ARTICLE

Received 25 Jan 2016 | Accepted 23 Sep 2016 | Published 9 Nov 2016

DOI: 10.1038/ncomms13340 OPEN

Decrease of SYNGAP1 in GABAergic cells impairs inhibitory synapse connectivity, synaptic inhibition and cognitive function

Martin H. Berryer1,2, Bidisha Chattopadhyaya1,2, Paul Xing1,2, Ilse Riebe1,3, Ciprian Bosoi2, Nathalie Sanon2, Judith Antoine-Bertrand4, Maxime Lvesque5, Massimo Avoli5, Fadi F. Hamdan2, Lionel Carmant1,2, Nathalie Lamarche-Vane4, Jean-Claude Lacaille1,3,*, Jacques L. Michaud1,2,6,* & Graziella Di Cristo1,2,*

Haploinsufciency of the SYNGAP1 gene, which codes for a Ras GTPase-activating protein, impairs cognition both in humans and in mice. Decrease of Syngap1 in mice has been previously shown to cause cognitive decits at least in part by inducing alterations in glutamatergic neurotransmission and premature maturation of excitatory connections. Whether Syngap1 plays a role in the development of cortical GABAergic connectivity and function remains unclear. Here, we show that Syngap1 haploinsufciency signicantly reduces the formation of perisomatic innervations by parvalbumin-positive basket cells, a major population of GABAergic neurons, in a cell-autonomous manner. We further show that Syngap1 haploinsufciency in GABAergic cells derived from the medial ganglionic eminence impairs their connectivity, reduces inhibitory synaptic activity and cortical gamma oscillation power, and causes cognitive decits. Our results indicate that Syngap1 plays a critical role in GABAergic circuit function and further suggest that Syngap1 haploinsufciency in GABAergic circuits may contribute to cognitive decits.

1 Department of Neurosciences, Universit de Montral, C.P. 6128, Succ. Centre-Ville, Montral, Quebec, Canada H3C 3J7. 2 CHU Sainte-Justine Research Center, 3175 Cte-ste-Catherine, Montral, Quebec, Canada H3T 1C5. 3 Groupe de Recherche sur le Systme Nerveux Central, Universit de Montral, C.P. 6128, succ. Centre-ville, Montral, Quebec, Canada H3C 3J7. 4 Department of Anatomy and Cell Biology, Cancer Research Program of the Research Institute of MUHC, McGill University, 2155 Guy Street, Suite 500, Montreal, Quebec, Canada H3H 2R9. 5 Department of Neurology and Neurosurgery, Montreal Neurological Institute, McGill University, 3801 University Street, Montreal, Quebec, Canada H3A 2B4. 6 Department of Pediatrics, Universit de Montral, CHU Sainte-Justine, 3175, chemin de la Cte-Sainte-Catherine, 7th oor, block 9, Montreal, Quebec, Canada H3T 1C5. * These authors contributed equally to this work. Correspondence and requests for materials should be addressed to J.L.-M. (email: mailto:[email protected]

Web End [email protected] )or to G.D.C. (email: mailto:[email protected]

Web End [email protected] ).

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Long-term changes in the strength of synaptic transmission are thought to be critical both during brain development and for learning and memory throughout life. The Ras family

GTPases, their downstream signalling proteins and upstream regulators are key biochemical cascades modulating synaptic plasticity. SYNGAP1 codes for a GTPase-activating protein (GAP) that physically interacts with the small GTPase Ras, which in turn acts in a cycle as a molecular switch with an active GTP-bound form and an inactive GDP-bound form1,2. Ras has a slow intrinsic GTPase activity, and GAPs such as SYNGAP1 negatively regulate Ras by enhancing the hydrolysis of GTP to GDP. The importance of SYNGAP1 in synaptic plasticity is exemplied by the fact that de novo mutations in the SYNGAP1 gene cause moderate or severe intellectual deciency (ID)39. SYNGAP1 function has been mainly studied in excitatory neurons. For example, in primary neuronal cultures, SYNGAP1 functions to limit excitatory synapse strength by restricting the expression of the AMPA receptor (AMPAR) at the postsynaptic membrane1,2,10,11. In mice, Syngap1 haploinsufciency causes abnormal synaptic plasticity as well as behavioural abnormalities and cognitive decits1215. Syngap1 / mice are also characterized by enhanced excitatory synaptic transmission early in life and the premature maturation of glutamatergic synapses16,17. Thus, it has been proposed that glutamatergic synaptic alterations represent the main contributing factor for the occurrence of cognitive and behavioural decits16,17.

During healthy cortical network activity, excitation is precisely balanced by GABAergic inhibition. Inhibitory activity not only regulates circuit excitability, but also restricts the temporal window for integration of excitatory synaptic inputs and resulting spike generation, thereby facilitating an accurate encoding of information in the brain18. In addition, GABAergic cells are implicated in generating temporal synchrony and oscillations among networks of pyramidal neurons, which are involved in complex cognitive functions, such as perception and memory19,20. Furthermore, GABAergic inhibition plays a critical role in modulating developmental plasticity in the young brain21. Highlighting the importance of GABA interneurons in cognitive functions, cortical circuits in several mouse models of ID and autistic-like behaviour show excitation/inhibition imbalance, which is due to alterations in glutamatergic or GABAergic neurotransmission, or more often, in both16,2227. Whether and to what extent Syngap1 haploinsufciency affects GABAergic cell circuits, thus contributing to excitation/inhibition imbalance and cognitive abnormalities remains unclear.

Here, we examined the specic contribution of Syngap1 to the formation of perisomatic innervations by parvalbumin-positive basket cells, a major population of GABAergic neurons, by single-cell deletion of Syngap1 in cortical organotypic cultures. In addition, we generated mice with specic deletion of Syngap1 in GABAergic neurons generated in the medial ganglionic eminence (MGE) to assess its role in the establishment of mature GABAergic connectivity and mouse cognitive function in vivo. We found that Syngap1 strongly modulated the formation of GABAergic synaptic connectivity and function and that MGE cell-type specic Syngap1 haploinsufciency altered cognition.

Results

Single-cell Syngap1 knockdown reduced PV cell innervations.

Syngap1 expression peaks when the processes of synaptogenesis and developmental plasticity are heightened28. While its expression in glutamatergic cell is well documented1,1416,2932, few studies have also reported SYNGAP1 expression in GABAergic neurons17,33,34. To conrm that SYNGAP1 is present in GABAergic neurons, we prepared dissociated

neuronal cultures from E18 wild-type embryos and immunostained them for GAD67, which is the main GABA synthesizing enzyme35, and SYNGAP1 at DIV21, after the peak of synapse formation. We found that GAD67-positive cells co-localized with SYNGAP1 (Supplementary Fig. 1a, 635% co-localization), indicating that SYNGAP1 is indeed expressed by GABAergic neurons.

GABAergic circuits comprise an astonishing variety of different cell types, exhibiting differences in molecular, morphological and electrophysiological properties19. These differences are particularly important in the light of recent discoveries suggesting that different GABAergic cell types are recruited by different behavioural events19. Among the different GABAergic neuron subtypes, the parvalbumin-expressing (PV ) basket cells

comprise the largest subpopulation in cortical circuits19. Each PV basket cell innervates hundreds of neurons, with large,

clustered boutons targeting the soma and the proximal dendrites of postsynaptic targets, an optimal location to control timing and frequency of action potential generation19,36. Such distinct features of PV basket cell innervations are achieved during

the rst postnatal month in rodents and are modulated by neural activity levels35,3739. We found that almost the totality of PV

basket cells express SYNGAP1 in dissociated neuronal cultures (Supplementary Fig. 1b) and thus we sought to investigate whether Syngap1 plays a role in the formation of the innervation of PV basket cells, by inducing single-cell Syngap1 deletion in

cortical organotypic cultures.To reduce Syngap1 expression in isolated PV basket cells

and simultaneously label their axonal arbours at synaptic resolution, we used a previously characterized promoter region PG67 (ref. 37) to express either the Cre recombinase together with GFP (PG67-GFP/Cre) or GFP alone (PG67-GFP; control basket cells) in cortical organotypic cultures prepared from Syngap1ox/ox mice35,3740. In organotypic cultures, PV basket

cells initially display very sparse and simple axons, which develop into complex and highly branched arbours in the following 4 weeks, recapitulating the in vivo situation37,38. We chose to induce Syngap1 deletion in PV basket cells at Equivalent

Postnatal day 10 (EP10 cultured prepared at Postnatal day

4 6DIV) and collect the cultures at EP24 because extensive and

stereotyped maturation of PV basket cell innervations occurs

during this time window37,3741.We investigated two aspects of PV basket cell axon

innervation: (1) the extent of perisomatic innervation around single neuronal somata (terminal branching and perisomatic bouton density) and (2) the fraction of potentially innervated cells in the eld (percentage of innervation). By studying the localization of pre- and post-synaptic markers and performing electron microscopy, we have previously shown that the vast majority of GFP-labelled boutons in our experimental condition represent presynaptic terminals35,37,42.

Whereas control basket cells at EP24 showed complex perisomatic innervations (Fig. 1a,b), Syngap1 knockdown in single-basket cells from EP10-24 induced a signicant reduction in the number of both axonal branching and synaptic boutons innervating the target neurons (NeuN-positive cells; Fig. 1cf: boutons/soma, 7.40.3 for control versus 5.20.5 for basket cells transfected with PG67-GFP/Cre; Students t-test P 0.002).

On the other hand, the percentage of potentially innervated neurons were not signicantly different between the two groups (Fig. 1g: 71%2 for control versus 66%2 for basket cells transfected with PG67-GFP/Cre; Students t-test, P 0.125),

suggesting that Syngap1 deletion specically affected local synapse formation of PV basket cells but not their overall axonal

growth. Syngap1 knockout at later age (EP16-24) caused a similar decrease in perisomatic bouton density (Supplementary Fig. 2,

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Figure 1 | Single-cell Cre-mediated inactivation of Syngap1 reduces the number of cortical GABAergic basket cell boutons and terminal branching. (a) Control GABAergic basket cell transfected with pGAD67-GFP (green) in EP24 cortical organotypic cultures from Syngap1ox/ox mice showing (b) rich axonal branching and numerous clustered boutons (arrowheads) around NeuN-positive somata (blue). (c,d) Conversely, a basket cell transfected with pGAD67-Cre/GFP from EP16-24 shows markedly reduced axonal branching and perisomatic boutons (arrowheads). (e) Bouton density and (f) complexity of terminal axon branching are signicantly decreased in pGAD67-Cre/GFP basket cells (e: Students t-test, *P 0.002; f: Students t-test, P 0.045 at

8 mm and P 0.010 at 9 mm), whereas the percentage of innervated cells (g) is not affected compared with age-matched control basket cells (Students

t-test, P 0.125). n 8 basket cells transfected with pGAD67-GFP from n 5 mice; n 6 basket cells transfected with pGAD67-Cre/GFP from n 5 mice.

Scale bar, (a,c) 50 mm; (b,d) 10 mm.

boutons/soma, 7.40.3 for control versus 4.70.5 for basket

cells transfected with PG67-GFP/Cre; Students t-test P 0.00023).

Altogether, these data demonstrate that Syngap1 promotes the formation of PV basket cell innervations in a cell-autonomous

manner.

MGE-specic Syngap1 knockdown impaired PV cell connectivity. Our data suggest that reducing Syngap1 expression has a direct impact on the formation of PV basket cell innervations

in vitro. To investigate the role of Syngap1 in PV cell circuits

in vivo, we generated mice that were heterozygous or homozygous for the Syngap1ox allele and hemizygous for the Tg(Nkx2.1-Cre) transgene. This approach allowed the conditional deletion of Syngap1 in cortical,43 hypothalamic43 and mesencephalic44 (striatum) GABAergic interneurons originating from the MGE as early as embryonic day 10.5 and throughout adulthood45. In mouse, Nkx2.1-expressing MGE precursors produce most of PV and Somatostatin (SST) cortical

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interneurons45. To conrm the specicity of CRE expression, we uorescently labelled the cells expressing Cre by crossing Tg(Nkx2.1-Cre);Syngap1ox/ mice with a GFP reporter line (RCE mouse46). We conrmed that cortical GFP cells

expressed either PV or SST (Supplementary Fig. 3; percentage of GFP cells expressing PV or SST, 747% and 256%,

respectively, n 3 mice). Further, the large majority of cortical

neurons immunopositive for PV also expressed GFP (856%, n 3 mice), as previously reported47.

We focused our study on Tg(Nkx2.1-Cre);Syngap1ox/ mice, since most of Tg(Nkx2.1-Cre);Syngap1ox/ox mice died at birth (9 out of 11, Tg(Nkx2.1-Cre);Syngap1ox/ox versus none of Tg(Nkx2.1-Cre);Syngap1ox/ mice) as it is the case for Syngap1 / mice. Therefore, Syngap1 expression in

MGE-derived cells may be required for survival. Alternatively, since both Syngap1 and Nkx2.1 are expressed in the developing lungs and heart28,29,45, it is possible that the deletion of Syngap1 outside the brain is the cause underlying this early mortality.

First, we investigated whether Syngap1 haploinsufciency restricted to MGE-derived GABAergic cells affected perisomatic innervations formed by PV basket cells in the cortex. In

particular, we analyzed the intensity of PV immunostaining around layer 5 NeuN-positive neurons in the somatosensory cortex of P45 Tg(Nkx2.1-Cre);Syngap1ox/ and control litter-mates as reported in27. In control mice, distinct PV-positive perisomatic bouton rings enclosed a large portion of the pyramidal cell soma, while PV-positive perisomatic rings were signicantly less developed in Tg(Nkx2.1-Cre);Syngap1ox/ (Fig. 2a,b,e: PV mean intensity (a.u.), 15.90.9 for Syngap1ox/ mice versus 10.10.8 for Tg(Nkx2.1-Cre);Syngap1ox/ mice;

One-way ANOVA post hoc Dunns test, P 0.00404), which

suggests a decrease of perisomatic boutons made by PV basket

cells. This effect was not restricted to the cortex, as we found a similar reduction in PV staining intensity around hippocampal CA1 pyramidal cells (PV mean intensity (a.u.), 172, n 52 cells

from three Syngap1ox/ mice versus 9.90.9, n 56 cells from

four Tg(Nkx2.1-Cre);Syngap1ox/ mice; one-way ANOVA, post hoc Dunns test, P 0.0183).

To evaluate whether germ-line Syngap1 haploinsufciency affects GABAergic perisomatic innervation formed by PV

basket cells in the cortex, we performed the same analysis in Syngap1 / and control littermates. We found a reduction in perisomatic PV-positive rings in the somatosensory cortex of

Syngap1 / mice, which was comparable to what we observed in Tg(Nkx2.1-Cre);Syngap1ox/ (Fig. 2ce; PV mean intensity (a.u.), 121, versus 8.60.7 from Syngap1/ and Syngap1 /

mice, respectively; one-way ANOVA, post hoc Dunns test P 0.0274). Thus, Syngap1 haploinsufciency both in germ line

and MGE-derived interneurons reduced cortical PV basket cell

bouton density in vivo.

To further investigate how Syngap1 haploinsufciency in MGE-derived GABAergic in MGE-derived GABAergic cells affect the formation of affects the formation of PV basket cell axonal

arbour and synaptic boutons, we prepared cortical organotypic cultures from P4 Tg(Nkx2.1-Cre);Syngap1ox/ mice and their control littermates. PV basket cells were labelled by biolistic

transfection of PG67-GFP. In EP24 organotypic cultures from control mice (Syngap1ox/ ), NeuN-positive somata were surrounded by highly branched basket cell axonal terminals and numerous perisomatic boutons (Fig. 3a,b); on the contrary, in age-matched cultures from Tg(Nkx2.1-Cre);Syngap1ox/ mice, we found a signicant decrease of the complexity of the terminal axonal branching (Fig. 3c,d,f) as well as of the perisomatic bouton density formed by basket cell around targeted neurons (Fig. 3e; boutons/soma, 101 for Syngap1ox/ versus 4.70.3 for

Tg(Nkx2.1-Cre); Syngap1ox/ , Students t-test P 0.02). Simi

larly to what we observed in single-basket cell knockout of Syngap1 performed at EP10-24, the fraction of innervated somata was not affected by Syngap1 knockdown in MGE-derived PV

basket cells at the embryonic stage (Fig. 3g, percentage of innervation, 69%3% for Syngap1ox/ versus 67%3% for

Tg(Nkx2.1-Cre);Syngap1ox/ ; Students t-test, P 0.623). All

together, these data show that Syngap1 haploinsufciency in MGE-derived neuron affects the formation of PV basket cell

innervations in vivo.

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Figure 2 | Both MGE-specic and germ-line Syngap1 haploinsufciency reduce PV perisomatic innervation in the cortex of young adult mice.

(a,b) Confocal images of layer 5 pyramidal cells in somatosensory cortex of P45 mice show distinct and intense PV-positive perisomatic rings (green), which enclosed a large portion of neuronal somata (NeuN, blue) in control Syngap1ox/ mice (a), whereas in Tg(Nkx2.1-Cre);Syngap1ox/ mice(b) perisomatic PV-ring are less intense and often do not form a complete ring around cell somata. (c,d) Similar differences can be observed between Syngap1 / (c) and Syngap1 / (d) mice. (e) Quantication show that mean PV uorescence per NeuN soma section is signicantly reduced in

Tg(Nkx2.1-Cre);Syngap1ox/ and Syngap1/ compared with their respective control littermates (One-way ANOVA with Dunns multiple comparisons post hoc method, *P 0.00404 for Tg(Nkx2.1-Cre);

Syngap1ox/ versus Syngap1ox/, *P 0.0274 versus Syngap1 / for

Syngap1 / ). Graph bars represent means.e.m., circles represent values for each analyzed mouse. n 91 neurons from 3 Syngap1ox/ mice; n 93

neurons from 4 Tg(Nkx2.1-Cre);Syngap1ox/ mice, n 100 neurons from

4 Syngap1 /, n 109 neurons from 4 Syngap1 / . Scale bar, 10 mm.

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a b

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Figure 3 | Syngap1 promotes terminal axonal branching and bouton formation in cortical MGE-derived basket cells. (a) A GABAergic basket cell transfected with pGAD67-GFP (green) in EP24 cortical organotypic cultures from Syngap1ox/ mice showing dense axonal innervation and clustered perisomatic boutons (b, arrowheads) around pyramidal somata (NeuN, blue). (c) In contrast, age-matched basket cells from organotypic cultures from

Tg(Nkx2.1-Cre);Syngap1ox/mice show strongly reduced terminal axonal branching and bouton density around neuronal somata (d, arrowheads). (e,f) MGE-derived basket cells from Tg(Nkx2.1-Cre);Syngap1ox/show signicantly reduced bouton density and less developed terminal branching (e: Students t-test, *P 0.02; f: Students t-test, P 0.035 at 6 mm, P 0.020 at 7 mm, P 0.045 at 8 mm and P 0.020 at 9 mm) compared with

age-matched basket cells from Syngap1ox/ cultures. (g) The percentage of innervated cells does not differ between the two phenotypes (Students t-test, P 0.623), suggesting that Syngap1 promotes the formation of local perisomatic innervations without affecting overall axonal growth. n 6 basket cells

from 3 Syngap1ox/mice; n 7 basket cells from 3 Tg(Nkx2.1-Cre);Syngap1ox/ mice. Scale bar, (a,c) 50 mm; (b,d) 10 mm.

MGE-specic Syngap1 knockdown impaired GABA transmission. The observation that PV basket cells in Tg(Nkx2.1-Cre);

Syngap1ox/ formed less boutons around their potential postsynaptic targets raises the possibility of an impairment in

GABAergic synaptic transmission. Thus, we examined the effects of MGE-specic Syngap1 knockdown on spontaneous inhibitory

synaptic transmission in acute cortical and hippocampal slices from adult Tg(Nkx2.1-Cre);Syngap1ox/ mice and their respective control littermates. We found that mean inter-event interval (IEI) of miniature inhibitory postsynaptic currents (mIPSCs) recorded from pyramidal neurons in L2-3 somato-sensory cortex was signicantly longer in Tg(Nkx2.1-

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Cre);Syngap1ox/ mice relative to the controls (Fig. 4a,c; IEI: 927 ms for Syngap1ox/ versus 14317 ms Tg(Nkx2.1-

Cre);Syngap1ox/ ; linear mixed model (LMM), P 0.004186).

Similarly, inter-event intervals of mIPSCs recorded from CA1 pyramidal neurons were signicantly longer in Tg(Nkx2.1-Cre);-Syngap1ox/ mice relative to the controls (Fig. 4e,g; IEI: 18426 ms for Syngap1ox/ versus 789157 ms Tg(Nkx2.1-

Cre);Syngap1ox/ ; LMM, P 0.00109). Amplitude of

mIPSCs was not affected in Tg(Nkx2.1-Cre); Syngap1ox/ mice compared with controls (Fig. 4a,c,e,g; LMM,

P40.5). Finally, mIPSC kinetics and mIPSC charge transfer were not signicantly different for cortical and hippocampal

neurons between the different genotypes (Supplementary Fig. 4). Therefore, Syngap1 haploinsufciency in MGE-derived interneurons in vivo strongly affects GABAergic transmission in adult mice.

To investigate whether inhibitory neurotransmission is also affected by germ-line deletion of Syngap1, we performed the same analysis in Syngap1 / and control littermates. We found no difference in inter-event intervals of mIPSC recorded from either

L2-3 or CA1 pyramidal neurons in Syngap1 / compared with control mice (Fig. 4b,d,f,h; L2-3: IEI: 11115 ms for Syngap1 / versus 10611 ms for Syngap1 / ; CA1: IEI: 15321 ms for

Syngap1 / versus 19128 ms for Syngap1 / ; LMM,

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Figure 4 | Syngap1 haploinsufciency in MGE-derived interneurons reduces mIPSC frequency. (a,b) Representative traces of mIPSCs from L2-3 pyramidal neurons in acute slices from Syngap1ox/ versus Tg(Nkx2.1-Cre);Syngap1ox/ (a) and Syngap1/ versus Syngap1/ (b) young adult mice.

(c,d) mIPSC inter-event intervals are signicantly longer in Tg(Nkx2.1-Cre);Syngap1ox/compared with Syngap1ox/ mice (c, LMM, genotypeeffect 49.117, *P 0.004186), but not in Syngap1 / versus Syngap1/ mice (d, LMM, genotype effect 1.952, P 0.5703). mIPSC amplitude

is not affected in either mouse line (c,d; LMM, P40.5). (e,f) Representative traces of mIPSCs from CA1 pyramidal neurons in acute slices from Syngap1ox/ versus Tg(Nkx2.1-Cre);Syngap1ox/ (e) and Syngap1 / versus Syngap1 / (f) young adult mice. (g,h) mIPSC inter-event intervals are signicantly increased in Tg(Nkx2.1-Cre);Syngap1ox/ compared with Syngap1ox/ mice (g; LMM, genotype effect 605.15, *P 0.00109 for IEI),

but they are not signicantly affected in neurons from Syngap1/ mice compared with control littermates (h; LMM, genotype effect 0.1203, P 0.9974

for IEI). mIPSC amplitude is not affected in either mouse line (LMM, P40.5). mIPSC frequency and amplitude are represented with Tukey boxplots (median1.5 interquartile range; box represents 1st3rd quartile). The cross represents mean values. Individual cell values from the same animal are

represented with the same symbols. Somatosensory cortex L2-3: n 11 neurons from n 3 Syngap1ox/ mice; n 12 neurons from n 3 Tg(Nkx2.1-Cre);

Syngap1ox/ mice; n 15 neurons from n 6 Syngap1 / mice; n 14 neurons from n 4 Syngap1/ . CA1: n 9 neurons from n 4

Syngap1ox/ mice; n 8 neurons from n 5 Tg(Nkx2.1-Cre);Syngap1ox/ mice; n 10 neurons from n 3 Syngap1/ mice; n 9 neurons from

n 3 Syngap / mice.

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P40.5). mIPSC amplitude, kinetics and charge transfer were also not affected (Fig. 4b,d,f,h and Supplementary Fig. 4). The differences observed between Syngap1 / and Tg(Nkx2.1-Cre);

Syngap1ox/ mice suggest that the concurrent Syngap1 haploinsufciency in glutamatergic and/or in GABAergic neurons, which do not originate from the MGE alters neuronal circuit development in a manner that compensates, at least partly, inhibitory synaptic decits originating from Syngap1 haploinsufciency in MGE-derived GABAergic neurons.

To further conrm that Syngap1 haploinsufciency in MGE-derived interneurons impairs functional cortical GABAergic connectivity in vivo, we targeted expression of the light-sensitive channel channelrodopsin-2 (ChR2) to MGE-derived GABAergic cells, by injecting a Cre-dependent adeno-associated virus in somatosensory cortex47 (Fig. 5a). Two-weeks post-transfection, we recorded inhibitory synaptic responses evoked by blue light pulses of different duration (input-output function) in layer 5 pyramidal cells. The amplitude of light-evoked IPSCs was signicantly smaller in Tg(Nkx2.1-Cre);Syngap1ox/ mice compared with those recorded in Tg(Nkx2.1-Cre);Syngap1 / littermates (Fig. 5b; two-way Repeated Measure ANOVA with

Bonferronis multiple comparison post hoc test, Po0.0001). Together with the observation that the number of cortical perisomatic boutons formed by PV baskets was

reduced in Tg(Nkx2.1-Cre);Syngap1ox/ (Figs 2 and 3), this result demonstrated that Syngap1 haploinsufciency impaired

GABAergic synapse formation and function of MGE-derived interneurons.

MGE-specic Syngap1 knockdown affected gamma oscillations. PV cells represent the large majority of cortical GABAergic

interneurons generated by MGE-derived precursors. Correlative, causal and computational evidence indicates that gamma oscillations in the 3080 Hz range depend on synchronous activity of PV cells.48,49 Since we found that PV cell

connectivity was reduced in both cortex and hippocampus of Tg(Nkx2.1-Cre);Syngap1ox/ mice (Fig. 2), we hypothesized that

PV cell synaptic impairment would lead to changes in gamma

oscillatory activity in these mice.

To test this hypothesis, we measured specic oscillatory patterns by video-electroencephalogram (EEG) recordings during active exploratory behaviour. We found that in the cortex, average power in the gamma frequency band was signicantly lower in Tg(Nkx2.1-Cre);Syngap1ox/ animals compared with control littermates (Fig. 6; 0.270.02 versus 0.320.02 for

Tg(Nkx2.1-Cre);Syngap1ox/ and Syngap1ox/ , respectively; Wilcoxon rank sum test, P 0.01). Similar results were observed

in the hippocampus (Fig. 6c; 0.290.02 versus 0.3350.005 for Tg(Nkx2.1-Cre);Syngap1ox/ and Syngap1ox/ , respectively;

Wilcoxon rank sum test P 0.001). Taken together, these data

demonstrate that Syngap1 haploinsufciency in MGE-derived interneurons alters brain network activity, which in turn may contribute to cognitive decits.

MGE-specic Syngap1 knockdown caused cognitive decits. While Syngap1 / mice die within the rst days after birth, adult Syngap1 / mice showed behavioural and cognitive decits, including hyperactivity, anxiolysis, abnormal reference, working and social memories12,1417. We have previously proposed that Syngap1 / mice represent an appropriate model to study the cognitive and behavioural abnormalities associated with the disruption of SYNGAP1 in humans, as pathogenic mutations documented up to now in this gene are predicted to cause a loss-of-function.7

To understand to what extent Syngap1 haploinsufciency in MGE-derived GABAergic neurons may contribute to the cognitive and behavioural decits observed in Syngap1 / mice, we compared the performance of young adult Syngap1 / ,

Tg(Nkx2.1-Cre);Syngap1ox/ mice and their respective control littermates in several behavioural tests. We rst assessed the locomotion activity using the open-eld arena. Relative to their wild-type littermates, Syngap1 / mice travelled more during a 10 min session (Fig. 7a; 404 m for Syngap1 / versus 576 m for Syngap1/ , MannWhitney rank-sum test, P 0.0032),

which is consistent with previously published observations12,1416.

a b

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Figure 5 | Syngap1 haploinsufciency in MGE-derived interneurons reduces their synaptic output to pyramidal cells. (a) Schematic of the experimental approach. pAAV.CAGGS.ex.ChR2.tdTomato.SV40 is bilaterally injected in somatosensory cortex of either Tg(Nkx2.1-Cre);Syngap1ox/ or Tg(Nkx2.1-Cre);

Syngap1/ young adult mice. This strategy allows ChR2 and tdTomato expression only in cells expressing Cre. (b) Upper panel. Traces of IPSCs recorded in response to light pulses of different duration in representative somatosensory cortex layer 5 pyramidal neurons in acute slices from Tg(Nkx2.1-Cre);

Syngap1/ (black) and Tg(Nkx2.1-Cre);Syngap1ox/ (red) mice. Lower panel. Summary graph showing data from input-output function of inhibitory responses evoked by light stimulation. The IPSC amplitudes are signicantly lower in Tg(Nkx2.1-Cre);Syngap1ox/ compared with Tg(Nkx2.1-Cre);

Syngap1/ , starting from the third point of the input-output function (two-way Repeated Measure ANOVA with Bonferronis multiple comparison post hoc test, Po0.0001). n 4 Tg(Nkx2.1-Cre);Syngap1 /mice (7 neurons) and n 4 Tg(Nkx2.1-Cre);Syngap1ox/ mice (9 neurons).

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Figure 6 | Syngap1 haploinsufciency in MGE-derived interneurons impairs cortical gamma oscillations during active exploration in awake mice. (a,b) Representative examples of EEG recordings from the cortex of adult (a) Syngap1ox/ and (b) Tg(Nkx2.1-Cre);Syngap1ox/ mice with corresponding spectrogram. Note that although theta oscillations (red boxes) are detected in both animals, gamma power is lower in Tg(Nkx2.1-Cre);Syngap1ox/ during these oscillations. (c) Bar graph showing the average power in the gamma frequency band in the cortex and the hippocampus for both groups. Note that in both regions, Tg(Nkx2.1-Cre);Syngap1ox/ showed less power in the gamma frequency band (Wilcoxon rank sum tests, *P 0.005, **P 0.0006).

n 3 mice for both genotype.

These results indicate that Syngap1/ mice are hyperactive and that they do not display major locomotor decits. Next, we tested anxiety-like behaviour using the elevated plus-maze test. Syngap1/ mice spent signicantly more time in the open arms than the wild-type littermates (Fig. 7b; 102% for Syngap1/ versus 254% for Syngap1 / , Students t-test, P 0.01),

suggesting a reduced level of anxiety-like behaviour in the germ-line Syngap1 heterozygous mice, as reported in previous studies14,16. Conversely, Tg(Nkx2.1-Cre);Syngap1ox/ showed normal levels of locomotion and anxiety-like behaviour

compared with Syngap1ox/mice (Fig. 7a,b; for open eld: 455 m for Syngap1ox/ versus 516 m for Tg(Nkx2.1-Cre);

Syngap1ox/ , MannWhitney rank sum test, P 0.503; for

elevated plus maze: 153% for Syngap1ox/ versus 213% Tg(Nkx2.1-Cre);Syngap1ox/ , Students t-test, P 0.136).

Several mouse models of ID and autism exhibit reduced social interaction behaviour17,23. We tested social interactions in Syngap1 / and Tg(Nkx2.1-Cre);Syngap1ox/ and their respective littermates. After a habituation period, we evaluated sociability by assessing the preference of the tested mice for an

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Figure 7 | Tg(Nkx2.1-Cre);Syngap1ox/ mice show cognitive decits that partially recapitulate those observed in Syngap1 / mice.(a,b) Syngap1 / mice show hyperactivity (a; MannWhitney rank sum test, *P 0.0032) and altered stress levels (b; Studentst -test, *P 0.01), while

Tg(Nkx2.1-Cre);Syngap1ox/ mice behave similarly to their control littermates in the open eld (a) and elevated plus maze (b) tests (a; MannWhitney rank sum test, P 0.503, b: Students t-test, P 0.136; NS, not signicant). (c,d) Syngap1 / mice (c) and Tg(Nkx2.1-Cre);Syngap1ox/ (d) mice

show social novelty preference impairment and spend similar amount of time in the chambers with either the novel (Stranger 2) or the familiar mouse (stranger 1), contrary to their control littermates, which spend more time with the novel mouse (Stranger 2 Stranger 1 Genotype, Two-way ANOVA with

Sidaks multiple comparison post hoc test, *Po0.05). (e) Both Tg(Nkx2.1-Cre);Syngap1ox/ and Syngap1 / mice perform worse than their littermates on the T-maze test (Students t-test, *P 0.035 for Syngap1 / versus Syngap1 / and *P 0.038 for Tg(Nkx2.1-Cre);Syngap1ox/ versus Syngap1ox/ ).

Open eld and Elevated T-Maze: n 12 Syngap1 /, n 11 Syngap1 / , n 12 Syngap1ox/, n 11 Tg(Nkx2.1-Cre);Syngap1ox/ mice. For

three-chamber test: n 10 Syngap1/ , n 10 Syngap1 / , n 10 Syngap1ox/ , n 16 Tg(Nkx2.1-Cre);Syngap1ox/ mice. For T-maze, n 15

Syngap1/ , n 9 Syngap1 / , n 13 Syngap1ox/ n 9 Tg(Nkx2.1-Cre);Syngap1ox/ mice.

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unknown wild-type conspecic mouse matched for age, sex and background versus an empty wire cage (Supplementary Fig. 5). Mice of all genotypes spent signicantly more time with an unfamiliar mouse (stranger 1) relative to the empty wire cage (Supplementary Fig. 5, two-way ANOVA Po0.05), indicating that social approach behaviour was normal in Syngap1 / and

Tg(Nkx2.1-Cre);Syngap1ox/ relative to their respective control littermates. Next, we tested whether social novelty preference was affected in these mice by assessing the preference for a second stranger mouse. Syngap1 / and Syngap1ox/ mice spent signicantly more time in the chamber containing the novel mouse (stranger 2) than in the chamber with the familiar one (stranger 1; Fig. 7c,d; stranger 2 vs stranger 1 (in s): 27129 versus 18422 for Syngap1 / ; 29727 versus 18718 for

Syngap1ox/ ; two-way ANOVA post hoc Sidaks multiple comparisons test Po0.05). In contrast, both Syngap1 / and

Tg(Nkx2.1-Cre);Syngap1ox/ spent similar amount of time with the novel versus the familiar mice (Fig. 7c,d, stranger 2 versus stranger 1 (in s): 24523 versus 20320 for Syngap1 / ;

27926 versus 21632 for Tg(Nkx2.1-Cre);Syngap1ox/ ; twoway ANOVA post hoc Sidaks multiple comparisons test

P40.05), indicating decits in social novelty preference in both Syngap1 / and Tg(Nkx2.1-Cre);Syngap1ox/ mice.

Finally, we tested spatial working memory by measuring spontaneous alternation in the T-maze. Spontaneous alternation was strongly altered in both Syngap1 / and Tg(Nkx2.1-Cre);

Syngap1ox/ relative to their respective control littermates (Fig. 7e; 676% for Syngap1 / versus 4111% for Syngap1 /

, Students t-test P 0.035, and 647% for Syngap1ox/

versus 33.33311% for Tg(Nkx2.1-Cre); Syngap1ox/ , Students t-test P 0.038), suggesting impaired

spatial working memory in both mutant lines. On the other hand, we found that Tg(Nkx2.1-Cre) mice showed no statistical difference in locomotion, anxiety, spontaneous alternation and social recognition behaviour (Supplementary Fig. 6). All together, these data show that specic inactivation of Syngap1 in MGE-derived interneurons recapitulates at least in part the behavioural and cognitive alterations observed in mice with germ-line Syngap1 haploinsufciency.

DiscussionOur data show that Syngap1 is required for the proper terminal axonal branching and bouton formation of cortical GABAergic PV basket cells, both in organotypic cortical cultures and

in vivo. Further, MGE-restricted Syngap1 haploinsufciency causes decits in cortical evoked-inhibitory synaptic transmission and gamma oscillations and specic impairments in social novelty preference and working memory, in adult mice. In contrast, a recent study did not observe any cognitive decits in Gad2-cre;Syngap1ox/ mice17. One possible explanation for this discrepancy is that Nkx2.1 and Gad2 may be expressed at different developmental time points. In fact, Nkx2.1 is already expressed in all MGE-derived GABAergic interneurons by E10.5. (ref. 45) On the other hand, while Gad2 transcription starts early during embryogenesis50 (around E11.5), it is possible that not all GABAergic cells express it at the same time. For example, GAD65, which is coded by Gad2, is barely expressed before P6 in rodent somatosensory cortex51. Syngap1 haploinsufciency appears to disrupt the function of excitatory circuits mainly by affecting their early synaptic development16,17. Our observations suggest that Syngap1 is also required during the early phases of the development of GABAergic circuit connectivity.

Another major difference is that, while Gad2 is expressed by most GABAergic interneurons, Nkx2.1 is expressed only by interneurons derived from the MGE, which include PV and

SST interneurons but not, for example, those positive for

the vasoactive intestinal polypeptide (VIP). Recent results demonstrate that VIP-expressing neurons form a disinhibitory microcircuit that is conserved across cortical regions52. In particular, VIP interneurons tend to inhibit most SST and

a fraction of PV interneurons. Inhibition of these interneurons

in turn disinhibits principal cells in vivo, providing a form of gain control.52 It is possible that removing Syngap1 in all interneurons may allow homeostatic synaptic adjustments that are not otherwise engaged when Syngap1 is removed only in MGE-derived interneurons. It will therefore be important to assess whether and how Syngap1 regulates the synaptic connectivity of distinct GABAergic interneuron types other than PV basket cells.

Disruption of excitatory/inhibitory balance is emerging as a common theme for many neurodevelopmental disorders53,54. However, the critical challenge is to understand how specic circuit alterations resulting from mutations affect the development of cognitive abilities. Our study suggests new avenues of research for the understanding of mechanisms involved in SYNGAP1-related ID. For example, our results showed that Syngap1 plays a role in the formation of perisomatic synapses by PV basket cells. GABAergic neurotransmission

from these cells promotes network gamma oscillations48,55. Cortical gamma oscillations increase in power during tasks that require complex processing of sensory information, attention, working memory and cognitive control, suggesting that gamma oscillations are crucial for cognition56. Interestingly, substantial evidence indicates that individuals with specic psychiatric disorders, such as schizophrenia or autism, show lower power of gamma oscillations induced during the performance of cognitive tasks compared with healthy individuals57,58. Here, we showed that MGE-specic Syngap1 haploinsufciency leads to reduced gamma oscillation power during exploration, which in turn may contribute to the occurrence of cognitive decits. It will be interesting to explore the presence of alterations in brain oscillations in patients carrying SYNGAP1 mutations. Furthermore, cortical GABAergic inhibition, in particular the one mediated by PV cells, has been suggested to play a key role

in critical period plasticity in the developing brain21,59. Critical periods represent heightened epochs of brain plasticity during childhood, during which experience can produce permanent, large-scale changes in neuronal circuits. By regulating critical period plasticity, PV cell-mediated inhibition may inuence

how experience shapes brain wiring during early life. As a consequence, altered PV cell connectivity and function could drive cortical neuronal circuits along abnormal developmental trajectories, which could then contribute to cognitive dysfunction. Ultimately, the understanding of SYNGAP1 function in specic inhibitory and excitatory circuits might lead to the development of tailored therapies.

MGE-derived interneurons include PV basket cells and

SST interneurons60, thus alterations in the synaptic

connectivity of this latter group may also contribute to the cognitive decits that were observed in Tg(Nkx2.1-Cre); Syngap1ox/ mice. Further, it is very likely that altered

GABAergic signalling results in either causal or compensatory alterations in non-GABA circuits as well, which can further play a role in cognitive dysfunctions in mutant mice. The main challenges will be to understand when these alterations arise and whether and to what extent cognitive decits are due to either altered neural circuit development leading to diverse changes in brain and behaviour and/or a state of continuous synaptic dysfunction in adulthood.

Haploinsufciency of the NF1 gene, which also codes for a RasGAP, causes neurobromatosis type 1, a complex neuro-

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cutaneous condition that is associated with cognitive impairment and autism spectrum disorders. Decrease of Nf1 induces decits in hippocampal-dependent spatial learning, amygdala dependent-social learning and prefrontal cortex-dependent working memory by increasing GABA release in these different areas of the brain through the activation of the RasERK pathway6164. The increase of Ras thus appears to produce opposite effects on GABA neurotransmission depending upon whether it is associated with Syngap1 or Nf1 haploinsufciency. How can we explain this paradox? One possibility is that Syngap1 and Nf1 affect Ras activity at different time points during the development of GABAergic circuits. As discussed above, Syngap1 haploinsufciency might impact the establishment of GABAergic connectivity by acting during early synaptic development. Nf1 might on the other hand modulate GABA release in mature synapses. Alternatively, it is possible that SYNGAP1 and the Nf1 product, neurobromin, function in distinct subcellular compartments of GABAergic neurons and thus regulate different processes. SYNGAP1 is associated with NMDA receptor complexes at the postsynaptic membrane of glutamatergic neurons1,2,29, raising the possibility that it also interacts with such receptors in GABAergic neurons65. In contrast, neurobromin has been shown to localize to smooth vesiculotubular elements, cisternal stacks and multivesicular bodies in the cell body and dendrites of Purkinje cells, but not with the plasma membrane66. All together, these observations suggest that SYNGAP1 and neurobromin modulate the development and function of GABAergic cells by regulating differently the spatial and/or temporal activity of Ras.

In summary, our study suggests that Syngap1 haploinsufciency affects GABAergic circuit connectivity and function, which in turn may contribute to cognitive alterations. Further studies will be required to determine whether pharmacological interventions during development can rescue these decits.

Methods

Mice. All procedures described here had been approved by the Comit Institutionnel de Bonnes Pratiques Animales en Recherche (CIBPAR) of the Research Center of Sainte-Justine Hospital in accordance with the principles published in the Canadian Council on Animals Cares (Guide to the Care and Use of Experimental Animals, Feb 91). Syngap1 / mice were kindly provided by

Dr Seth Grant (Edinburgh University, United Kingdom) and Syngap1ox/ox by Drs. Irene Knuesel and Mary Muhia (University of Zurich, Switzerland). They were generated and genotyped as described in refs 10,15. They were maintained as a heterozygous line onto a C57Bl/6 background. Syngap1ox/oxmice were crossed with a mouse line bearing a transgene encoding the enzyme Cre recombinase under the control of the Nkx2.1 promoter (Jackson Laboratory #008661). This promoter drives the expression of the Cre protein in GABAergic interneurons derived from the MGE starting at embryonic day 10.5 (ref. 45). The resulting animals were referred to as Tg(Nkx2.1-Cre);Syngap1ox/ mice. To obtain Tg(Nkx2.1-Cre);

Syngap1ox/ox mice, we crossed Tg(Nkx2.1-Cre);Syngap1ox/ individuals with Syngap1ox/ox mice. To validate the specicity of Cre expression, we backcrossed these mice with a GFP reporter line (RCE mouse46). Animals of both sexes were used in all the experiments.

Primary cortical neuron culture. Cortical neurons from E18 rat embryos were dissociated mechanically and plated on dishes treated with poly-D-lysine(0.1 mg ml 1; Sigma-Aldrich, St. Louis, MO). Neurons were cultured overnight in attachment medium: MEM (Invitrogen) supplemented with 1 mM sodium pyruvate (Invitrogen), 0.6% D-glucose (Sigma-Aldrich) and 10% horse serum. The medium was replaced the next day with maintenance medium: Neurobasal-A medium (Invitrogen) supplemented with 2% B27 (Invitrogen) and 1% L-glutamine (Invitrogen). The maintenance medium was replaced with fresh medium at 3DIV. Subsequently, the medium was replaced every 6 days with maintenance medium until collecting the cells. Cultures were incubated in a humidied incubator at37 C with a 5% CO2-enriched atmosphere during 21 days then were xed in 100%

methanol ( 20 C) for 5 min. The xation was stopped by adding 0.3 M glycine

for 5 min. Neurons were permeabilized with 0.25% Triton in phosphate buffer pH7.4, washed and blocked for 0.5 h in 3% BSA at room temperature. Cultures were then incubated for 1 h with anti-GAD67 antibody (mouse, 1:200, Abcam #26116) or anti-PV antibody (mouse, 1:500, Sigma, #P3088) and anti-SYNGAP1 antibody (rabbit, 1:200, Abcam #3344), followed by incubation with Alexa 488-conjugated

IgG (goat anti-rabbit, 1:400, Invitrogen #A-11008) and Alexa 555-conjugated IgG (goat anti-mouse1:400, Invitrogen #A-21422) for 0.5 h at room temperature (RT), then mounted in Prolong (Invitrogen #P-7481) and stored at 4 C. Images were acquired using a confocal microscope (LEICA TCS SPE or Leica TSC SP8).

Cortical organotypic culture and biolistic transfection. Slice culture preparation and gene gun transfection were performed as described in37,40. Briey, brains from postnatal days 45 Syngap1ox/ox, Tg(Nkx2.1-Cre);Syngap1ox/and Syngap1ox/ were sliced coronally (400 mm thick) using a chopper (Stoelting). Slices were plated on Millicell membrane inserts. Culture medium (containing DMEM, 20% horse serum, 1 mM glutamine, 13 mM glucose, 1 mM CaCl2, 2 mM MgSO4, 0.5 mM ml 1 insulin, 30 mM HEPES, 5 mM NaHCO3, and 0.001% ascorbic acid) was placed under the membrane inserts. Slices were incubated in a humidied incubator at 34 C with 5% CO2. Medium was changed three times per week. For biolisitic transfection, 1.6 mm gold particles (BioRad) were coated with 2530 mg of each one of the plasmids of interest. DNA-coated gold particle were then shot using a gene gun (Bio-Rad) at high pressure (180c) at the age specied in the result section, incubated for 8 or 14 days in the same culture medium as described above. In experiments where Syngap1 was deleted in PV single-basket cells in an otherwise

wild-type background, organotypic slices from Syngap1ox/ox mice were transfected either with pGAD67-GFP (Syngap1 / , control basket cells), or pGAD67-Cre/pGAD67-GFP (Syngap1 / basket cells). In particular, for each mouse half of the organotypic cultures were transfected with pGAD67-GFP and half

with pGAD67-Cre/pGAD67-GFP, thus allowing us to control for inter-animal variability. Organotypic slices from Tg(Nkx2.1-Cre);Syngap1ox/ and

Syngap1ox/ were transfected with pGAD67-GFP to visualize PV basket cells

morphology a minimum of 5 days before imaging.

Analysis of basket cells in vitro. Slices were xed and immunostained as in ref.40. To visualize basket cell targeted neurons, we used anti-NeuN (monoclonal antibody, 1:400; Millipore Bioscience Research Reagents, #MAB377), followed by incubation with Alexa Fluor 633-conjugated goat anti-mouse IgG (1:400; Invitrogen A-21053). Only one basket cell was acquired from each organotypic culture. Non-overlapping elds of axonal innervation from well-isolated basket cells were acquired with a 63 glycerol-immersion objective (NA 1.3; Leica) using

a confocal microscope (LEICA TCS SPE) and them analyzed with Neurolucida software (MicroBrightField). Axon branch complexity around a single pyramidal cell soma was quantied as the average number of intersections between a basket cell axon and each one of 9 Sholl spheres traced with 1 mm increment from the centre of the pyramidal cell soma. Bouton density around each pyramidal cell soma was dened as the total number of GFP boutons identied in a radius of 9 mm

from the centre of the pyramidal cell soma. For each basket cell, we analyzed 1520 pyramidal neurons. The percentage of pyramidal somata innervated by basket cells was dened in a confocal stack by the number of somata contacted by the GFP

axon divided by the total number of somata. At least two elds were imaged for each basket cell and the results were averaged. For these experiments, the number of basket cells was used as independent replicate (N). Data are presented as mean s.e.m. Imaging and quantication were performed independently by two different operators. All quantication was done blind to the genotype or the experimental conditions.

Analysis of perisomatic innervation in vivo. P45 mice were anesthetized and perfused transcardially with 4% paraformaldehyde (PFA 4%) in phosphate buffer, pH 7.4. Brains were removed, immerged in PFA 4% overnight then cryoprotected in 30% sucrose (in sodiumphosphate buffer pH 7.2) and nally embedded in optimal cutting temperature Tissue Tek. Coronal sections (40 mm) from

Syngap1 / , Tg(Nkx2.1-Cre);Syngap1ox/ and their control littermates of both sexes were cut using a cryostat (Leica VT100). Brain sections were blocked in 10%

normal goat serum (NGS) and 0.3% Triton X-100 for 2 h at RT. Slices were then incubated overnight at 4 C with anti-Parvalbumin (rabbit 1:8,000, Swant, #PV25) and anti-NeuN antibodies (mouse 1:400, Chemicon, #MAB377) followed by incubation with Alexa 488-conjugated anti-rabbit IgG and Alexa 633-conjugated anti-mouse IgG (1:400, Invitrogen, A-11008 and A-21053, respectively) for 2 h at RT. After washing, slices were mounted in Vectashield mounting medium (Vector). Confocal images were taken using a 63 oil objective (Leica NA 1.3).

Scans from each channel were collected in multiple-track mode and subsequently merged. For each animal, three to four coronal sections containing the somato-sensory cortex and an equal number containing the CA1 region of the hippo-campus were imaged. Stacks were acquired with 1 mm steps, exported as TIFF les and analyzed with ImageJ software. We analyzed the intensity of PV-positive puncta around layer 5 pyramidal cell somata because the size of their apical dendrite rendered their identication fairly easy, therefore reducing the variability in the analysis. For each identied neuronal soma, intensity was quantied in the optical section where the soma prole was larger, in particular an area 2 mm distal from the edge of a neuron prole was traced and outlined, and staining intensity within this area was measured. Results of at least 30 NeuN-positive somata from the somatosensory cortex of each mouse were averaged. For these experiments, the number of animals was used as independent replicate (N). Data are presented as

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mean s.e.m. Imaging and quantication were performed independently by two different operators. All quantication was done blind to the genotype.

Viral vector and stereotaxic injections. The pAAV.CAGGS.ex.ChR2.tdTomato. SV40 was a gift from Scott Sternson (Addgene plasmid # 18917) and was produced as AAV2/9 serotype by the UPenn Vector Core Facilities (University of Pennsylvania, Philadelphia). Mice aged postnatal day 2428 (P24-P28) wereused for all surgeries. Bilateral viral injections were performed at the following stereotaxic coordinates: 1.5 mm from bregma, 1.5 mm lateral from midline and0.70 mm vertical from cortical surface. Surgical procedures were standardizedto minimize the variability of AAV injections. To ensure minimal leak into surrounding brain areas, injection pipettes remained in the brain for B5 min after injection before being slowly withdrawn. The nal injected volume for the AAV was 0.5 ml. We waited 2 weeks for maximal viral expression. The titre for the viruses was B2.69 1012 genome copies per ml.

Electrophysiology. All the following experiments were done by investigators blind to the genotype until after data analysis was completed.mIPSC recordings: Acute slices (300 mm thickness) were prepared from hippocampus or somatosensory cortex of 79 week old Syngap1 / ,

Tg(Nkx2.1-Cre);Syngap1ox/ mice and their respective control littermates of both sexes25. Slices were cut on a Leica vibratome in ice-cold oxygenated (95% O2, 5% CO2) cutting solution containing 87 mM NaCl, 2.5 mM KCl, 25 mM NaHCO3,0.5 mM CaCl2, 1.25 mM NaH2PO4, 7 mM MgCl2, 25 mM glucose, 75 mM sucrose, 3 mM pyruvic acid and 1 mM ascorbic acid. Slices were then transfered to oxygenated (95% O2, 5% CO2) articial cerebrospinal uid containing: 124 mM

NaCl, 2.5 mM KCl, 1.25 mM NaH2PO4, 2 mM MgSO4, 2 mM CaCl2, 26 mM NaHCO3 and 10 mM glucose (pH 7.27.3; 300 mOsm) and allowed to recover at room temperature for at least 1 h before recording in articial cerebrospinal uid. Whole-cell patch clamp recordings were obtained from visually identied pyramidal neurons in hippocampal CA1 region or somatosensory cortex layer 23 using borosilicate pipettes (35 MO) and an upright microscope (Nikon Eclipse,

E600FN), equipped with a water immersion long-working distance objective ( 40,

Nomarski optics) and an infrared video camera. To record mIPSCs, the internal solution contained 130 mM CsCl, 10 mM HEPES, 2 mM MgCl2, 0.5 mM EGTA,5 mM di-Na-phosphocreatine, 2 mM ATP-Tris, 0.4 mM GTP-Tris, 5 mM QX-134 (pH 7.27.3; 280 mOsm; Alomone Labs). mIPSCs were measured by holding the cells at 60 mV in the presence of 10 mM CNQX, 50 mM D-APV and 0.5 mM TTX

(to block AMPA receptors, NMDA receptors and sodium channels, respectively; Abcam Biochemicals). Data was acquired using Multiclamp 700A/B ampliers (Molecular Devices) and digitized using Digidata 1322A/1440A and pClamp 10 (Molecular Devices). Recordings were low-pass ltered at 3 kHz and digitized at 20 kHz. Series resistance was regularly monitored during experiments and data were included only if the holding current and series resistance were stable. mPSCs were analysed using Mini-Analysis 6.0.3 (Synaptosoft) after detection of a well-dened baseline. Averages of at least 150 events from each cell were considered for analysis. Data are presented as mean s.e.m., unless otherwise specied.

Optogenetics: Slices were prepared as described above. Whole-cell patch clamp recordings were obtained from visually identied pyramidal neurons in somatosensory cortex layer 5 using borosilicate pipettes (35 MO) and an upright microscope (Olympus BX50WI), equipped with a water immersion long-working distance objective ( 40, Nomarski optics) and an infrared video camera. Care was

taken to record from brain slices showing similar dense AAV tranfection, that is, tdTomato expression. The internal solution contained 120 mM CsMeSO3, 5 mM NaCl, 1 mM MgCl2, 10 mM HEPES, 10 mM diNa-phosphocreatine, 2 mM

ATP-tris, 0.4 mM GTP-tris, 0.5 mM spermine and 2 mM QX-314-Cl. Light-evoked IPSCs were recorded by holding the cell at 0 mV in the presence of 10 mM CNQX and 50 mM DL-APV. IPSCs were evoked by brief pulses of blue light (470 nm, custom-made LED system) delivered to the whole slice every 30 s via a light guide positioned above the slice. Data was acquired using a Multiclamp 700A amplier (Molecular Devices) and digitized using Digidata1440A and pClamp 10 (Molecular Devices). Recordings were low-pass ltered at 3 kHz and digitized at 20 kHz. Series resistance was regularly monitored during experiments, and data were included only if the holding current and series resistance were stable. Light-evoked IPSCs were analyzed using Clampt 10 (Molecular devices). For statistical analysis, the number of animals was used as independent replicates (N).

EEG recordings and gamma oscillation analysis: To analyze power in the gamma frequency band (3080 Hz), we monitored P80P100 mice by continuous video-EEG recordings after implantation of electrodes in the hippocampus and the overlying cortex. The insertion of electrodes was performed under isourane anaesthesia, while the head of the mouse was immobilized in a stereotaxic frame. A stainless steel bipolar electrode (Plastics-1 Inc., Roanoke, VA, USA) was positioned at the following coordinates with reference to Bregma: AP 1 mm,

ML 1 mm and DV 1.5 mm for one electrode in the hippocampus and

0.5 mm for the one in the cortex. Following a 5-day recovery period, EEG was recorded with a Stellate systems 32-channel video-EEG recording unit for 2 weeks. Mice were monitored during 6-hour sessions (afternoon and night). An operator blind to the genotype extracted EEG traces during mouse exploratory behaviour spanning 30120 s. A total of 10 min of active exploration was selected foreach mouse.

EEG recordings from the cortex and hippocampus were rst analyzed to detect time periods of strong theta oscillations, which were indicative of stable recordings during which the animal was exploring. To detect theta oscillations, we used the spectrogram method using discrete short-time Fourier transforms. More specically, data sampled at 200 Hz were rst low-pass ltered by a 100th order nite impulse response lter. Spectrograms were then built from the data set and separated into 1 s intervals, to which a Hamming window was applied. The discrete Fourier transforms were then evaluated over 214 points with zero padding. Finally, for each time slot, the algorithm identied oscillations with the highest intensity in the theta frequency band (412 Hz) and that lasted at least 1 s. The power spectral density was normalized in amplitude from 0 to 1 and equalized with an exponential function with exponent 0.15 to improve its contrast to random noise. This analysis resulted in a list of theta oscillations for each extracted EEG recording. For each time period of theta oscillations, we then calculated the average power in the gamma frequency band. Analysis was performed in Matlab (7.11.0) (The Mathworks, Natick, MA, USA). Results are expressed as means.e.m. The investigator was blind to the genotype until after data analysis was completed.

Behavioural studies. All animals were kept under a light-dark cycle (12 h light12 h dark) in a temperature and humidity controlled room. Food and water were available ad libitum. Room lights were kept low during all procedures. For all experiments, a camera was mounted above the arena; images were capturedand transmitted to a computer running the Smart software (Panlab, Harvard Apparatus). The sequence of animals tested was randomized by the genotype. Care was taken to test litters containing both the genotypes specic to the breeding. Results are presented as mean s.e.m.

Spontaneous open-eld activity. The open-eld test was performed as previously described14. Each subject (P25) was gently placed in the centre of the open-eld, allowed to freely explore undisturbed for 10 min, after which the animal was removed, the arena cleaned with 70% ethanol and dried before testing the next animal. Locomotor activity was indexed as the total distance travelled (m).

Elevated plus maze. Experiments were performed as described in ref. 67. The test session lasted 5 min during which the animals (P27) were allowed to explore the maze freely before being removed and returned to their home-cage. The percentage of time spent in the open arms (open/(open closed) 100) was scored as a

measure of anxiety-related behaviour.

Three-chamber. A three-chamber arena was used to assess the social recognition performance of the mice68. The tested animal (P36) was placed in the middle of the central chamber and allowed to explore all the chambers for 10 min. During this habituation session, small wire cages were present, one in each opposite chamber. After habituation, an unfamiliar conspecic of the same sex and age (Stranger 1) was placed inside a small wire cage whereas the other remained empty. The tested animal was allowed to freely explore the three chambers of the apparatus for10 min. At the end of this 10 min, a new unfamiliar mouse of the same sex and the same age (Stranger 2) was placed in the previously unoccupied wire cage and the tested mouse was examined for an additional 10 min to assess preference for social novelty. Stanger 1 and stranger 2 animals originated from different home cages and had never been in physical contact with the tested mice or between each other. Social novelty preference was evaluated by quantifying the time spent by the tested mice in each chamber during the third 10 min session.

T-maze. A discret-two-trials spontaneous alternation paradigm in a T-maze apparatus was used to assess the working memory69. Each test consisted of a two free-choice trials separated by a 1 min inter-trial interval (ITI) for 3 consecutive days. At the beginning of each trial, the animals (P38-40) were placed in the starting arm, allowed to freely move until one arm was chosen. The animals were left in the choice arm for 10 s before being removed and placed in the home-cage for 50 s. Then, the individuals were allowed to perform another free-choice trial. If the mice entered in the opposite arm than the rst trial, the responses were considered as an alternation.

Statistical analysis. Data were expressed as means.e.m. unless otherwise specied in the legends. Normality tests were performed for all data analysed. Differences between two groups were assessed with the Students t-test for normally distributed data or with the MannWhitney rank sum test for not-normally distributed data. Differences between multiple groups were assessed with one-way ANOVA with either Dunns or Tukeys post hoc test for non-normally distributed and normally distributed data, respectively. Two-way ANOVA with Sidaks multiple comparison post hoc test was used for the detection of differences in the novelty social recognition test. Two-way Repeated Measure ANOVA with Bonferronis multiple comparison post hoc test was used for analysing light-evoked IPSCs, considering N of mice as independent replicates. mIPSC frequency and amplitude were represented with Tukey boxplots (median1.5 interquartile range; box represents 1st3rd quartile). In the

same graph, a cross represented mean mIPSC frequency and amplitude values.

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NATURE COMMUNICATIONS | DOI: 10.1038/ncomms13340 ARTICLE

In addition, all individual cell values were reported, using different symbols for different animals. mIPSC frequency and amplitude were analysed using a LMM, modelling animal as a random effect and genotype as xed effect. We used this statistical analysis because we considered the number of mice as independent replicates and the number of cell in each mouse as repeated measures. For gamma oscillation power analysis, averages from the two genotypes were compared with Wilcoxon rank sum tests since values were not normally distributed. Finally, two-tailed power analysis was performed for all experimental data, using alpha 0.05

and desired power 0.8. Statistical analysis was performed using Prism 5.0

(GraphPad Software), SigmaStat 3.5 (Systat) and the function lmer implemented in the R package lme4 specically for LMM.

Three animals were excluded from the analysis of electrophysiological recordings because the genotype was ambiguous (n 1 mouse) or tdTomato

uorescence was not detectable after AAV injection (n 2 mice).

Data availability. Detailed statistics and data that support the ndings of this study are available from the corresponding authors on request.

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Acknowledgements

This work was supported by the Fondation Jean-Louis Lvesque (to J.L.M.), Canadian

Institutes of Health Research (operating grant MOP-10848 to J.-C.L. and MOP-130430

to G.D.C.), the Fonds de la Recherche du Qubec-Sant (grant to J.-C.L. FRQS; Groupe

de Recherche sur le Systme Nerveux Central). J.-C.L. is the recipient of the Canada

Research Chair in Cellular and Molecular Neurophysiology. G.D.C. is the recipient of the

Canada Research Chair in Neural Circuit Development. M.H.B. was supported by a

studentship from the Rseau de Mdecine Gntique Applique (Montreal, Canada).

B.C. was supported by a fellowship of the CHU Ste.Justine Foundation. P.X. was

supported by a studentship from the Natural Sciences and Engineering Research Council

of Canada. I.R. was supported by a postdoctoral fellowship of the Savoy Foundation.

We acknowledge Dr Luis Barreiro (CHU Ste.Justine, Canada) for his invaluable help with

statistical analysis of electrophysiological data, Dr S. Grant (Centre for Clinical Brain

Sciences, The University of Edinburgh, United Kingdom) for providing the Syngap1 /

mice, Drs I. Knuesel and M. Muhia (Institute of Pharmacology and Toxicology,

University of Zurich, Switzerland) for the Syngap1ox/ox mouse line, Alexis

Lupien-Meilleur, the Comit Institutionnel de Bonnes Pratiques Animales en Recherche

(CIBPAR) and all members of the animal facility of the Research Center of Sainte-Justine

Hospital (Montreal University, Canada) for their invaluable technical help, D. Rochefort

(Mental health university institute, Douglas Hospital, McGill University, Canada) for

sharing his expertise in behavioural studies and Dr Elsa Rossignol for many insightful

comments on this work.

Author contributions

M.H.B., B.C., J.-C.L., J.L.M. and G.D.C. designed the experiments. M.H.B., B.C., P.X., I.R.,

C.B., N.S., J.A.B., M.L., M.A., F.F.H., L.C., J.-C.L. and N.L.V. performed experiments

or/and analysed data, M.H.B., B.C., J.-C.L., J.L.M. and G.D.C. wrote the manuscript.

Additional information

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How to cite this article: Berryer, M. H. et al. Decrease of SYNGAP1 in GABAergic cells

impairs inhibitory synapse connectivity, synaptic inhibition and cognitive function.

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