Low levels of muscarinic M1 receptor-positive neurons in cortical layers III and V in Brodmann areas 9 and 17 from individuals with schizophrenia.

BACKGROUND: Results of neuroimaging and postmortem studies suggest that people with schizophrenia may have lower levels of muscarinic M1 receptors (CHRM1) in the cortex, but not in the hippocampus or thalamus. Here, we use a novel immunohistochemical approach to better understand the likely cause of these low receptor levels. METHODS: We determined the distribution and number of CHRM1-positive (CHRM1+) neurons in the cortex, medial dorsal nucleus of the thalamus and regions of the hippocampus from controls (n = 12, 12 and 5, respectively) and people with schizophrenia (n = 24, 24 and 13, respectively). RESULTS: Compared with controls, levels of CHRM1+ neurons in people with schizophrenia were lower on pyramidal cells in layer III of Brodmann areas 9 (-44%) and 17 (-45%), and in layer V in Brodmann areas 9 (-45%) and 17 (-62%). We found no significant differences in the number of CHRM1+ neurons in the medial dorsal nucleus of the thalamus or in the hippocampus. LIMITATIONS: Although diagnostic cohort sizes were typical for this type of study, they were relatively small. As well, people with schizophrenia were treated with antipsychotic drugs before death. CONCLUSION: The loss of CHRM1+ pyramidal cells in the cortex of people with schizophrenia may underpin derangements in the cholinergic regulation of GABAergic activity in cortical layer III and in cortical/subcortical communication via pyramidal cells in layer V.

Low levels of muscarinic M1 receptor-positive neurons in cortical layers III and V in Brodmann areas 9 and 17 from individuals with schizophrenia.

BACKGROUND: Results of neuroimaging and postmortem studies suggest that people with schizophrenia may have lower levels of muscarinic M1 receptors (CHRM1) in the cortex, but not in the hippocampus or thalamus. Here, we use a novel immunohistochemical approach to better understand the likely cause of these low receptor levels. METHODS: We determined the distribution and number of CHRM1-positive (CHRM1+) neurons in the cortex, medial dorsal nucleus of the thalamus and regions of the hippocampus from controls (n = 12, 12 and 5, respectively) and people with schizophrenia (n = 24, 24 and 13, respectively). RESULTS: Compared with controls, levels of CHRM1+ neurons in people with schizophrenia were lower on pyramidal cells in layer III of Brodmann areas 9 (-44%) and 17 (-45%), and in layer V in Brodmann areas 9 (-45%) and 17 (-62%). We found no significant differences in the number of CHRM1+ neurons in the medial dorsal nucleus of the thalamus or in the hippocampus. LIMITATIONS: Although diagnostic cohort sizes were typical for this type of study, they were relatively small. As well, people with schizophrenia were treated with antipsychotic drugs before death. CONCLUSION: The loss of CHRM1+ pyramidal cells in the cortex of people with schizophrenia may underpin derangements in the cholinergic regulation of GABAergic activity in cortical layer III and in cortical/subcortical communication via pyramidal cells in layer V.

The distribution of muscarinic M1 receptors in the human hippocampus.

The muscarinic M1 receptor plays a significant role in cognition, probably by modulating information processing in key regions such as the hippocampus. To understand how the muscarinic M1 receptor achieves these functions in the hippocampus, it is critical to know the distribution of the receptor within this complex brain region. To date, there are limited data on the distribution of muscarinic M1 receptors in the human hippocampus which may also be confounded because some anti-muscarinic receptor antibodies have been shown to lack specificity. Initially, using Western blotting and immunohistochemistry, we showed the anti-muscarinic M1 receptor antibody to be used in our study bound to a single 62kDa protein that was absent in mice lacking the muscarinic M1 receptor gene. Then, using immunohistochemistry, we determined the distribution of muscarinic M1 receptors in human hippocampus from 10 subjects with no discernible history of a neurological or psychiatric disorder. Our data shows the muscarinic M1 receptor to be predominantly on pyramidal cells in the hippocampus. Muscarinic M1 receptor positive cells were most apparent in the deep polymorphic layer of the dentate gyrus, the pyramidal cell layer of cornu ammonis region 3, the cellular layers of the subiculum, layer II of the presubiculum and layer III and V of the parahippocampal gyrus. Positive cells were less numerous and less intensely stained in the pyramidal layer of cornu ammonis region 2 and were sparse in the molecular layer of the dentate gyrus as well as cornu ammonis region 1. Although immunoreactivity was present in the granular layer of the dentate gyrus, it was difficult to identity individual immunopositive cells, possibly due to the density of cells. This distribution of the muscarinic M1 receptors in human hippocampus, and its localisation on glutamatergic cells, would suggest the receptor has a significant role in modulating excitatory hippocampal neurotransmission.

The neuropsychiatric and neuropsychological features of chronic fatigue syndrome: revisiting the enigma.

The aim of this article is to provide a comprehensive and updated review of the key neuropsychiatric and neuropsychological complaints associated with chronic fatigue syndrome (CFS). Neuropsychiatric and neuropsychological difficulties are common in CFS and are linked primarily to disorders of mood, affect and behaviour. The neuropsychiatric complaint most frequently encountered amongst CFS patients is depression and in particular major depressive disorder (MDD). Despite decades of research, the precise aetiological relationship between CFS and MDD remains poorly understood. This has resulted in the development of a number of interesting and polarised hypotheses regarding the aetiological nature of CFS. Recent scientific advances have however begun to unravel a number of interesting inflammatory and immunological explanations that suggest CFS and MDD are distinct yet interrelated conditions. The possibility that the overlap between CFS and MDD might be explained in terms of shared oxidative and nitrosative (IO&NS) pathways is an area of intense research interest and is reviewed in detail in this article. The overlap between CFS and MDD is further differentiated by variations in HPA axis activity between the two disorders. Important immunological differences between MDD and CFS are also reviewed with particular emphasis on antiviral RNase L pathways in CFS. In addition to the presence of neuropsychiatric complaints, CFS is also associated with neuropsychological symptoms such as impaired attention, memory and reaction time. The key neuropsychological problems reported by CFS patients are also included in the review in an effort to understand the significance of cognitive impairment in CFS.

The spatial relationship between neurons and astrocytes in HIV-associated dementia.

Specific neuronal spatial distributional patterns have previously been correlated with increasing severity of HIV-associated dementia (HAD). As astrocytes are also a putative site of neurotoxicity, we investigated the spatial relationships of astrocytes with pyramidal and interneurons in the superior frontal gyrus from 29 patients who died from acquired immunodeficiency syndrome. Frontal cortical brain tissue was taken from diseased HIV patients who had been assessed for the presence and severity of HAD using the Memorial Sloan-Kettering Scale. No correlation was found between neuronal density and severity of dementia. However, the pattern of astrocytes became more clustered as dementia progressed. Bivariate spatial pattern analysis of neuronal populations with astrocytes revealed that, with increasing dementia severity, astrocytes and large pyramidal neurons increasingly "repelled" each other, while astrocytes and interneurons evidenced increasing "attraction." This implies that astrocytes may be more likely to be situated in the vicinity of surviving interneurons but less likely to be situated near surviving large pyramidal neurons in the setting of progressing HAD.

Suppression of human immunodeficiency virus replication in human brain tissue by nucleoside reverse transcriptase inhibitors.

Human immunodeficiency virus (HIV) infection of the brain is associated pathologically with neuronal damage and loss. Clinically cognitive impairments can develop, which in some can be improved by highly active antiretroviral therapy (HAART), whereas in others, the infection persists despite treatment. The efficacy of antiretrovirals to treat cognitive impairments may be related to their ability to suppress viral replication in the brain and also to prevent neurodegeneration. To investigate this question, the authors assessed the ability of stavudine (300 nM), zidovudine (2 nM), and abacavir (300 nM) to suppress viral replication in human brain tissue aggregates infected with HIV-1 SF162. Aggregates were cultured for 4 weeks and exposed to nucleoside reverse transcriptase inhibitors (NRTIs) either 24 h prior, simultaneously, or 24 h post infection. Viral replication was assessed by p24 enzyme-linked immunosorbent assay (ELISA) in culture medium. The authors observed a statistically significant reduction in the rate of viral replication for stavudine added 24 h prior to infection univariate analysis of variance ([UANOVA], t = 2.55, df = 17, P =.021). Decreased viral replication observed with zidovudine and abacavir was not statistically significant.

Interaction between HIV and intravenous heroin abuse?

In this article I will review the findings of the potential interactive effects of HIV infection and heroin use as observed in both clinical and laboratory studies. Some of the findings are discrepant and I will endeavour to propose models that could accommodate these variant results as well as suggest factors that could be considered in analysing future investigations in order to resolve these apparent discrepancies.

Assessing the efficacy of highly active antiretroviral therapy in the brain.

The devastating effects of HIV infection have been documented for the last 2 decades. Since the 1980s over 60 million people have been infected and at present 40 million people globally are living with HIV. HIV infects the central nervous system (CNS) early in the disease process. Indeed, numerous studies document the presence of HIV within the cerebrospinal fluid (CSF). Direct infection of the brain by HIV ultimately results in HIV associated dementia (HAD), which (prior to the advent of antiretroviral therapy) affected 20% of patients. An increasing number of drugs have been developed to treat this infection and delay the development of AIDS. Current treatment is aimed at inhibiting viral replication, and thus, lowering the viral load. However a subsequent increase in viral load can occur as patients become resistant to drug therapy. In the era of HAART, the incidence of HAD has been reduced, whereas the prevalence rate is increasing as people with HIV survive longer. However, in a study of initial AIDS defining illnesses, the proportion with HIV related dementia did not decline following introduction of HAART. In a separate study, no decrease was found in the incidence of dementia per se, although there was a decrease in the incidence of all AIDS-defining illnesses during this time period. It is evident from most studies that since the introduction of HAART, its effect on HAD is not entirely clear, although the majority of findings indicate that it is beneficial. Here we will outline the issues relevant to preventing HAD by HAART.