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Folia Neuropathologica
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vol. 48
 
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Case report
Dementia means number of things – the overlap of neurodegeneration with brain iron accumulation (NBIA) and Alzheimer changes: an autopsy case

Dorota Dziewulska
,
Izabela Domitrz
,
Anna Domżał-Stryga

Folia Neuropathologica 2010; 48 (2): 129-133
Online publish date: 2010/07/01
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- Dementia means.pdf  [0.09 MB]
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Introduction

Neurodegeneration with brain iron accumulation (NBIA) (former Hallervorden-Spatz syndrome) comprises a clinically and genetically heterogeneous collection of disorders that share common key feature – iron storage in the basal ganglia. For decades, regardless of marked clinical heterogeneity, most patients with radiographic or pathologic evidence of iron accumulation in brain were given this diagnosis. In recent years introduction of ge­netic examination allowed to reclassificate this group of disorders due to various genetic mutations [6]:
1) autosomal recessive panthotenate kinase-associa-ted neurodegeneration (PKAN) caused by mutations in gene encoding pantothenate kinase 2,
2) autosomal recessive aceruloplasminemia due to mutations in ceruloplasmin gene,
3) cases with mutations in gene encoding phospholipase A2,
4) autosomal dominant neuroferritinopathy due to mutations in gene encoding the ferritin light chain (NBIA-2),
5) sporadic cases of the CNS degeneration with iron accumulation in which genetic background has not been identified (NBIA-1). These cases account for 75% of all cases of NBIA [15].
Similarity of NBIA clinical picture to symptoms and signs present in other neurodegenerative dis- eases, as well as a diverse morphological images and a presence of sporadic forms of the disorder makes that NBIA is rarely diagnosed. We reported of an aty-pical case of NBIA with very late onset at the age of 51 years, long duration (26 years) and uncommon morphological picture. Our case of NBIA illustrates the heterogeneity of the disorder and contributes to the increasing evidences of overlapping of pathomorphological changes in different neurodegenerative diseases.

Case report

A 77-year-old women with parkinsonism, psychia-tric symptoms and progressing dementia was admitted to the hospital because of disturbances in consciousness and deterioration of the general state. The first symptoms of the disease appeared at the age of 51 years as rigidity and hypokinesia. Parkinson’s disease (PD) was diagnosed and she received L-Dopa continued for the next eighteen years. The response for the treatment was described initially as rather poor then as non effective. At the age of 55 years hypersalivation and dystonia of the left hand was observed. Two years later motor dysfunction of the right upper limb and disturbances in memory, speaking and reading appeared. During next 10 years of relentlessly progressive course of the disease the patient developed dysarthria, posture problems, sudden falls, dysphagia, marked hypokinesia, insomnia, vision worsening, severe dyskinesias and depression. At the age of 69 years left pallidotomy was performed because of ineffectiveness of the L-Dopa treatment. During next years delusions, hallucinations, psychomotor agitation and periods of hypersomnia were observed. At the age of 76 years the patient was bed-ridden.
At the last admission to the hospital neurological examination revealed severe dementia, rigidity, mioclonic jerks and bilateral Babinski sign. Routine hematological, biochemical and cerebrospinal fluid examinations were within normal limits. In EEG pseudoperiodic generalized discharges were seen. Brain MRI scan revealed hypointensive changes in both globi pallidi, dispersed lacunar vasogenic foci and brain atrophy (Fig. 1). Four weeks after the admission to the hospital the patient died because of circulatory and respiratory insufficiency.
The patient’s mother was diagnosed by general practitioner as PD and died 20 years after the disease onset at the age of 70 years.
On gross sectioning generalized brain atrophy and rust-brown pigmentation and cavities in both globi pallidi were seen (Fig. 2A). Pearl’s stain detected iron accumulation in the substantia nigra and basal ganglia (Fig. 2D), mainly in the globi pallidi. Iron deposits were found around blood vessels (Fig. 2E), in glial cells, macrophages (Fig. 2F) and in scattered neurons. In cerebral hemispheres (Fig. 2B), cerebellum (Fig. 3C) and brain stem numerous axonal spheroids were seen. Spheroids were tau-ferritin- amyloid negative but majority of them were immunoreactive to -synuclein. In addition to iron deposition and spheroid formation, immunoreactive to -synuclein Lewy body-like intraneuronal inclusions (Fig. 2G), dystrophic neurites (Fig. 2H) and extracellular deposits of -synuclein were seen. They were observed in cerebral cortex, substantia nigra, nucleus locus ceruleus, and, less numerous, in cerebellum and other brain stem structures.
Substantia nigra and nucleus locus ceruleus revealed nearly total loss of neurons, extracellular deposits of neuromelanin and severe tissue spongiosis. Other neuropathologic findings included diffuse moderate demyelination of the white matter and neuronal loss in cerebral cortex with subsequent gliosis.
The immune reaction with antibodies to tau protein showed neurofibrillary tangles (Fig. 2I) loca-lized mainly within transenthorinal cortex and neuropil threads (Fig. 2J) in the hippocampus and subiculum. According to Braak classification [3], localization of tangles was characteristic for stage I of AD. The immune reaction with antibodies to -amyloid revealed numerous amyloid plaques in cerebral cortex (Fig. 2K) and vessel amyloidosis (Fig. 2L). Distribution of the amyloid and neuritic plaques was similar to the typical pattern for AD. The number of the plaques fulfilled the CERAD criteria for probable AD [9].
Although genetic examination was not performed, retrospective analysis of clinical symptoms and characteristic morphological changes enabled diagnose NBIA.

Discussion

We reported on a patient with an unusual late onset and long course of NBIA with mixed morphological changes in the brain fulfilling neuropathologic diagnostic criteria for NBIA and AD.
In humans overlap between various neurode­generative disorders is a well known phenomenon. Since PD pathology is involved in morphological picture of NBIA and has been described previously, the most interesting finding in the reported case is the coexistence of histopathological changes characte-ristic for AD and NBIA. Several papers on NBIA have reported a presence of tau-positive neurofibrillary tangles but, according to our knowledge, this is the first report wherein numerous amyloid plaques were also found.
Although coexistence of NBIA and AD may be accidental, there is also a possibility that a particular relationship exists between these two neurodegene-rative diseases. Our case may be an unique manifestation of such relationship because usually NBIA patients die relatively early (in the young or middle age), so there is no enough time to develop pathology associated with aging process such as AD.
It is known that the maintenance of iron homeo-stasis is critical for the cell: iron deficiency impairs cell growth while iron overload can cause cellular damage. Characteristic feature for NBIA is abnormal iron deposition but this phenomenon has been reported not only in genetic disorders with mutations in the iron metabolic pathways, but also in many other neurodegenerative disorders including AD.
Dysregulation of brain iron homeostasis is one of the pathogenetical hypotheses in AD. In AD patients abnormalities in several proteins involved in cerebral iron transport have been described in several papers (references in: [12]). Investigations revealed defective ceruloplasmin, overexpression of lactoferritin, reduced level of iron-binding protein metallo-thionein III in astrocytes and significantly elevated level of other iron-binding protein, protein 97 (mela-notransferrin) in cerebrospinal fluid. Moreover, a correlation between the increased concentration of melanotransferrin in the serum and the progression of AD was also observed.
In AD brains, increased concentration of iron was found in and around amyloid plaques [4,8] that suggests that iron accumulation may influence amyloid plaque formation [2]. -amyloid is a high-affinity me-talloprotein that easily aggregates in the presence of biometals such as iron [7]. It has been also demonstrated that iron can modulate amyloid precursor holo-protein expression [9]. Additional evidence of the involvement of iron metabolism in AD development is the finding that patients with transferrin subtype C2 and mutations in hemochromatosis gene HFE are more common in AD suffers than in general population [11,14], and the presence of the C2 variant plus the HFE mutation increased the risk of AD five-folded [13].
There are several possible relationships between development of AD and NBIA.
Firstly, the coexistence of NBIA and AD in the same patient may be connected with iron toxicity. Despite considerable investigations, it is still not clear whether excessive iron accumulation in NBIA is an initial event that causes neuronal death or is a consequence of the disease process. On the basis of current neuropathological evidences, it seems reasonable to suggest that iron accumulation is the first step in degenerative process in NBIA [15]. It is possible that iron accumulation in NBIA disrupts normal control mechanisms of amyloid and tau protein expression. Disturbances in iron metabolism leading to the metal accumulation cause generation of free radicals damaging cellular macromolecules. Abnormal proteins, in turn, may disturb critical cellular metabolic processes result in cell death. It is believed that free-radical pathway could be a common mechanism in many neurodegenerative diseases. So, iron dyshomeostasis could trigger independently both NBIA and AD in the same patient.
Secondly, it is possible that not iron but -synuclein accumulation in NBIA may contribute to the development of AD. It was demonstrated that -synuclein can induce fibrillation of tau protein and its co-incubation with tau synergistically induces aggregation of the proteins [5]. -synuclein significantly stimulates also nitric oxide synthase (NOS) activity and, by oxidative stress, can trigger mitochondrial failure and cell death [1]. The same mechanisms may participate in development of Alzheimer’s pathology in the course of NBIA and in this situation AD would be secondary to NBIA.
Thirdly, neurodegenerative disorders share not only similar metabolic processes but brain cells, particularly neurons, have a limited repertoire of response to injury. This narrow range of non-specific reactivity makes that certain neurons can display fibrillary aggregats typical for two or more different diseases.
In summary, although it has been still unknown whether NBIA can give rise to AD or both disorders develop independently, their coexistence may not only contribute to the increasing evidences of the overlap in various neurodegenerative diseases but in the future may confound also their classification.

References

 1. Adamczyk A, Kaźmierczak A. Alpha-synuclein inhibits poly (ADP-ribose) polymerase-1 (PARP-1) activity via NO-dependent pathway. Folia Neuropathol 2009; 47: 247-251.  
2. Armstrong RA. The molecular biology of senile plaques and neurofibrillary tangles in Alzheimer’s disease. Folia Neuropathol 2009; 47: 289-299.  
3. Braak H, Alafuzoff I, Arzberger T, Kretzschmar H, del Tredici K. Staging of Alzheimer disease-associated neurofibrillary patho-logy using paraffin sections and immunocytochemistry. Acta Neuropathol 2006; 112: 389-404.  
4. Collingwood JF, Chong RK, Kasama T, Cervera-Gontard L, Dunin-Borkowski RE, Perry G, Pósfai M, Siedlak SL, Simpson ET, Smith MA, Dobson J. Three-dimensional tomographic imaging and characterization of iron compounds within Alzheimer’s plaque core material. J Alzh Dis 2008; 14: 235-245.  
5. Giasson BI, Forman MS, Higuchi M, Golbe LI, Graves CL, Kotzbauer PT, Trojanowski JQ, Lee VM. Initiation and synergistic fibrillization of tau and alpha-synuclein. Science 2003; 300: 636-640.  
6. Gregory A, Hayflick SJ. Neurodegeneration with brain iron accumulation. Folia Neuropathol 2005; 43: 286-296.  
7. Huang X, Atwood CS, Moir RD, Hartshorn MA, Tanzi RE, Bush AI. Trace metal contamination initiates the apparent auto-aggregation, amyloidosis, and oligomerization of Alzheimer’s A beta peptides. J Biol Inorg Chem 2004; 9: 954-960.  
8. Lovell MA, Robertson JD, Teesdale WJ, Campbell JL, Markesbery WR. Copper, iron and zinc in Alzheimer’s disease senile plaques. J Neurol Sci 1998; 158: 47-52.  
9. Mandel S, Amit T, Bar-Am O, Youdim MB. Iron dysregulation in Alzheimer’s disease: multimodal brain permeable iron chelating drugs, possessing neuroprotective-neurorescue and amyloid precursor protein-processing regulatory activities as therapeutic agents. Prog Neurobiol 2007; 82: 348-360.
10. Mirra SS, Heyman A, McKeel D, Sumi SM, Crain BJ, Brownlee LM, Vogel FS, Hughes JP, van Belle G, Berg L. The consortium to establish a registry for Alzheimer’s disease (CERAD). Standarization of neuropathologic assessment of Alzheimer’s disease. Neurology 1991; 41: 479-486.
11. Moalem S, Percy ME, Andrews DF, Kruck TP, Wong S, Dalton AJ, Mehta P, Fedor B, Warren AC. Are hereditary hemochromatosis mutations involved in Alzheimer disease? Am J Med Genet 2000; 93: 58-66.
12. Qian ZM, Shen X. Brain iron transport in neurodegeneration. Trends Mol Med 2001; 7: 103-108.
13. Robson KJ, Lehmann DJ, Wimhurst VL, Livesey KJ, Combrinck M, Merryweather-Clarke AT, Warden DR, Smith AD. Synergy between the C2 allele of transferrin and the C282Y allele of the haemochromatosis gene (HFE) as risk factors for developing Alzheimer’s disease. J Med Genet 2004; 41: 261-265.
14. Zambenedetti P, De Bellis G, Biunno I, Musicco M, Zatta P. Transferrin C2 variant does confer a risk for Alzheimer’s disease in caucasians. J Alzh Dis 2003; 5: 423-427.
15. Zarranz JJ, Gomez-Esteban JC, Atares B, Lezcano E, Forcadas M. Tau-predominant-associated pathology in a sporadic late-onset Hallervorden-Spatz syndrome. Mov Dis 2006; 21: 107-111.
Copyright: © 2010 Mossakowski Medical Research Centre Polish Academy of Sciences and the Polish Association of Neuropathologists. This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) License (http://creativecommons.org/licenses/by-nc-sa/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material, provided the original work is properly cited and states its license.
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