Jean‐Philippe David

OBJECTIVE: To determine the spatiotemporal mapping of neurofibrillary degeneration (NFD) in normal aging and the different stages of AD. BACKGROUND: The pathophysiologic significance of AD lesions, namely amyloid plaques and neurofibrillary tangles, is still unclear, especially their interrelationship and their link with cognitive impairment. METHODS: The study included 130 patients of various ages and different cognitive statuses, from nondemented control subjects (n = 60, prospective study) to patients with severe definite AD. Paired helical filaments (PHF)-tau and Abeta were used as biochemical and histologic markers of NFD and amyloid plaques, respectively. RESULTS: NFD with PHF-tau was systematically present in variable amounts in the hippocampal region of nondemented patients age >75 years. When NFD was found in other brain areas, it was always along a stereotyped, sequential, hierarchical pathway. The progression was categorized into 10 stages according to the brain regions affected: transentorhinal cortex (S1), entorhinal (S2), hippocampus (S3), anterior temporal cortex (S4), inferior temporal cortex (S5), medium temporal cortex (S6), polymodal association areas (prefrontal, parietal inferior, temporal superior) (S7), unimodal areas (S8), primary motor (S9a) or sensory (S9b, S9c) areas, and all neocortical areas (S10). Up to stage 6, the disease could be asymptomatic. In all cases studied here, stage 7 individuals with two polymodal association areas affected by tau pathologic states were cognitively impaired. CONCLUSIONS: The relationship between NFD and Alzheimer-type dementia, and the criteria for a biochemical diagnosis of AD, are documented, and an association between AD and the extent of NFD in defined brain areas is shown.

Some neurosteroids have been shown to display beneficial effects on neuroprotection in rodents. To investigate the physiopathological significance of neurosteroids in Alzheimer's disease (AD), we compared the concentrations of pregnenolone, pregnenolone sulfate (PREGS), dehydroepiandrosterone, dehydroepiandrosterone sulfate (DHEAS), progesterone, and allopregnanolone, measured by gas chromatography-mass spectrometry, in individual brain regions of AD patients and aged nondemented controls, including hippocampus, amygdala, frontal cortex, striatum, hypothalamus, and cerebellum. A general trend toward decreased levels of all steroids was observed in all AD patients' brain regions compared with controls: PREGS and DHEAS were significantly lower in the striatum and cerebellum, and DHEAS was also significantly reduced in the hypothalamus. A significant negative correlation was found between the levels of cortical beta-amyloid peptides and those of PREGS in the striatum and cerebellum and between the levels of phosphorylated tau proteins and DHEAS in the hypothalamus. This study provides reference values for steroid concentrations determined by gas chromatography-mass spectrometry in various regions of the aged human brain. High levels of key proteins implicated in the formation of plaques and neurofibrillary tangles were correlated with decreased brain levels of PREGS and DHEAS, suggesting a possible neuroprotective role of these neurosteroids in AD.

OBJECTIVE: To determine the spatiotemporal mapping of tau pathologies and insoluble pools of Abeta in aging and sporadic AD, and their contribution to the physiopathologic, clinical, and neuropathologic features. METHODS: The authors studied 130 patients of various ages and different cognitive status, from nondemented controls (n = 60) to patients with severe definite AD (n = 70) who were followed prospectively. Insoluble Abeta 42 and 40 species were fully solubilized and quantified in the main neocortical areas, with a new procedure adapted to human brain tissue. Tau pathology staging was determined in 10 different brain areas, using Western blots. RESULTS: In AD, there is a constellation of amyloid phenotypes, extending from cases with exclusively aggregated Abeta 42 to cases with, in addition, large quantities of insoluble Abeta 40 species. Five other points were observed: 1) There was no spatial and temporal overlap in the distribution of these two insoluble Abeta species in cortical brain areas. 2) In contrast to solubilized Abeta 40 aggregates composed essentially of monomers and dimers, solubilized Abeta 42 was essentially observed as dimers and multimers. 3) Abeta 42 aggregates were observed at the early stages of tau pathology, whereas the insoluble Abeta 40 pool was found at the last stages. 4) During the progression of the disease, Abeta aggregates increase in quantity and heterogeneity, in close parallel to the extension of tau pathology. 5) There was no spatial overlap between Abeta aggregation that is widespread and heterogeneously distributed in cortical areas and tau pathology that is progressing sequentially, stereotypically, and hierarchically. CONCLUSIONS: These observations demonstrate that Abeta 42 aggregation, and not Abeta 40, is the marker that is close to Alzheimer etiology. It should be the main target for the early biological diagnosis of AD and modeling. Furthermore, the spatial mismatch between amyloid ss-precursor protein (APP) and tau pathologies in cortical brain areas demonstrates that neurodegeneration is not a direct consequence of extracellular Abeta neurotoxicity. Hence, there is a synergetic effect of APP dysfunction, revealed by Abeta aggregation, on the neuron-to-neuron propagation of tau pathology.

Tau proteins aggregate into different neuronal inclusions in several neurodegenerative disorders. In Alzheimer's disease (AD), hyperphosphorylated Tau from paired helical filaments (PHF) of neurofibrillary tangles, named PHF-Tau, have an electrophoretic profile with four main bands (Tau 55, 64, 69, 74 kDa). In Pick's disease, phosphorylated Tau from Pick bodies are made of two major components (Tau 55, 64 kDa) and a minor 69 kDa. Here we show, using specific antibodies against translated exon 2, 3 or 10 of Tau isoforms, that the set of Tau isoforms engaged in the most insoluble part of PHF in AD is made of Tau isoforms with exon 10 while they are lacking in phosphorylated Tau from Pick's disease. Our results suggest that specific sets of Tau isoforms distinguish between typical neuronal inclusions.