EHMT1 regulates Parvalbumin-positive interneuron development and GABAergic input in sensory cortical areas

Kleefstra Syndrome (KS, OMIM#610253) is a rare syndromic form of intellectual disability (ID) associated with autistic features (Kleefstra et al. 2005, 2012; Koemans et al. 2017; Vermeulen et al. 2017), caused by haploinsufficiency of the EHMT1 gene. The EHMT1 protein (also known as GLP or KMT1D) functions as a repressive epigenetic modifier by mono- and dimethylating euchromatic Histone 3 on Lysine 9 (H3K9me1/2; Benevento et al. 2015; Iwase et al. 2017; Shinkai and Tachibana 2011; Tachibana et al. 2005). Mice with a heterozygous loss-of-function mutation in the Ehmt1 gene recapitulate the core phenotypes of KS, including low muscle tone, delayed development of sensory modalities and craniofacial abnormalities (Balemans et al. 2010, 2014). Ehmt1^+/− mice show a delayed onset of sensory experiences (eye opening) and sensory reaction (acoustic startle response; Balemans et al. 2014), as well as impaired learning and exploration, reduced locomotor activity, and increased anxiety (Balemans et al. 2013). This phenotype is partially replicated in excitatory-neuron specific Ehmt1 knockout mice (CaMKIIa-Cre), which also present with hypoactivity and learning deficits, but do not show an anxiety-like phenotype (Schaefer et al. 2009).

On a physiological level, we previously reported hyperexcitability in Ehmt1^+/− hippocampal excitatory neurons (Frega et al. 2020) as well as deficits in evoked excitatory transmission in auditory cortex (Frega et al. 2019). Those excitatory phenotypes are broadly replicated in cultured neurons derived from both rodents and human KS patient-derived iPS cells (Frega et al. 2019; Martens et al. 2016). Ehmt1^+/− neurons show a deficit in homeostatic synaptic scaling (upscaling at excitatory synapses) in response to input deprivation, both in primary cultures and in the visual cortex (Benevento et al. 2016). On a molecular level, Ehmt1 and its homolog Ehmt2 co-regulate activity-dependent gene expression in the hippocampus and amygdala (Gupta-Agarwal et al. 2012, 2014).

Interestingly, the deficit in sensory development observed in Ehmt1^+/− mice (Balemans et al. 2014) was not observed in excitatory-neuron specific Ehmt1 conditional knockout mice (Ehmt1^flox/+ x CaMKIIa-Cre; Schaefer et al. 2009), suggesting an inhibitory component for the developmental deficit. This hypothesis is strengthened by recent physiological evidence of an inhibitory impairment in the Ehmt1^+/− hippocampal stratum oriens (Frega et al. 2020), which is enriched in PV⁺ basket cells (Booker and Vida 2018), indicating PV⁺ neurons as a possible target subpopulation. In sensory cortical areas, PV⁺ interneurons set the pace for the maturation of the entire circuit, which might explain the sensory developmental deficit observed in Ehmt1^+/− mice. However, the influence of Ehmt1 on the trajectory of different inhibitory interneuron classes remains unknown.

Parvalbumin-positive (PV⁺) interneurons are the largest group of GABAergic interneurons (releasing γ-amino butyric acid) in the cortex and directly control firing in their target cells (Tremblay et al. 2016). They mature relatively late during cortical development, during a time of heightened sensitivity to environmental influences known as the critical period (Hensch 2005; Marín 2016; Reh et al. 2020; Trachtenberg 2015). During the critical period, PV⁺ neurons start expressing the calcium-buffering protein PV and generate perineuronal nets (PNNs), a honeycomb-like extracellular matrix structure that elevates their firing rate and effectively locks in their excitatory input at this timepoint (Favuzzi et al. 2019; Sigal et al. 2019; Testa et al. 2019). The timing of PV⁺ interneuron maturation is plastic and depends on sensory input (Marín 2016). Interestingly, mouse models for ID and autism spectrum disorders (ASD) show temporal shifts in both directions: earlier maturation in Mecp2^−/y mice, a mouse model for Rett Syndrome (Krishnan et al. 2015, 2017; Patrizi et al. 2019), and delayed maturation in Fmr1^−/y mice, a mouse model for Fragile X Syndrome (Goel et al. 2018; Harlow et al. 2010; Reinhard et al. 2019). Strikingly, PV⁺ neuron-specific knockout of Mecp2 prevented a critical period altogether (Banerjee et al. 2016; He et al. 2014), underlining PV⁺ neuron development in sensory cortices as a possible point of convergence in neurodevelopmental disorders.

Here, we investigated the developmental trajectory of PV⁺ neurons in the three largest primary sensory cortical areas (A1, S1, V1), at three relevant timepoints for their respective development. In order to quantify inhibitory neurotransmission, we also measured the output of PV⁺ neurons onto pyramidal neurons in auditory cortex layer 2/3. We find that in Ehmt1^+/− mice, PV⁺ neuron maturation is delayed at postnatal day (P) 14 in layer 4 in all regions examined. With the exception of S1 layer 4, PV⁺ maturation markers in Ehmt1^+/− mice normalize to wild-type levels later in development. Genetic labelling of PV⁺ cells showed no difference in any region in adulthood, indicating a dynamic effect of Ehmt1 on PV⁺ expression. In agreement with this delay of PV⁺ neuron maturation, we find a reduction of inhibitory synaptic function in the Ehmt1^+/− auditory cortex at P14. As a cause, we identify a reduced release probability for GABAergic synapses, specifically from fast-spiking (putative PV⁺) neurons.

We first investigated whether a heterozygous loss of Ehmt1 influences the developmental trajectory of PV⁺ GABAergic interneurons in the sensory cortices in mice. We compared heterozygous Ehmt1 mutant (Ehmt1^+/−) mice to wild-type (Ehmt1^+/+) littermates, a construct valid model for KS (Balemans et al. 2010), and because a full knockout is lethal at the embryonic stage (Tachibana et al. 2005). We selected three well-characterized sensory regions: primary auditory cortex (A1), the barrel subfield in the primary somatosensory cortex (S1), and the primary visual cortex (V1). In each region, we generated a timeline of PV⁺ neuron maturation, measuring two maturation markers, Parvalbumin (PV) and Perineuronal Nets (PNNs) in cortical layers 2/3 and 4. Both layers are crucial for sensory cortex function. In the simplest version of the canonical sensory cortical model, layer 4 is the thalamo-recipient “input” layer that first receives sensory input during development. Layer 4 neurons then send the processed input to neurons in layer 2/3, which integrate both locally and wide-range inputs. Consequentially, layer 2/3 is thought to mature later than layer 4 (Butt et al. 2017). We selected three timepoints based on the developmental trajectory of the primary auditory cortex (A1): P14 is expected to be the onset of the auditory critical period for thalamocortical input to layer 4 (Barkat et al. 2011). It is also the timepoint at which Ehmt1^+/+ mice show an acoustic startle response (Balemans et al. 2014). The second timepoint, P28, is thought to be after the end of the auditory cortical critical period (Oswald and Reyes 2011; Kalish et al. 2020). For the third timepoint we selected P56, when mice are considered adult for the purposes of sensory development.

Here we describe a region- and time point-specific influence of Ehmt1 haploinsufficiency on the development and function of PV⁺ neurons. In all three sensory cortical areas, we found a reduction of PV⁺ developmental markers in layer 4 at P14 (see Supplementary Fig. S4 for an overview). In Ehmt1^+/− A1 and V1, those markers normalized to wild-type levels by P28, indicating a delayed PV⁺ maturation. In contrast, in the Ehmt1^+/− S1 layer 4, PV⁺ maturation markers remained reduced into adulthood (P56), which implies an area-specific permanent immature state for S1 in Ehmt1^+/− mice. Genetic labelling coupled with whole-brain immunostaining and clearing using the iDisco + protocol (Renier et al. 2014, 2016) showed no difference between the genotypes at P56 in any primary sensory cortex (Supplementary Fig. S2), including S1 layer 4. This indicates that in Ehmt1^+/− mice, the generation and migration of MGE-derived (future PV⁺ and SST⁺ neurons) is not impaired in the primary sensory cortices, which raises the interesting possibility that continuous downregulation of PV⁺ neurons identified with anti-PV immunostainings might be an activity-dependent downregulation due to reduced circuit activity in the barrel cortex.

The “integrative” layer 2/3 was more variable across regions and time. In the A1 layer 2/3, we observed a developmental delay in Ehmt1^+/−, similar to A1 layer 4. However, S1 and V1 layer 2/3 showed no differences between genotypes at any age (Supplementary Fig. S4). We then investigated whether the immature PV⁺ phenotype at P14 is also reflected at the functional level. We found that GABAergic input to A1 layer 2/3 pyramidal neurons is reduced in Ehmt1^+/−. This reduction is selectively caused by a reduced GABA-release probability at the PV⁺ presynapse in Ehmt1^+/− cortex.

Auditory cortex is the only sensory area we tested where PV⁺ maturation was impaired in both L2/3 and 4 at P14, but normalized later in development. In mice, P14 is the middle of the critical period for the auditory cortical tonotopic map (Barkat et al. 2011; Takesian et al. 2018). It therefore seems that in Ehmt1^+/− mice, the auditory critical period might be shifted past P14, which is consistent with earlier studies in which the appearance of an acoustic startle response was delayed in Ehmt1^+/− by approximately one day, from P13.5 in Ehmt1^+/+ to P14.5 in Ehmt1^+/− (Balemans et al. 2014).

This poses the question whether an early change in PV⁺ developmental trajectory causes lasting network defects in Ehmt1^+/− sensory cortices, even once the expression of PV and PNNs have normalized to wild-type levels. Evidence from other mouse models with changed PV⁺ developmental trajectories indicates that this could be the case. In Mecp2^−/y mice, for example, PV⁺ neurons develop precociously before the onset of vision, resulting in impaired sensory perception in adulthood (Durand et al. 2012; Patrizi et al. 2019) and a premature closure of the critical period (Krishnan et al. 2015). An early sensory change affects sensory-cortex dependent learning in adult mice, recently shown in Mecp2^+/− mice with pup retrieval, a learned maternal behavior that is dependent on active remodeling of PV⁺ neurons (Krishnan et al. 2017). Specifically, Mecp2^+/− females showed impaired PV and PNN remodeling following surrogate maternal experience, and consequentially displayed impaired pup-gathering behavior (Krishnan et al. 2017; Lau et al. 2020a, b).

In the primary visual cortex, we observe an early (P14) PV⁺ maturation delay in Ehmt1^+/− layer 4, but not in layer 2/3. P14 is just after the timepoint of eye opening in WT mice, and this event is delayed in Ehmt1^+/− mice, to P16 (Balemans et al. 2014). As a result, the reduced PV⁺ interneuron count in layer 4 at P14 could be due to a delay in the arrival of sensory information in Ehmt1^+/− mice. Interestingly, a delayed onset of visual perception has been linked to a delayed closure of the auditory critical period in wild-type mice (Mowery et al. 2016), which poses an interesting possibility of cross-modal plasticity.

In the Ehmt1^+/− somatosensory cortex layer 4, we found that the density of PV⁺ interneurons remains low into adulthood. A possible explanation might be a blurred representation of the barrel field, as for example in Fmr1^−/y mice (Juczewski et al. 2016). As PV⁺ interneurons are located in the barrel walls, a blurred representation might imply a permanently reduced PV⁺ interneuron count as well (Selby et al. 2007). Alternatively, the reduced PV⁺ count might reflect an inactive state of the whisker system in general, similar to a state of sensory deprivation (McRae et al. 2007), which would be consistent with the fact that genetic labelling of PV⁺ neurons did not show a difference between genotypes (Supp. Fig. S2c). The somatosensory system is the only of the sensory systems tested here that requires active movement (i.e. sweeping of the whiskers), with precisely timed sensorimotor integration between S1, secondary somatosensory cortex (S2) and motor cortical areas (see for a review: Petersen 2007). This type of precise, long-range connectivity between areas may be impaired in Ehmt1^+/− mice, for example due to dysregulated expression of guidance cues such as clustered Protocadherins (Iacono et al. 2018). Defects may also occur further upstream, as Ehmt1 is also expressed in the developing whisker pad (Kleefstra et al. 2005) and during the development of sensory subcortical circuitry (Ebbers et al. 2016). Functionally, a permanently reduced PV⁺ interneuron activity such as caused by early whisker trimming has been linked to deficits in sensory acuity, hypersensitivity to stimuli (Antoine et al. 2019) and social deficits (Wolfe et al. 2011). As a consequence, the deficits in social and sensory behavior in Ehmt1^+/− mice may be partially mediated by a reduced S1 L4 inhibitory function (Balemans et al. 2010, 2013, 2014).

The emergence of PV and PNNs was approximately equal in our measurements, which indicates that PV and PNN are expressed at approximately the same rate (Supplementary Fig. S3). When we plot the percentage of PV⁺ cells that also express PNNs (Supplementary Fig. S1), we see that the percentage of double-labelled PV⁺ neurons is generally higher in layer 4 than layer 2/3, and higher in the somatosensory cortex than in either visual or auditory. Interestingly, we only observe significant reductions in the percentage of double-labelled cells in Ehmt1^+/− during the critical period for the respective region, with A1 layer 2/3 and 4 at P14, S1 layer 2/3 at P14, and V layer 2/3 at P28 (Supplementary Figure S1). PNNs are honeycomb-like structures that enwrap soma and proximal dendrites of (mostly) PV⁺ neurons (review: Testa et al. 2019). Recent reports indicate the activity level of PV⁺ neurons cell-autonomously regulate the production of PNNs and PNN-modifying enzymes even in adulthood (Devienne et al. 2019). In the Fmr1^−/y mouse, a delay of both PV⁺ and PNN development is visible, which in this mouse is caused by an overproduction of the PNN modifier MMP-9 during the auditory critical period (Wen et al. 2018). Interestingly, while the PV⁺ developmental trajectory in Fmr1^−/y matches our Ehmt1^+/− findings, MMP-9 is downregulated during development in the Ehmt1^+/− cortex (Iacono et al. 2017). Thus, here we observe a phenotypic convergence despite molecular divergence in the PNN modification pathway.

PNNs enhance the capacity of PV⁺ neurons for high-frequency firing by reducing the membrane capacitance (Tewari et al. 2018) and clustering ion channels (Favuzzi et al. 2017). PNNs also bind extracellular molecules that are important for the developmental trajectory of PV⁺ neurons, for example the axon guidance cues Semaphorin 3a/b (De Winter et al. 2016) and the trans-synaptic transcription factor Otx2. This homeoprotein is not produced anywhere in the cortex, but rather in sensory afferents and the choroid plexus (Spatazza et al. 2013; Sugiyama et al. 2008). Otx2 binds to PNNs and enters the future PV⁺ cell, where it triggers a genetic program for critical period plasticity (Beurdeley et al. 2012; Prochiantz and Di Nardo 2015; Testa et al. 2019) by upregulation of Gadd45b, a DNA demethylase that orchestrates the large-scale change in the transcriptomic landscape during the critical period, including clustering of MeCP2 in the nucleus (Apulei et al. 2019), where it has been shown to directly bind to and methylate the Pvalb promoter region (Patrizi et al. 2019). Interestingly, MeCP2 has recently been shown to be a direct target of Ehmt1 in non-neuronal cells (Choi et al. 2018). Besides signalling by Otx2, another interesting candidate might be the signalling molecule BDNF, which is both important for PV⁺ neuron maturation (Berghuis et al. 2006; Huang et al. 1999) and negatively regulated by EHMT1 (Benevento et al. 2016). Specifically, EHMT1 methylates histones around the activity-dependent Bdnf promoter IV in response to network silencing, leading to a failure of activity-dependent Bdnf repression in Ehmt1^+/− neurons (Benevento et al. 2016). However, it is currently unknown whether EHMT1 also plays a role in Bdnf upregulation via promoters other than Bdnf IV, as happens during normal cortical development (Du et al. 2018). Interestingly, emerging evidence links BDNF signaling to the MeCP2^−/y synaptic phenotype as well (Sampathkumar et al. 2016), even though also in this case a precise molecular mechanism still remains to be found. Quite possibly, several different signaling systems (e.g. Otx2 and BDNF, as well as circuit activity levels) could converge on PV⁺ neurons during the critical period, triggering a common genetic program including PV expression and PNN production. In turn, the actual execution of this of this genetic program would require precisely targeted epigenetic modulation, possibly including Gadd45b and MeCP2 as well as EHMT1. Consequentially, an Ehmt1 haploinsufficiency could cause an incomplete transition from the pre-critical period transcriptomic state to the post-critical period transcriptomic state, thus delaying the critical period.

A series of recent reports indicates that reduced feedforward inhibition is a common feature in several mouse models of ASD (Antoine et al. 2019; Banerjee et al. 2016). Across at least five different mouse models of ASD, feedforward inhibition was found to be much more impaired than feedforward excitation, resulting in a shifted E/I balance towards excitation. Our results are consistent with this interpretation, as we find a decreased GABAergic transmission (Fig. 4). In Ehmt1-deficient cells from rodents and humans, excitatory transmission is not impaired at resting membrane potential, but summation of excitatory input is impacted by an upregulation of NMDA receptors (Frega et al. 2019, 2020). Antoine et al. (2019) argue that excitation and inhibition are matched to yield stable in vivo firing patterns. This homeostatic regulation might still prove maladaptive in some situations, resulting in widened integration time windows and an inability to compensate for extremely high or low input levels. Also here, Ehmt1^+/− mice fit the template of impaired adaptation, as excitatory synaptic scaling-up in response to input deprivation is impaired in Ehmt1^+/− mice (Benevento et al. 2016). To summarize, in Ehmt1^+/− mice we find a region- and layer-specific developmental delay of PV⁺ neuron maturation in the three main sensory cortical areas. PV⁺ neurons also are functionally immature, showing a reduced inhibitory output specifically caused by a reduced release probability. As a consequence, we predict a delayed closing of the critical period in auditory and somatosensory cortex. Both the onset and the closing of the critical period require coordinated changes in gene expression in PV⁺ neurons (Apulei et al. 2019), which has been shown to require epigenetic remodeling such as by the DNA methylation reader MeCP2 (Krishnan et al. 2015), which interestingly was recently shown to be a direct target of Ehmt1 in non-neuronal cells (Choi et al. 2018). It is therefore conceivable that a loss of Ehmt1 would lead to a cell-autonomous failure of epigenetic remodeling, resulting in an incomplete repression of previously expressed gene sets and thus a slowed transition into and out of the CP. This concept could be generalized to other changes in gene expression, and indeed is consistent with activity-dependent scaling of excitatory synapses in Ehmt1^+/− neurons (Benevento et al. 2016) and activity-dependent rapid methylation of early-response genes by EHMT1 and EHMT2 (Gupta-Agarwal et al. 2012). We predict that finding out how the epigenetic landscape changes in inhibitory neurons—and when those changes fail—will be an important addition to solving the secret of the dynamic brain.