Lewy pathology in the submandibular gland of individuals with incidental Lewy body disease and sporadic Parkinson’s disease

A retrospective autopsy-based study of the human submandibular gland, one of the three major salivary glands, together with anatomically related peripheral structures (cervical superior ganglion, cervical sympathetic trunk, vagal nerve at the level of the carotid bifurcation), was conducted on a cohort consisting of 33 individuals, including 9 patients with neuropathologically confirmed Parkinson’s disease (PD), three individuals with incidental Lewy body disease (iLBD), 2 individuals with neuropathologically confirmed multiple system atrophy (MSA), and 19 controls, using α-synuclein immunohistochemistry in 100 μm polyethylene glycol-embedded tissue sections. Lewy pathology (LP) was present in the submandibular glands and cervical superior ganglia in PD (9/9 cases) and iLBD (2/3 cases) but not in MSA or controls. The cervical sympathetic trunk (7/9 PD cases, 2/3 iLBD cases) and peripheral vagal nerves (9/9 PD cases, 2/3 iLBD cases) also displayed LP. The results are discussed within the context of hyposmia as well as autonomic dysfunction in PD (sialorrhea, sialopenia, dysphagia). Potential disease-related changes in salivary volume, contents, and viscosity might make it possible, in combination with other tests, to employ human saliva as a biomarker.     

Sequestration of iron by Lewy bodies in Parkinson’s disease

Central to the oxidative stress hypothesis of Parkinson’s disease (PD) pathogenesis is the ability of iron to generate hydroxyl radicals via the Fenton reaction, and the consistent demonstration of iron elevation in the pars compacta region of the substantia nigra. However, uncertainty exists as to whether the excess iron exists in a state suitable for redox chemistry. Here, using a method we developed that detects redox-active iron in situ, we were able to demonstrate strong labeling of Lewy bodies in substantia nigra pars compacta neurons in PD. In contrast, cortical Lewy bodies in cases of Lewy body variant of Alzheimer’s disease were unstained. While the presence of elevated iron in PD substantiates the oxidative stress hypothesis, one must remember that these are viable neurons, indicating that Lewy bodies may act to sequester iron in PD brains in a protective, rather than degenerative, mechanism. The absence of redox-active iron in neocortical Lewy bodies highlights a fundamental difference between cortical and brain stem Lewy bodies. Received: 9 February 2000 / Revised: 31 March 2000 / Accepted: 2 April 2000     

CSF diagnosis of Alzheimer’s disease and dementia with Lewy bodies

Summary. Differential diagnosis of Alzheimer’s disease (AD) and dementia with Lewy bodies (DLB) is often crucial. CSF Tau protein and Amyloid-beta (Aβ) peptides have shown diagnostic value for the diagnosis of AD, but discrimination from DLB was poor. Herein, we investigate CSF of 18 patients with probable AD, 25 with probable DLB and 14 non-demented disease controls (NDC) by Aβ-SDS-PAGE/immunoblot and commercially available ELISAs for Aβ1-42 and tau. CSF Aβ peptide patterns and tau exhibited disease specific alterations among AD and DLB. The ratio of Aβ1-42 to Aβ1-38 and Aβ1-42 to Aβ1-37, respectively, in combination with absolute tau, yielded a sensitivity and specificity of 100 and 92%, respectively. We conclude that CSF Aβ peptide patterns and tau levels reflect disease-specific pathophysiological pathways of these dementias as distinct neurochemical phenotypes. Combined evaluation of these biomarkers provides a reasonable accuracy for differential diagnosis of AD and DLB.     

The role of α-synuclein assembly and metabolism in the pathogenesis of Lewy body disease

Parkinson’s disease (PD) and dementia with Lewy bodies (DLB) are members of a family of disorders characterized by the presence of inclusion bodies, or Lewy bodies (LBs), filled with aggregates of α-synuclein. These diseases are a leading cause of movement disorders and dementia in the aging population, and it is crucial to understand the factors leading to the accumulation and assembly of these α-synuclein aggregates. Previous studies have uncovered much about the factors leading to aggregation and the mechanisms causing neurotoxicity of these inclusion bodies; however, little is known about factors that promote the degradation and prevent the aggregation of α-synuclein. The present article provides a review of recent efforts in the investigation of factors involved in α-synuclein metabolism and the mechanisms involved in preventing accumulation of α-synuclein and degrading this molecule. Understanding these processes might provide targets for the development of novel therapies for disorders such as DLB and PD.     

Lewy body pathology in Alzheimer’s disease

Lewy bodies, the characteristic pathological lesion of substantia nigra neurons in Parkinson's disease (PD), are frequently observed to accompany the amyloid plaque and neurofibrillary tangle pathology of Alzheimer's disease (AD). However the typical anatomic distribution of Lewy bodies in AD is distinct from PD. The most common site of occurrence is the amygdala, where Lewy bodies are observed in approximately 60% of both sporadic and familial AD. Other common sites of occurrence include the periamygdaloid and entorhinal cortex, while neocortical and brainstem areas develop Lewy bodies in a lower percentage of cases. In contrast, dementia with Lewy bodies (DLB), defined by widespread neocortical and brainstem Lewy bodies but frequently accompanied by variable levels of AD-type pathology, represents the other end of a spectrum of pathology associated with dementia. The observation of Lewy bodies in familial AD cases suggests that like neurofibrillary tangles, the formation of Lewy bodies can be induced by the pathological state caused by Abeta-amyloid overproduction. The role of Lewy body formation in the dysfunction and degeneration of neurons remains unclear. The protein alpha-synuclein appears to be an important structural component of Lewy bodies, an observation spurred by the discovery of point mutations in the alpha-synuclein gene linked to rare cases of autosomal dominant PD. Further investigation of alpha-synuclein and its relationship to pathological conditions promoting Lewy body formation in AD, PD, and DLB may yield further insight into pathogenesis of these diseases.     

Evidence that incidental Lewy body disease is pre-symptomatic Parkinson’s disease

Lewy bodies, the histologic hallmark of Parkinson’s disease (PD), are detected in the brains of about 10% of clinically normal people over the age of 60 years. When Lewy bodies are found in normal individuals, the process is sometimes referred to as incidental Lewy body disease (iLBD). The distribution of Lewy bodies in iLBD is similar to the distribution in PD, but neuronal populations vulnerable to Lewy bodies do not show significant neuronal loss in iLBD. It remains unknown if Lewy bodies in this setting represent pre-symptomatic PD or an age-related change unrelated to PD. To address this question we identified cases of iLBD and used a marker for dopaminergic and noradrenergic neurons, tyrosine hydroxylase (TH), to determine if there were changes similar to those found in PD. TH immunoreactivity in the striatum and the epicardial nerve fibers was decreased in iLBD compared to normal controls, but not to the same extent as in PD. The findings suggest that iLBD is preclinical PD and that the lack of symptoms is due to subthreshold pathology.     

Effect of topographical distribution of α-synuclein pathology on TDP-43 accumulation in Lewy body disease

It has been reported that the development of TDP-43 pathology in cases of Lewy body disease (LBD) might be associated with the severity of tau pathology. However, the impact of α-synuclein pathology on TDP-43 accumulation in LBD remains unclear. To clarify whether α-synuclein pathology has an effect on TDP-43 accumulation, independent of tau pathology, we examined by immunohistochemistry 56 cases of LBD using a phosphorylation-dependent TDP-43 antibody. The frequency of TDP-43 pathology in all LBD cases was 18% (10/56). In 37 LBD cases with no or low tau burden (LBD-Ltau; Braak NFT stages 0-II), the frequency of TDP-43 pathology was 19% (7/37). The frequency of TDP-43 pathology in diffuse neocortical type LBD-Ltau cases was 36% (4/11), which was higher than those in limbic and brain stem-predominant types (11–14%). The amygdala and entorhinal cortex were the most frequently affected sites of TDP-43 pathology in LBD-Ltau cases. In LBD-Ltau cases, the proportion of diffuse neocortical type LBD was higher in the TDP-43-positive cases, than that in TDP-43-negative cases (57 vs. 23%). In all LBD cases, α-synuclein pathology in the temporal cortex was significantly more severe in TDP-43-positive cases, and significantly correlated with the severity of TDP-43 pathology in the amygdala. In a multivariate model, the presence of severe α-synuclein pathology was significantly associated with the development of TDP-43 pathology independent of age at death and tau pathology. In the amygdala, TDP-43 was often colocalized with α-synuclein or tau. Given these findings, we suggest that α-synuclein pathology is associated with TDP-43 accumulation in LBD cases.     

Diffuse Lewy body disease - a clinical syndrome or a disease entity?

Most clinicians and researchers still accept diffuse Lewy body disease (DLBD) as a clinicopathological entity. Dementia with fluctuating cognitive deficits, a parkinsonian syndrome, and visual hallucinations are the core symptoms of this proposed disease entity. From a neuropathological point of view, many examples of patients with progressive dementia showing evidence of extensive Lewy body formation in the cerebral cortex together with the occurrence of Lewy bodies in substantia nigra and locus coeruleus have been identified. Confusingly, a large majority of cases showing typical features of DLBD also present with an Alzheimer pathology in the hippocampus and cerebral cortex. It is far from clear that DLBD represents a specific disease entity rather an intermediate variant between Alzheimer disease and idiopathic parkinsonian syndromes. Nevertheless, from a clinical point of view it may be of importance to characterize patients with a symptomatology of DLBD because important management issues such as avoidance of severe neuroleptic sensitivity reactions, dopaminergic antiparkinsonian treatment and a beneficial response to cholinesterase inhibitors can be applied.     

Pathological entity of dementia with Lewy bodies and its differentiation from Alzheimer’s disease

We reclassified the pathological subtypes of dementia with Lewy bodies (DLB), based on both Lewy pathology and Alzheimer pathology, to clarify the pathological entity of DLB and the boundary between DLB and Alzheimers disease (AD) in autopsied cases, using both pathological and immunohistochemical methods. DLB was classified as either limbic type or neocortical type according to the degree of Lewy pathology including Lewy bodies (LB) and LB-related neurites by our staging, and was classified as pure form, common form or AD form according to the degree of Alzheimer pathology including neurofibrillary tangles (NFT) and amyloid deposits by Braak staging. These combined subtypes were lined up on a spectrum, not only with Lewy pathology but also with other DLB-related pathologies including Alzheimer pathology, neuronal loss in the substantia nigra, spongiform change in the transentorhinal cortex and LB-related neurites in the CA2–3 region. In contrast, the Lewy pathology of AD did not meet the stages of Lewy pathology in DLB, and there were scarcely any similarities in other DLB-related pathologies between AD and DLB. In addition, the Lewy pathology of AD had characteristics different from that of DLB, including the coexistence rate of LB with NFT, and the immunohistochemical and immunoelectron microscopic findings of LB and LB-related neurites. These findings suggest that DLB is a distinctive pathological entity that can be differentiated from AD, although it shows some pathological subtypes.     

Parkinson's disease dementia: what's in a Lewy body?

This brief review deals with pathological aspects of dementia associated with Parkinson's disease (PDD). PDD has been variably linked with cortical Lewy body topography and density. alpha-Synuclein and Alzheimer-type pathology frequently co-exist, suggesting that a combination of pathology related to protein dysmetabolism, possibly with synergistic protein-protein interaction, underpins the cognitive impairment in PDD. Dementia may therefore ensue when a "toxic threshold" is reached, irrespective of the combination of pathologies involved in reaching that threshold. The nature of this putative protein-protein interaction needs to be further elucidated, and also whether there are specific clinical correlates of the pathological substrate. Serum and cerebrospinal fluid proteins or imaging techniques may be useful in future as biomarkers to identify the relative contribution of Lewy-related and Alzheimer-type pathology in a given case of PDD and to inform the rational use of drugs that can reduce alpha-synuclein aggregation and beta-amyloid production.     

Atrophy of the cholinergic basal forebrain in dementia with Lewy bodies and Alzheimer’s disease dementia

Similar to Alzheimer’s disease (AD), dementia with Lewy bodies (DLB) is characterized by a profound degeneration of cortically-projecting cholinergic neurons of the basal forebrain (BF) and associated depletion of cortical cholinergic activity. We aimed to investigate subregional atrophy of the BF in DLB in vivo and compare it to the pattern of BF atrophy in AD. Structural MRI scans of 11 patients with DLB, 11 patients with Alzheimer’s disease, and 22 healthy controls were analysed using a recently developed technique for automated BF morphometry based on high-dimensional image warping and cytoarchitectonic maps of BF cholinergic nuclei. For comparison, hippocampus volume was assessed within the same morphometric framework using recently published consensus criteria for the definition of hippocampus outlines on MRI. The DLB group demonstrated pronounced and subregion-specific atrophy of the BF which was comparable to BF atrophy in AD: volume of the nucleus basalis Meynert was significantly reduced by 20–25 %, whereas rostral BF nuclei were only marginally affected. By contrast, hippocampus volume was markedly less affected in DLB compared to AD. Global cognition as determined by MMSE score was associated with BF volume in AD, but not in DLB, whereas visuoperceptual function as determined by the trail making test was associated with BF volume in DLB, but not in AD. DLB may be characterized by a more selective degeneration of the cholinergic BF compared to AD, which may be related to the differential cognitive profiles in both conditions.     

Follow-up investigations in cerebrospinal fluid of patients with dementia with Lewy bodies and Alzheimer’s disease

Summary. Measuring proteins in cerebrospinal fluid (CSF) has gained wide acceptance for the differential diagnosis of dementia. Some groups have already extended these investigations in Alzheimers disease (AD) by asking how stable these markers are in follow-up analysis, if they depend on the stage of disease and whether they can be used to monitor the progression and biological effects of treatment. We evaluated 21 patients with dementia with Lewy bodies (DLB) and 19 patients with AD, on two occasions, with regard to levels of tau protein, tau protein phosphorylated at threonine 181 (p-tau), A42, A40 and S-100B protein, using a set of commercially available assays.Tau protein levels were lower in DLB in first and second LP compared to AD and decreased during course of both groups. P-tau levels were increased in AD and DLB and decreased during follow-up. A42 and A40 remained relatively stable during follow-up but we found a slight increase of the median A42 level in DLB, whereas in AD, A42 tends to decrease during follow-up. S-100B protein increased during follow-up in both diseases.The protein dynamics in DLB and AD are relatively similar. S-100B protein may be a useful marker for follow-up in neurodegenerative diseases but has to be analysed in longer follow-up periods. Tau protein may be used to differentiate between DLB and AD.Follow-up CSF analyses are of limited value for the differentiation of AD and DLB. We conclude that more specific markers have to be established for the differentiation and follow-up of these diseases.     

The synaptic pathology of α-synuclein aggregation in dementia with Lewy bodies, Parkinson’s disease and Parkinson’s disease dementia

Parkinson’s disease (PD) and dementia with Lewy bodies (DLB) are usually associated with loss of dopaminergic neurons. Loss of substantia nigra neurons and presence of Lewy body inclusions in some of the remaining neurons are the hallmark pathology seen in the final stages of the disease. Attempts to correlate Lewy body pathology to either cell death or severity of clinical symptoms, however, have not been successful. While the pathophysiology of the neurodegenerative process can hardly be explained by Lewy bodies, the clinical symptoms do indicate a degenerative process located at the presynapse resulting in a neurotransmitter deficiency. Recently it was shown that 90% or even more of α-synuclein aggregates in DLB cases were located at the presynapses in the form of very small deposits. In parallel, dendritic spines are retracted, whereas the presynapses are relatively preserved, suggesting a neurotransmitter deprivation. The same α-synuclein pathology can be demonstrated for PD. These findings give rise to the notion that not cell death but rather α-synuclein aggregate-related synaptic dysfunction causes the neurodegeneration. This opens new perspectives for understanding PD and DLB. If presynaptic α-synuclein aggregation, not neuronal loss, is the key issue of the neurodegenerative process, then PD and DLB may eventually be treatable in the future. The disease may progress via trans-synaptical spread, suggesting that stem cell transplants are of limited use. Future therapies may focus on the regeneration of synapses.     

Eyelid retraction in dementia with Lewy bodies and Parkinson’s disease

Journal of Neurology -     

Neuronal pentraxin II is highly upregulated in Parkinson’s disease and a novel component of Lewy bodies

Neuronal pentraxin II (NPTX2) is the most highly upregulated gene in the Parkinsonian substantia nigra based on our whole genome expression profiling results. We show here that it is a novel component of Lewy bodies and Lewy neurites in sporadic Parkinson’s disease (PD). NPTX2 is also known as the neuronal activity-regulated protein (Narp), which is secreted and involved in long-term neuronal plasticity. Narp further regulates AMPA receptors which have been found to mediate highly selective non-apoptotic cell death of dopaminergic neurons. NPTX2/Narp is found in close association with alpha-synuclein aggregates in both substantia nigra and cerebral cortex in PD but unlike alpha-synuclein gene expression, which is down-regulated in the Parkinsonian nigra, NPTX2 could represent a driver of the disease process. In view of its profound (>800%) upregulation and its established role in synaptic plasticity as well as dopaminergic nerve cell death, NPTX2 is a very interesting novel player which is likely to be involved in the pathway dysregulation which underlies PD. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users. This work was supported by the Parkinson’s Disease Society of the UK.     

Can alzheimer's disease and dementias with Lewy bodies be distinguished clinically?

To determine if Alzheimer's disease (AD), its Lewy body (LB) variant (LBV), and diffuse LB disease (DLBD) are distinguishable at initial clinical evaluation, data from autopsy-confirmed AD, LBV, and DLBD were examined. No significant differences were found in age at onset, age at death, total duration of illness, duration of illness before initial visit, duration of illness from initial visit to death, or severity of illness at initial evaluation. Hallucinations and delusions were significantly more frequent for LBV and DLBD, respectively, than for AD, and falls were more frequent for DLBD than for AD. Extrapyramidal symptoms (EPS) were less frequent in neuroleptic-free AD subjects than in LB subjects; the percentage of AD patients with EPS after neuroleptic exposure was less than that among LB patients. Seizures were significantly more common for DLBD than for AD or LBV. LB dementias differed from AD at initial evaluation, with more frequent hallucinations and delusions, EPSs, and seizures, and longitudinally in neuroleptic sensitivity, but the data did not distinguish LBV from DLBD.     

The role of α-synuclein gene multiplications in early-onset Parkinson’s disease and dementia with Lewy bodies

Summary. Background: A triplication of the α-synuclein gene was found to cause autosomal dominant Lewy body disease in two distinct families. Method: We searched for alterations of α-synuclein gene dosage and analysed the entire coding region for point mutations in 54 dementia with Lewy body disease (DLB) and in 103 young onset Parkinson’s disease (PD) patients from Central Europe. Results: We could not detect any quantitative alterations in the gene dosage of α-synuclein. Mutational screening of the entire coding region of α-synuclein revealed only one silent mutation V3V (adenine9guanine) in one case. Conclusions: Thus, this phenomenon appears not to be a major cause in the pathogenesis of sporadic DLB and young onset PD in this European population.