Pyramidal cell-selective GluN1 knockout causes impairments in salience attribution and related EEG activity.

Schizophrenia is a disabling psychiatric disease characterized by symptoms including hallucinations, delusions, social withdrawal, loss of pleasure, and inappropriate affect. Although schizophrenia is marked by dysfunction in dopaminergic and glutamatergic signaling, it is not presently clear how these dysfunctions give rise to symptoms. The aberrant salience hypothesis of schizophrenia argues that abnormal attribution of motivational salience to stimuli is one of the main contributors to both positive and negative symptoms of schizophrenia. The proposed mechanisms for this hypothesis are overactive striatal dopaminergic and hypoactive glutamatergic signaling. The current study assessed salience attribution in mice (n = 72) using an oddball paradigm in which an infrequent stimulus either co-occurred with shock (conditioned group) or was presented alone (non-conditioned group). Behavioral response (freezing) and electroencephalogram (whole brain and amygdala) were used to assess salience attribution. Mice with pyramidal cell-selective knockout of ionotropic glutamate receptors (GluN1) were used to reproduce a prominent physiological change involved in schizophrenia. Non-conditioned knockout mice froze significantly more in response to the unpaired stimulus than non-conditioned wild-type mice, suggesting that this irrelevant cue acquired motivational salience for the knockouts. In accordance with this finding, low-frequency event-related spectral perturbation was significantly increased in non-conditioned knockout mice relative to both conditioned knockout and non-conditioned wild-type mice. These results suggest that pyramidal cell-selective GluN1 knockout leads to inappropriate attribution of salience for irrelevant stimuli as characterized by abnormalities in both behavior and brain circuitry functions.

High fat diet produces brain insulin resistance, synaptodendritic abnormalities and altered behavior in mice.

Insulin resistance and other features of the metabolic syndrome are increasingly recognized for their effects on cognitive health. To ascertain mechanisms by which this occurs, we fed mice a very high fat diet (60% kcal by fat) for 17days or a moderate high fat diet (HFD, 45% kcal by fat) for 8weeks and examined changes in brain insulin signaling responses, hippocampal synaptodendritic protein expression, and spatial working memory. Compared to normal control diet mice, cerebral cortex tissues of HFD mice were insulin-resistant as evidenced by failed activation of Akt, S6 and GSK3ß with ex-vivo insulin stimulation. Importantly, we found that expression of brain IPMK, which is necessary for mTOR/Akt signaling, remained decreased in HFD mice upon activation of AMPK. HFD mouse hippocampus exhibited increased expression of serine-phosphorylated insulin receptor substrate 1 (IRS1-pS(616)), a marker of insulin resistance, as well as decreased expression of PSD-95, a scaffolding protein enriched in post-synaptic densities, and synaptopodin, an actin-associated protein enriched in spine apparatuses. Spatial working memory was impaired as assessed by decreased spontaneous alternation in a T-maze. These findings indicate that HFD is associated with telencephalic insulin resistance and deleterious effects on synaptic integrity and cognitive behaviors.

Neuronal Activity-Induced Sterol Regulatory Element Binding Protein-1 (SREBP1) is Disrupted in Dysbindin-Null Mice-Potential Link to Cognitive Impairment in Schizophrenia.

Schizophrenia is a chronic debilitating neuropsychiatric disorder that affects about 1 % of the population. Dystrobrevin-binding protein 1 (DTNBP1 or dysbindin) is one of the Research Domain Constructs (RDoC) associated with cognition and is significantly reduced in the brain of schizophrenia patients. To further understand the molecular underpinnings of pathogenesis of schizophrenia, we have performed microarray analyses of the hippocampi from dysbindin knockout mice, and found that genes involved in the lipogenic pathway are suppressed. Moreover, we discovered that maturation of a master transcriptional regulator for lipid synthesis, sterol regulatory element binding protein-1 (SREBP1) is induced by neuronal activity, and is required for induction of the immediate early gene ARC (activity-regulated cytoskeleton-associated protein), necessary for synaptic plasticity and memory. We found that nuclear SREBP1 is dramatically reduced in dysbindin-1 knockout mice and postmortem brain tissues from human patients with schizophrenia. Furthermore, activity-dependent maturation of SREBP1 as well as ARC expression were attenuated in dysbindin-1 knockout mice, and these deficits were restored by an atypical antipsychotic drug, clozapine. Together, results indicate an important role of dysbindin-1 in neuronal activity induced SREBP1 and ARC, which could be related to cognitive deficits in schizophrenia.

Lysosomal iron modulates NMDA receptor-mediated excitation via small GTPase, Dexras1.

BACKGROUND: Activation of NMDA receptors can induce iron movement into neurons by the small GTPase Dexras1 via the divalent metal transporter 1 (DMT1). This pathway under pathological conditions such as NMDA excitotoxicity contributes to metal-catalyzed reactive oxygen species (ROS) generation and neuronal cell death, and yet its physiological role is not well understood. RESULTS: We found that genetic and pharmacological ablation of this neuronal iron pathway in the mice increased glutamatergic transmission. Voltage sensitive dye imaging of hippocampal slices and whole-cell patch clamping of synaptic currents, indicated that the increase in excitability was due to synaptic modification of NMDA receptor activity via modulation of the PKC/Src/NR2A pathway. Moreover, we identified that lysosomal iron serves as a main source for intracellular iron signaling modulating glutamatergic excitability. CONCLUSIONS: Our data indicates that intracellular iron is dynamically regulated in the neurons and robustly modulate synaptic excitability under physiological condition. Since NMDA receptors play a central role in synaptic neurophysiology, plasticity, neuronal homeostasis, neurodevelopment as well as in the neurobiology of many diseases, endogenous iron is therefore likely to have functional relevance to each of these areas.

EEG biomarkers of target engagement, therapeutic effect, and disease process.

Studies suggest that abnormalities in glutamate and GABA signaling contribute to deficits in schizophrenia and related conditions and that these neurochemical abnormalities produce changes in electroencephalographic (EEG) indices, including event-related potentials and event-related power within specific frequency ranges. Furthermore, clinical studies suggest that a subset of EEG biomarkers is associated with symptoms. This review addresses the relationship between EEG and behavior in preclinical models of N-methyl-d-aspartate (NMDA)-receptor hypofunction, as well as how these models can be used to screen therapies. Data from schizophrenia patients are juxtaposed with data from animal models, and EEG and behavioral data from mice with disruption of NMDA receptors in excitatory and/or inhibitory neurons are then compared to the pattern observed in schizophrenia. Also discussed are results following exposure to potential therapeutic agents, including GABAB agonists. Furthermore, evidence demonstrates that elevated resting gamma power is associated with deficits in social interactions. Consistent with elevated baseline noise, excitatory neurons from transgenic mice show increased intrinsic excitability in in vitro-slice patch-clamp studies across model systems. GABAB receptor agonists reduce this excitability, improve gamma-band responses, and reverse behavioral deficits in mice. Data suggest that baseline gamma power is associated with social function and GABAB agonists may be useful for schizophrenia. Translational EEG biomarkers reflect target engagement and can contribute to the design of more efficient drug trials, likely accelerating the development of new therapeutics for central nervous system disorders.