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¹ Institute of Neuroscience (CNR), 56100 Pisa, Italy
² International School for Advanced Studies (SISSA), 34014 Trieste, Italy
³ Molecular Signaling Section, Laboratory of Bioorganic Chemistry, NIDDK, National Institutes of Health, Bethesda, MD 20892, USA
⁴ Dipartimento di Scienze e Tecnologie Biomediche, Università dell'Aquila, 67010, L'Aquila, Italy

	Abstract

Top Abstract Introduction Methods Results Discussion References

 
In the present report, we focused our attention on the role played by the muscarinic acetylcholine receptors (mAChRs) in different forms of long-term synaptic plasticity. Specifically, we investigated long-term potentiation (LTP) and long-term depression (LTD) expression elicited by theta-burst stimulation (TBS) and low-frequency stimulation (LFS), respectively, in visual cortical slices obtained from different mAChR knockout (KO) mice. A normal LTP was evoked in M₁/M₃ double KO mice, while LTP was impaired in the M₂/M₄ double KO animals. On the other hand, LFS induced LTD in M₂/M₄ double KO mice, but failed to do so in M₁/M₃ KO mice. Interestingly, LFS produced LTP instead of LTD in M₁/M₃ KO mice. Analysis of mAChR single KO mice revealed that LTP was affected only by the simultaneous absence of both M₂ and M₄ receptors. A LFS-dependent shift from LTD to LTP was also observed in slices from M₁ KO mice, while LTD was simply abolished in slices from M₃ KO mice. Using pharmacological tools, we showed that LTP in control mice was blocked by pertussis toxin, an inhibitor of G_i/o proteins, but not by raising intracellular cAMP levels. In addition, the inhibition of phospholipase C by U73122 induced the same shift from LTD to LTP after LFS observed in M₁ single KO and M₁/M₃ double KO mice. Our results indicate that different mAChR subtypes regulate different forms of long-term synaptic plasticity in the mouse visual cortex, activating specific G proteins and downstream intracellular mechanisms.

(Received 13 July 2006; accepted after revision 4 October 2006; first published online 5 October 2006)
Corresponding author L. Domenici: Dipartimento di Scienze e Tecnologie Biomediche, Università dell'Aquila, 67010, L'Aquila, Italy. Email: domenici{at}in.cnr.it

	Introduction

Top Abstract Introduction Methods Results Discussion References

 
A great number of studies conducted at physiological, morphological and behavioural levels have clearly demonstrated the involvement of the cholinergic system in the regulation of several brain functions. Cortical ACh release affects synaptic transmission (Krnjevic & Ropert, 1981; Gil et al. 1997; Kuczewski et al. 2005a), development of neuronal circuitry (Hohmann et al. 1991; Siciliano et al. 1997; Robertson et al. 1998; for a review see Gu, 2002) and high cognitive functions such as attention, learning and memory (Damasio et al. 1985; Casamenti et al. 1998; Steriade et al. 1991; Leanza et al. 1995; Everitt & Robbins, 1997; Sarter & Bruno, 2000; Dalley et al. 2001; Conner et al. 2003). The activity of the cholinergic system is also involved in the plastic reorganization of neuronal connectivity in the cerebral cortex (Aztiria et al. 2004). Interestingly, long-term potentiation (LTP) and long-term depression (LTD), two forms of synaptic plasticity believed to participate in the shaping of neuronal connections as well as in learning and memory, are regulated by cholinergic transmission (Brocher et al. 1992; Kirkwood et al. 1999; Pesavento et al. 2000). The fact that the reduction of cortical cholinergic innervation produces a shift from LTP to LTD that can be prevented by exogenous application of ACh (Kuczewski et al. 2005b) suggests a regulatory action of ACh on the direction of synaptic plasticity (LTP versus LTD). However, the role played by the different types of cholinergic receptors in these forms of plastic modifications remains to be determined (for a review see Bear, 2003). In the present report, we focused our attention on the role played by the muscarinic ACh receptors (mAChRs), and in particular, whether different mAChRs subtypes have different roles in the induction of LTP and LTD. Using mutant mice together with pharmacological tools, we investigated the role of different mAChRs in LTP and LTD. In particular, LTP induction and maintenance, as well as LTD, were studied in occipital slices from mice lacking specific mAChR subtypes. In addition, the roles of G_i/o proteins and phospholipase C (PLC) activation on long-term synaptic plasticity were evaluated by using pharmacological tools.

	Methods

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All experiments were carried out with mice that were at least 6 weeks old, and conducted following the European Community Council Directive for animal treatment. The generation of homozygous M₁–M₅ receptor single knockout (KO) mice (genetic background: 129/SvEv x CF1 (M1, M₃, M₄ and M₅) or 129J1 x CF1 (M2)) has been previously described (Gomeza et al. 1999a,b; Yamada et al. 2001a,b; Fisahn et al. 2002). The generation and genetic background of the M₂/M₄ and M₁/M₃ double KO mice has been previously described (Duttaroy et al. 2002; Gautam et al. 2004). For each KO strain, wild-type (WT) mice of the same mixed genetic background were used in parallel as controls. In a subset of experiments, we also used mAChR KO mice that had been backcrossed for 10 generations onto the C57BL/6NTac background (Taconic Farms, Germantown, NY, USA).

Slice preparation and electrophysiology

Animals were anaesthetized by intraperitoneal injection of urethane (1.2 g kg^–1; Sigma, St Louis, MO, USA) and decapitated immediately after disappearance of tail pinch reflex. Cortical coronal sections (400 µm thick) of the occipital pole were sliced with a vibratome. All steps were performed in ice-cold standard artificial cerebrospinal fluid (ACSF) solution (mM: NaCl, 126; KCl, 2.5; CaCl₂, 2.5; MgCl₂ 1.25; NaH₂PO₄, 1.2; NaHCO₃, 19; and glucose, 11) bubbled with 95% O₂–5% CO₂ unless otherwise stated. Prior to recording, slices were stored for at least 1 h in a recovery chamber containing oxygenated ACSF, at 33 ± 1°C. During electrophysiological recordings, slices were perfused at 3–4 ml min^–1 with oxygenated ACSF, at 33 ± 1°C.

In a separate group of slices, the composition of ACSF used to perfuse slices was modified to block the AMPA glutamate receptor and to isolate NMDA receptor (NMDAr)-mediated field potential (FP). Modified ACSF contained high calcium (3 mM CaCl₂) and low magnesium (0.1 mM MgCl₂) in the presence of 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; Sigma; 20 µM; see drugs) and glycine (1 µM).

Extracellular FPs were evoked via a tungsten concentric bipolar stimulating electrode placed in layer IV. The recording electrode (pulled glass capillaries, o.d. 1.0 mm, i.d. 0.78 mm) was filled with ACSF solution and placed in layer II/III. The amplitude of the FPs in layer II/III was used as a measure of the evoked population excitatory current (see Kuczewski et al. 2005a,b). Baseline responses were obtained with a stimulation intensity that yielded 50–60% of maximal amplitude. FP amplitudes were monitored every 20 s and averaged every three responses. Theta-burst stimulation (TBS; 10 bursts of 5 pulses at 100 Hz; 250 ms between bursts) was used for LTP induction; low-frequency stimulation (LFS; 900 pulses at 1 Hz) was used for LTD induction. At least 10 min of stable basal FPs were recorded before TBS or LFS. LTP and LTD amplitudes were measured as relative values obtained by averaging the FP amplitudes during the last 10 min of recording after TBS and LFS, respectively, and normalized with respect to the average of FP amplitudes during 10 min of basal stimulation. Values are expressed as mean amplitude percentage change (±S.E.M.).

Drugs

The following drugs were used: atropine (Sigma) to block mAChRs; CNQX to block AMPA glutamate receptors (AMPAr); 1-[6-[[(17ß)-3-methoxyestra-1,3,5(10)-trien-17-yl]amino]hexyl]-1H-pyrrole-2,5-dione (U73122; Alexis Biochemicals) to block PLC; pertussis toxin (PTx; Sigma), a G_i/o-protein inhibitor; forskolin (Sigma) to stimulate adenylate cyclase; Ro 20-1724 (Sigma), an inhibitor of cAMP phosphodiesterase. Atropine (1 µM), U73122 (4 µM), forskolin (40 µM) and Ro 20-1724 (50 µM) were bath applied through the perfusion medium for 10 or 20 min, starting 5 min before TBS or LFS, respectively. CNQX (20 µM) was dissolved in modified ACSF and bath applied. Briefly, at the beginning slices were bath perfused with standard ACSF for at least 10 min and FPs were recorded. After 10 min, standard ACSF was substituted with modified ACSF plus CNQX. This step was followed by wash out and recovery of slices in standard ACSF.

In experiments involving PTx treatment, slices were incubated in ACSF containing PTx (5 µg ml^–1) for at least 6 h before recordings.

Histochemistry

Mice were anaesthetized by intraperitoneal injection of urethane (1.2 g kg^–1; Sigma) and perfused with 4% paraformaldehyde/PBS (pH 7.4) after disappearance of tail pinch reflex. Samples were cryoprotected in 30% sucrose/PBS at 4°C, and coronal sections (40 µm thick) were cut on a freezing microtome and collected in four series. One of the series was subjected to Nissl staining. Another series of sections from each mouse group was processed for acetylcholinesterase (AChE) histochemistry, as described elsewhere (Hedreen et al. 1985), in order to determine whether the lack of mAChRs affected normal terminal cholinergic innervation of the cortex. In brief, sections were incubated in a medium containing sodium citrate, copper sulphate, potassium ferricyanide, and acetylthiocholine iodide, at pH 6. Non-specific esterases were inhibited by the addition of ethopropazine (Sigma) at a final concentration of 10^–4 M to the incubation mixture. The reaction product was finally intensified by 1 min incubation with ammonium sulphide and silver nitrate. Sections from control and KO mice were processed simultaneously in order to avoid artefacts in the estimation of the AChE-positive fibre density. Mounted sections were analysed in a blinded fashion under the microscope and the density of cholinergic fibres was determined using the NIH Image software (Rasband & Bright, 1995). The optical density of the corpus callosum, which normally contains no AChE-positive fibres, was used as a blank and was therefore subtracted from that of the visual cortex.

Statistics

Statistical comparison between FP amplitudes measured during baseline and during the last 10 min of recording following TBS or LFS was performed by applying Student's t test. The t test was also used for comparisons among different groups. Differences were considered significant with P < 0.05.

	Results

Top Abstract Introduction Methods Results Discussion References

 
In occipital slices of WT mice LTP and LTD were induced by TBS and LFS, respectively (LTP: 124 ± 7% of baseline after TBS, n = 7; Fig. 1A; LTD: 73 ± 9% of baseline after LFS, n = 6; Fig. 1B). In order to investigate whether LTP and LTD require the activation of mAChR, we bath applied the mAChR antagonist atropine; the duration of atropine application was 10 min, centred around TBS, and 20 min during LFS (Fig 1C and D). Atropine, 1 µM, prevented both LTP (98 ± 4%, n = 6; Fig. 1C) and LTD (98 ± 9%, n = 6; Fig. 1D) without interfering with basal responses (Fig 1E, n = 10). Therefore the activation of mAChRs is necessary to induce LTP and LTD.

View larger version (31K): [in this window] [in a new window]   Figure 1.  Synaptic plasticity in the visual cortex of wild-type (WT) mice requires muscarinic acetylcholine receptor (mAChR) activation A, theta-burst stimulation (TBS) of layer IV produces a stable long-term potentiation (LTP) in the visual cortex slices. B, low-frequency stimulation (LFS) of layer IV produces a stable long-term depression (LTD) in the visual cortex slices. C, LTP is prevented by bath application of 1 µM atropine. D, LTD is prevented by bath application of 1 µM atropine. E, bath application of 1 µM atropine has no effect on baseline synaptic responses. Black horizontal bars in B and D represent the time window of LFS. Grey horizontal bars represent atropine application time windows. Top inserts in A, B, C, D and E show representative field potentials (FPs). Scale bars for FPs are shown in E.

View larger version (31K): [in this window] [in a new window]   Figure 2.  LTP and LTD depend on different mAChR subtypes in mouse visual cortex A, TBS stimulation failed to induce LTP in the visual cortex slices of M2/M4 but not M1/M3 double knockout (KO) mice. B, LFS produced a normal LTD in the visual cortex slices of M2/M4 KO animals, but produced an LTP in the visual cortex slices of M1/M3 KO mice (black horizontal bar represents the time window of LFS). Top inserts in A and B show representative FPs; horizontal scale bar, 10 ms; vertical scale bar, 0.5 mV. C, input–output curves in WT, M1/M3 and M2/M4 KO slices; FP amplitudes are normalized with respect to values at 10 V stimulation. D, top insets show representative FP recorded in standard artificial cerebrospinal fluid (ACSF) (left) and NMDAr-mediated FP in modified ACSF (high calcium, low magnesium, see Methods) plus CNQX (right); the asterisk indicates the non-synaptic component of the FP. The histogram shows the mean values of FP amplitude (NMDAr-mediated FP) in modified ACSF expressed as percentage of FP amplitude in standard ACSF. Briefly, FPs in layer II–III (frequency of stimulus 0.05 Hz) were recorded in slices bath perfused with standard ACSF; after 10 min, standard ACSF was substituted with modified ACSF containing high calcium and low magnesium plus CNQX. No significant differences in NMDAr FP amplitude were found between WT, M1/M3 and M2/M4 KO mice.

View larger version (104K): [in this window] [in a new window]   Figure 3.  Cortical slices from M1/M3 and M2/M4 double KO mice exhibit normal cholinergic fibre density and distribution A, acetylcholinesterase (AChE) positive fibre density was measured from the boxed field shown in layers II–III of the visual cortex. High-magnification views of the equivalent squared area shown in A are shown in B for each of the double KO mice and the respective controls (calibration bar is 950 µm for A and 190 µm for B). C, results of densitometric analyses carried out on AChE-stained sections (3 animals per group).

View larger version (19K): [in this window] [in a new window]   Figure 4.  M2 and M4 mAChR single KO mice show normal LTP, while LTD is impaired in M1 and M3 mAChR single KO mice A, in visual cortex slices of M2 and M4 single KO mice, TBS induced a normal LTP. B, LFS failed to induce LTD in the visual cortex slices of M3 single KO mice, and produced an LTP in M1 single KO mice (black horizontal bar represents the time window of LFS). Top inserts in A and B show representative FPs; vertical scale bar, 0.5 mV, horizontal scale bar, 5 ms.

To exclude the possibility that the mixed genetic background of the mutant mice used affected the outcome of the studies described above, we repeated key experiments with M₁ single KO, M₃ single KO and M₂/M₄ double KO mice that had been backcrossed for 10 generations onto the C57BL/6NTac background. We found that LFS induced the shift from LTD to LTP in backcrossed M₁ single KO mice (127 ± 5%, n = 7), but failed to induce LTD in backcrossed M₃ single KO mice (99 ± 11%, n = 5; Fig. 5A and B); TBS failed to induce LTP in backcrossed M₂/M₄ double KO mice (109 ± 8, n = 5; Fig. 5C). Thus, the results obtained with the backcrossed KO mice exclude the possibility that the observed changes in LTP and LTD are dependent on a specific (mixed) mouse genetic background.

View larger version (17K): [in this window] [in a new window]   Figure 5.  Control experiments using cortical slices from backcrossed M1 single KO, M3 single KO, and M2/M4 double KO mice Cortical slices were prepared from KO mice that had been backcrossed for 10 generations onto the C57BL/6NTac background. A, LFS induced LTP in M1 single KO mice. B, LFS failed to induce LTD in M3 single KO mice. C, TBS failed to induce LTP in M2/M4 double KO mice.

View larger version (23K): [in this window] [in a new window]   Figure 6.  Inhibition of Gi/o proteins but not of phospholipase C (PLC) blocks TBS-induced LTP in WT cortical slices A, preincubation of slices with 5 µg ml–1 pertussis toxin (PTx) inhibits LTP after TBS stimulation. B, bath application of forskolin (40 µM) does not influence TBS-induced LTP. C, bath application of Ro 20-1724 (50 µM) does not affect TBS-induced LTP, in analogy to the results shown in B. D, bath application of the PLC inhibitor U73122 (4 µM) has no effect on LTP induction. Grey horizontal bars in A, B, C and D represent drug application time windows.

View larger version (22K): [in this window] [in a new window]   Figure 7.  LFS-induced LTP in M1 single KO mice is muscarinic receptor dependent, and requires activation of PTx-sensitive G proteins A, in WT slices, bath application of U73122 (4 µM) during LFS mimics the absence of M1 receptors, inducing a shift to LTP. B, WT slices preincubated with PTx (5 µg ml–1) show normal LTD after LFS. C, bath application of atropine (1 µM) inhibits the LFS induced shift to LTP in M1 KO slices. D, the LFS-induced shift to LTP in M1 KO slices is blocked by PTx pretreatment. Grey horizontal bars in A and C represent the time windows of drug application.

Thus, these results indicate that PTx-sensitive G proteins control LTP induced by TBS, while PTx-insensitive G proteins, via activation of PLC, are involved in LTD induced by LFS. The paradoxical shift from LTD to LTP induced by LFS in the absence of M₁ receptors is a mixed effect due to failure of PLC activation coupled with the activation of PTx-sensitive G proteins.

	Discussion

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In the present paper, we showed that LTP and LTD rely on the activation of different mAChRs. The principal mAChR subtypes expressed in rodent cortex are M1, M₂, M₃ and M₄ (Levey et al. 1991; Kuczewski et al. 2005a). These receptors can be grouped according to the type of G proteins that they activate. M₂ and M₄ mAChRs are coupled to the PTx-sensitive G_i and G_o proteins, leading to the inhibition of adenylyl cyclase, whereas the M₁ and M₃ mAChRs preferentially interact with the PTx-insensitive G_q/11 and G₁₃ proteins, leading to the activation of phospholipases C and D (for a review see Wess, 1996). We showed that different mAChRs control different forms of long-term synaptic plasticity. Indeed, an impairment of LTP but not of LTD was found in M₂/M₄ mAChR double KO mice, while M₁/M₃ KO mice lacked LTD but showed normal LTP. The analysis of mAChR single KO mice demonstrated that LTP was not affected in M₂ or M₄ single KO animals, while an impairment of LTD was observed in the absence of either M₁ or M₃ mAChRs. On the other hand, the expression of LTD requires M₁- and M₃-dependent stimulation of PTx-insensitive G proteins. In M₁/M₃ double KO and in M₁ single KO mice, LFS induced a LTP instead of LTD.

The present data suggest that the expression of cortical synaptic plasticity depends on the activation of different G-protein-linked pathways activated by different mAChR. Our data suggest that M₂- and M₄-dependent activation of G_i and/or G_o proteins is required for LTP but not for LTD. PTx, an inhibitor of G_i and G_o proteins, blocked LTP induction by TBS in control mice, suggesting that M₂ and M₄ mAChRs are involved in the induction and/or maintenance of LTP, but not LTD, through activation of G_i/G_o. We also examined whether modulation of intracellular cAMP levels is involved in LTP expression. To this aim we used two different compounds, forskolin and Ro 20-1724, both of which raise intracellular cAMP levels. LTP in WT slices was not affected by either compound, suggesting that inhibition of cAMP through G_i/G_o is not required for LTP. Since G_i/G_o activation leads to inhibition of adenylate cyclase through G subunits, as well as activation of other effector proteins such as PI3 kinase (PI3K) through G_ß (Rosenblum et al. 2000), it is possible that G_i/o proteins coupled to M₂/M₄ receptors can activate G_ß-dependent pathways converging on MAP kinases, such as extracellular signal regulated kinases (ERKs; Koch et al. 1994; Crespo et al. 1994). In agreement with this notion, LTP in visual cortex requires the activation of ERK (Di Cristo et al. 2001).

Our data suggest that more complex mechanisms underlie LTD induction. As shown by the results obtained with single KO mice, the absence of M₃ mAChRs results in the blockade of LTD, suggesting a role of M₃ mAChRs in LTD. The lack of M₁ mAChRs induced a paradoxical shift from LTD to LTP following LFS. Studies with atropine demonstrated that this shift involves signalling via mAChRs. Moreover, using an inhibitor of PLC (U73122; Thompson et al. 1991; Yule & Williams, 1992) in control slices we were able to reproduce the shift from LTD to LTP following LFS. Interestingly, LTP was enhanced in slices treated with U73122 with respect to single M₁ and double M₁/M₃ KO mice, suggesting that the lack of M₁ and M₃ mAChRs is not sufficient to completely abolish PLC activation involved in long-term synaptic plasticity. Indeed, other neurotransmitter receptors such as the serotonin 5-HT₂ receptor (Edagawa et al. 2000) and the metabotropic glutamate receptors (Otani et al. 2002) are involved in forms of cortical plasticity dependent on PLC activation. Using PTx in M₁ single KO mice, we showed that the paradoxical LTP generation after LFS is blocked. Thus, the shift from LTP to LTD in the absence of M₁ mAChRs is due to failure of PLC activation coupled to PTx-sensitive G protein action.

Regarding long-term synaptic plasticity, the present results suggest that the direction of synaptic plasticity depends on the combined activity of different mAChRs. An intriguing possibility is that ACh, by acting on different mAChR subtypes, regulates the Bienenstock-Cooper-Munro (BMC) threshold for synaptic modification. According to the BMC model, a given synaptic stimulus could produce either LTP or LTD depending on whether or not it is able to overcome a certain modification threshold (_m; reviewed by Bear, 2003). According to this hypothesis, _m would be affected by an imbalance between M₁/M₃ and M₂/M₄ receptor signalling in a way that the predominant activation of M₂/M₄ receptors in absence of M₁ receptors, as occurring in M₁ single KO mice, would lead to a decreased _m, favouring the induction of LTP over LTD. Consistent with this concept, a recent report showed that _m could vary according to the expression levels of different NMDA receptor subunits (Philpot et al. 2001). From previous studies, there is increasing evidence that mAChRs and NMDA receptors interact to modulate neuronal plasticity in the visual cortex (Boroojerdi et al. 2001) and in other brain areas (Liu et al. 2004; Massey et al. 2004; Young et al. 2004; Grishin et al. 2005). Thus, it remains to be investigated whether the interaction of mAChRs and NMDA receptors at the cellular level may lead to the modulation of _m.

Another possibility is that in the absence of the M₁ receptors, the M₂ and M₄ receptors that show higher affinity for ACh than the M₃ receptor (Lazareno & Birdsall, 1995) would be preferentially activated leading to LTP instead of LTD.

In the present paper, we showed that LTP was normal in M₂ and M₄ single KO animals. Previous studies (for a review see Wess, 2004) have shown that the disruption of one specific mAChR gene has little effect on the expression levels of the remaining mAChRs. Our data therefore strongly suggest that LTP in the visual cortex is affected only when both M₂ and M₄ mAChRs are lacking. Our results differ from recent data obtained in the hippocampus where the absence of M₂ receptors is sufficient to produce a pronounced impairment of LTP (Seeger et al. 2004), indicative of local differences in the dependence of LTP and LTD on single mAChRs. Thus, the local and selective activation of different mAChR subtypes by ACh may contribute to the multitude of actions that the cholinergic system exerts on brain functions, such as learning and memory, attention and sensory map plasticity, through modulation of the different forms of long-term synaptic plasticity.

	Footnotes

 
N. Origlia and N. Kuczewski contributed equally to this work.

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	Acknowledgements

 
We are grateful to Roberto Maggio and Tommaso Pizzorusso for helpful discussions. We acknowledge Carlo Orsini for online acquisition software and for technical assistance. This work was partially supported by a grant (05/140) from Fondazione Cassa di Risparmio, Pisa.

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