Brain-Derived Neurotrophic Factor Differentially Regulates Excitatory and Inhibitory Synaptic Transmission in Hippocampal Cultures

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The Journal of Neuroscience, May 1, 2000, 20(9):3221-3232

Brain-Derived Neurotrophic Factor Differentially Regulates Excitatory and Inhibitory Synaptic Transmission in Hippocampal Cultures
M. McLean Bolton, Andrew J. Pittman, and Donald C. Lo
Department of Neurobiology, Duke University Medical Center, Durham, North Carolina 27710

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Brain-derived neurotrophic factor (BDNF) has been postulated to be a key signaling molecule in regulating synaptic strengthand overall circuit activity. In this context, we have found thatBDNF dramatically increases the frequency of spontaneously initiatedaction potentials in hippocampal neurons in dissociated culture.Using analysis of unitary synaptic transmission and immunocytochemicalmethods, we determined that chronic treatment with BDNF potentiatesboth excitatory and inhibitory transmission, but that it doesso via different mechanisms. BDNF strengthens excitation primarilyby augmenting the amplitude of AMPA receptor-mediated miniatureEPSCs (mEPSCs) but enhances inhibition by increasing the frequencyof mIPSC and increasing the size of GABAergic synaptic terminals.In contrast to observations in other systems, BDNF-mediated increasesin AMPA-receptor mediated mEPSC amplitudes did not require activity,because blocking action potentials with tetrodotoxin for the entireduration of BDNF treatment had no effect on the magnitude of thisenhancement. These forms of synaptic regulations appear to bea selective action of BDNF because intrinsic excitability, synapsenumber, and neuronal survival are not affected in these cultures.Thus, although BDNF induces a net increase in overall circuitactivity, this results from potentiation of both excitatory andinhibitory synaptic drive through distinct and selective physiologicalmechanisms.

Key words: neurotrophins; BDNF; hippocampal neurons; synaptic plasticity; excitatory synaptic transmission; inhibitory synaptic transmission; AMPA receptors; NMDA receptors

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Members of the neurotrophin family of peptide growth factors, particularly brain-derived neurotrophic factor (BDNF), are emergingas important mediators of activity-dependent modifications insynaptic strength. Their biological roles in such processes, however,remain uncertain. Whereas in some situations BDNF has been foundto increase synaptic strength, such as at developing neuromuscularsynapses and at excitatory synapses onto CA1 hippocampal neurons(Lohof et al., 1993; Vicario-Abejon et al., 1998; Sherwood andLo, 1999), in cortical cultures, BDNF has been proposed to regulatethe strength of all synapses onto a given neuron to maintain homeostasis(Rutherford et al., 1998). Consistent with both of these potentialbiological roles, the production and release of BDNF is activity-dependentin a variety of neuronal systems (McAllister et al., 1999).

Evidence supporting a role for BDNF in activity-dependent strengthening of specific synapses falls into two categories: acuteexperiments in which the effects of BDNF manifest within minutes,and chronic experiments in which effects take days to develop.Suppression of BDNF expression by gene deletion or introductionof antisense oligonucleotides results in deficiencies in hippocampallong-term potentiation (LTP), which can be rescued by acute provisionof exogenous BDNF (Korte et al., 1995, 1996a,b; Patterson et al.,1996). BDNF has also been reported to enhance basal synaptic transmissionat Schaffer collateral-CA1 synapses (Kang and Schuman, 1995a,b)(but see Figurov et al., 1996; Patterson et al., 1996; Frerkinget al., 1998; Gottschalk et al., 1998) and to interact with tetanus-inducedLTP in this region (Figurov et al., 1996; Gottschalk et al., 1998;Korte et al., 1998). Similar acute potentiative effects have beenfound in the hippocampal CA3 region and dentate gyrus (Scharfman,1997, 1999). In neocortex, there is evidence that BDNF potentiatesbasal synaptic transmission (Akaneya et al., 1996, 1997; Carmignotoet al., 1997) (but see Huber et al., 1998; Kinoshita et al., 1999)and that BDNF increases the probability of inducing LTP ratherthan long-term depression for a range of stimulus paradigms (Akaneyaet al., 1996, 1997; Huber et al., 1998; Kinoshita et al., 1999;Sermasi et al., 1999). Finally, rapid enhancement of excitatorytransmission has also been demonstrated in dissociated hippocampalcultures (Lessmann et al., 1994; Levine et al., 1995, 1996, 1998;Lessmann and Heumann, 1998; Li et al., 1998; Song et al., 1998)and at developing neuromuscular synapses in culture (Lohof etal., 1993; Wang et al., 1995; Stoop and Poo, 1996; Boulanger andPoo, 1999a,b).

More recently, long-term synaptic strengthening by BDNF has been observed in cultured hippocampal neurons. In autaptic culturesof glutamatergic CA1 neurons, chronic BDNF treatment increasesquantal amplitude and the amplitude of evoked synaptic transmissionin parallel (Sherwood and Lo, 1999). In dissociated cultures ofearly embryonic hippocampal neurons, BDNF increases the numberof functional synaptic connections (Vicario-Abejon et al., 1998).In contrast, studies of long-term effects of BDNF in dissociatedcortical cultures have suggested that BDNF decreases neuronalfiring rate by reducing the strength of all excitatory inputsonto a given neuron (Rutherford et al., 1998; Turrigiano and Nelson,1998; Turrigiano et al., 1998; Turrigiano, 1999).

To begin to understand this apparent pleiotropy of BDNF action, we examined the regulation of synaptic activity by BDNF inhippocampal cultures in which effects on overall action potentialactivity, excitation, and inhibition can be analyzed separately.In these cultures, we observed that, rather than maintaining actionpotential firing rates at a constant level, BDNF increased overallspontaneous firing rate by approximately threefold. We found thatactions of BDNF underlying this increase in activity involvedenhancement of both excitatory and inhibitory synaptic transmissionin parallel but via distinct cellular mechanisms. BDNF selectivelyincreased the quantal amplitude of AMPA receptor-mediated excitatorytransmission, an increase that did not require ongoing actionpotential activity. In contrast, BDNF did not affect the quantalamplitude of GABAergic transmission but rather increased the frequencyof spontaneous quantal inhibitory transmission. Thus, althoughthese effects contained a homeostatic component, the overall actionof BDNF was strongly stimulatory and supports a role for BDNFas a mediator of activity-dependent plasticity in vivo.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cell culture. Standard dissociated hippocampal cultures were prepared from postnatal day 0 rat pups using the technique ofPan et al. (1993). Briefly, rat pups were anesthetized using isofluorane,and hippocampi were dissected into HBSS (Life Technologies, Gaithersburg,MD) with 10 mM HEPES. Each hippocampus was diced and incubatedat 37°C for 45 min in HBSS containing 20 U/ml papain (Worthington,Freehold, NJ), 0.5 mM EDTA, 1.5 mM CaCl₂, and 10 mM HEPES (Sigma,St. Louis, MO). The papain solution was removed, and residualpapain was inactivated by the addition of serum-containing medium.The cells were then triturated by passage through fire-polishedPasteur pipettes with sequentially smaller diameter openings.Cells were plated at a density of 200,000 cells per dish in 35mm dishes that had been coated with poly-D-lysine and merosin(Life Technologies). After 1 d in culture, 25% of the medium wasexchanged, and the mitotic inhibitor 5-fluoro-2-deoxyuridine wasadded to minimize glialproliferation.

Neurotrophin treatment. Hippocampal cultures were allowed to establish for 3 d, after which either 100 ng/ml BDNF or 5 µg/mlTrkB-IgG (both generous gifts from Regeneron Pharmaceuticals,Tarrytown, NY) was added; we have shown previously that theseconcentrations of BDNF and TrkB-IgG are effective over the timecourse of several days and are low enough to avoid cross activationof other neurotrophin receptors (Lesser and Lo, 1995; Lesser etal., 1997; Riddle et al., 1997; Sherwood et al., 1997; Sherwoodand Lo, 1999). Electrophysiological recordings were made after4-7 d oftreatment.

Electrophysiology. Electrophysiological recordings were made with an Axopatch 1D patch-clamp amplifier (Axon Instruments,Foster City, CA), and data were acquired using an INDEC Systemsanalog-to-digital converter and custom software written in-housein Visual Basic (Microsoft, Seattle, WA). Whole-cell patch-clamprecording was done using standard methods (Hamill et al., 1981).Borosilicate patch pipettes were pulled to resistances of 3-4M $Omega$ . For synaptic currents, data were acquired continuously at2.5 kHz sampling frequency and filtered at 1 kHz using a four-poleBessel filter. Recordings with leak currents >100 pA or seriesresistances >20 M $Omega$ werediscarded.

For recording AMPA receptor-mediated synaptic currents, the extracellular solution contained (in mM): 137 NaCl, 5 KCl, 3 CaCl₂,1MgCl₂, 10 glucose, and 5 HEPES, adjusted to 310 mOsm and pH 7.25.To block GABA_A receptor-mediated and action potential-driven synaptictransmission, 25 µM bicuculline and 1 µM tetrodotoxin (TTX) wereincluded in the extracellular solution. The intracellular solutioncontained (in mM): 100 gluconic acid, 0.6 EGTA, 5 MgCl₂, 2 Na₂-ATP,0.3 Na₂-GTP, and 40 HEPES, adjusted to 310 mOsm and pH 7.25. Forrecording NMDA receptor-mediated synaptic currents, identicalsolutions were used, except that the extracellular solution wasnominally Mg²⁺-free and contained 3 µM 2,3-dihydroxy-6-nitro-7-sulphamoylbenzo(f)-quinoxalinedione(NBQX) and 10 µM glycine. For recording GABA_A receptor-mediatedsynaptic currents, the intracellular solution contained (in mM):110 KCl, 10 EGTA, 5 MgCl₂, 2 Na₂-ATP, 0.3 Na₂-GTP, and 30 HEPES,adjusted to 310 mOsm and pH 7.25. The extracellular solution wasthe same as described for AMPA receptor-mediated currents butcontaining 3 µM NBQX instead ofbicuculline.

Intrinsic excitability was measured in current-clamp mode. The intracellular solution contained (in mM): 144 K-gluconate,0.5 EGTA, 1 MgCl₂, 2 Na₂ATP, 0.3 Na₂GTP, and 0.5 HEPES, adjustedto 310 mOsm and pH 7.25. Membrane voltages were sampled at 10kHz and filtered at 2 kHz. To elicit action potential activity,a series of depolarizing pulses of 160 msec duration were deliveredto the cells. Input-output relationships were determined by plottingthe current injected versus action potential firing frequency.Action potential height, half-width, and spike threshold weremeasured off-line. Membrane capacitance, series resistance, andinput resistance were measured under voltageclamp.

On-cell patch-clamp recording was used for noninvasive measurement of the frequency of action potential activity. Data wereacquired at 5 kHz in voltage-follower recording mode and filteredat 2 kHz. The extracellular and pipette solutions were the same,containing (in mM): 137 NaCl, 5 KCl, 3 CaCl₂, 1 MgCl₂, 10 glucose,0.01 glycine, and 5 HEPES, adjusted to 310 mOsm and pH 7.25.

Immunocytochemistry. To measure neuronal survival and the percentage of inhibitory neurons, parallel cultures were double-labeledusing a mouse monoclonal antibody directed against the GABAergicneuronal marker glutamic acid decarboxylase (GAD) (1:500; Chemicon,Temecula, CA) and a rabbit polyclonal antibody against neuron-specificenolase (NSE) (1:500; Chemicon). GAD immunostaining was visualizedwith an Oregon Green 488-conjugated goat anti-mouse secondaryantibody (1:400; Molecular Probes, Eugene, OR); NSE immunostainingwas visualized with a Cy3-conjugated goat anti-rabbit secondaryantibody (1:400; Chemicon). On the fifth day of neurotrophin treatment,cultures were fixed in 4% paraformaldehyde and 5% sucrose in PBSand then washed with PBS. Nonspecific binding was blocked with10% goat serum in PBS, and cells were permeabilized with 0.1%Triton X-100. Cultures were then incubated overnight with primaryantibody at 4°C, followed by incubation in secondary antibodyfor 1 hr at room temperature. Finally, cultures were rinsed withPBS, mounted in Molwiol, andcoverslipped.

Cell counts were done with the experimenter blinded on an inverted Zeiss (Oberkochen, Germany) microscope (Axiovert) witha 10× objective. Mean numbers of GAD- or NSE-positive neuronsper field were calculated by counting the number of GAD-positivecells in a field using fluorescein filters and then switchingto rhodamine filters and recounting the same field for NSE-positivecells. Fields were analyzed by randomly placing the objectiveand then sequentially moving the dish through a vertical stripof 10fields.

To quantify total numbers of synapses per field and numbers of inhibitory synapses per field, cultures were double-labeledusing a mouse anti-synapsin monoclonal antibody (1:500; Chemicon)and a rabbit anti-GAD polyclonal antibody (1:1000; Chemicon).GAD immunostaining was visualized with an Oregon Green 488-conjugatedgoat anti-rabbit secondary antibody (1:500; Molecular Probes);synapsin immunostaining was visualized with a Cy3-conjugated goatanti-mouse secondary antibody (1:500; Chemicon). The immunostainingprocedure was the same as describedabove.

As for cell counts, synapse quantification was done with the experimenter blinded. Images were acquired and digitized usinga Hamamatsu (Shizouka, Japan) chilled CCD camera on a Zeiss Axioscopeusing a 40× oil-immersion objective; exposure times were heldconstant for each fluorochrome. Images were taken by randomlyplacing the objective and then sequentially moving the dish througha vertical strip of 10 fields. Images were analyzed using ScionImage software (Scion Corp., Frederick, MD); briefly, a mask containingthe location and area of each synapsin or GAD puncta was madeusing a combination of thresholding and manual highlighting. Numbers,areas, and intensities of these punctae were then determined usingbuilt-in Scion Imagefunctions.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

BDNF increases spontaneous activity in dissociated cultures of hippocampal neurons

To investigate the role of BDNF in regulating the overall excitability of dissociated cultures of hippocampal neurons, cultureswere treated for 4-7 d with 100 ng/ml BDNF and compared with untreatedcontrols and cultures in which endogenous BDNF was neutralizedwith 5 µg/ml TrkB-IgG (Shelton et al., 1995; McAllister et al.,1996, 1997). Spontaneous action potentials in neurons with pyramidalmorphology were then recorded using cell-attached patch-clamprecording as a rapid and relatively noninvasive measurement ofcircuit activity. BDNF treatment increased the average spontaneousaction potential firing rates of neurons by approximately threefoldcompared with untreated controls (n = 33, 27, and 36 for BDNF,control, and TrkB-IgG cultures, respectively; BDNF vs control,p < 0.009 by ANOVA) (Fig. 1). Interestingly, there was no significantdifference between untreated controls and TrkB-IgG-treated neuronswith respect to firing rate (p > 0.60) or for any other electrophysiologicalparameter measured in this study, suggesting that levels of endogenousBDNF are below the physiological threshold required to modulateactivity in these low-density cultures. This is consistent withthe finding that endogenous BDNF levels are negligible in autaptichippocampal cultures (Sherwood and Lo, 1999).

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Figure 1. BDNF increases spontaneous action potential firing rate. A, Representative trace illustrating the waveform of an action potential recorded with an on-cell patch pipette; this configuration was used to measure action potential frequency in dissociated hippocampal cultures. Voltage traces were inverted about the vertical axis to conform to convention. Data were acquired at 5 kHz in voltage-follower recording mode and filtered at 2 kHz. B, Spontaneous action potential firing was increased in cultures treated with BDNF. Representative on-cell recordings shown at a compressed time base from cells treated for 4-7 d with 100 ng/ml BDNF (top), untreated (Control, middle), or treated with 5 µg/ml TrkB-IgG (bottom). Cultures were rinsed in recording saline several times to ensure that no BDNF or TrkB-IgG was present at the time of recording. C, Left, BDNF treatment increased the spontaneous firing rate of pyramidal neurons approximately threefold compared with untreated controls; means ± SEM are shown. *p < 0.009 indicates a significant difference by ANOVA between BDNF and either control or TrkB-IgG treatment groups; n = 33, 27, and 36 for BDNF, control, and TrkB-IgG groups, respectively. Right, Elevated action potential firing rates induced by BDNF persisted in disinhibited circuits. BDNF appeared to increase excitatory synaptic transmission directly because the increase in spontaneous firing rates of pyramidal neurons persisted after acute blockade of inhibitory transmission by bicuculline during the recording period. *p < 3 × 10⁵ indicates a significant difference by ANOVA between BDNF and either control or TrkB-IgG treatment groups; n = 43, 36, and 12 for BDNF, control, and TrkB-IgG groups, respectively.

This striking increase in spontaneous firing rate could have arisen from an increase in the strength of excitation, a decreasein the strength of inhibition, or both. To evaluate the effectof BDNF on excitation directly, the contribution of inhibitionto circuit activity was eliminated during the period of electrophysiologicalrecording by pharmacologically blocking GABA_A receptors acutelywith bicuculline and measuring action potential firing rates inthese disinhibited circuits. Under these conditions, BDNF stillelevated spontaneous action potential firing rate by approximatelytwofold, indicating that the action of BDNF must include, at leastin part, a direct potentiation of excitatory synaptic transmission(n = 43, 36, and 12 for BDNF, control, and TrkB-IgG cultures,respectively; BDNF vs control, p < 3 × 10⁵ by ANOVA) (Fig. 1).

BDNF does not influence neuronal survival

We next asked whether the action of BDNF contained a component that influenced the balance of excitation and inhibition inthese cultures via differential regulation of survival of excitatoryversus inhibitory neurons. We found that, by quantifying neuronaldensity in BDNF-treated, control, and TrkB-IgG-treated cultures,BDNF had no measurable effect on total neuronal survival (n =161 fields counted for each condition; p > 0.35 by ANOVA for anypairwise comparison) (Fig. 2A). Although there was no change inoverall neuronal density, BDNF increased the percentage of neuronsexpressing the inhibitory neuronal marker GAD (n = 180 fieldscounted for each condition; BDNF vs control, p < 0.008 by ANOVA)(Fig. 2B).

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Figure 2. BDNF enhances the phenotypic differentiation of GABAergic neurons but has no effect on neuronal survival. Hippocampal cultures were treated for 5 d with either BDNF or TrkB-IgG or were left untreated; cultures were then double-labeled for the neuronal marker NSE and the GABAergic neuronal marker GAD. Numbers of NSE-positive and GAD-positive neurons were counted independently; all counts were done blind. A, BDNF treatment did not affect neuronal survival. Means ± SEM are shown; n = 9 dishes per condition with 20 fields counted and averaged per dish; p > 0.35 for any pairwise comparison by ANOVA. B, BDNF increased the percentage of GAD-positive neurons. *p < 0.008 indicates a significant difference by ANOVA between BDNF and either control or TrkB-IgG treatment groups; n = 9 dishes per condition with 20 fields counted and averaged per dish.

There are two possible interpretations of this result. First, BDNF may have caused a decrease in the survival of non-GABAergicneurons that was exactly balanced by an increase in survival ofGABAergic neurons. Second, BDNF may have promoted the neurochemicalmaturation of inhibitory neurons such that the level of GAD expressionwas increased to detectable levels in a greater percentage ofinhibitory neurons, with no effect on neuronal survival per se.The latter interpretation is consistent with previous work suggestingthat BDNF potentiates phenotypic differentiation of GABAergicneurons (Ip et al., 1993; Nawa et al., 1993; Mizuno et al., 1994;Ventimiglia et al., 1995; Marty et al., 1996a,b; Rutherford etal., 1997; Vicario-Abejon et al., 1998). Furthermore, other studieshave shown that BDNF-mediated increases in GABA and neuropeptideexpression levels are reversible, thus arguing against differentialsurvival as a mechanism for BDNF action (Marty and Onteniente,1997; Rutherford et al., 1997).

Because BDNF did not affect overall neuronal density and its enhancement of inhibitory neuronal differentiation would be predictedto decrease circuit activity, these factors were not likely tocontribute positively to the observed increase of circuit activityinduced by BDNF. Thus, these findings suggested that BDNF mustincrease circuit activity by other mechanisms, such as enhancedsynaptic drive or by increased intrinsic membraneexcitability.

BDNF does not regulate intrinsic excitability

Because the action potential firing properties of a network depend on the intrinsic excitability of its neuronal elementsas well as the synaptic connectivity of the ensemble, we nextinvestigated whether BDNF regulated intrinsic membrane excitabilityin these cultures. Accordingly, we measured several parametersof action potential activity that was generated by injecting aseries of current pulses of increasing amplitude into current-clampedneurons; voltage responses to these current pulses were measuredwhile all synaptic transmission was blocked pharmacologically.Most importantly, we found that BDNF did not change the firingrate of neurons at any of the current injection amplitudes examined(Fig. 3). Additionally, we found that BDNF affected neither actionpotential shape, as measured by action potential height and half-width(Table 1), nor the voltage threshold at which the regenerativeaction potentials were first observed.

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Figure 3. BDNF does not affect intrinsic membrane excitability. A, Representative whole-cell current-clamp traces of action potential trains elicited in a control cell by depolarizing the membrane by a sequence of inward current pulses (left to right: 10, 20, 30, and 40 pA). Top traces show voltage responses to 160 msec depolarizing current pulses (bottom traces) relative to resting potential; synaptic transmission was blocked pharmacologically during the recording period as described in Materials and Methods. Data were sampled at 10 kHz and filtered at 2 kHz. B, BDNF treatment did not alter input-output relationships for current injection versus action potential firing rate. Neither augmentation (squares) nor depletion (circles) of BDNF affected action potential firing rate at any of the current injection amplitudes examined compared with untreated controls (triangles). Means ± SEM are shown; n = 27, 23, and 24 for BDNF, control, and TrkB-IgG groups, respectively.


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Table 1. BDNF does not alter intrinsic excitability

Similarly, there were no differences between BDNF-treated and control or TrkB-IgG-treated neurons in resting membrane potential(Table 1), but BDNF did cause a small increase in capacitanceand a decrease in input resistance (Table 1). These minor differencesin particular membrane properties suggested that BDNF may havehad small effects on the morphology of these neurons, but it isunlikely that these differences contributed significantly to increasingspontaneous circuit activity for two reasons: first, neither theshape, frequency, or voltage-threshold of action potentials, norany other aspect of intrinsic excitability measured, was changedby BDNF; second, the rise and decay kinetics of AMPA receptor-mediatedsynaptic currents were not affected by BDNF (see followingsections).

BDNF selectively increases the amplitude of AMPA receptor-mediated miniature EPSCs

Because the firing rate of neurons is determined, in part, by the number, strength and temporal characteristics of its individualexcitatory and inhibitory synaptic inputs, we next examined theeffects of BDNF on unitary synaptic transmission. We first measuredthe behavior of miniature EPSCs (mEPSCs) by blocking sodium channel-mediatedaction potential activity with TTX and recording spontaneous mEPSCsunder whole-cell voltage clamp (Fig. 4). We found that BDNF significantlyincreased the amplitude of AMPA receptor-mediated mEPSCs by ~30%(n = 82, 44, and 69 for BDNF, control, and TrkB-IgG cultures,respectively; BDNF vs control, p < 0.007 by ANOVA) (Fig. 5A).BDNF shifted the cumulative probability distribution of AMPA receptor-mediatedmEPSC amplitudes uniformly toward larger amplitudes (Fig. 5C),suggesting that the action of BDNF was not limited to a subsetof synapses of a particular quantal size and that there was nosaturation of mEPSC sizes at higher amplitudes. This increasein the amplitude of unitary synaptic transmission by BDNF wasaccompanied by a significant increase in mEPSC frequency in BDNF-treatedcompared with TrkB-IgG-treated cells, but not compared with controlcells (n = 83, 45, and 73 for BDNF, control, and TrkB-IgG cultures,respectively; BDNF vs TrkB-IgG, p < 0.04 by ANOVA; BDNF vs control,p > 0.7 by ANOVA) (Fig. 5B). BDNF had no effect on the decay ratesof either AMPA or NMDA receptor-mediated synaptic currents (Table2). Together, these findings suggested that BDNF increased excitationin these cultures predominantly by selectively increasing theamplitude of AMPA receptor-mediated synaptic currents withoutsubstantially affecting other aspects of excitatory synaptic transmission.

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Figure 4. BDNF increases the amplitude but does not change the kinetics of AMPA receptor-mediated mEPSCs. A, Population averages of pharmacologically isolated AMPA receptor-mediated mEPSCs from all cells in each treatment group show the increase in mEPSC amplitude induced by BDNF; n = 82, 44, and 69 for BDNF (top), control (middle), and TrkB-IgG (bottom) groups, respectively. Note that the time courses of these averaged mEPSCs are similar; data were acquired continuously under voltage clamp at 2.5 kHz and filtered at 1 kHz. B, Representative recordings of AMPA receptor-mediated mEPSCs on a compressed time base illustrate the lack of effect of BDNF treatment on mEPSC frequency; traces from neurons in BDNF (top), control (middle), and TrkB-IgG (bottom) groups are shown.

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Figure 5. BDNF increases AMPA receptor-mediated mEPSC amplitude. A, BDNF increased mEPSC amplitude by ~30% compared with control cells and by ~40% compared with TrkB-IgG treated neurons (n = 82, 44, and 69 for BDNF, control, and TrkB-IgG groups, respectively). *p < 0.007 indicates a significant difference by ANOVA between BDNF and either control or TrkB-IgG groups; means ± SEM are shown. Data were acquired continuously under voltage clamp at 2.5 kHz and filtered at 1 kHz. B, mEPSC frequency was elevated by BDNF- compared with TrkB-IgG-treated cells but not significantly so compared with control cells; n = 83, 45, and 73 for BDNF, control, and TrkB-IgG groups, respectively. *p < 0.042 and line indicate a significant difference by ANOVA between the BDNF and TrkB-IgG groups; p > 0.69 by ANOVA between BDNF and control groups. C, BDNF treatment shifted mEPSC amplitudes uniformly toward higher amplitudes as shown in cumulative probability distributions; all mEPSCs recorded in a 3 min interval from 40 randomly chosen neurons in each treatment condition were grouped and analyzed.


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Table 2. BDNF does not alter decay kinetics of either excitatory or inhibitory synaptic currents

BDNF induction of AMPA receptor-mediated mEPSC amplitude does not require activity

Several previous studies have reported that the actions of neurotrophins are activity-dependent or that activity and neurotrophinsinteract in their regulation of the physiological properties ofneurons and neuronal circuits (Marty et al., 1996a; McAllisteret al., 1996; Rutherford et al., 1997). We therefore asked whetherthe potentiative effect of BDNF on excitation observed here wasdependent on ongoing electrical activity by blocking action potentialactivity with 5 µM TTX for the entire duration of BDNF or TrkB-IgGtreatment. We found, surprisingly, that TTX had no effect on theenhancement of mEPSC amplitude by BDNF (n = 38, 30, 39, and 29for BDNF, TrkB-IgG, BDNF plus TTX, and TrkB-IgG plus TTX cultures,respectively; BDNF vs TrkB-IgG, p < 0.01 by ANOVA; BDNF plus TTXvs TrkB-IgG plus TTX, p < 10⁴ by ANOVA) (Fig. 6A). In fact, TTX appeared to increase slightlythe magnitude of enhancement by BDNF, from 31 to 53% in the presenceof TTX. We verified that the TTX used remained active for theduration of the experiment by applying media containing the TTXto naïve cells and observing complete sodium channel blockade(data not shown). Thus, the regulation of AMPA receptor-mediatedmEPSC amplitude by BDNF did not require concurrent action potentialactivity and thus may differ from other reported actions of BDNF.

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Figure 6. BDNF regulation of mEPSC amplitude does not require activity. A, The addition of 5 µM TTX to block action potential activity for the entire duration of the treatment period did not block the enhancement of mEPSC amplitude by BDNF; mEPSC amplitudes increased by 31 and 53% with and without TTX treatment, respectively. Means ± SEM are shown; without TTX, n = 38 and 30 for BDNF and TrkB-IgG groups, respectively, p < 0.01 by ANOVA; with TTX, n = 39 and 29 for BDNF and TrkB-IgG groups, respectively, p < 10⁴ by ANOVA. B, BDNF, TTX, or BDNF and TTX treatment together did not significantly alter mEPSC frequency. Means ± SEM are shown; without TTX, n = 38 and 30 for BDNF and TrkB-IgG groups, respectively, p > 0.99 by ANOVA; with TTX, n = 39 and 29 for BDNF and TrkB-IgG groups, respectively, p > 0.93 by ANOVA.

BDNF selectively increases the frequency of GABA_A-mediated mIPSCs

To determine whether BDNF also regulated the unitary properties of inhibitory synaptic transmission, we next recorded mIPSCsarising from GABAergic inputs onto neurons with pyramidal morphology.During the recording period, TTX and NBQX were added to the extracellularsolution to block action potentials and glutamatergic inputs,respectively. We found that BDNF treatment increased the frequencyof mIPSCs by almost twofold (n = 35, 31, and 35 for BDNF, control,and TrkB-IgG cultures, respectively; BDNF vs control, p < 0.028by ANOVA) (Fig. 7D). In contrast to the increase in AMPA receptor-mediatedmEPSC amplitude described above, GABA_A receptor-mediated mIPSCamplitudes were not affected by BDNF (n = 35, 31, and 35 for BDNF,control, and TrkB-IgG cultures, respectively; BDNF vs control,p > 0.6 by ANOVA) (Fig. 7C). As with AMPA- and NMDA-mediated synapticcurrents, BDNF did not alter the kinetics of synaptic currentsmediated by GABA_A receptors (Table 2). These findings indicatedthat, although BDNF potentiated both excitatory and inhibitorysynaptic transmission in these cultures, it did so through distinctphysiological mechanisms.

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Figure 7. BDNF increases GABA_A receptor-mediated mIPSC frequency but not amplitude. A, Population averages of pharmacologically isolated GABA_A receptor-mediated mIPSCs from all cells in each treatment group show similar amplitude and time courses; n = 35, 31, and 33 for BDNF (top), control (middle), and TrkB-IgG (bottom) groups, respectively. Data were acquired continuously under voltage clamp at 2.5 kHz and filtered at 1 kHz. B, Representative recordings of GABA_A receptor-mediated mIPSCs on a compressed time base show the elevation of mIPSC frequency induced by BDNF treatment; traces from neurons in BDNF (top), control (middle), and TrkB-IgG (bottom) groups are shown. C, In contrast, BDNF treatment had no effect on GABA_A receptor-mediated mIPSC amplitude. Means ± SEM are shown; n = 35, 31, and 33 for BDNF, control, and TrkB-IgG groups, respectively. D, BDNF treatment increased mIPSC frequency by ~1.8 fold compared with controls. *p < 0.028 indicates a significant difference by ANOVA between BDNF and either control or TrkB-IgG treatment groups; n = 35, 31, and 35 for BDNF, control, and TrkB-IgG groups, respectively.

BDNF does not change synapse number but enhances differentiation of GABAergic terminals

Finally, we asked whether BDNF regulated inhibition by regulating numbers of GABAergic inputs because we observed that BDNFincreased the frequency of mIPSCs. First, we quantified totalnumbers of presumptive synapses by immunostaining with antibodiesagainst the synaptic vesicle protein synapsin I (Fig. 8A). Becausesynapsin I is present in the terminals of both excitatory andinhibitory neurons, these initial measurements reflected the combinednumber of glutamatergic and GABAergic synapses. BDNF did not increasenumbers of synapses per field, terminal size, or intensity ofsynapsin labeling; in fact, there was a slight increase in numbersof synapses in cultures in which endogenous BDNF had been antagonizedwith TrkB-IgG (Fig. 9, left).

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Figure 8. Immunostaining against synaptic markers in hippocampal neuronal cultures. Cultures were double-labeled with anti-synapsin and anti-GAD antibodies to visualize all and only GABAergic synaptic terminals, respectively. Synaptic punctae staining with both antibodies represented inhibitory presynaptic terminals (filled arrow), whereas those staining with the anti-synapsin antibody only were considered to be excitatory (open arrow). Scale bar, 10 µm.

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Figure 9. BDNF does not affect synaptogenesis but does enhance GABAergic phenotype. A, BDNF treatment did not increase synaptic density as quantified by either anti-synapsin (left) or anti-GAD (right) staining; in fact, synaptic density was slightly increased by TrkB-IgG treatment by both measures. *p < 0.03 indicates significant differences by ANOVA (anti-synapsin) and p < 0.02 by ANOVA (anti-GAD) between TrkB-IgG and either control or BDNF groups; n = 23 (anti-synapsin) and n = 24 (anti-GAD) dishes scored in each treatment group. B, BDNF treatment did not increase synaptic terminal size significantly in the population as a whole (anti-synapsin staining, left) but did increase average GAD-positive terminal size by ~50%. *p < 0.01 indicates a significant difference by ANOVA between BDNF and either control or TrkB-IgG groups; n = 22, 23, and 21 dishes scored for BDNF, control, and TrkB-IgG treatment groups, respectively. C, Similarly, BDNF treatment did not affect the intensity of synapsin labeling (left) but did increase the average staining intensity of GAD-positive terminals (right). *p < 0.002 indicates a significant difference by ANOVA between BDNF and either control or TrkB-IgG groups; n = 22, 23, and 24 dishes scored for BDNF, control, and TrkB-IgG treatment groups, respectively.

We next examined GABAergic terminals specifically with an antibody directed against GAD (Fig. 8B). BDNF did not increase thenumber of GAD-positive synapses; as found for synapsin staining,however, there was a slight increase in the number of GAD punctaewith TrkB-IgG treatment (Fig. 9A, right). Strikingly, BDNF increasedaverage GABA terminal size by 50% and concomitantly increasedthe fluorescence intensity of these punctae, presumably reflectingan increase in the level of GAD expression (Fig. 9B, right). Togetherwith the increased mIPSC frequency described above, these observationssuggest that BDNF increased inhibition by increasing the efficacyand/or probability of transmission at GABAergicsynapses.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We have found that BDNF strongly regulates both excitation and inhibition in dissociated cultures of hippocampal neurons.Although the increase in excitation was dominant in that overalllevels of spontaneous activity in these cultures were increasedafter BDNF treatment, this parallel enhancement of excitationand inhibition also resulted in partial homeostasis in terms ofcircuit activity. The increase in circuit activity produced byBDNF arose principally from changes in excitatory and inhibitorysynaptic drive, both relative and absolute, but via distinct physiologicalmechanisms, with no significant changes in intrinsic neuronalexcitability or neuronalsurvival.

BDNF regulation of excitation

We found that long-term treatment of hippocampal cultures with BDNF led to a selective increase in the quantal size of AMPAreceptor-mediated mEPSCs. Such a change is consistent with a postsynapticmechanism. Moreover, the absence of kinetic changes in AMPA receptor-mediatedsynaptic currents limits possible cellular and molecular mechanismsto those that do not alter the kinetic profile of postsynapticcurrents. For example, an increase in numbers of functional AMPAreceptors at synaptic sites would be expected to increase mEPSCamplitude without affecting kinetics; in fact, changes in thehalf-life of AMPA receptors can result in changes in receptordensity that have been shown to correlate with quantal size (O'Brienet al., 1998). Recently, rapid insertion and removal of AMPA receptorsfrom potentiated and depressed synapses has been proposed to underliechanges in synaptic efficacy (Carroll et al., 1999; Lissin etal., 1999; Shi et al., 1999), suggesting that longer term actionof BDNF such as those reported here may similarly involve increasesin the density of AMPA receptors at synapses. BDNF has, for example,recently been demonstrated to increase the expression of AMPAreceptor subunit 1 and 2/3 protein in neocortical neurons (Narisawa-Saitoet al., 1999a,b). Alternatively, BDNF may induce the accumulationof AMPA receptors at synapses previously devoid of these receptorsas has been proposed for "silent" synapses in neonatal hippocampus(Isaac et al., 1995; Liao et al., 1995; Durand et al., 1996; Wuet al., 1996).

Changes in the composition or functional states of AMPA receptors are also possible that have minimal effects on the overalltime course of mEPSCs. For example, induction of LTP in CA1 hippocampusand Ca²⁺/calmodulin kinase II phosphorylation of the glutamate receptorsubunit GluR1 have been shown to produce increases in AMPA receptorsingle-channel conductance (Tan et al., 1994; Barria et al., 1997a,b;Mammen et al., 1997; Benke et al., 1998; Derkach et al., 1999).Our results are also consistent, however, with an increase inthe amount of glutamate packaged per vesicle (for review, seeReimer et al., 1998) as has been reported recently for catecholamines(Pothos et al., 1998). In this context, it is interesting thatthere was increased mEPSC frequency in BDNF-treated neurons becausechanges in the frequency of mEPSCs is often associated with presynapticalterations, such as in probability ofrelease.

Interestingly, BDNF did not affect the kinetics of the synaptic currents measured in this study (neither AMPA, NMDA, nor GABA_Areceptor-mediated), a finding that has several implications. First,any effects BDNF may have had on neuronal morphology, spatialdistribution of synaptic inputs, or input resistance did not alterthe passive membrane properties of the neuron sufficiently toaffect the time course of such fast synaptic currents (Mennericket al., 1995; Bekkers and Stevens, 1996). Second, in the caseof AMPA receptor-mediated mEPSCs, the potential cellular mechanismsresponsible for the quantal amplitude increase induced by BDNFare limited to those that do not affect the rate of decay of synapticcurrents, as discussed above; however, our experiments do notspecifically address mechanisms such as regulation of glutamatetransporter function, whose contribution to synaptic current kineticsremains uncertain (for review, see Clements, 1996; Diamond andJahr, 1997; Mennerick et al., 1999). Finally, that BDNF did notregulate the decay time course of NMDA receptor-mediated synapticcurrents suggests that BDNF does not alter the subunit compositionof the NMDA receptors under these conditions because changes inthe relative expression of NR2A-NR2D subunits have been shown,for example, to alter NMDA receptor decay times significantly(Carmignoto and Vicini, 1992; Hestrin, 1992).

A previous study using hippocampal cultures from embryonic day 16 rats found similar BDNF-mediated increases in the amplitudeof sucrose-evoked mEPSCs, but at this early developmental stage,the dominant effect was an increase in the number of functionalsynapses (Vicario-Abejon et al., 1998). Our results are more consistentwith studies in CA1 hippocampal autapses in which BDNF inducesa 1.7-fold increase in quantal amplitude of AMPA receptor-mediatedmEPSCs and a parallel increase in the amplitude of evoked synapticcurrents (Sherwood and Lo, 1999). Interestingly, the effects ofBDNF described here and by Vicario-Abejon et al. (1998) and Sherwoodand Lo (1999) are quite different from those reported recentlyin dissociated cultures of visual cortical neurons (Rutherfordet al., 1998; Turrigiano et al., 1998). In these studies, thequantal amplitude of AMPA-mediated synaptic currents was scaledby activity; Rutherford et al. (1998) reported that BDNF preventsthis increase in AMPA receptor-mediated quantal amplitude in responseto activity blockade, the opposite of the action of BDNF foundhere. Interestingly, however, bipolar interneurons as describedby Rutherford et al. (1998) responded to BDNF similarly to thehippocampal pyramidal neurons in the presentstudy.

Such differences in BDNF regulation of synaptic transmission presumably arise from the pleiotropy and cell context-dependenceof BDNF action and emphasize the diversity of roles BDNF may transpireto play in synaptic development and plasticity. In this context,it is notable that there are developmental differences in therelative abundance of GluR1-GluR4 subunits and the alternativesplicing variants, GluR Flip and GluR Flop, between pyramidalcells of the hippocampus and cortex (Boulter et al., 1990; Keinanenet al., 1990; Sommer et al., 1990; Monyer et al., 1991; Pellegrini-Giampietroet al., 1991; Petralia and Wenthold, 1992; Craig et al., 1993;Eshhar et al., 1993; Conti et al., 1994). Such differences insubunit expression may contribute to the apparent regional differencein regulation of quantal amplitude by BDNF in hippocampus versuscortex.

BDNF regulation of inhibition

We found that inhibitory synaptic transmission was also enhanced by chronic BDNF treatment but that the physiological mechanismsunderlying this potentiation were different from those that enhancedexcitatory synaptic drive. In this case, BDNF selectively increasedthe frequency of mIPSCs with no effects on their quantal amplitudeor kinetic properties. Such frequency changes could have arisenfrom changes in probability of transmitter release, numbers ofinhibitory synaptic contacts, or both. Our finding that the numberof GABAergic terminals was not affected by BDNF but that the sizeof inhibitory terminals and intensity of GAD immunostaining wasincreased suggests that BDNF is likely to have enhanced the probabilityof transmitter releasepresynaptically.

The 40% increase in the ratio of neurons that showed detectable anti-GAD staining we observed after BDNF treatment was similarto previous reports of increases in GABAergic phenotypic differentiation,but not inhibitory neuronal numbers, after treatment with BDNFin vitro and in vivo (Ip et al., 1993; Nawa et al., 1993, 1994;Croll et al., 1994; Marty et al., 1996a,b). Interestingly, BDNFis not synthesized by GABAergic interneurons (Cellerino et al.,1996; Rocamora et al., 1996; Schmidt-Kastner et al., 1996), butrather their source of BDNF is thought to be neighboring glutamatergicneurons (Nawa et al., 1995; Marty et al., 1996a). Such observationscontinue to support a general role for BDNF in regulating inhibitorysynaptic transmission and are consistent with BDNF acting as anactivity-dependent, target-derived differentiation factor forGABAergic interneurons. In turn, such regulation of GABAergictransmission by BDNF and activity would be expected to have majorramifications for neural development and function (Hendry andJones, 1988).

In summary, our experiments have shown that BDNF can have profound effects on the function of neural circuits and that itcan do so via regulation of selective aspects of excitatory andinhibitory synaptic function. In combination with activity-dependentproduction and localized release of neurotrophins (Wetmore etal., 1994; Blochl and Thoenen, 1995, 1996; Goodman et al., 1996;Fawcett et al., 1997, 1998; Smith et al., 1997; Wang and Poo,1997; Moller et al., 1998), such effects of BDNF provide powerfulmechanisms of action in their increasingly apparent roles in regulatingsynaptic development andplasticity.

  FOOTNOTES

Received Nov. 10, 1999; revised Jan. 21, 2000; accepted Feb. 2, 2000.

This work was supported by National Institutes of Health Grants NS32742 (to D.L.) and MH11519 (to M.B.) and The McKnight EndowmentFund for Neuroscience (D.L.). We thank D. Fitzpatrick, S. Lesser,N. Tang Sherwood, and T. Yacoubian for their helpful commentson this manuscript and valuable discussions on experimental design.We also thank Regeneron Pharmaceuticals for their generous provisionof recombinant BDNF and TrkB-IgG.
Correspondence should be addressed to Donald C. Lo, Department of Neurobiology Box 3209, Duke University Medical Center, Durham,NC 27710. E-mail: lo{at}neuro.duke.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Akaneya Y, Tsumoto T, Hatanaka H (1996) Brain-derived neurotrophic factor blocks long-term depression in rat visual cortex. J Neurophysiol 76:4198-4201[Abstract/Free Full Text].
Akaneya Y, Tsumoto T, Kinoshita S, Hatanaka H (1997) Brain-derived neurotrophic factor enhances long-term potentiation in rat visual cortex. J Neurosci 17:6707-6716[Abstract/Free Full Text].
Barria A, Derkach V, Soderling T (1997a) Identification of the Ca²⁺/calmodulin-dependent protein kinase II regulatory phosphorylation site in the alpha-amino-3-hydroxyl-5-methyl-4-isoxazole-propionate-type glutamate receptor. J Biol Chem 272:32727-32730[Abstract/Free Full Text].
Barria A, Muller D, Derkach V, Griffith LC, Soderling TR (1997b) Regulatory phosphorylation of AMPA-type glutamate receptors by CaM-KII during long-term potentiation. Science 276:2042-2045[Abstract/Free Full Text].
Bekkers JM, Stevens CF (1996) Cable properties of cultured hippocampal neurons determined from sucrose-evoked miniature EPSCs. J Neurophysiol 75:1250-1255[Abstract/Free Full Text].
Benke TA, Luthi A, Isaac JT, Collingridge GL (1998) Modulation of AMPA receptor unitary conductance by synaptic activity. Nature 393:793-797[Medline].
Blochl A, Thoenen H (1995) Characterization of nerve growth factor (NGF) release from hippocampal neurons: evidence for a constitutive and an unconventional sodium-dependent regulated pathway. Eur J Neurosci 7:1220-1228[ISI][Medline].
Blochl A, Thoenen H (1996) Localization of cellular storage compartments and sites of constitutive and activity-dependent release of nerve growth factor (NGF) in primary cultures of hippocampal neurons. Mol Cell Neurosci 7:173-190[ISI][Medline].
Boulanger L, Poo M (1999a) Gating of BDNF-induced synaptic potentiation by cAMP. Science 284:1982-1984[Abstract/Free Full Text].
Boulanger L, Poo MM (1999b) Presynaptic depolarization facilitates neurotrophin-induced synaptic potentiation. Nat Neurosci 2:346-351[ISI][Medline].
Boulter J, Hollmann M, O'Shea-Greenfield A, Hartley M, Deneris E, Maron C, Heinemann S (1990) Molecular cloning and functional expression of glutamate receptor subunit genes. Science 249:1033-1037[Abstract/Free Full Text].
Carmignoto G, Vicini S (1992) Activity-dependent decrease in NMDA receptor responses during development of the visual cortex. Science 258:1007-1011[Abstract/Free Full Text].
Carmignoto G, Pizzorusso T, Tia S, Vicini S (1997) Brain-derived neurotrophic factor and nerve growth factor potentiate excitatory synaptic transmission in the rat visual cortex. J Physiol (Lond) 498:153-164[ISI][Medline].
Carroll RC, Lissin DV, von Zastrow M, Nicoll RA, Malenka RC (1999) Rapid redistribution of glutamate receptors contributes to long-term depression in hippocampal cultures. Nat Neurosci 2:454-460[ISI][Medline].
Cellerino A, Maffei L, Domenici L (1996) The distribution of brain-derived neurotrophic factor and its receptor trkB in parvalbumin-containing neurons of the rat visual cortex. Eur J Neurosci 8:1190-1197[ISI][Medline].
Clements JD (1996) Transmitter timecourse in the synaptic cleft: its role in central synaptic function. Trends Neurosci 19:163-171[ISI][Medline].
Conti F, Minelli A, Brecha NC (1994) Cellular localization and laminar distribution of AMPA glutamate receptor subunits mRNAs and proteins in the rat cerebral cortex. J Comp Neurol 350:241-259[ISI][Medline].
Craig AM, Blackstone CD, Huganir RL, Banker G (1993) The distribution of glutamate receptors in cultured rat hippocampal neurons: postsynaptic clustering of AMPA-selective subunits. Neuron 10:1055-1068[ISI][Medline].
Croll SD, Wiegand SJ, Anderson KD, Lindsay RM, Nawa H (1994) Regulation of neuropeptides in adult rat forebrain by the neurotrophins BDNF and NGF. Eur J Neurosci 6:1343-1353[ISI][Medline].
Derkach V, Barria A, Soderling TR (1999) Ca²⁺/calmodulin-kinase II enhances channel conductance of alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate type glutamate receptors. Proc Natl Acad Sci USA 96:3269-3274[Abstract/Free Full Text].
Diamond JS, Jahr CE (1997) Transporters buffer synaptically released glutamate on a submillisecond time scale. J Neurosci 17:4672-4687[Abstract/Free Full Text].
Durand GM, Kovalchuk Y, Konnerth A (1996) Long-term potentiation and functional synapse induction in developing hippocampus. Nature 381:71-75[Medline].
Eshhar N, Petralia RS, Winters CA, Niedzielski AS, Wenthold RJ (1993) The segregation and expression of glutamate receptor subunits in cultured hippocampal neurons. Neuroscience 57:943-964[ISI][Medline].
Fawcett JP, Aloyz R, McLean JH, Pareek S, Miller FD, McPherson PS, Murphy RA (1997) Detection of brain-derived neurotrophic factor in a vesicular fraction of brain synaptosomes. J Biol Chem 272:8837-8840[Abstract/Free Full Text].
Fawcett JP, Bamji SX, Causing CG, Aloyz R, Ase AR, Reader TA, McLean JH, Miller FD (1998) Functional evidence that BDNF is an anterograde neuronal trophic factor in the CNS. J Neurosci 18:2808-2821[Abstract/Free Full Text].
Figurov A, Pozzo-Miller LD, Olafsson P, Wang T, Lu B (1996) Regulation of synaptic responses to high-frequency stimulation and LTP by neurotrophins in the hippocampus. Nature 381:706-709[Medline].
Frerking M, Malenka RC, Nicoll RA (1998) Brain-derived neurotrophic factor (BDNF) modulates inhibitory, but not excitatory, transmission in the CA1 region of the hippocampus. J Neurophysiol 80:3383-3386[Abstract/Free Full Text].
Goodman LJ, Valverde J, Lim F, Geschwind MD, Federoff HJ, Geller AI, Hefti F (1996) Regulated release and polarized localization of brain-derived neurotrophic factor in hippocampal neurons. Mol Cell Neurosci 7:222-238[ISI][Medline].
Gottschalk W, Pozzo-Miller LD, Figurov A, Lu B (1998) Presynaptic modulation of synaptic transmission and plasticity by brain-derived neurotrophic factor in the developing hippocampus. J Neurosci 18:6830-6839[Abstract/Free Full Text].
Hamill OP, Marty A, Neher E, Sakmann B, Sigworth FJ (1981) Improved patch-clamp techniques for high-resolution current recording from cells and cell-free membrane patches. Pflügers Arch 391:85-100[ISI][Medline].
Hendry SH, Jones EG (1988) Activity-dependent regulation of GABA expression in the visual cortex of adult monkeys. Neuron 1:701-712[ISI][Medline].
Hestrin S (1992) Developmental regulation of NMDA receptor-mediated synaptic currents at a central synapse. Nature 357:686-689[Medline].
Huber KM, Sawtell NB, Bear MF (1998) Brain-derived neurotrophic factor alters the synaptic modification threshold in visual cortex. Neuropharmacology 37:571-579[ISI][Medline].
Ip NY, Li Y, Yancopoulos GD, Lindsay RM (1993) Cultured hippocampal neurons show responses to BDNF, NT-3, and NT-4, but not NGF. J Neurosci 13:3394-3405[Abstract].
Isaac JT, Nicoll RA, Malenka RC (1995) Evidence for silent synapses: implications for the expression of LTP. Neuron 15:427-434[ISI][Medline].
Kang H, Schuman EM (1995a) Long-lasting neurotrophin-induced enhancement of synaptic transmission in the adult hippocampus. Science 267:1658-1662[Abstract/Free Full Text].
Kang HJ, Schuman EM (1995b) Neurotrophin-induced modulation of synaptic transmission in the adult hippocampus. J Physiol (Paris) 89:11-22[ISI][Medline].
Keinanen K, Wisden W, Sommer B, Werner P, Herb A, Verdoorn TA, Sakmann B, Seeburg PH (1990) A family of AMPA-selective glutamate receptors. Science 249:556-560[Abstract/Free Full Text].
Kinoshita S, Yasuda H, Taniguchi N, Katoh-Semba R, Hatanaka H, Tsumoto T (1999) Brain-derived neurotrophic factor prevents low-frequency inputs from inducing long-term depression in the developing visual cortex. J Neurosci 19:2122-2130[Abstract/Free Full Text].
Korte M, Carroll P, Wolf E, Brem G, Thoenen H, Bonhoeffer T (1995) Hippocampal long-term potentiation is impaired in mice lacking brain-derived neurotrophic factor. Proc Natl Acad Sci USA 92:8856-8860[Abstract/Free Full Text].
Korte M, Griesbeck O, Gravel C, Carroll P, Staiger V, Thoenen H, Bonhoeffer T (1996a) Virus-mediated gene transfer into hippocampal CA1 region restores long-term potentiation in brain-derived neurotrophic factor mutant mice. Proc Natl Acad Sci USA 93:12547-12552[Abstract/Free Full Text].
Korte M, Staiger V, Griesbeck O, Thoenen H, Bonhoeffer T (1996b) The involvement of brain-derived neurotrophic factor in hippocampal long-term potentiation revealed by gene targeting experiments. J Physiol (Paris) 90:157-164[ISI][Medline].
Korte M, Kang H, Bonhoeffer T, Schuman E (1998) A role for BDNF in the late-phase of hippocampal long-term potentiation. Neuropharmacology 37:553-559[ISI][Medline].
Lesser SS, Lo DC (1995) Regulation of voltage-gated ion channels by NGF and ciliary neurotrophic factor in SK-N-SH neuroblastoma cells. J Neurosci 15:253-261[Abstract].
Lesser SS, Sherwood NT, Lo DC (1997) Neurotrophins differentially regulate voltage-gated ion channels. Mol Cell Neurosci 10:173-183.
Lessmann V, Heumann R (1998) Modulation of unitary glutamatergic synapses by neurotrophin-4/5 or brain-derived neurotrophic factor in hippocampal microcultures: presynaptic enhancement depends on pre-established paired-pulse facilitation. Neuroscience 86:399-413[ISI][Medline].
Lessmann V, Gottmann K, Heumann R (1994) BDNF and NT-4/5 enhance glutamatergic synaptic transmission in cultured hippocampal neurones. NeuroReport 6:21-25[ISI][Medline].
Levine ES, Dreyfus CF, Black IB, Plummer MR (1995) Brain-derived neurotrophic factor rapidly enhances synaptic transmission in hippocampal neurons via postsynaptic tyrosine kinase receptors. Proc Natl Acad Sci USA 92:8074-8077[Abstract/Free Full Text].
Levine ES, Dreyfus CF, Black IB, Plummer MR (1996) Selective role for trkB neurotrophin receptors in rapid modulation of hippocampal synaptic transmission. Brain Research. Mol Brain Res 38:300-303[Medline].
Levine ES, Crozier RA, Black IB, Plummer MR (1998) Brain-derived neurotrophic factor modulates hippocampal synaptic transmission by increasing N-methyl-D-aspartic acid receptor activity. Proc Natl Acad Sci USA 95:10235-10239[Abstract/Free Full Text].
Li YX, Xu Y, Ju D, Lester HA, Davidson N, Schuman EM (1998) Expression of a dominant negative TrkB receptor, T1, reveals a requirement for presynaptic signaling in BDNF-induced synaptic potentiation in cultured hippocampal neurons. Proc Natl Acad Sci USA 95:10884-10889[Abstract/Free Full Text]