Dimethylated lysine 9 of histone 3 is elevated in schizophrenia and exhibits a divergent response to histone deacetylase inhibitors in lymphocyte cultures.

BACKGROUND: A restrictive chromatin state has been thought to be operant in the pathophysiology of schizophrenia. Our objective was to ascertain whether differences exist between baseline levels of a repressive chromatin mark such as dimethylated lysine 9 of histone 3 (H3K9me2) in patients with schizophrenia and healthy controls and whether a histone deacetylase (HDAC) inhibitor in an in vitro assay would differentially affect chromatin structure based on diagnosis. METHODS: We obtained blood samples from 19 healthy controls and 25 patients with schizophrenia and isolated their lymphocytes. We measured baseline H3K9me2 levels (normalized to total histone 1) in the lymphocytes from all participants via Western blot analysis. To examine the effects of an HDAC inhibitor on H3K9me2, we cultured the lymphocytes from participants with trichostatin A (TSA) for 24 hours and then measured changes in H3K9me2 relative to the control condition (dimethyl sulfoxide). RESULTS: Patients with schizophrenia had significantly higher mean baseline levels of H3K9me2 than healthy controls (6.52 v. 2.78, p = 0.028). Moreover, there was a significant negative correlation between age at onset of illness and levels of H3K9me2 (Spearman's rho = -0.588, p = 0.008). In the lymphocyte cultures, TSA induced divergent responses in terms of H3K9me2 levels from patients with schizophrenia compared with healthy controls (F(1,14) = 5.082, p = 0.041). LIMITATIONS: The use of lymphocytes to study schizophrenia has its limitations because they may not be appropriate models of synaptic activity or other brain-specific activities. CONCLUSION: Our results provide further evidence that schizophrenia is associated with a restrictive chromatin state that is also less modifiable using HDAC inhibitors.

The melatonin receptor MT1 is required for the differential regulatory actions of melatonin on neuronal 'clock' gene expression in striatal neurons in vitro.

Through inhibitory G protein-coupled melatonin receptors, melatonin regulates intracellular signaling systems and also the transcriptional activity of certain genes. Clock genes are proposed as regulatory factors in forming dopamine-related behaviors and mood and melatonin has the ability to regulate these processes. Melatonin-mediated changes in clock gene expression have been reported in brain regions, including the striatum, that are crucial for the development of dopaminergic behaviors and mood. However, it is not known whether melatonin receptors present in striatum mediate these effects. Therefore, we investigated the role of the melatonin/melatonin receptor system on clock gene expression using a model of primary neuronal cultures prepared from striatum. We found that melatonin at the receptor affinity range (i.e., nm) affects the expression of the clock genes mPer1, mClock, mBmal1 and mNPAS2 (neuronal PAS domain protein 2) differentially in a pertussis toxin-sensitive manner: a decrease in Per1 and Clock, an increase in NPAS2 and no change in Bmal1 expression. Furthermore, mutating MT1 melatonin receptor (i.e., MT1 knockouts, MT1(-/-)) reversed melatonin-induced changes, indicating the involvement of MT1 receptor in the regulatory action of melatonin on neuronal clock gene expression. Therefore, by controlling clock gene expression we propose melatonin receptors (i.e., MT1) as novel therapeutic targets for the pathobiologies of dopamine-related behaviors and mood.

Depolarization induces downregulation of DNMT1 and DNMT3a in primary cortical cultures.

DNA methylation in post-mitotic neurons is reported to serve a variety of functions from survival during development to the consolidation of memory. Of particular interest with regards neuronal functioning is the change in site-specific methylation of a variety of gene promoters in the context of neuronal depolarization and the coding of new information. We examined the expression of DNMT1 and DNMT3a, representative of a maintenance and de novo methyltransferase respectively, in response to in-vitro depolarization of cortical neurons, using standard techniques such as high potassium (KCl) or the sodium channel agonist veratridine. KCl and veratridine mediated depolarization caused a modest but significant and replicable reduction in the mRNA and protein expression of both DNMTs that was time and dose dependent. These effects were supported by parallel increases in the mRNA expression of BDNF exon-1 and exon-4 as a typical response of neurons to depolarization and to rule out the possibility of impaired transcriptional activity as a trivial explanation. In addition to effects on mRNA and protein expression, functional DNA methyltransferase activity was reduced in nuclear protein extracts from cells exposed to a depolarization condition. Also, these changes could not be explained by differential neuronal loss as measured by cell viability cytochemistry. Our results support the idea that a reduction in DNA methyltransferase activity in the activated and depolarized neuron could contribute to the enhanced intensity and multiplicity of gene expression frequently reported.