Concentrations of toxic metals and essential trace elements vary among individual neurons in the human locus ceruleus.

OBJECTIVE: Damage to locus ceruleus neurons could play a part in the pathogenesis of neurodegenerative disorders such as Alzheimer's disease, Parkinson's disease, and multiple sclerosis because of impairment of the blood-brain barrier and enhanced neuroinflammation. The locus ceruleus has connections throughout the brain and spinal cord, so the characteristic widespread multifocal pathology in these disorders could be due to damage to different subsets of locus ceruleus neurons. Previous studies have shown that only certain locus ceruleus neurons accumulate the neurotoxic metal mercury. To find out if concentrations of other toxic metals or of essential trace elements also vary between individual locus ceruleus neurons, we used synchrotron X-ray fluorescence microscopy on frozen sections of locus ceruleus neurons taken from people with multiple sclerosis, in whom the locus ceruleus is structurally intact. MATERIALS AND METHODS: Paraffin embedded sections containing the locus ceruleus from seven people with multiple sclerosis were stained with autometallography that demonstrates accumulations of mercury, silver and bismuth. These were compared to maps of multiple elements obtained from frozen sections of locus ceruleus neurons from the same people using X-ray fluorescence microscopy. Neurons in the anterior pons from three of these donors were used as internal controls. RESULTS: Autometallography staining was observed in scattered locus ceruleus neurons from three of the seven donors. X-ray fluorescence microscopy showed variations among individual locus ceruleus neurons in levels of mercury, selenium, iron, copper, lead, bromine, and rubidium. Variations between donors of locus ceruleus neuronal average levels of mercury, iron, copper, and bromine were also detected. Anterior pons neurons contained no mercury, had varied levels of iron, and had lower copper levels than locus ceruleus neurons. CONCLUSIONS: Individual human locus ceruleus neurons contain varying levels of toxic metals and essential trace elements. In contrast, most toxic metals are absent or at low levels in nearby anterior pons neurons. The locus ceruleus plays a role in numerous central nervous system functions, including maintaining the blood-brain-barrier and limiting neuroinflammation. Toxic metals, or alterations in essential trace metals within individual locus ceruleus neurons, could be one factor determining the non-random destruction of locus ceruleus neurons in normal aging and neurodegenerative diseases, and subsequently the sites of the widespread multifocal central nervous system pathology in these disorders.

Striatal ß-amyloid in dementia with Lewy bodies but not Parkinson's disease.

Professor Jellinger first identified that striatal Aß deposition at postmortem seemed to differentiate cases of dementia with Lewy bodies (DLB) from those with Parkinson's disease dementia (PDD), a finding subsequently questioned. Our replication study in 34 prospectively studied cases assessed the ability of striatal Aß deposition to differentiate DLB from PDD, and also assessed the relationship between striatal and cortical Aß deposition and α-synuclein-immunoreactive pathologies, using previously published protocols. Cases with DLB had significantly shorter durations and greater dementia severities compared with cases with PDD. Striatal Aß-immunoreactive plaques were only consistently found in cases with DLB and correlated with both the severity (positive correlation) and duration (negative correlation) of dementia. Striatal Aß-immunoreactive plaques also positively correlated with the severity of α-synuclein-immunoreactive pathologies as well as cortical Aß-positive plaques. Striatal Aß deposition positively predicted dementia in Lewy body cases with high specificity and had the greatest sensitivity to differentiate DLB from PDD with 100% negative predictive value. These data suggest that striatal Aß deposition in Lewy body diseases contributes to early dementia and in these cases may impact on the efficacy of treatments targeting the striatum.

Selection of reference gene expression in a schizophrenia brain cohort.

OBJECTIVE: In order to conduct postmortem human brain research into the neuropatho-logical basis of schizophrenia, it is critical to establish cohorts that are well-characterized and well-matched. The aim of the present study was therefore to determine if specimen characteristics including: diagnosis, age, postmortem interval (PMI), brain acidity (pH), and/or the agonal state of the subject at death related to RNA quality, and to determine the most appropriate reference gene mRNAs. METHODS: A matched cohort was selected of 74 subjects (schizophrenia/schizoaffective disorder, n = 37; controls, n = 37). Middle frontal gyrus tissue was pulverized, tissue pH was measured, RNA isolated for cDNA from each case, and RNA integrity number (RIN) measurements were assessed. Using quantitative reverse transcription-polymerase chain reaction, nine housekeeper genes were measured and a geomean calculated per case in each diagnostic group. RESULTS: The RINs were very good (mean = 7.3) and all nine housekeeper control genes were significantly correlated with RIN. Seven of nine housekeeper genes were also correlated with pH; two clinical variables, agonal state and duration of illness, did have an effect on some control mRNAs. No major impact of PMI or freezer time on housekeeper mRNAs was detected. The results show that people with schizophrenia had significantly less PPIA and SDHA mRNA and tended to have less GUSB and B2M mRNA, suggesting that these control genes may not be good candidates for normalization. CONCLUSIONS: In the present cohort <10% variability in RINs was detected and the diagnostic groups were well matched overall. The cohort was adequately powered (0.80-0.90) to detect mRNA differences (25%) due to disease. The study suggests that multiple factors should be considered in mRNA expression studies of human brain tissues. When schizophrenia cases are adequately matched to control cases subtle differences in gene expression can be reliably detected.

Anticipation of onset age in familial Parkinson's disease without SCA gene mutations.

Assessment of a series of 279 cases with Lewy body disease revealed 14 families having a family history consistent with autosomal dominant inheritance, eight of these with dominant Parkinsonism and six with dominant dementia. Analysis of the age at onset and genetic features in these families revealed significant anticipation only in a subset of parkinsonian families, with no pathological alleles for spinocerebellar ataxias or the common alpha-synuclein or LRRK2 point mutations.

Identification of families with cortical Lewy body disease.

Until recently, cortical Lewy body disease (CLB) was considered essentially the same as dementia with Lewy bodies (DLB). It is now known patients with Parkinson's disease (PD) with a later-onset dementia (PD-dementia) have the same pattern and extent of cortical Lewy body pathology. Inheritance patterns of CLB have not been evaluated previously. To identify genetic influence on CLB, all cases with this pathology need to be considered. We selected 180 cases meeting clinical and/or pathological criteria for DLB or PD (+/-dementia) from two patient groups: a PD and PD-dementia brain donor program, and a case-control study of Alzheimer's disease (AD). Cases meeting NINCDS-ADRDA criteria for probable AD were excluded and non-demented PD cases used as a comparison group. A detailed family history was taken analyzing onset and progression of dementia and PD phenotypes and a family tree constructed. The frequency of a positive family history of dementia and/or PD and risk of developing CLB in relatives was calculated. Fifty-five percent of dementia and 52% of PD cohorts did not have relatives with clinical disease. There was no increased frequency of familial disease in the CLB cohort compared with PD. However, in half the CLB families, rather than a dominant dementia, the clinical presentation varied (dementia and/or PD). Unlike PD, there was an increased risk of dementia if CLB was present in a parent ( approximately 20% risk) compared with another family member ( approximately 5% risk), suggesting CLB is more likely than PD to occur in a pattern consistent with autosomal dominant inheritance.

Disruption of frontocerebellar circuitry and function in alcoholism.

This article represents a symposium of the 2002 joint meeting of RSA and ISBRA held in San Francisco. Presentations were Neuropathology of alcohol-related cerebellar damage in humans, by Antony J. Harding; Neuropathological evidence of cerebellar damage in an animal model of alcoholism, by Roberta Pentney and Cynthia Dlugos; Understanding cortical-cerebellar circuits through neuroimaging study of chronic alcoholics, by Peter R. Martin and Mitchell H. Parks; and Functional reorganization of the brain in alcoholism: neuroimaging evidence, by John E. Desmond, S.H. Annabel Chen, Michelle R. Pryor, Eve De Rosa, Adolf Pfefferbaum, and Edith V. Sullivan.

Clinical correlates of selective pathology in the amygdala of patients with Parkinson's disease.

The amygdala exhibits significant pathological changes in Parkinson's disease, including atrophy and Lewy body (LB) formation. Amygdala pathology has been suggested to contribute to some clinical features of Parkinson's disease, including deficits of olfaction and facial expression. The degree of neuronal loss in amygdala subnuclei and the relationship with LB formation in non-demented Parkinson's disease cases have not been examined previously. Using stereological methods, the volume of neurones and the number of neurones in amygdala subdivisions were estimated in 18 prospectively studied, non-demented patients with Parkinson's disease and 16 age- and sex-matched controls. Careful exclusion (all cortical disease) and inclusion (non-demented, levodopa-responsive, idiopathic Parkinson's disease or controls) criteria were applied. Seven Parkinson's disease cases experienced well-formed visual hallucinations many years after disease onset, while nine Parkinson's disease cases and three controls were treated for depression. Anatomically, the amygdala was subdivided into the lateral nucleus, the basal (basolateral and basomedial) nuclei and the corticomedial (central, medial and cortical nuclei) complex. LB and Lewy neurites were identified by immunohistochemistry for alpha-synuclein and ubiquitin and were assessed semiquantitatively. LB were found throughout the amygdala in Parkinson's disease, being present in approximately 4% of neurones. Total amygdala volume was reduced by 20% in Parkinson's disease (P = 0.02) and LB concentrated in the cortical and basolateral nuclei. Lewy neurites were present in most cases but did not correlate with any structural or functional variable. Amygdala volume loss was largely due to a 30% reduction in volume (P = 0.01) and the total estimated number of neurones (P = 0.007) in the corticomedial complex. The degree of neurone loss and the proportion of LB-containing neurones in the cortical nucleus within this complex were constant across Parkinson's disease cases and neither variable was related to disease duration (R(2 )< 0.03; P > 0.5). The cortical nucleus has major olfactory connections and its degeneration is likely to contribute to the early selective anosmia common in Parkinson's disease. There was a small reduction in neuronal density in the basolateral nucleus in all Parkinson's disease cases, but no consistent volume or cell loss within this region. However, the proportion of LB-containing neurones in the basolateral nucleus was nearly doubled in cases that exhibited visual hallucinations, suggesting that neuronal dysfunction in this nucleus contributes to this late clinical feature. Detailed quantitation of the other amygdala subdivisions failed to reveal any other substantial anomalies or any associations with depression. Thus, the impact of Parkinson's disease on the amygdala is highly selective and correlates with both early and late clinical features.

Neuron loss from the hippocampus of Alzheimer's disease exceeds extracellular neurofibrillary tangle formation.

Neurofibrillary tangle (NFT) formation in the CA1 region of the hippocampus is one of the early events in the pathogenesis of Alzheimer's disease (AD). As the disease progresses more NFTs form and there is substantial neuron loss. In this study we investigated whether NFT formation accounts for all the CA1 pyramidal neuron loss seen in AD. Using unbiased stereological techniques, we estimated the total number of neurons and the number of intra- and extra-cellular NFTs in the hippocampus of 10 patients with AD and 10 age-matched controls. Marked neuronal loss (approximately 60%) was identified in AD, although NFTs accounted for only a small proportion of this loss (2.2-17.2%, mean 8.1%). Analysis of NFT accumulation with duration of dementia showed a linear relationship, supporting the belief that NFTs progressively accumulate with time.

Selective hippocampal neuron loss in dementia with Lewy bodies.

Hippocampal volume and neuron number were measured using stereological techniques in pathologically confirmed dementia with Lewy bodies (n = 8), Parkinson's disease only (n = 4), and controls (n = 9). We, and others, have previously shown considerable cell loss in the CA1 and subiculum subregions in Alzheimer's disease. In contrast, these regions were spared in dementia with Lewy bodies where a selective loss of lower presubiculum pyramidal neurons was found. These findings suggest a selective loss of frontally projecting hippocampal neurons in dementia with Lewy bodies versus those projecting to temporal lobe regions in Alzheimer's disease.