Abstract
Cortical gamma oscillations are believed to be involved in mental processes which are disturbed in schizophrenia. For example, the magnitudes of sensory-evoked oscillations, as measured by auditory steady-state responses (ASSRs) at 40 Hz, are robustly diminished, whereas the baseline gamma power is enhanced in schizophrenia. Such dual gamma oscillation abnormalities are also present in a mouse model of N-methyl-D-aspartate receptor hypofunction (Ppp1r2cre/Grin1 knockout mice). However, it is unclear whether the abnormal gamma oscillations are associated with dysfunction in schizophrenia. We found that glycogen synthase kinase-3 (GSK3) is overactivated in corticolimbic parvalbumin-positive GABAergic interneurons in Grin1 mutant mice. Here we addressed whether GSK3β inhibition reverses both abnormal gamma oscillations and behavioral deficits with high correlation by pharmacological and genetic approach. We demonstrated that the paralog selective-GSK3β inhibitor, but not GSK3α inhibitor, normalizes the diminished ASSRs, excessive baseline gamma power, and deficits in spatial working memory and prepulse inhibition (PPI) of acoustic startle in Grin1 mutant mice. Cell-type specific GSK3B knockdown, but not GSK3A knockdown, also reversed abnormal gamma oscillations and behavioral deficits. Moreover, GSK3B knockdown, but not GSK3A knockdown, reverses the mutants’ in vivo spike synchrony deficits. Finally, ex vivo patch-clamp recording from pairs of neighboring cortical pyramidal neurons showed a reduction of synchronous spontaneous inhibitory-postsynaptic-current events in mutants, which was reversed by GSK3β inhibition genetically and pharmacologically. Together, GSK3β inhibition in corticolimbic interneurons ameliorates the deficits in spatial working memory and PPI, presumably by restoration of synchronous GABA release, synchronous spike firing, and evoked-gamma power increase with lowered baseline power.
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Introduction
The disturbance of neural oscillations in the gamma frequency band (30–100 Hz) is considered to be a core pathophysiological feature of schizophrenia, particularly in the generation of cognitive dysfunction [1, 2]. For example, clinical electroencephalogram has shown reduction of auditory steady-state responses (ASSRs) at 40 Hz in patients with schizophrenia, which are electrophysiological responses entrained to the frequency and phase of a periodic auditory stimulus generated by auditory cortex activity [3, 4]. The impairment of visual-evoked gamma oscillation in schizophrenia was also observed during Gestalt stimuli [5]. In addition to impairment in evoked gamma oscillations, spontaneous or baseline gamma-band cortical activity during the resting state is also reported in schizophrenia [6,7,8]. However, it is unclear whether such abnormal gamma oscillations are causally linked to cognitive impairments in schizophrenia.
Preclinically, administration of uncompetitive N-methyl-D-aspartate receptor (NMDAR) antagonists, such as ketamine and MK-801, in rodents dose-dependently reduces sensory-evoked gamma responses [9, 10] and increases spontaneous or baseline gamma oscillations [11,12,13]. Furthermore, positive associations have been reported between abnormalities in EEG gamma power and deficits in prepulse inhibition (PPI) of acoustic startle induced by the NMDAR antagonists, suggesting that gamma power abnormalities may be responsible for sensory processing disturbance [14]. Schizophrenia-related behaviors, including PPI and Y-maze alternation (to assess spatial working memory), are also defective in a genetically-engineered mouse model of NMDAR hypofunction [15]. In this model, indispensable NMDAR subunit Grin1 is missing from ~50% of cortical and hippocampal GABAergic neurons, a majority of which are parvalbumin (PV)-positive fast-spiking interneurons, in early postnatal development (Ppp1r2cre/Grin1 knockout (KO) mice) [16]. Notably, 40-Hz click train-evoked ASSR deficits and spontaneous local field potential broad-band power increase in the pre-stimulus period are both observed in this mutants [17]. Genetic Grin1 deletion selectively from PV neurons in awake mice also resulted in increased baseline gamma power [18, 19] and impaired optogenetically evoked-gamma oscillations [19], suggesting that Grin1-deleted PV neurons play a role in abnormal gamma oscillations. However, it remains to be addressed whether abnormal gamma oscillations are strongly associated with cognitive dysfunction in the genetic NMDAR hypofunction model.
Glycogen synthase kinase-3 (GSK3) is a Ser/Thr protein kinase that is ubiquitously expressed in all mammalian tissues and subcellular organelles, including the brain with high expression. Accumulating evidence suggests that GSK3 regulatory pathways are altered and GSK3 activity increases in the schizophrenia [20, 21]. GSK3 comprises two structurally and functionally related serine/threonine kinases encoded by two distinct genes, GSK3A and GSK3B. Both kinases are inherently active under resting conditions, and are primarily regulated by phosphorylation at two levels: (i) inhibitory phosphorylation of serine residues S21/S9 in GSK3α/β and (ii) tyrosine phosphorylation at Y279/Y216 in GSK3α/β, which augments their activity and relieves substrate-priming by other kinases [22]. Notably, nonselective GSK3 inhibitors have been shown to alleviate the behavioral impairments induced by ketamine treatment [23] and in the 22q11.2 microdeletion mouse model [24].
Here we report that proper GSK3β activity in corticolimbic GABAergic neurons is crucial for the emergence of the gamma oscillation and cognitive function in aforementioned Grin1 mouse model of NMDAR hypofunction [16]. To determine which isoform of GSK3, GSK3α vs GSK3β, is critically involved in the gamma oscillations, we used the paralog-selective GSK3 inhibitors, BRD0705 for GSK3α and BRD3731 for GSK3β. To further determine whether GSK3 in corticolimbic GABAergic neurons is crucial for the emergence of abnormal gamma oscillations and behaviors, we have generated a floxed-GSK3A mouse line to conditionally delete the GSK3A, with the complimentary use of a floxed-GSK3B mouse strain. We assess whether both deficits in ASSRs and cognitive behavior could consistently be reversed by manipulation of GSK3β activity in the Grin1 mutant mice.
Materials and methods
All experimental procedures were approved by the Institutional Animal Care and Use Committee at University of Alabama at Birmingham and Southern Research. For detailed experiential procedures, see Supplementary Information.
Animals
We employed Ppp1r2-cre/floxed-Grin1 KO mice (or simply Grin1 mutant mice), in which genetic deletion of obligatory Grin1 subunit is introduced in ~50% cortical and hippocampal GABAergic interneurons from the postnatal second week [16]. To reduce the kinase activity of GSK3A or GSK3B in Grin1-deleted GABAergic neurons, either floxed-GSK3A or floxed-GSK3B mouse strain was bred to Grin1 mutant mice to generate GABAergic neuron-specific GSK3 heterozygous KO mice (namely, GSK3A- or GSK3B-knockdown mice). The generation of floxed-GSK3A mouse strain is described in Supplementary Fig. S1. The floxed-GSK3B strain was obtained from Dr. J. Woodgett [25].
Immunohistochemistry
Immunohistochemistry was performed as previously described [16]. Briefly, sections containing auditory cortex were double-immunostained with rabbit anti-GSK3α (1:200, G08-63R-25, SignalChem, USA), rabbit anti-GSK3β (1:1000, ab32391, Abcam, USA), or rabbit GSK3β phospho-Y216 (1:150, ab75745 Abcam, USA), and mouse anti-PV (1:5000, 235, Swant, Switzerland). Images of the auditory cortex were captured using confocal microscope (Nikon A1). NIH ImageJ software was used to measure the integrated density of GSK3α, GSK3β and GSK3-phospho (Y279/Y216) in PV-positive interneurons or non-PV neurons. The corrected total cell fluorescence (CTCF) was calculated as previously described [26]. Results are presented as normalized florescence, which is the ratio of CTCF value of the protein to the CTCF values of corresponding proteins in non-PV neurons of floxed-control mice.
GSK inhibitors
A non-selective GSK3 inhibitor, SB216763 (2.5 mg/kg, i.p.; Tocris, Ellisiville, MO) was dissolved in 10% DMSO and 10% Tween80/PBS. Another non-selective GSK3 inhibitor, TDZD-8 (2.5 mg/kg, i.p; Abcam, Cambridge, MA) was dissolved in 1.25% DMSO and 5% Tween80/PBS. These two non-selective GSK3 inhibitors are brain-permeable as previously described [27, 28]. The paralog-selective GSK3β inhibitor BRD3731 (30 mg/kg, i.p.) and paralog-selective GSK3α inhibitor BRD0705 (30 mg/kg, i.p.) were synthesized by referring to the protocols [29]. BRD3731 and BRD0705 were dissolved in 2% DMSO and 2% Tween80/PBS. Each was administered to the mice one hr before in vivo electrophysiology tests or behavioral tests.
In vivo multi-unit recording
In vivo multiunit recording was performed as previously described [16]. Briefly, animals (both sexes, 10–15 week-old) were implanted with a microarray carrying six tetrodes into the somatosensory cortex, and were subjected to a linear track to record the unit activity. To analyze the level of synchronization of isolated pyramidal neurons, pairs of cells recorded in the same tetrode were subjected to cross-correlation analysis. More details are provided in Supplementary Methods.
In vivo LFP recording
In vivo LFP recoding was also performed as previously described [17]. Briefly, LFP recording was performed from primary auditory cortex of awake, head-restrained mice (both sexes, 10–15 week-old) in an auditory isolation chamber (background sound level, 35 dB SPL). Five hundred-ms long click trains consisting of 80-dB white-noise pulses presented at 40 Hz (40-Hz click-train stimuli) were applied 50 times with an inter-stimulus interval (ISI) of 20 s. A long ISI was used to robustly evoke the LFP N1 potentials by each click sound (50 times). To measure “evoked ASSR power”, the LFP responses, for each after subtraction of spontaneous LFP at the mid-time point of the preceding ISI, were averaged across 50 click trains, and then spectral analysis on the averaged LFP was performed. To measure “total ASSR power,” spectral analysis was performed on each of LFP traces after subtraction of spontaneous LFP, and then the results of spectra were averaged. Baseline (spontaneous) LFP powers during the pre-stimulus period were also measured during the last 10 s (50 segments of 200-ms bin and averaged) prior to the first click-train stimulus. To calculate the intertrial coherence, phase locking to click-trains was performed in a frequency range 0–100 Hz with 60% overlapping window. Analyses were performed under per-animal design and per-electrode channel design, and male and female data were mixed since no clear sex differences were observed. More details are provided in Supplementary Methods.
Ex vivo multiple patch clamp recording
To measure spontaneous inhibitory postsynaptic currents (sIPSCs) from pairs of neighboring (<50 µm apart) neurons ex vivo, multiple patch-clamp recordings were performed in auditory cortex layer 2/3 in the presence of CNQX (20 µM) and AP5 (50 µM). Synchronous events were detected by custom written Microsoft Excel (Statcel 4th ed.) macro by defining the sIPSC events (> 5pA) coinciding within ±10 ms of signal window. More details are provided in Supplementary Methods.
Mouse behavioral tests
Y-maze spontaneous alternation was conducted to assess spatial working memory, as previously described [16]. PPI of acoustic startle was also performed to measure a pre-attentive aspect of cognitive function [30]. Male and female data were mixed because no clear sex difference was observed.
Statistical analyses
Statistical analyses were conducted using JASP (version 0.12.1) (Univ Amsterdam open-source data analysis software). Student’s t test, paired t test and factorial analysis of variance (ANOVA) were employed wherever appropriate. When main effects or interaction effects were significant, Tukey-Kramer post hoc analysis was conducted to determine which groups differ significantly from other groups. Data are presented as mean ± s.e.m. Significance was considered at p < 0.05.
Results
Over-activation of GSK3 in cortical Grin1-deleted PV-positive neurons
To explore whether GSK3 is up-regulated in the Grin1 mutant mice, we measured fluorescence intensity of auditory cortical neurons produced by fluorescent-labeled antibodies against GSK3α, GSK3β, and phospho-GSK3 (at Y279 for GSK3α and at Y216 for GSK3β), an auto-activated form of GSK3 [31, 32], respectively (Fig. 1). Although the expression of GSK3α (Fig. 1a) and GSK3β (Fig. 1b), both, are higher in the cortical layer 2/3 PV neurons compared to the nearby non-PV neurons (largely pyramidal neurons), no difference in the protein levels was detected between the genotypes in either PV neurons or non-PV neurons. However, tyrosine phosphorylation at Y279/Y216 in GSK3α/β was significantly intensified in the PV neurons of mutant mice (increased by 40%), compared to the PV neurons of floxed control mice (Fig. 1c), suggesting that NMDAR deletion in PV neurons leads to over-activation of GSK3 in the PV neurons.
Non-selective GSK3 inhibitor reversed stimulus-evoked gamma oscillation deficits, spontaneous gamma oscillation and cognitive dysfunction in Grin1 mutant mice
To assess the impact of predictive GSK3 over-activity on the in vivo stimulus-evoked LFP gamma oscillations, we used a non-selective GSK3 inhibitor, TDZD-8. Before TDZD-8 administration, ASSRs were measured from the Grin1 mutant mice and floxed-control mice during 40-Hz click trains (Fig. 2a). As previously reported [17], 40-Hz click trains evoked the N1 potential (defined as the amplitude of the first prominent negative peak) followed by the robust increase in the power magnitudes, in particular at low gamma frequency range, in the floxed-Grin1 control mice (Fig. 2a). Genotypic comparison revealed a profound reduction of the evoked ASSR power amplitudes at 40-Hz in the Grin1 mutant mice (Fig. 2a, b). One hr after administration of TDZD-8, the evoked powers were restored in the mutant mice whereas no drug effect was observed in controls (Fig. 2b). The analysis of total ASSR power using the same LFPs reach the same conclusions (Supplementary Fig. S3A and Supplementary Result and Discussion). In addition, we found that the degree of phase locking in the ASSR to 40-Hz click trains was lower in the mutants, which was also reversed in the mutant mice in per-channel analysis, while being unaffected in the floxed-control mice (Fig. 2c). TDZD-8 also normalized abnormally high baseline gamma power amplitudes during the last 10 s prior to the onset of the first click-train (referred to a pre-stimulus period), to the baseline level of control mice (Fig. 2d). On the other hand, the N1 amplitudes evoked by click trains were smaller in the mutant mice, which were unaffected by TDZD-8 (Fig. 2e). These results suggest that acute GSK3 inhibition alleviates the evoked-power deficits and reversed the baseline gamma power in the pre-stimulus period of the mutant mice.
We also assessed whether TDZD-8 restored the normal behavior in the Grin1 mutant mice. TDZD-8 restored the Y-maze spontaneous alternation, which was diminished in the mutant mice as previously described [16] (Fig. 2f). Pretreatment with TDZD-8 also alleviated the deficits in PPI of startle in the mutant mice (Fig. 2g). These results suggest that acute GSK3 inhibition ameliorates cognitive dysfunction of the Grin1 mutant mice.
Paralog-selective GSK3β inhibitor, but not GSK3α inhibitor, normalized the deficits in gamma oscillation and cognitive dysfunction of Grin1 mutant mice
To determine the over-activation of which isoform, GSK3α or GSK3β, elicits the gamma oscillation deficits, we used a paralog-selective GSK3β inhibitor BRD3731 and a GSK3α inhibitor BRD0705. Administration of BRD3731, but not BRD0705, reversed the gamma oscillation deficits in the mutant mice (Fig. 3a, b). On the other hand, neither BRD3731 nor BRD0705 affected the evoked-gamma oscillation in the floxed-control mice. The total ASSR power analysis reach the same conclusion (Supplementary Fig. S3B). In addition, administration of BRD3731, but not BRD0705, also augmented phase locking factor at 40 Hz in the mutant mice (Fig. 3c). Pretreatment with BRD3731, but not BRD0705, suppressed abnormally high mutants’ baseline gamma and beta power to the normal level in the pre-stimulus period (Fig. 3d and Supplementary Fig. S5). On the other hand, neither BRD3731 nor BRD0705 affected the N1 amplitudes of the mutant mice, nor any parameters in the floxed-control mice (Supplementary Fig. S4A). Finally, BRD3731, but not BRD0705, rescued the spatial working memory of Grin1 mutant mice in Y-maze alternation task (Fig. 3e). Pretreatment with BRD3731, but not BRD0705, also ameliorated the mutants’ PPI deficits (Fig. 3f). The startle reflex itself was unaffected by either genotypes or drug treatments (Supplementary Fig. S5A). These results suggest that GSK3β inhibition, but not GSK3α inhibition, is crucial for restoration of gamma oscillations and cognitive function.
GABAergic neuron-selective GSK3B knockdown reverses stimulus-evoked gamma oscillation deficits, excessive baseline gamma oscillations and cognitive dysfunction
To address whether GABAergic neuron-specific GSK3β inhibition is sufficient for restoration of gamma oscillations and cognitive behavior, we bred either a floxed-GSK3A or a floxed-GSK3B mouse strain to the Ppp1r2cre/Grin1 KO mice to produce the corticolimbic GABAergic neuron-selective heterozygous deletion of GSK3A or GSK3B gene, respectively, on Grin1 mutant genetic background (GABAergic neuron-selective knockdown). Genetic GSK3B knockdown, but GSK3A knockdown, fully alleviated the defective gamma power amplitudes (Fig. 4a and Supplementary Fig. S3C) and phase locking factors at 40 Hz of the Grin1 mutant mice (Fig. 4b). GSK3B knockdown, but not GSK3A knockdown, also fully normalized baseline gamma oscillation during the pre-stimulus period (Fig. 4c). However, neither genetic GSK3A nor GSK3B knockdown altered the N1 amplitudes (Supplementary Fig. S3D). We also examined whether knockdown of GSK3-isoform restores the cognitive behavior. Genetic GSK3B knockdown, but not GSK3A knockdown, improved the Y-maze spontaneous alternation (Fig. 4e) and PPI of the Grin1 mutant mice (Fig. 4f). No difference was detected in the startle amplitudes between the genotypes (Supplementary Fig. S5B). These results suggest that GSK3β inhibition in corticolimbic GABAergic neurons is sufficient for restoration of gamma oscillations and cognitive function.
GABAergic neuron-selective GSK3B knockdown alleviated in vivo spike synchrony and ex vivo synchronous sIPSC deficits
To assess whether GSK3 inhibitors impact on spike synchrony in vivo, we measured multi-unit activity from somatosensory cortex in the Grin1 mutant mice before and after drug treatment. Individual spikes were obtained from nearby pyramidal neurons through the tetrodes’ cell-cluster analysis during simple linear track exploration (Fig. 5a). As previously reported [16], the Grin1 mutant mice showed much lower correlation coefficients of spikes from pairs of pyramidal neurons compared to the control mice (Fig. 5c). Pretreatment with the non-selective GSK3 inhibitor SB216763 or TDZD-8 both increased in vivo spike synchrony as measured by cross-correlation magnitude, in the Grin1 mutant mice (Fig. 5b). To determine which isoform of GSK3 results in vivo spike synchrony defects, multi-unit recording from somatosensory cortex was also performed in the GABAergic neuron-selective GSK3α and GSK3β knockdown mice. As shown in Fig. 5c, in vivo spike synchrony was restored in genetic GSK3β knockdown animals, but not in GSK3α knockdown animals.
In another series of experiments, we measured spontaneous IPSCs (sIPSCs) from pairs of layer 2/3 pyramidal neurons of auditory cortex. Ex vivo recordings were obtained in brain slices prepared from floxed-control and Grin1 mutant mice (Fig. 5d). The Grin1 mutant mice showed a significant reduction in synchronous sIPSC events between pairs of simultaneously recorded pyramidal neurons (Fig. 5e), suggesting an impairment in synchronous GABA release from Grin1-deleted neurons. Notably, synchronous events of sIPSCs were significantly increased to the levels of controls by bath-application of BRD3731 (40 µM). In addition, in GABAergic neuron-selective GSK3B knockdown animals, the number of synchronous events in layer 2/3 pyramidal cells was equivalent to the number of control mice. Inter-event intervals of sIPSCs were not significantly altered across groups (Fig. 5f), suggesting that synchronous GABA release is disturbed by Grin1-deletion in the GABAergic neurons.
Discussion
We demonstrated that GSK3β inhibition restores the in vivo cortical gamma oscillation and cognitive function in the mouse model of Grin1 hypofunction relevant to schizophrenia. Specifically, we found that (1) elevated phospho-GSK3 (at Y216 in GSK3β) immunoreactivity in the PV neurons (presumably Grin1-deleted), but not pyramidal neurons, in the auditory cortex of the Grin1 mutant mice, (2) normalization of the diminished evoked-gamma oscillations, abnormally high baseline gamma oscillation, and behavioral deficits in the Grin1 mutant mice by administration of non-selective GSK3 inhibitors, (3) reversal of the evoked-gamma oscillations, baseline gamma power, spatial working memory and PPI by paralog-selective GSK3β inhibitor (BRD3731), but not by GSK3α inhibitor (BRD0705), and (4) restoration of evoked-gamma oscillations, baseline gamma power, and cognitive behaviors by corticolimbic GABAergic neuron-selective GSK3B genetic knockdown. These findings suggest that GSK3β inhibition in corticolimbic GABAergic neurons rescues cognitive behavior in the NMDAR hypofunction mouse model, in strong association to the restoration of normal synchronous oscillatory brain activity at gamma frequency both in the stimulus and pre-stimulus period. Consistently, in vivo deficits in spike synchrony from pairs of cortical layer 2/3 pyramidal neuron was reversed by GSK3β inhibition and by GABAergic neuron-specific knockdown of GSK3B, but not GSK3A. Ex vivo reduction of synchronous sIPSC event number in pairs of pyramidal neurons were also restored by GSK3β inhibition and by GABAergic neuron-selective GSK3B genetic knockdown, suggesting that evoked-gamma oscillation deficit in the Grin1 mutant mice is attributed to the synchronous GABA release impairment and subsequent pyramidal cells’ spike synchrony deficits.
Two distinct gamma power abnormalities originating from Grin1-deleted PV neurons
Abnormal cortical gamma oscillatory activity appears to underlie impairment in higher cognitive functions associated with schizophrenia. Originating from the landmark observation by Kwon et al. [3], several groups have confirmed the reduction of the evoked power and synchronization to 40-Hz click-train stimuli in patients with schizophrenia [33,34,35]. On the other hand, spontaneous gamma power has also been reported to increase during the pre-stimulus baseline period in patients experiencing positive auditory symptoms [6] or during the resting state [7, 8]. However, it has been debated whether the mechanisms of producing such two gamma abnormalities are shared or distinct. We previously demonstrated that Grin1 deletion in cortical GABAergic neurons elicits such dual gamma abnormalities in the same animal [17]. We postulated that the evoked gamma power deficits could be due to the impaired feed-forward inhibition of thalamo-cortical circuits in response to acoustic stimuli by the defective cortical PV neurons, which may attenuate the phase-locked firing of pyramidal neurons at gamma frequency range [17]. On the other hand, the reason for the elevated baseline gamma power may be attributable to the aberrant or “noisy” spike firing of pyramidal neurons, due to the cortical disinhibition by defective PV neurons. The present study corroborates this prediction and further suggests a shared underlying mechanism between the two, because both abnormalities are consistently reversed together upon various GSK3β activity manipulations. The responsible cell-type is likely to be PV neurons, because PV neuron-specific Grin1 deletion in mice results in optogenetically-evoked gamma oscillation deficits and increased baseline power [18, 19]. In the Grin1 mutant mice of this study, a majority (75–84%) of cortical PV neurons is Grin1-deleted, whereas Cre recombination frequency is much lower in other PV-negative GABAergic neurons [16].
Curiously, the spontaneous gamma power (200-ms segment) at the mid-time point of ISIs was normal (in z-score) and unaffected by the GSK3β inhibition. Since auditory layer 2/3 PV neurons are consistently suppressed in active wakefulness by acoustic stimuli [36], functional insufficiency of Grin1-deleted PV neurons may be masked when click-trains are being applied [17]. Alternatively, long ISI (20 s) used in this study might decay the noise level at the mid-time point of ISI. An increase in induced gamma power has been reported in schizophrenia in relatively short ISIs (~1–3 s) during auditory steady-state stimulation [37,38,39]. Regardless, it suggests that the evoked-gamma power deficit is not simply caused by elevation of spontaneous power during the click-train stimulus period.
From Grin1 deletion in PV neuron to evoked-gamma power and phase deficits
Axons of a single PV neuron in the cortex and hippocampus innervate hundreds of pyramidal cells [40]. It has been reported that sIPSCs between pairs of nearby pyramidal cells in mouse entorhinal cortex are highly correlated [41]. Indeed, the simultaneous occurrence of multiple sIPSCs among cortical layer2/3 pyramidal neurons was frequently detected in the floxed-control mice (Fig. 5d). However, such synchronous sIPSCs were less frequent in the Grin1 mutant mice, which was reversed by the selective GSK3β inhibitor and GABAergic neuron-selective GSK3 knockdown (Fig. 5e). These findings are consistent with a prevailing hypothesis that gamma oscillation abnormalities are attributable to impaired GABAergic neurotransmission [42, 43]. Further investigation is warranted, however, to determine the underlying mechanism(s) of synchronous GABA release, as GABA release frequency appeared to be unaffected (Fig. 5f).
Anyhow, such impairment of synchronous perisomatic inhibition onto pyramidal neurons could lead to in vivo spike synchrony deficit in Grin1 mutant mice. This is presumably because PV-positive basket cells predominantly innervate to the soma and proximal dendritic areas of pyramidal cells [44], providing a robust perisomatic inhibition, thereby controlling spike generation [45]. Subsequently, spike synchrony deficits could give rise to impairments in synchronized LFP oscillations to the 40-Hz click-train stimuli, because LFP oscillations are at least partly attributed to the synchronization of neuronal firing rate on the same time scale [46].
Disturbance of gamma oscillation leading to cognitive deficits
One potential approach to assess the relation between gamma oscillation abnormalities and cognitive dysfunction is to explore whether reversing the gamma abnormalities could lead to the restoration of cognitive function. Enhanced GABAergic activity with the potentiator of α2 subunit containing GABAA receptors improved frontal gamma oscillatory activity and working memory in patients with schizophrenia [47]. Preclinically, GABAB receptor agonist baclofen has suggested to improve gamma synchrony and spatial working memory deficits in the NMDAR hypomorph mice [48]. Recently, GSK3 inhibition has been shown to rescue the deficits in spatial working memory and in phase-locking of mPFC activity to theta/gamma oscillations in the ventral hippocampus of 22q11.2 microdeletion model mice [24].
Limitations
We repeatedly showed that systemic or GABAergic neuron-selective GSK3β inhibition restores the in vivo spike synchrony, gamma oscillations and cognitive behaviors altogether, suggesting that spike synchrony, gamma oscillation and cognitive function are tightly associated. However, it should be noted that, while LFP gamma oscillations were assessed in the auditory cortex and in vivo spike synchrony in somatosensory cortex, the behavioral tests assessed may be dependent on other brain regions, such as the prefrontal cortex and/or hippocampus [49, 50]. Thus, a direct link has not been established between evoked-gamma oscillations and cognitive function. Consistent demonstration of reversal responses by GSK3 inhibition among the manipulations may suggest that restoration of gamma oscillations and spike synchrony elicited by GSK3β inhibition at PV-positive interneurons may constitute a shared mechanism across the cortical areas.
Secondly, this study involved a relatively small sample size (five mice for each genotype) owing to the difficulty in recording the stimulus-evoked LFPs from mouse primary auditory cortex [17]. However, the results under per-animal analysis design were fully replicated by under per-channel analysis design, suggesting the robustness of the findings.
In summary, we demonstrated a strong association between the integrity of cortical gamma oscillations and cognitive function, by manipulating GSK3β activity. The precise cellular mechanism regarding how GSK3β kinase inhibition ameliorates the synchronous GABA release, in vivo spike synchrony and LFP gamma oscillations has remained unsolved. However, impaired synchronous inhibition of pyramidal neurons by Grin1-deleted PV neurons appears to be a key mechanism underlying schizophrenia-like phenotypes. Further study is warranted towards potential development of therapeutic interventions of schizophrenia.
Funding and disclosure
This work was funded by grants from the National Institute of Mental Health R01 MH110681 (KN) and partly by Change Campaign Fund at Southern Research. The authors report no biomedical financial interests or potential conflicts of interest.
References
Uhlhaas PJ, Singer W. Abnormal neural oscillations and synchrony in schizophrenia. Nat Rev Neurosci. 2010;11:100–13.
Lesh TA, Niendam TA, Minzenberg MJ, Carter CS. Cognitive control deficits in schizophrenia: mechanisms and meaning. Neuropsychopharmacology. 2011;36:316–38.
Kwon JS, O’Donnell BF, Wallenstein GV, Greene RW, Hirayasu Y, Nestor PG, et al. Gamma frequency-range abnormalities to auditory stimulation in schizophrenia. Arch Gen Psychiatry. 1999;56:1001–5.
Light GA, Hsu JL, Hsieh MH, Meyer-Gomes K, Sprock J, Swerdlow NR, et al. Gamma band oscillations reveal neural network cortical coherence dysfunction in schizophrenia patients. Biol Psychiatry. 2006;60:1231–40.
Spencer KM, Nestor PG, Perlmutter R, Niznikiewicz MA, Klump MC, Frumin M, et al. Neural synchrony indexes disordered perception and cognition in schizophrenia. Proc Natl Acad Sci USA. 2004;101:17288–93.
Spencer KM. Baseline gamma power during auditory steady-state stimulation in schizophrenia. Front Hum Neurosci. 2012;5:1–7.
Kikuchi M, Hashimoto T, Nagasawa T, Hirosawa T, Minabe Y, Yoshimura M, et al. Frontal areas contribute to reduced global coordination of resting-state gamma activities in drug-naïve patients with schizophrenia. Schizophr Res. 2011;130:187–94.
Andreou C, Nolte G, Leicht G, Polomac N, Hanganu-Opatz IL, Lambert M, et al. Increased resting-state gamma-band connectivity in first-episode schizophrenia. Schizophr Bull. 2015;41:930–9.
Kulikova SP, Tolmacheva EA, Anderson P, Gaudias J, Adams BE, Zheng T, et al. Opposite effects of ketamine and deep brain stimulation on rat thalamocortical information processing. Eur J Neurosci. 2012;36:3407–19.
Saunders JA, Gandal MJ, Siegel SJ. NMDA antagonists recreate signal-to-noise ratio and timing perturbations present in schizophrenia. Neurobiol Dis. 2012;46:93–100.
Pinault D. N-methyl D-aspartate receptor antagonists ketamine and MK-801 induce wake-related aberrant gamma oscillations in the rat neocortex. Biol Psychiatry. 2008;63:730–5.
Ehrlichman RS, Gandal MJ, Maxwell CR, Lazarewicz MT, Finkel LH, Contreras D, et al. N-methyl-D-aspartic acid receptor antagonist-induced frequency oscillations in mice recreate pattern of electrophysiological deficits in schizophrenia. Neuroscience. 2009;158:705–12.
Hakami T, Jones NC, Tolmacheva EA, Gaudias J, Chaumont J, Salzberg M, et al. NMDA receptor hypofunction leads to generalized and persistent aberrant gamma oscillations independent of hyperlocomotion and the state of consciousness. PLoS One. 2009;4:e6755.
Jones NC, Anderson P, Rind G, Sullivan C, van den Buuse M, O’Brien TJ. Effects of aberrant gamma frequency oscillations on prepulse inhibition. Int J Neuropsychopharmacol. 2014;17:1671–81.
Nakazawa K, Sapkota K. The origin of NMDA receptor hypofunction in schizophrenia. Pharm Ther. 2020;205:107426.
Belforte JE, Zsiros V, Sklar ER, Jiang Z, Yu G, Li Y, et al. Postnatal NMDA receptor ablation in corticolimbic interneurons confers schizophrenia-like phenotypes. Nat Neurosci. 2010;13:76–83.
Nakao K, Nakazawa K. Brain state-dependent abnormal LFP activity in the auditory cortex of a schizophrenia mouse model. Front Neurosci. 2014;8:168.
Korotkova T, Fuchs EC, Ponomarenko A, von Engelhardt J, Monyer H. NMDA receptor ablation on parvalbumin-positive interneurons impairs hippocampal synchrony, spatial representations, and working memory. Neuron. 2010;68:557–69.
Carlén M, Meletis K, Siegle JH, Cardin JA, Futai K, Vierling-Claassen D, et al. A critical role for NMDA receptors in parvalbumin interneurons for gamma rhythm induction and behavior. Mol Psychiatry. 2012;17:537–48.
Emamian ES, Hall D, Birnbaum MJ, Karayiorgou M, Gogos JA. Convergent evidence for impaired AKT1-GSK3β signaling in schizophrenia. Nat Genet. 2004;36:131–7.
Lovestone S, Killick R, Di Forti M, Murray R. Schizophrenia as a GSK-3 dysregulation disorder. Trends Neurosci. 2007;30:142–9.
Cole AR, Knebel A, Morrice NA, Robertson LA, Irving AJ, Connolly CN, et al. GSK-3 phosphorylation of the Alzheimer epitope within collapsin response mediator proteins regulates axon elongation in primary neurons. J Biol Chem. 2004;279:50176–80.
Chan MH, Chiu PH, Lin CY, Chen HH. Inhibition of glycogen synthase kinase-3 attenuates psychotomimetic effects of ketamine. Schizophr Res. 2012;136:96–103.
Tamura M, Mukai J, Gordon JA, Gogos JA. Developmental inhibition of Gsk3 rescues behavioral and neurophysiological deficits in a mouse model of schizophrenia predisposition. Neuron. 2016;89:1100–9.
Patel S, Doble BW, MacAulay K, Sinclair EM, Drucker DJ, Woodgett JR. Tissue-specific role of glycogen synthase kinase 3 in glucose homeostasis and insulin action. Mol Cell Biol. 2008;28:6314–28.
McCloy RA, Rogers S, Caldon CE, Lorca T, Castro A, Burgess A. Partial inhibition of Cdk1 in G2 phase overrides the SAC and decouples mitotic events. Cell Cycle. 2014;13:1400–12.
Lipina TV, Wang M, Liu F, Roder JC. Synergistic interactions between PDE4B and GSK-3: DISC1 mutant mice. Neuropharmacology. 2012;62:1252–62.
Eldar-Finkelman H, Martinez A. GSK-3 inhibitors: preclinical and clinical focus on CNS. Front Mol Neurosci. 2011;4:1–18.
Wagner FF, Benajiba L, Campbell AJ, Weïwer M, Sacher JR, Gale JP, et al. Exploiting an Asp-Glu “switch” in glycogen synthase kinase 3 to design paralog-selective inhibitors for use in acute myeloid leukemia. Sci Transl Med. 2018;10:eaam8460.
Swerdlow NR, Weber M, Qu Y, Light GA, Braff DL. Realistic expectations of prepulse inhibition in translational models for schizophrenia research. Psychopharmacol. 2008;199:331–88.
Hughes K, Nikolakaki E, Plyte SE, Totty NF, Woodgett JR. Modulation of the glycogen synthase kinase-3 family by tyrosine phosphorylation. EMBO J. 1993;12:803–8.
Wang QM, Fiol CJ, DePaoli-Roach AA, Roach PJ. Glycogen synthase kinase-3β is a dual specificity kinase differentially regulated by tyrosine and serine/threonine phosphorylation. J Biol Chem. 1994;269:14566–74.
O’Donnell BF, Vohs JL, Krishnan GP, Rass O, Hetrick WP, Morzorati SL. The auditory steady-state response (ASSR): a translational biomarker for schizophrenia. Suppl Clin Neurophysiol. 2013;62:101–12.
Sivarao D. The 40-Hz auditory steady-state response: a selective biomarker for cortical NMDA function. Ann N. Y Acad Sci. 2015;1344:27–36.
Thuné H, Recasens M, Uhlhaas PJ. The 40-Hz auditory steady-state response in patients with schizophrenia. JAMA Psychiatry. 2016;73:1145–53.
Sakata S, Harris KD. Laminar-dependent effects of cortical state on auditory cortical spontaneous activity. Front Neural Circuits. 2012;6:109.
Hamm JP, Gilmore CS, Clementz BA. Augmented gamma band auditory steady-state responses: support for NMDA hypofunction in schizophrenia. Schizophr Res. 2012;138:1–7.
O’Donnell BF, Vohs JL, Krishnan GP, Rass O, Hetrick WP, Morzorati SL. The auditory steady-state response (ASSR). Suppl Clin Neurophysiol. 2013;62:101–12.
Tada M, Kirihara K, Koshiyama D, Fujioka M, Usui K, Uka T, et al. Gamma-band auditory steady-state response as a neurophysiological marker for excitation and inhibition balance: a review for understanding schizophrenia and other neuropsychiatric disorders. Clin EEG Neurosci. 2020;51:234–43.
Bartos M, Vida I, Jonas P. Synaptic mechanisms of synchronized gamma oscillations in inhibitory interneuron networks. Nat Rev Neurosci. 2007;8:45–56.
Salkoff DB, Zagha E, Yuzgec O, McCormick DA. Synaptic mechanisms of tight spike synchrony at gamma frequency in cerebral cortex. J Neurosci. 2015;35:10236–51.
Buzsáki G, Wang X-J. Mechanisms of gamma oscillations. Annu Rev Neurosci. 2012;35:203–25.
McNally JM, McCarley RW. Gamma band oscillations: a key to understanding schizophrenia symptoms and neural circuit abnormalities. Curr Opin Psychiatry. 2016;29:202–10.
Melchitzky DS, Sesack SR, Lewis DA. Parvalbumin-immunoreactive axon terminals in macaque monkey and human prefrontal cortex: Laminar, regional, and target specificity of type I and type II synapses. J Comp Neurol. 1999;408:11–22.
Soltesz I, Smetters D, Mody I. Tonic inhibition originates from synapses close to the soma. Neuron. 1995;14:1273–83.
Denker M, Roux S, Lindén H, Diesmann M, Riehle A, Grün S. The local field potential reflects surplus spike synchrony. Cereb Cortex. 2011;21:2681–95.
Lewis DA, Cho RY, Carter CS, Eklund K, Forster S, Kelly MA, et al. Subunit-selective modulation of GABA type A receptor neurotransmission and cognition in schizophrenia. Am J Psychiatry. 2008;165:1585–93.
Gandal MJ, Anderson RL, Billingslea EN, Carlson GC, Roberts TPL, Siegel SJ. Mice with reduced NMDA receptor expression: more consistent with autism than schizophrenia? Genes Brain Behav. 2012;11:740–50.
van Asselen M, Kessels RPC, Neggers SFW, Kappelle LJ, Frijns CJM, Postma A. Brain areas involved in spatial working memory. Neuropsychologia. 2006;44:1185–94.
Li L, Du Y, Li N, Wu X, Wu Y. Top-down modulation of prepulse inhibition of the startle reflex in humans and rats. Neurosci Biobehav Rev. 2009;33:1157–67.
Acknowledgements
We thank Dr. J. Woodgett for providing a floxed-GSK3B strain, Andrew Fitzgerald for advice on data analysis, and Lynae Hanks for critical reading of the manuscript. Services for generation of a floxed-GSK3A mouse line was obtained from the University of Alabama at Birmingham Transgenic & Genetically Engineered Model Systems Core Facility (RAK), which are supported by awards NIH P30 CA13148, P30 AR048311, P30 DK074038, P30 DK05336, and P60 DK079626.
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KN and KN designed research. KN performed in vivo electrophysiology and behavior tests and analyzed the data. MS performed ex vivo electrophysiology, analyzed the data. JJH supervised the electrophysiological data analysis. KS performed immunohistochemistry and analyzed the data. BRD compounds were synthesized by RH CR, and BH contributed to transgenic work. KN and KN wrote the paper.
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Nakao, K., Singh, M., Sapkota, K. et al. GSK3β inhibition restores cortical gamma oscillation and cognitive behavior in a mouse model of NMDA receptor hypofunction relevant to schizophrenia. Neuropsychopharmacol. 45, 2207–2218 (2020). https://doi.org/10.1038/s41386-020-00819-0
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DOI: https://doi.org/10.1038/s41386-020-00819-0
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