demonstrate that, after microinjectionof this vector into POR cortex, the vast majority of recombinantgene expression is in glutamatergic and GABAergic neurons inPOR cortex. Thus, any changes in learning that may occur aftergene transfer are most likely attributable to the effects ofPkc ${Delta}$ on the physiology of glutamatergic and/or GABAergic neuronsin POR cortex.

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Figure 2. Minimal recombinant gene expression was detected in specific cortical areas that project to POR cortex, and no recombinant gene expression was observed in specific subcortical areas. The rats were killed at 4 d after microinjection of vector into POR cortex. a, b, High-power views show two ${beta}$ -gal-immunoreactive cells, one each in perirhinal cortex (a) and lateral visual association cortex (b). c, Summary of the cortical areas that contain or lack ${beta}$ -gal-immunoreactive cells. The nomenclature for cortical areas, and the densities of the projections to POR cortex, are according to Burwell and Amaral (1998a). d, e, Low-power views show no ${beta}$ -gal-immunoreactive cells in either hippocampus (d) or amygdala (e). f, g, Basal forebrain: ChAT-IR identifies the medial and lateral septum (f), and no ${beta}$ -gal-immunoreactive cells were detected in an adjacent section (g). h, i, Midbrain: TH-IR identifies the substantia nigra pars compacta and ventral tegmental area (h), and no ${beta}$ -gal-immunoreactivecellsweredetectedinanadjacentsection(i).j,Summaryofthesubcorticalareasthatlack ${beta}$ -gal-immunoreactivecells. The nomenclature is according to Paxinos and Watson (1986). Scale bars: a, b,25 µm; d–i, 200 µm.

Recombinant gene expression was maintained for the time required for visual testing
In most experiments, new object sets were learned between 2and 4 weeks after gene transfer (detailed below). Using PCR,we showed that vector DNA is present in the POR cortex of ratskilled after visual testing (Fig. 3a). Furthermore, we documentedlong-term recombinant gene expression using five different assays,RT-PCR, in situ hybridization, X-gal staining, ${beta}$ -gal-IR, andflag-IR. Using RT-PCR, pkc ${Delta}$ RNA was detected in the POR cortexof rats killed at 3 weeks after gene transfer (Fig. 3A). Thebands produced from samples isolated from three rats (Rats 1–3lanes) comigrated with the band produced using plasmid DNA astemplate (plasmid DNA lane). The signal was from RNA, and notfrom DNA, because a reaction that omitted the RT lacked theband (Rat 3 no RT lane). No band was observed in the absenceof any RNA sample or plasmid DNA (no template lane). Using insitu hybridization, recombinant RNAs were localized to POR cortexcells in rats killed after visual testing (Fig. 3b); the hybridizationprobe recognizes the 3' untranslated region in both pkc ${Delta}$ andLac Z RNAs. No signal was observed if the hybridization probewas omitted (Fig. 3c). Also, no signal was observed in the entorhinalcortex of rats that received Pkc ${Delta}$ (Fig. 3d) or in the POR cortexof no-surgery rats (Fig. 3e). Additionally, both ${beta}$ -gal and Pkc ${Delta}$ proteins were detected in rats killed after visual testing;X-gal-positive cells were observed (Fig. 3f), cells that coexpress ${beta}$ -gal-IR and flag-IR [Pkc ${Delta}$ contains the flag tag (Song et al.,1998)] were observed (Fig. 3g–i), and ${beta}$ -gal-IR was localizedto neurons (Fig. 3j–l). Furthermore, in rats killed at3 weeks after gene transfer, >80% of the cells that containedPkc ${Delta}$ were neurons, as shown by costaining for flag-IR and a neuronalmarker (GAP-43-Ser41-P, detailed below).

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Figure 3. Long-term recombinant gene expression in POR cortex neurons. a, PCR analysis of pkc ${Delta}$ vector DNA and RT-PCR analysisofpkc ${Delta}$ RNA. The rats were killed at 3 weeksm after genetransfer. ThepredictedsizeofthePCR and RT-PCR products is 1003 bp. b–e, In situ hybridization was performed on rats killed after visual testing. The digoxigenin-containing hybridization probe was visualized using an alkaline phosphatase-conjugated anti-digoxigenin antibody and the alkaline phosphatase reaction (black). Sections were counterstained with methyl green, which stains nuclei. b, c, A rat that received Pkc ${Delta}$ : POR cortex (b) and entorhinal cortex (c). Filled arrows, Hybridization signal; open arrows, cell nuclei. d, A no-surgery rat, POR cortex. e, No hybridization probe, a rat that received Pkc ${Delta}$ , POR cortex (section proximal to that in b). f, X-gal-positive cells in POR cortex in a rat killed after visual testing. g–i, Coexpression of ${beta}$ -gal and Pkc ${Delta}$ in POR cortex in a rat killed after visual testing: ${beta}$ -gal-IR (g), flag-IR (h), merged(i). Arrows,Costainedcells.j–l, ${beta}$ -galisexpressedinPORcortexneuronsinaratkilledaftervisualtesting: ${beta}$ -gal-IR(j),NeuN-IR (k), merged (l). Arrows, Costained cells; open arrowhead, NeuN-IR only. Scale bars: b (for b–e, j–l), f, g (for g–i), 25µm.

The minimal side effects that were observed are unlikely toenhance learning. There were minimal cytopathic effects andcell infiltration at the injection site, consistent with previousreports (Fraefel et al., 1996, their Fig. 5 and Table 2) (supplementaldata, available at www.jneurosci.org as supplemental material).No brain tumors or gross behavioral abnormalities were observed.None of the rats that received Pkc ${Delta}$ (or control vectors) displayedany behaviors that would suggest seizure activity. Also, althoughseizures induce c-fos, rats that received Pkc ${Delta}$ and no visualtesting contained only very low numbers of c-fos-immunoreactivecells in POR cortex (detailed below).
Pkc ${Delta}$ activated PKC pathways in POR cortex during the time of visual testing
We investigated the effects of Pkc ${Delta}$ on the phosphorylation stateof five different PKC substrates in POR cortex neurons. We usedphospho-specific antibodies to examine the prevalence of specificphospho-proteins in Pkc ${Delta}$ - or Pkc ${Delta}$ GG-containing cells or in unaffectedneurons. In rats killed at 3 weeks after gene transfer, Pkc ${Delta}$ -containingcells were identified using an anti-flag antibody, and thesesections were costained with an antibody against a specificphospho-protein. Pkc ${Delta}$ -containing cells showed high levels ofcostaining for two phospho-proteins that play critical rolesin neurotransmitter release, GAP-43-Ser41-P (Fig. 4a–c)and dynamin-Ser795-P (supplemental Fig. S1a–c, availableat www.jneurosci.org as supplemental material). Pkc ${Delta}$ -containingcells also showed high levels of costaining for the phosphorylatedforms of two receptors that are essential for glutamatergicneurotransmission and learning, AMPA receptor GluR2 subunit-Ser880-P(supplemental Fig. S2a–c, available at www.jneurosci.orgas supplemental material) and NMDA receptor NR1 subunit-Ser896-P(supplemental Fig. S3a–c, available at www.jneurosci.orgas supplemental material). Additionally, Pkc ${Delta}$ -containing cellsshowed high levels of costaining for a phospho-protein involvedin signal transduction, MARCKS-Ser159/163-P (supplemental Fig.S4a–c, available at www.jneurosci.org as supplemental material).In contrast, Pkc ${Delta}$ GG-containing cells, or neurons inno-surgery rats (identified using an anti-NeuN antibody), showedonly low levels of costaining for each of these five phospho-proteins(for GAP-43-Ser41-P, see Fig. 4d–i) (for the other fourphospho-proteins, see supplemental Figs. S1–S4, d–i).Cell counts established that Pkc ${Delta}$ , but not Pkc ${Delta}$ GG, supported 240–1140%increases in costaining for each of these five phospho-proteinscompared with neurons in no-surgery rats (Fig. 4m) (supplementalTable S2, available at www.jneurosci.org as supplemental material).Pkc ${Delta}$ likely increased phosphorylation of each of these substratesduring the time of visual learning because similar increaseswere observed in rats killed at either 4 d or 3 weeks aftergene transfer. These increases in phosphorylation state werelikely attributable to direct phosphorylation by Pkc ${Delta}$ becauseeach of these PKC phosphorylation sites is not known to be phosphorylatedby other protein kinases. As an additional control, Pkc ${Delta}$ didnot increase costaining for a phospho-protein that is not aPKC substrate, CaMKII-Thr286-P (Fig. 4m) (supplemental Fig.S5, Table S2, available at www.jneurosci.org as supplemental material);to verify this assay, no-surgery rats were treatedwith systemic clozapine, and neurons showed increased costainingfor CaMKII-Thr286-P.
Next, we determined the maximum potential level of costainingfor each phosphoprotein by measuring the percentages of neuronsthat contain each protein independent of phosphorylation. Neuronsin no-surgery rats were costained for each protein independentof phosphorylation, and costaining was observed using four ofthe antibodies (for GAP-43, see Fig. 4j–l) (for dynamin,AMPA GluR2, and NMDA NR1, see supplemental Figs. S1–S3,j–l, available at www.jneurosci.org as supplemental material);MARCKS was detected in a dense neuropil that obscured NeuN costaining(data not shown). Cell counts showed that Pkc ${Delta}$ supported levelsof costaining for phospho-GAP-43, phospho-dynamin, phospho-AMPAreceptors, and phospho-NMDA receptors that approached the maximumpotential levels (Fig. 4m) (supplemental Table S2, availableat www.jneurosci.org as supplemental material).
Additionally, we used Western analysis to confirm that Pkc ${Delta}$ increasedphosphorylation of dynamin. We killed rats at 4 d after genetransfer, prepared protein extracts from tissue proximal tothe injection sites, and probed Western blots with antibodiesthat recognize either phosphodynamin (Fig. 4n) or dynamin independentof phosphorylation (Fig. 4o). Densitometry scans of the blotsshowed that Pkc ${Delta}$ , but not Pkc ${Delta}$ GG, increased the levels of phospho-dynamincompared with the levels found in no-surgery rats (Pkc ${Delta}$ /no-surgery,2.4 ± 0.5; Pkc ${Delta}$ GG/no-surgery, 0.9 ± 0.2; mean ±SEM; p < 0.05, t test). Pkc ${Delta}$ did not affect the levels ofdynamin protein (Pkc ${Delta}$ /no-surgery, 1.1 ± 0.1; Pkc ${Delta}$ GG/no-surgery,0.9 ± 0.1; p > 0.05).

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Figure 4. Pkc ${Delta}$ increased phosphorylation of five PKC substrates in POR cortex cells, and Pkc ${Delta}$ supported activation-dependent increases in neurotransmitter release from cultured temporal cortex cells. a–l, Pkc ${Delta}$ increased costaining for phosphorylated GAP-43 in POR cortex neurons, in a rat killed at 3 weeks after gene transfer. a–c, Pkc ${Delta}$ phosphorylated GAP-43: flag-IR (a), GAP-43-Ser41-P-IR (b), merged (c). Filled arrows, Costained cells; open arrows, flag-IR only. d–f, Pkc ${Delta}$ GG did not phosphorylate GAP-43: flag-IR (d), GAP-43-Ser41-P-IR (e), merged (f). g–i, Neurons in no-surgery rats contained low levels of phosphorylated GAP-43: NeuN-IR (g), GAP-43-Ser41-P-IR (h), merged (i). j–l, Neurons in no-surgery rats contained GAP-43 protein: NeuN-IR (j), GAP-43-IR (k), merged (l). m, The percentage of costaining for Pkc ${Delta}$ and specific phospho-proteins and controls; 100–400cellswerecountedforeachcondition.n,WesternblotanalysisshowedthatPkc ${Delta}$ ,butnotPkc ${Delta}$ GG,increasedthelevels of dynamin-Ser795-P compared with the levels in no-surgery rats. o, Western blot analysis showed that Pkc ${Delta}$ did not alter the levels of dynamin protein (independent of phosphorylation) compared with the levels in either Pkc ${Delta}$ GG or no-surgery rats. p, Pkc ${Delta}$ , but not Pkc ${Delta}$ GG, supported increases in the 4-AP-dependent release of Glu and GABA from cultured temporal cortex cells compared with mock infection (mean ± SEM). Each condition was in triplicate, and the experiment was repeated twice (6 wells per condition total). Scale bar: (in a) a–l,25 µm.

Because activation of PKC increases neurotransmitter release(Nichols et al., 1987; Waters and Smith, 2000), we examinedthe effects of Pkc ${Delta}$ on neurotransmitter release from culturedtemporal cortex neurons. We infected temporal cortex cells indissociated cultures and, 1 d later, measured release of preloaded,radiolabeled [¹⁴C]Glu and [³H]GABA. Pkc ${Delta}$ did not affect basalefflux (low K⁺) of Glu or GABA compared with the controls (Pkc ${Delta}$ GGor mock infection, p > 0.05, ANOVAs) (Fig. 4p). We mimickedactivation-dependent conditions by blocking specific voltage-gatedpotassium channels with 4-AP. Of note, Pkc ${Delta}$ , but not Pkc ${Delta}$ GG, supportedincreases in the 4-AP-dependent release of Glu and GABA comparedwith mock infection (Fig. 4p) [Pkc ${Delta}$ vs Pkc ${Delta}$ GG or mock, p <0.01 (Glu) or p < 0.05 (GABA); Pkc ${Delta}$ GG vs mock, p > 0.05(Glu or GABA)]. The 4-AP-dependent release of Glu and GABA wasCa²⁺ dependent in each condition (data not shown; p > 0.05).Thus, Pkc ${Delta}$ increased phosphorylation of two proteins that playcritical roles in neurotransmitter release, GAP-43 and dynamin,and Pkc ${Delta}$ supported activation-dependent increases in neurotransmitterrelease from both cultured sympathetic neurons (Song et al.,1998, their Table 3) and cultured temporal cortex neurons.
Pkc ${Delta}$ in POR cortex neurons enhanced visual object learning
Rats were tested on simultaneous visual object discriminationsusing a computer-controlled touchscreen apparatus. For eachtrial, the rats pressed a lever to obtain an object set andpressed a touchscreen to choose an object (Cook et al., 2004,their Methods). To ensure uniform testing conditions, each apparatuswas enclosed in a light-proof, sound-attenuating chamber. Throughoutthe behavioral testing, the rats were identified by a code thatcontained no information about their gene transfer condition.
Visual learning was evaluated after activation of PKC pathwaysin POR cortex neurons. In the experimental protocol (Fig. 5a),rats were first trained to discriminate between horizontal versusvertical bars ( ${equiv}$ vs ),and, after gene transfer, the rats were retested on this orientationdiscrimination. There were no significant differences in accuracybetween the groups on this orientation discrimination, beforeor after gene transfer, in any experiment (Fig. 5b,c) (p >0.05, ANOVAs). The rats were then trained on a new discrimination( ${square}$ vs +), after which histological analyses were performed. Fourindependent experiments were performed. Each experiment containedthree groups: (1) Pkc ${Delta}$ in POR cortex, (2) a vector system controlgroup (either ${beta}$ -gal only or ${beta}$ -gal and Pkc ${Delta}$ GG), and (3) a no genetransfer control group [vehicle alone (PBS) or no surgery] (supplementalTable S3, available at www.jneurosci.org as supplemental material).In the first experiment, the rats that received Pkc ${Delta}$ learnedthe new object set ( ${square}$ vs +) to a significantly higher level ofaccuracy than the different controls (Fig. 5b) (sessions 6–10,p < 0.001, ANOVA; statistical comparisons used the last fivesessions because most of the learning was completed by sessions5–6). The Pkc ${Delta}$ group also required fewer sessions to reach75% correct compared with the control group [second session $≥$ 75%: Pkc ${Delta}$ , 5.0 ± 0.60 (mean ± SEM); control ( ${beta}$ -galand PBS), 7.2 ± 0.61; p < 0.05]. In three additionalexperiments, the rats that received Pkc ${Delta}$ also showed higher levelsof accuracy compared with the controls (data not shown) [experiment2, sessions 5–9, p < 0.05 (rats inadvertently killedafter session 9); experiment 3, sessions 6–10, p <0.05; experiment 4, sessions 6–10, p = 0.068; but sessions6–9, p < 0.04; and sessions 4–10, p < 0.03].

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Figure 5. Rats that received Pkc ${Delta}$ in POR cortex displayed enhanced performance on a new object set ( ${square}$ vs +). a, A time line showing the experimental design. b, In one experiment, the performance on ${equiv}$ versus , before or after gene transfer, was similar for the rats in the different groups (mean ± SEM). In contrast, the rats that received Pkc ${Delta}$ exhibited enhanced performance on a new object set, ${square}$ versus + (mean ± SEM; Pkc ${Delta}$ , n = 8 rats; ${beta}$ -gal, n = 11 rats; PBS, n = 9 rats). c, The performance of the rats from four independent experiments [Pkc ${Delta}$ , n = 28 rats; vector system controls, n = 43 rats; (Pkc ${Delta}$ GG plus ${beta}$ -gal, n = 21 rats; ${beta}$ -gal only, n = 22 rats; these subgroups was virtually indistinguishable); PBS, n = 25 rats; no surgery, n = 27 rats].d,RatsthatreceivedPkc ${Delta}$ inSSpcortexdisplayedsimilarperformanceon ${square}$ versus + compared with the rats in the combined control group (vector system controls, PBS,andnosurgery;Pkc ${Delta}$ /SSpcortex, n = 9 rats; other rats from c). e, The numbers of trials per session completed by the rats in each group (mean ± SEM).

To isolate performance within individual sessions, we examinedthe performance of all of the rats from the four experiments,using a series of separate ANOVAs (Fig. 5c). For each of sessions6, 7, 8, 9, and 10, we found no significant differences betweenthe no-surgery group and the other control groups (no surgeryvs either PBS or Pkc ${Delta}$ GG plus ${beta}$ -gal; p > 0.05). Of most importance,we found that the rats that received Pkc ${Delta}$ displayed significantlyhigher accuracies during each of sessions 6, 7, and 8 comparedwith the combined control group (no surgery, PBS, and Pkc ${Delta}$ GGplus ${beta}$ -gal; p < 0.05), and a higher accuracy that approachedsignificance for session 9 (p = 0.096). The accuracy exhibitedby the rats in the control groups was comparable with that inother touchscreen paradigms (Markham et al., 1996). There weresmall variations in the performance of the control groups betweenthe four experiments, resulting in modestly larger differencesbetween the control groups for the combined four experiments(Fig. 5c) than for each individual experiment (such as Fig.5b). Despite this modest variation in the control groups betweenexperiments, Pkc ${Delta}$ consistently increased accuracy 5–15%in the combined four experiments (Fig. 5c, sessions 6–10).
As an additional control, delivery of Pkc ${Delta}$ into cells in a corticalarea not involved in visual learning, SSp cortex, did not enhancelearning relative to controls and was significantly poorer thanPkc ${Delta}$ in POR cortex (Fig. 5d) (sessions 6–10; Pkc ${Delta}$ in SSpcortex vs combined controls, p > 0.05; Pkc ${Delta}$ in SSp cortexvs Pkc ${Delta}$ in POR cortex, p $≤$ 0.001). Also, the enhanced performanceexhibited by the Pkc ${Delta}$ in POR cortex group was not attributableto the completion of more trials because all of the groups completedsimilar numbers of trials throughout the testing (Fig. 5e) (p> 0.05).
We established that the activity of NMDA receptors is requiredfor this discrimination because systemic injection of dizocilpinereduced performance to chance in rats that received Pkc ${Delta}$ in PORcortex [dizocilpine, 52 ± 6% correct (mean ± SEM);next session, 84 ± 2%; p < 0.001 (t test); systemicPBS, 87 ± 2%; next session, 87 ± 2%; p > 0.05].Injection of dizocilpine did not significantly affect motoractivity (dizocilpine, 111 ± 9 trials; next session,125 ± 4 trials; systemic PBS, 118 ± 8 trials;next session, 116 ± 12 trials).
To confirm that the POR cortex neurons that contained Pkc ${Delta}$ supportedthe enhanced learning, we investigated the relationship betweenthe numbers of transfected cells and the learning in individualrats. Two planned comparisons were evaluated using Pearson'sproduct moment correlations. (Although we used this linear regressionmethod to establish correlations, we recognize that complexnonlinear mechanisms may influence how the numbers and typesof transfected cells affect performance.) We examined the learningrate by evaluating the number of sessions required to reachtwo sessions $≥$ 75% correct. We examined steady-state accuracyby evaluating the average percentage correct for sessions 6–10.For the rats that received Pkc ${Delta}$ in POR cortex, the numbers oftransfected cells correlated with both the learning rate (Fig.6a) and the steady-state accuracy (Fig. 6d), but the rats thatreceived either Pkc ${Delta}$ GG in POR cortex (Fig. 6b,e) or Pkc ${Delta}$ in SSpcortex (Fig. 6c,f) did not exhibit these correlations (learningrates: Pkc ${Delta}$ in POR cortex, r₍₁₁₎ = –0.67, p < 0.05;Pkc ${Delta}$ GG in POR cortex, r₍₁₂₎ = –0.10, p > 0.05; Pkc ${Delta}$ inSSp cortex, r₍₉₎ = –0.23, p > 0.05; steady-state accuracies:Pkc ${Delta}$ in POR cortex, r₍₁₁₎ = 0.86, p < 0.01; Pkc ${Delta}$ GG in POR cortex,r₍₁₂₎ =–0.18, p > 0.05; Pkc ${Delta}$ in SSp cortex, r₍₉₎ =–0.094,p > 0.05). Thus, activation of PKC pathways in POR cortexneurons enhanced learning (Fig. 5), and the number of transfectedneurons correlated with both the learning rate and steady-stateaccuracy (Fig. 6).

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Figure 6. For individual rats that received Pkc ${Delta}$ in POR cortex, the numbers of transfected cells was correlated with performance on ${square}$ versus +. a–c, Learning rates (second session $≥$ 75%): Pkc ${Delta}$ in POR cortex (a), Pkc ${Delta}$ GG in POR cortex (b), Pkc ${Delta}$ in SSp cortex (c). d–f, Steady-state accuracies (average of sessions 6–10): Pkc ${Delta}$ in POR cortex (d), Pkc ${Delta}$ GG in POR cortex (e), Pkc ${Delta}$ in SSp cortex (f).

Learning of object sets of varying difficulty
We next examined how the level of difficulty of an object setmodified the effects of Pkc ${Delta}$ on learning. Again, there were nodifferences between the different groups on the retested orientationdiscrimination (Fig. 7a) ( ${equiv}$ vs ;p > 0.05). The rats that received Pkc ${Delta}$ displayed enhancedaccuracy on /versus \ compared with the control groups (Fig.7a) (sessions 6–10; Pkc ${Delta}$ vs either Pkc ${Delta}$ GG or no surgery,p < 0.01; Pkc ${Delta}$ GG vs no surgery, p > 0.05). The two objectsets /versus \ and ${square}$ versus + appear to be of similar difficulty,because most rats learned these object sets in four to six sessions.There were small differences in the learning of these two imagesets (compare Figs. 5b, 7a), but these differences were notstatistically significant [Pkc ${Delta}$ ${square}$ vs + (Fig. 5b) compared withPkc ${Delta}$ / vs \ p > 0.05; control groups ${square}$ vs + (Fig. 5b) comparedwith control groups / vs \ p > 0.05]. A second phase testedthese rats on an easier object set that was learned in lessthan one session, and there were no differences between thegroups (Fig. 7b, top) (p > 0.05). Conversely, rats that receivedPkc ${Delta}$ failed to learn a difficult object set that the rats ina control group also failed to learn (Fig. 7b, bottom). Thus,five experiments (Figs. 5, 7) (supplemental Table S3, availableat www.jneurosci.org as supplemental material) showed that Pkc ${Delta}$ enhanced the learning of two different object sets of similar,intermediate difficulty.

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Figure 7. Performance on object sets of different difficulties. a, Rats that received Pkc ${Delta}$ in POR cortex displayed enhanced performance on an object set learned in four to six sessions (/ vs \ compared with the rats in the control groups (Pkc ${Delta}$ , n = 12 rats; Pkc ${Delta}$ GG, n = 10 rats; no surgery, n = 10 rats). The rats in the different groups showed similar learning on ${equiv}$ versus . b, The rats in the different groups exhibited similar performances on an object set that was learned in less than one session ( vs ${top}$ ) or on an object set that was not acquired ( vs ${bot}$ ).

Pkc ${Delta}$ potentiated the activity of specific POR cortex circuits during the learning
We investigated the levels of neuronal activity in neurons proximalto the transfected neurons. We focused on the sustained neuronalactivity produced by accurate visual discrimination rather thanchanges in synaptic plasticity during the initial learning,by examining the rats after session 10 on ${square}$ versus +. To examinethe activity of many neurons located proximal to the transfectedneurons, we measured induction of three IE genes, c-fos, Arc,and Zif268. Visual learning increases c-fos-immunoreactive celldensity in POR cortex (Wan et al., 1999); Arc-IR is a markerfor active synapses (Lyford et al., 1995); and Zif268 is requiredfor late LTP, long-term memory, and reconsolidation (Bozon etal., 2003). Thus, any changes observed in all three assays werelikely caused by sustained neuronal activity rather than bycoincidental induction of all three IE genes by independentmechanisms unrelated to neuronal activity.
Rats were killed immediately after session 10, neuronal activitywas assayed using c-fos-IR, or Arc-IR, or Zif268-IR, and thetransfected cells were identified using X-gal staining. Controlrats that received Pkc ${Delta}$ GG/ ${square}$ versus + contained relatively uniformlevels of c-fos-IR and Arc-IR at different distances from theinjection site (Fig. 8a,d). In contrast, experimental rats thatreceived Pkc ${Delta}$ / ${square}$ versus + contained elevated levels of c-fos-IRand Arc-IR proximal to the injection sites (Fig. 8b,e). High-powerviews showed that the c-fos-IR was localized to nuclei, andthe Arc-IR was localized to processes (Fig. 8c,f). Additionally,sections from a rat that received Pkc ${Delta}$ / ${square}$ versus + were costainedfor c-fos-IR and Zif268-IR, and high-power views showed thatc-fos-IR and Zif268-IR were present in many of the same cells(Fig. 8g–i).
We used stereology to quantify c-fos-immunoreactive cell densitiesand Arc-immunoreactive densities in column-shaped volumes, extendingfrom the cortical surface to the white matter, at differentdistances from the injection site. A photomicrograph of thestereological counting contours (Fig. 8j) shows that most ofthe transfected cells were contained within an $~$ 200-µm-widevolume [volume labels: injection site dorsal (I-D) or injectionsite ventral (I-V)]. We also counted three volumes at increasingdistances from the injection site in either the dorsal or ventraldirections (volume labels: dorsal or ventral 1, 2, or 3 (abbreviatedD-1 through V-3)].
Of note, rats that received Pkc ${Delta}$ / ${square}$ versus + contained higher c-fos-immunoreactivecell density (270%) and Arc-immunoreactive density (250%) in $~$ 200-µm-wide and $~$ 600-µm-wide volumes, respectively,centered on the injection site compared with the other volumes(Fig. 8k,l) (c-fos-IR: ${Sigma}$ I-D,I-V volumes compared with ${Sigma}$ D1–3,V1–3volumes, p < 0.001; ${Sigma}$ D1–3 compared with ${Sigma}$ V1–3,p > 0.05; Arc-IR: ${Sigma}$ V-1,I,D-1 compared with ${Sigma}$ D2–4,V2–4,p < 0.005; ${Sigma}$ D2–4 compared with ${Sigma}$ V2–4, p > 0.05).The wider ( $~$ 600 µm) volume of increased Arc-immunoreactivedensity, a marker for active synapses (Lyford et al., 1995),may be attributable to axon collaterals from neurons withinthe $~$ 200-µm-wide volume of increased c-fos-immunoreactivecell density. These increases in neuronal activity requiredlearning a new object set ( ${square}$ vs +), because these increases werenot observed in rats that received Pkc ${Delta}$ and retesting after genetransfer on the initial discrimination ( ${equiv}$ vs ) (Fig. 8k,l) (c-fos-IR: Pkc ${Delta}$ / ${square}$ vs + ${Sigma}$ I-D,I-V comparedwith Pkc ${Delta}$ / ${equiv}$ vs , p <0.001; Arc-IR: Pkc ${Delta}$ / ${square}$ vs + ${Sigma}$ V-1,I,D-1 compared with Pkc ${Delta}$ / ${equiv}$ vs , p < 0.001).

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