Melbourne Veterinary School - Research Publications
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ItemCholinergic connectivity: it's implications for psychiatric disorders(FRONTIERS MEDIA SA, 2013-05-03)Acetylcholine has been implicated in both the pathophysiology and treatment of a number of psychiatric disorders, with most of the data related to its role and therapeutic potential focusing on schizophrenia. However, there is little thought given to the consequences of the documented changes in the cholinergic system and how they may affect the functioning of the brain. This review looks at the cholinergic system and its interactions with the intrinsic neurotransmitters glutamate and gamma-amino butyric acid as well as those with the projection neurotransmitters most implicated in the pathophysiologies of psychiatric disorders; dopamine and serotonin. In addition, with the recent focus on the role of factors normally associated with inflammation in the pathophysiologies of psychiatric disorders, links between the cholinergic system and these factors will also be examined. These interfaces are put into context, primarily for schizophrenia, by looking at the changes in each of these systems in the disorder and exploring, theoretically, whether the changes are interconnected with those seen in the cholinergic system. Thus, this review will provide a comprehensive overview of the connectivity between the cholinergic system and some of the major areas of research into the pathophysiologies of psychiatric disorders, resulting in a critical appraisal of the potential outcomes of a dysregulated central cholinergic system.
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ItemPotential Molecular and Cellular Mechanism of Psychotropic Drugs(KOREAN COLL NEUROPSYCHOPHARMACOLOGY, 2014-08)Psychiatric disorders are among the most debilitating of all medical illnesses. Whilst there are drugs that can be used to treat these disorders, they give sub-optimal recovery in many people and a significant number of individuals do not respond to any treatments and remain treatment resistant. Surprisingly, the mechanism by which psychotropic drugs cause their therapeutic benefits remain unknown but likely involves the underlying molecular pathways affected by the drugs. Hence, in this review, we have focused on recent findings on the molecular mechanism affected by antipsychotic, mood stabilizing and antidepressant drugs at the levels of epigenetics, intracellular signalling cascades and microRNAs. We posit that understanding these important interactions will result in a better understanding of how these drugs act which in turn may aid in considering how to develop drugs with better efficacy or increased therapeutic reach.
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ItemDifferent changes in cortical tumor necrosis factor-α-related pathways in schizophrenia and mood disorders(NATURE PUBLISHING GROUP, 2013-07)The growing body of evidence implicating tumor necrosis factor-α (TNFα) in the pathophysiology of psychiatric disorders led us to measure levels of that protein in the cortex of subjects with major depressive disorders (MDD). Having reported an increase (458%) in the levels of the transmembrane (tmTNFα), but not the soluble (sTNFα), form of the protein in Brodmann's area (BA) 46, but not 24, in people with the disorder, we decided to examine additional components of TNFα-related pathways in the same regions in people with MDD and extend our studies to the same cortical regions of people with schizophrenia (Sz) and bipolar disorders (BD). Using postmortem tissue, western blots and quantitative PCR, we have now shown there is a significant increase (305%) in tmTNFα in Brodmann's area 24, but not 46, from subjects with BD, and that levels of the protein were not altered in Sz. Levels of sTNFα were not altered in BD or Sz. In addition, we have shown that levels of TNF receptor 1 (TNFR1) mRNA are increased in BA 24 (53%) and BA 46 (82%) in people with Sz, whereas levels of TNFR2 mRNA was decreased in BA 46 in people with mood disorders (MDD=-51%; BD=-67%). Levels of proteins frequently used as surrogate markers of neuronal, astrocytic and microglia numbers, as well as levels of the pro-inflammatory marker (interleukin 1β), were not changed in the cortex of people with mood disorders. Our data suggest there are differential changes in TNFα-related markers in the cortex of people with MDD, BD and Sz that may not be related to classical inflammation and may cause changes in different TNFα-related signaling pathways.
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ItemCholinergic muscarinic M4 receptor gene polymorphisms: A potential risk factor and pharmacogenomic marker for schizophrenia(ELSEVIER, 2013-05)Although schizophrenia is a widespread disorder of unknown aetiology, we have previously shown that muscarinic M4 receptor (CHRM4) expression is decreased in the hippocampus and caudate-putamen from subjects with the disorder, implicating the receptor in its pathophysiology. These findings led us to determine whether variation in the CHRM4 gene sequence was associated with an altered risk of schizophrenia by sequencing the CHRM4 gene from the brains of 76 people with the disorder and 74 people with no history of psychiatric disorders. In addition, because the CHRM4 is a potential target for antipsychotic drug development, we investigated whether variations in CHRM4 sequence were associated with final recorded doses of, and life-time exposure to, antipsychotic drugs. Gene sequencing identified two single nucleotide polymorphisms (SNPs; rs2067482 and rs72910092) in the CHRM4 gene. For rs2067482, our data suggested that both genotype (1341C/C; p = 0.05) and allele (C; p = 0.03) were associated with an increased risk of schizophrenia. In addition, there was a strong trend (p = 0.08) towards an association between CHRM4 sequence and increased lifetime exposure to antipsychotic drugs. Furthermore, there was a trend for people with the C allele to be prescribed benzodiazepines more frequently (p = 0.06) than those with the T allele. These data, albeit on small cohorts, are consistent with genetic variance at rs2067482 contributing to an altered risk of developing schizophrenia which requires more forceful pharmacotherapy to achieve a clinical response.
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ItemAn investigation of the factors that regulate muscarinic receptor expression in schizophrenia(ELSEVIER, 2014-09)We previously identified a group of subjects with schizophrenia who, on average, have a 75% decrease in cholinergic receptor, muscarinic 1 (CHRM1) in Brodmann's area (BA) 9. To extend this finding, we determined i) if the decrease in CHRM1 was present in another functionally related CNS region (BA6), ii) whether the marked decrease in CHRM1 was accompanied by changes in levels of other CHRMs and iii) potential factors responsible for the decreased CHRM1 expression. We measured CHRM1 and CHRM3 using in situ radioligand binding with [(3)H]pirenzepine and [(3)H]4-DAMP respectively in BA6 from 20 subjects with schizophrenia who had low levels of CHRM1 in BA9 (SzLow[(3)H]PZP), 18 subjects with schizophrenia whose levels of CHRM1 were similar to controls (SzNormal[(3)H]PZP) and 20 control subjects. Levels of CHRM1, 3 and 4 mRNA were measured using qPCR and levels of the transcription factors, SP1 and SP3, were determined using Western blots. In BA6, the density of [(3)H]pirenzepine binding was decreased in subjects with SzLow[(3)H]PZP (p<0.001) compared to controls. The density of [(3)H]4-DAMP binding, levels of CHRM1, 3 and 4 mRNA and levels of SP1 and SP3 was not significantly different between the three groups. This study shows that the previously identified decrease in CHRM1 expression is not confined to the dorsolateral prefrontal cortex but is present in other cortical areas. The effect shows some specificity to CHRM1, with no change in levels of binding to CHRM3. Furthermore, this decrease in CHRM1 does not appear to be associated with low levels of CHRM1 mRNA or to simply be regulated by the transcription factors, SP1 and SP3, suggesting that other mechanisms are responsible for the decreased CHRM1 in these subjects.