Original article
Density and spatial pattern of β-amyloid (Aβ) deposits in corticobasal degeneration

Introduction

Corticobasal degeneration (CBD) is a rare, progre­s­sive movement disorder [29], the most characteris­tic clinical features of which in­clude limb dysfunction [42,43,51], parkinsonism [49], apraxia [43], and de­men­­tia [49]. An individual patient, however, may exhi­bit a wide variety of clinical symptoms [46] including myoclonus [23], memory loss, be­ha­viour­al change, speech, and gait problems [43].

Neuropathologically, CBD is characterized by a pro­gressive cortical atrophy affecting the anterior ce­rebral cortex [46], the fronto-parietal region [33], and the superior temporal cortex [33]. As a consequence, the disease is regarded as a subtype of frontotemporal lobar degeneration (FTLD) [22]. There is atrophy of the basal ganglia, including the caudate nucleus [39,47] and substantia nigra (Kawasaki et al. 1996). In addition, widespread neuronal and glial pathology is present including ballooned neurons (BN) [41], neuropil threads [35], tau-immunoreactive neuronal cytoplasmic inclusions (NCI) [33], oligodendroglial inclusions (GI) [40], and astrocytic plaques (AP) [26]. CBD is therefore also classified as a tauopathy, a group of disorders that includes Alzheimer’s disease (AD), Pick’s disease (PiD), progressive supranuclear palsy (PSP), the NFT-predominant form of senile dementia (NFT-SD), argyrophilic grain disease (AGD), and the parkinsonism-dementia complex of Guam (Guam PDC) [28].

During a quantitative study of the pathology of 12 cases of CBD [17], -amyloid (A) deposits were observed in the cerebral cortex and/or hippocampus in three cases. A deposits have been reported previously in CBD [43] and could represent the overlap or co-occurrence of CBD with AD [10,18]. Hence, to clarify the role of A deposition in CBD, the density, distribution, and spatial pattern of the A deposits were studied in these three cases and compared with previously reported data from normal elderly brains [2,3] and from AD [2,11,15].

Material and methods

Cases

The CBD cases (Table I) were obtained from the Brain Bank, Department of Neuropathology, Institute of Psychiatry, King’s College London, UK. There is no specific clinical phenotype of CBD as diverse presentations of the disease are present [27]. However, the pathology of the cases was consistent with the criteria recommended by the National Institute of Health (NIH) Office of Rare Diseases for the pathological diagnosis of CBD [27]. First, NCI, GI and AP were present. Second, inclusions were present in the white and grey matter of various cortical and striatal regions. Third, neuronal loss was present in focal cortical areas and in the substantia nigra. CBD can be confused with PSP with cortical involvement and these two disorders were separated by the absence of ‘tuft-shaped astrocytes’ [50] and the lower density of inclusions in the subthalamic nucleus in CBD [48]. The apolipoprotein E (APOE) genotype of two of the cases (A, B) was 2/3 or 3/3 while the genotype of the third case (C) was 3/4.

Tissue preparation

After death, the consent of the next of kin was obtained for brain removal, following local Ethical Committee procedure and the 1995 Declaration of Helsinki (as modified Edinburgh, 2000). Tissue blocks were taken from the frontal cortex at the level of the genu of the corpus callosum to study the superior frontal gyrus (SFG) and motor cortex (MC), parietal cortex (PC) to study the superior parietal gyrus (SPG) at the level of the splenium of the corpus callosum, occipital cortex to study areas B17 and B18, and temporal cortex at the level of the lateral geniculate body. Within the temporal lobe, the superior temporal gyrus (STG) (B22), parahippocampal gyrus (PHG) (B28), hippocampus (HC), and dentate gyrus (DG) were investigated. Sequential tissue sections were stained by the following procedures: (1) haematoxylin and eosin (H/E), (2) ubiquitin, (3) phosphorylation-independent rabbit polyclonal antibody TP007 against tau [21], and (4) rabbit polyclonal antibody raised against the 12-28 amino acid sequence of the A protein [45]. The three most common morphological subtypes of A depo­sit were identified in the A-immunolabelled sections using previously defined criteria [6,24]: (1) dif­fuse deposits were 10-200 µm in diameter, irregular in shape with diffuse boundaries, and lightly stained, (2) primitive deposits were 20-60 µm, well demarcated, more symmetrical in shape, and strongly stained, (3) classic deposits were 20-100 µm, had a distinct central ‘core’ surrounded by a ‘corona’ of dystrophic neu­rites, and (4) compact deposits comprised a conden­sed core of A without the presence of a corona.

Morphometric methods

In each cortical region, A deposits were counted along a strip of tissue using 1000 × 200 µm contiguous sample fields, the short edge of the sample field being aligned with the pia mater [8,12]. Contiguous samples were located in the upper cortical laminae and included lamina I, II, and most of III, the short edge of the sample field being aligned with the surface of the pia mater. In the hippocampus, the lesions were counted from CA1 to CA4. From CA1 to CA3, the short dimension of the contiguous sample field was aligned with the alveus. Sampling was continued into sector CA4 using a guideline marked on the slide. In the DG, the sample field was aligned with the upper edge of the granule cell layer since A deposits were present within the molecular layer.

Data analysis

The spatial pattern of the A deposits in each brain region was studied using spatial pattern analysis described previously [1,5,9,12]. This method uses the variance-mean ratio (V/M) of the data to determine whether the A deposits were distributed randomly (V/M = 1), regularly (V/M < 1), or were clustered (V/M > 1) along a strip of tissue. Counts of deposits in adjacent sample fields were added together successively to provide data for increasing field sizes, e.g., 200 × 1000 µm, 400 × 1000 µm, 800 × 1000 µm etc., up to a size limited by the length of the strip sampled and the V/M ratio calculated for each size. V/M was then plotted against field size to determine whether the clusters of a feature were regularly or randomly distributed and to estimate the mean cluster size parallel to the tissue boundary. A V/M peak indicates the presence of regularly spaced clusters while an in­crease in V/M to an asymptotic level suggests the presence of randomly distributed clusters. The statistical significance of a peak was tested using a 't' test [5].

Results

The three most common morphological types of A deposit commonly found in AD, viz., diffuse, pri­mitive, and classic deposits, were also observed in the CBD cases (Fig. 1). In addition, a smaller number of more ‘compact’ A deposits were identified. Two of the cases (A, C) had all four types of A deposit while case B had diffuse and classic-type deposits only.

The density of A deposits in each brain region of each case is shown in Table II. In two cases (A, B), the density of the primitive, classic and compact A deposits was generally low (<1 deposit per mm²) and their distribution was restricted to either the frontal and motor cortex (case A) or to the occipital cortex (case B). Of these cases, case A had greater numbers of diffuse deposits in the frontal and motor cortex. In one case (case C), there was a greater density of A deposits throughout the cerebral cortex and deposits were also present in the CA sectors of the hippocampus and molecular layer of the DG. In case C, the density of the diffuse deposits was greatest in the occipital and temporal cortex (16-18 deposits per mm²), primitive deposits in the temporal cortex (14 deposits per mm²), classic deposits in the frontal cortex (5.3 deposits per mm²), and compact deposits in the parietal cortex (2.65 deposits per mm²).

The spatial pattern of the A deposits in each brain region is shown in Table III. Clustering of the A deposits, with clusters ranging in size from 200 to >6400 µm in diameter, was evident in 25/27 (93%) of the brain areas analysed. In addition, clusters of A deposits were regularly distributed parallel to the tissue boundary in 52% of the brain areas exhibiting clustering. In two cortical areas of case C, there was evidence of clustering at two scales, suggesting that the smaller clusters were aggregated into larger clusters. In the remaining analyses, large clusters of A deposits were observed, of at least 6400 µm in diame­ter, but without evidence of regular spacing.

Discussion

Of the original 12 cases of CBD studied using quantitative methods [17], A deposition was observed in three of the cases. In two cases, the density of the A deposits was low and their distribution was restricted to a small number of cortical regions. The density of the A deposit subtypes in these two cases was within the range reported for elderly non-demented brains [2,3]. A pathology in the remaining CBD case, however, was more extensive and showed similarities to that previously reported in AD [2,13,15]. The densities of A deposits in the frontal, occipital and temporal cortex were similar to AD [2-4] but the density in the parietal cortex was significantly lower than in AD. In addition, the spatial pattern of the A deposits, i.e., clustering of deposits with a regular distribution of clusters parallel to the tissue boundary, was similar to that reported in AD [1,7,11].

A number of hypotheses could account for A de­position in CBD. First, the presence of A deposits could be age-related. The density and distribution of A de­posits in two of the CBD cases is similar to normal control brains [2,3], consistent with aging. A number of studies of A pathology have demonstrated overlaps between AD and aging. Mann and Jones [38], for example, observed A deposits in non-demented individuals older than 60 years, deposits being rare before this age. After 60 years of age, A deposits were present in a variety of different disorders due to aging, especially in the temporal cortex [37]. In 14 non-demented elderly cases [3], A deposits were present in the temporal lobe in eight cases, but only in cortical gyri, the CA sectors of the HC and DG being spared. In addition, there were variations in the density of A deposits in control cases with a significant overlap with AD. The pattern of clustering of the A deposits was also similar in control and AD cases, i.e., the deposits were aggregated into clusters that were regularly distributed parallel to the pia mater, suggesting that the formation of A deposits was similar in AD and in aging [3]. In a further study of non-demented centenarians [25], A deposits were recorded in the PHG, whether demented or not demented, but the hippocampus was spared, suggesting little relationship between lesion density and severity of mental deficits.

Secondly, in case C the density and distribution of the deposits were similar to those reported in AD [2,3] and therefore A deposition in this case may be the result of the co-existence of AD and CBD [10,11,18]. The clinical syndrome of CBD is complex and variable and at least 50% of patients exhibit the signs and symptoms of an additional disorder, e.g., AD, PSP, or Parkinson’s disease (PD) [43]. Typical AD cases, however, also have abundant neurofibrillary tangles (NFT). The paired helical filaments (PHF) of the inclusions present in CBD are wider than those of AD and have a longer periodicity [36]. In addition, PHF-tau in CBD is composed predominantly of 4-repeat (4R) tau [44] while abnormally aggregated tau from AD contains both 3R and 4R tau [30]. Hence, although the A pathology in the present case resembles that of AD, there are differences in tau-immunoreactive pathology compared with AD.

Third, A deposits in CBD could be associated with the development of capillary amyloid angiopathy (CAA), which often results in increased A deposition [14]. The deposition of A in capillary and arteriolar walls is a common pathological observation in AD and in unselected post-mortems with age [19]. There was no evidence in the present cases, however, of any significant A deposition in relation to the vessel walls.

Fourth, A deposition is also related to APOE genotype, enhanced deposition being observed in cases expressing the e4 allele [20]. An increased frequency of allele e4 has been recorded in cases of CBD, and in 5/7 patients expressing the e4 allele, A deposition was recorded in the hippocampus and cerebral cortex [43]. In the present study, case C had the highest densities and most widespread distribution of A deposits and expressed genotype 3/4 whereas the other two cases with low densities of deposits expressed either genotype 2/3 or 3/3. Hence, it is hypothesized that enhanced A deposition in case C represents the influence of APOE allele e4.

In conclusion, in a quantitative study of 12 cases of CBD, three were shown to possess AD-type patho­logy in the form of A deposits. The density of A deposits in two of the cases was similar to that of elderly non-demented brains but in one case, the den­sity and spatial patterns of the deposits resembled those of AD. A pathology has now been shown to be associated with dementia with Lewy bodies (DLB) [16], amyotrophic lateral sclerosis (ALS) [31], Creutzfeldt-Jakob disease (CJD) [31], as well as CBD [43]. Hence, A pathology can be observed in several distinct clinical contexts and it is possible that pre­sence of the APOE e4 allele is the common feature in these disorders enhancing A deposition.

Acknowledgments

The assistance of the Brain Bank, Institute of Psychiatry, London in providing tissue sections for this study is gratefully acknowledged. We thank Mr. David Mackay and Mrs. Heidi Barnes for their excellent technical assistance.

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