A research strategy directed toward identifying specific neurochemical markers operative in the etiopathology of psychotic disorders lead to the identification of a downregulation (30-50%) of Reln and glutamic acid decarboxylase 67(GAD67) expression in prefrontal cortex and other brain areas of schizoprenia and bipolar disorder patients with psychosis.
We propose an integrative model, with multiple molecular and cellular mechanisms contributing to transcriptional dysregulation of GAD67 and cortical dysfunction in psychosis.
Strong support for the use of imidazenil in psychosis emerges from experiments with reeler mice or with methionine-treated mice, which express a pronounced reelin and GAD(67) downregulation that is also operative in SZ and BP disorders.
RNA and DNA extracted from the saliva samples of patients with methamphetamine dependency with and without psychosis as well as control subjects (each group 25) were analyzed for expression and promoter DNA methylation status of DRD1, DRD2, DRD3, DRD4, MB-COMT, GAD1, and AKT1 using qRT-PCR and q-MSP, respectively.
This study indicates that genetic variability in GAD1 and GAD2 contributes to risk of METH dependence and METH psychosis in the Thai population and indicates the role of the GABAergic system in these disorders.
Studies on the 3-dimensional architecture of the GAD1 locus in neurons, including developmentally regulated higher order chromatin compromised by the disease process, together with exploration of locus-specific epigenetic interventions in animal models, could pave the way for future treatments of psychosis and schizophrenia.
While the current study provides information on GAD25 and GAD67 mRNA transcript levels in whole blood of FEP patients, further correlation and validation work between brain regions, cerebrospinal fluid and peripheral blood expression profiling are required to provide a better understanding of GAD25 and GAD67.