Florbetapir F 18 amyloid PET and 36-month cognitive decline: a prospective multicenter study.

This study was designed to evaluate whether subjects with amyloid beta (Aß) pathology, detected using florbetapir positron emission tomorgraphy (PET), demonstrated greater cognitive decline than subjects without Aß pathology. Sixty-nine cognitively normal (CN) controls, 52 with recently diagnosed mild cognitive impairment (MCI) and 31 with probable Alzheimer's disease (AD) dementia were included in the study. PET images obtained in these subjects were visually rated as positive (Aß+) or negative (Aß-), blind to diagnosis. Fourteen percent (10/69) of CN, 37% (19/52) of MCI and 68% (21/31) of AD were Aß+. The primary outcome was change in ADAS-Cog score in MCI subjects after 36 months; however, additional outcomes included change on measures of cognition, function and diagnostic status. Aß+ MCI subjects demonstrated greater worsening compared with Aß- subjects on the ADAS-Cog over 36 months (5.66 ± 1.47 vs -0.71 ± 1.09, P = 0.0014) as well as on the mini-mental state exam (MMSE), digit symbol substitution (DSS) test, and a verbal fluency test (P < 0.05). Similar to MCI subjects, Aß+ CN subjects showed greater decline on the ADAS-Cog, digit-symbol-substitution test and verbal fluency (P<0.05), whereas Aß+ AD patients showed greater declines in verbal fluency and the MMSE (P < 0.05). Aß+ subjects in all diagnostic groups also showed greater decline on the CDR-SB (P<0.04), a global clinical assessment. Aß+ subjects did not show significantly greater declines on the ADCS-ADL or Wechsler Memory Scale. Overall, these findings suggest that in CN, MCI and AD subjects, florbetapir PET Aß+ subjects show greater cognitive and global deterioration over a 3-year follow-up than Aß- subjects do.

Cognition and amyloid load in Alzheimer disease imaged with florbetapir F 18(AV-45) positron emission tomography.

OBJECTIVE: To examine the association between regional brain uptake of a novel amyloid positron emission tomography (PET) tracer florbetapir F 18 ([(18)F]-AV-45) and cognitive performance in a pilot study. DESIGN: Cross-sectional comparison of [(18)F]-AV-45 in AD patients versus controls. SETTING: Three specialty memory clinics. PARTICIPANTS: Eleven participants with probable Alzheimer disease (AD) by NINDS/ADRDA criteria and 15 healthy comparison (HC) participants. MEASUREMENTS: Participants underwent PET imaging following a 370 MBq (10 mCi) intravenous administration of [(18)F]-AV-45. Regional/cerebellar standardized uptake value ratios (SUVRs) were calculated. Cognition was assessed using Mini-Mental State Examination, Alzheimer's Disease Assessment Scale-Cognitive subscale (ADAS-Cog), Wechsler Logical Memory IA (immediate recall) test (LMIA), and verbal category fluency. RESULTS: Greater [(18)F]-AV-45 SUVR was associated with poorer performance on all cognitive tests. In the HC group, occipital, parietal, precuneus, temporal, and cortical average SUVR was associated with greater ADAS-Cog, and greater anterior cingulate SUVR was associated with lower LMIA. Two HC participants had [(18)F]-AV-45 cortical/cerebellar SUVR greater than 1.5, one of whom had deficits in episodic recall and on follow-up met criteria for amnestic mild cognitive impairment. CONCLUSION: [(18)F]-AV-45 SUVR in several brain regions was associated with worse global cognitive performance particularly in HC, suggesting its potential as a marker of preclinical AD.

The use of the exploratory IND in the evaluation and development of 18F-PET radiopharmaceuticals for amyloid imaging in the brain: a review of one company's experience.

AIM AND METHODS: The regulatory mechanism of exploratory INDs established in 2006 by the US Food and Drug Administration (FDA) is useful for the evaluation of tracer dose radiopharmaceutical agents, and especially valuable for development of amyloid imaging agents because of the absence of appropriate animal models. The authors employed exploratory INDs to study four related novel 18F-labeled positron emission tomography (PET) amyloid imaging agents, 18F-AV-19, 18F-AV-45, 18F-AV-138 and 18F-AV-144. These exploratory INDs contained preclinical data on the mechanism of action, secondary pharmacology, biodistribution, pharmacokinetics and dosimetry and results from a single dose, extended acute toxicology study. Each compound was then tested in a human PET study in up to 15 healthy elderly controls (HC) and 15 patients with AD. Compared to HC, patients with AD showed accumulation of tracer in cortical areas expected to be high in amyloid deposition with all four tracer compounds, and no serious adverse events were observed for any of the tracers. RESULTS: .18F-AV-45 showed the best imaging characteristics and was chosen for further development under a traditional IND. CONCLUSIONS: In summary the exploratory IND pathway was very useful for comparing four related agents with respect to efficacy (amyloid plaque binding), kinetics and dosimetry.

Neuronal localization of the TNFalpha converting enzyme (TACE) in brain tissue and its correlation to amyloid plaques.

The tumor necrosis factor (TNF)-alpha converting enzyme (TACE) can cleave the cell-surface ectodomain of the amyloid-beta precursor protein (APP), thus decreasing the generation of amyloid-beta (Abeta) by cultured non-neuronal cells. While the amyloidogenic processing of APP in neurons is linked to the pathogenesis of Alzheimer's disease (AD), the expression of TACE in neurons has not yet been examined. Thus, we assessed TACE expression in a series of neuronal and non-neuronal cell types by Western blots. We found that TACE was present in neurons and was only faintly detectable in lysates of astrocytes, oligodendrocytes, and microglial cells. Immunohistochemical analysis was used to determine the cellular localization of TACE in the human brain, and its expression was detected in distinct neuronal populations, including pyramidal neurons of the cerebral cortex and granular cell layer neurons in the hippocampus. Very low levels of TACE were seen in the cerebellum, with Purkinje cells at the granular-molecular boundary staining faintly. Because TACE was localized predominantly in areas of the brain that are affected by amyloid plaques in AD, we examined its expression in a series of AD brains. We found that AD and control brains showed similar levels of TACE staining, as well as similar patterns of TACE expression. By double labeling for Abeta plaques and TACE, we found that TACE-positive neurons often colocalized with amyloid plaques in AD brains. These observations support a neuronal role for TACE and suggest a mechanism for its involvement in AD pathogenesis as an antagonist of Abeta formation.

Radioiodinated styrylbenzenes and thioflavins as probes for amyloid aggregates.

We report for the first time that small molecule-based radiodiodinated ligands, showing selective binding to Abeta aggregates, cross the intact blood-brain barrier by simple diffusion. Four novel ligands showing preferential labeling of amyloid aggregates of Abeta(1-40) and Abeta(1-42) peptides, commonly associated with plaques in the brain of people with Alzheimer's disease (AD), were developed. Two 125I-labeled styrylbenzenes, (E,E)-1-iodo-2,5-bis(3-hydroxycarbonyl-4-hydroxy)styrylbenzene, 12 (ISB), and (E,E)-1-iodo-2,5-bis(3-hydroxycarbonyl-4-methoxy)styrylbenzene, 13 (IMSB), and two 125I-labeled thioflavins, 2-[4'-(dimethylamino)phenyl]-6-iodobenzothiazole, 18a (TZDM), and 2-[4'-(4''-methylpiperazin-1-yl)phenyl]-6-iodobenzothiazole, 18b (TZPI), were prepared at a high specific activity (2200 Ci/mmol). In vitro binding studies of these ligands showed excellent binding affinities with Kd values of 0.08, 0.13, 0.06, and 0.13 nM for aggregates of Abeta(1-40) and 0.15, 0.73, 0.14, and 0.15 nM for aggregates of Abeta(1-42), respectively. Interestingly, under a competitive-binding assaying condition, different binding sites on Abeta(1-40) and Abeta(1-42) aggregates, which are mutually exclusive, were observed for styrylbenzenes and thioflavins. Autoradiography studies of postmortem brain sections of a patient with Down's syndrome known to contain primarily Abeta(1-42) aggregates in the brain showed that both [(125)I]18a and [125I]18b labeled these brain sections, but [125I]13, selective for Abeta(1-40) aggregates, exhibited very low labeling of the comparable brain section. Biodistribution studies in normal mice after an iv injection showed that [125I]18a and [(125)I]18b exhibited excellent brain uptake and retention, the levels of which were much higher than those of [125I]12 and [125I]13. These findings strongly suggest that the new radioiodinated ligands, [125I]12 (ISB), [125I]13 (IMSB), [125I]18a (TZDM), and [125I]18b (TZPI), may be useful as biomarkers for studying Abeta(1-40) as well as Abeta(1-42) aggregates of amyloidogenesis in AD patients.

Amyloid precursor protein and amyloid beta peptide in human platelets. Role of cyclooxygenase and protein kinase C.

The main component of Alzheimer's disease (AD) senile plaques is amyloid-beta peptide (Abeta), a proteolytic fragment of the amyloid precursor protein (APP). Platelets contain both APP and Abeta and may contribute to the perivascular amyloid deposition seen in AD. However, no data are available concerning the biochemical mechanism(s) involved in their formation and release by these cells. We found that human platelets released APP and Abeta following activation with collagen or arachidonic acid. Inhibition of platelet cyclooxygenase (COX) reduced APP but not Abeta release following those stimuli. In contrast, activation of platelets by thrombin and calcium ionophore caused release of both APP and Abeta in a COX-independent fashion. Ex vivo studies showed that, despite suppression of COX activity, administration of aspirin did not modify Abeta or APP levels in serum or plasma, suggesting that this enzyme plays only a minor role in vivo. We examined the regulation of APP cleavage and release from activated platelets and found that cleavage requires protein kinase C (PKC) activity and is regulated by the intracellular second messengers phosphatidylinositol 2-phosphate and Ca(2+). Our data provide the first evidence that in human platelets COX is a minor component of APP secretion whereas PKC plays a major role in the secretory cleavage of APP. By contrast, Abeta release may represent secretion of preformed peptide and is totally independent of both COX and PKC activity.

In vivo detection of amyloid plaques in a mouse model of Alzheimer's disease.

Strategies for treating Alzheimer's disease (AD) include therapies designed to decrease senile plaque (SP) formation and/or promote clearance of SPs, but clinical trials of these treatments are limited by the lack of effective methods to monitor changes in plaque burden in the brains of living AD patients. However, because SPs are extracellular deposits of amyloid-beta peptides (Abeta), it may be possible to eventually develop radioligands that cross the blood-brain barrier (BBB) and label SPs so they can be visualized by current imaging methods. As a first step toward the generation of such a radioligand, we developed a probe, [(trans,trans)-1-bromo-2, 5-bis-(3-hydroxycarbonyl-4-hydroxy)styrylbenzene (BSB)], and we report here that BSB has the following properties essential for a probe that can detect SPs in vivo. First, BSB sensitively labels SPs in AD brain sections. Second, BSB permeates living cells in culture and binds specifically to intracellular Abeta aggregates. Third, after intracerebral injection in living transgenic mouse models of AD amyloidosis, BSB labels SPs composed of human Abeta with high sensitivity and specificity. Fourth, BSB crosses the BBB and labels numerous AD-like SPs throughout the brain of the transgenic mice after i.v. injection. Thus, we conclude that BSB is an appropriate starting point for future efforts to generate an antemortem diagnostic for AD.

Protein kinase C-dependent alpha-secretase competes with beta-secretase for cleavage of amyloid-beta precursor protein in the trans-golgi network.

The release of amyloidogenic amyloid-beta peptide (Abeta) from amyloid-beta precursor protein (APP) requires cleavage by beta- and gamma-secretases. In contrast, alpha-secretase cleaves APP within the Abeta sequence and precludes amyloidogenesis. Regulated and unregulated alpha-secretase activities have been reported, and the fraction of cellular alpha-secretase activity regulated by protein kinase C (PKC) has been attributed to the ADAM (a disintegrin and metalloprotease) family members TACE and ADAM-10. Although unregulated alpha-secretase cleavage of APP has been shown to occur at the cell surface, we sought to identify the intracellular site of PKC-regulated alpha-secretase APP cleavage. To accomplish this, we measured levels of secreted ectodomains and C-terminal fragments of APP generated by alpha-secretase (sAPPalpha) (C83) versus beta-secretase (sAPPbeta) (C99) and secreted Abeta in cultured cells treated with PKC and inhibitors of TACE/ADAM-10. We found that PKC stimulation increased sAPPalpha but decreased sAPPbeta levels by altering the competition between alpha- versus beta-secretase for APP within the same organelle rather than by perturbing APP trafficking. Moreover, data implicating the trans-Golgi network (TGN) as a major site for beta-secretase activity prompted us to hypothesize that PKC-regulated alpha-secretase(s) also reside in this organelle. To test this hypothesis, we performed studies demonstrating proteolytically mature TACE intracellularly, and we also showed that regulated alpha-secretase APP cleavage occurs in the TGN using an APP mutant construct targeted specifically to the TGN. By detecting regulated alpha-secretase APP cleavage in the TGN by TACE/ADAM-10, we reveal ADAM activity in a novel location. Finally, the competition between TACE/ADAM-10 and beta-secretase for intracellular APP cleavage may represent a novel target for the discovery of new therapeutic agents to treat Alzheimer's disease.

A distinct ER/IC gamma-secretase competes with the proteasome for cleavage of APP.

The deposition of amyloid-beta peptides (Abeta) in senile plaques (SPs) is a central pathological feature of Alzheimer's disease (AD). Since SPs are composed predominantly of Abeta1-42, which is more amyloidogenic in vitro, the enzymes involved in generating Abeta1-42 may be particularly important to the pathogenesis of AD. In contrast to Abeta1-40, which is generated in the trans-Golgi network and other cytoplasmic organelles, intracellular Abeta1-42 is produced in the endoplasmic reticulum/intermediate compartment (ER/IC), where it accumulates in a stable insoluble pool. Since this pool of insoluble Abeta1-42 may play a critical role in AD amyloidogenesis, we sought to determine how the production of intracellular Abeta is regulated. Surprisingly, the production of insoluble intracellular Abeta1-42 was increased by a putative gamma-secretase inhibitor as well as by an inhibitor of the proteasome. We further demonstrate that this increased generation of Abeta1-42 in the ER/IC is due to a reduction in the turnover of Abeta-containing APP C-terminal fragments. We conclude that the proteasome is a novel site for degradation of ER/IC-generated APP fragments. Proteasome inhibitors may augment the availability of APP C-terminal fragments for gamma-secretase cleavage and thereby increase production of Abeta1-42 in the ER/IC. Based on the organelle-specific differences in the generation of Abeta by gamma-secretase, we conclude that intracellular ER/IC-generated Abeta1-42 and secreted Abeta1-40 are produced by different gamma-secretases. Further, the fact that a putative gamma-secretase inhibitor had opposite effects on the production of secreted and intracellular Abeta may have important implications for AD drug design.

Quantifying Aß(1-40) and Aß (1-42) Using Sandwich-ELISA.

The role of Aß accumulation in the pathogenesis of Alzheimer's disease (AD) is supported by genetic studies showing that mutations in the amyloid-ß precursor protein (APP) that alter Aß production are linked to a subset of familial AD (FAD) cases with autosomal penetrance (reviewed in ref. 1). Several of these FAD-associated APP mutations, as well as FAD-associated mutations in the presenilin 1 (PS1) and presenilin 2 (PS2) genes, lead to an increase in the production of Aß(1)-(42) relative to Aß(1)_(40). This, combined with the observation that these peptides are differentially deposited in senile plaques (SPs) in vivo, suggests that differential production of Aß(1)-(40) and Aß(1)_(42) may be crucially important in the pathogenesis of AD. Thus, it is important to use techniques that not only quantitate Aß production, but also specifically differentiate between these two peptides in a variety of experimental paradigms. Here we describe the use of a highly sensitive sandwich-ELISA (enzyme-linked immunosorbent assay) to quantitate both Aß(1)-(40) and Aß(1)-(42) in soluble pools, after secretion by cultured cells into the medium or in human cerebrospinal fluid (CSF) samples, as well as in insoluble pools, as found intracellularly in cultured cells, or deposited in the brain parenchyma.

Detection of a novel intraneuronal pool of insoluble amyloid beta protein that accumulates with time in culture.

The amyloid-beta peptide (Abeta) is produced at several sites within cultured human NT2N neurons with Abeta1-42 specifically generated in the endoplasmic reticulum/intermediate compartment. Since Abeta is found as insoluble deposits in senile plaques of the AD brain, and the Abeta peptide can polymerize into insoluble fibrils in vitro, we examined the possibility that Abeta1-40, and particularly the more highly amyloidogenic Abeta1-42, accumulate in an insoluble pool within NT2N neurons. Remarkably, we found that formic acid extraction of the NT2N cells solubilized a pool of previously undetectable Abeta that accounted for over half of the total intracellular Abeta. Abeta1-42 was more abundant than Abeta1-40 in this pool, and most of the insoluble Abeta1-42 was generated in the endoplasmic reticulum/intermediate compartment pathway. High levels of insoluble Abeta were also detected in several nonneuronal cell lines engineered to overexpress the amyloid-beta precursor protein. This insoluble intracellular pool of Abeta was exceptionally stable, and accumulated in NT2N neurons in a time-dependent manner, increasing 12-fold over a 7-wk period in culture. These novel findings suggest that Abeta amyloidogenesis may be initiated within living neurons rather than in the extracellular space. Thus, the data presented here require a reexamination of the prevailing view about the pathogenesis of Abeta deposition in the AD brain.

The molecular cloning and characterization of Drosophila melanogaster myosin-IA and myosin-IB.

In this paper we describe the isolation and characterization of myosin-IA and myosin-IB, two distinct class I myosins from Drosophila melanogaster. A polymerase chain reaction based strategy using degenerate primers directed against two highly-conserved regions in the head domain of most myosins resulted in the isolation of these two novel myosins-I in addition to a number of previously identified myosins from three Drosophila cDNA libraries. A approximately 3.9 kilobase cDNA clone encoding the putative full-length myosin-IA gene product was isolated from an early embryonic library. Its deduced amino acid sequence predicts a protein of 1011 residues (117,094 Da) with a typical although highly basic myosin head, a neck composed of two IQ motifs, and a unique tail. A approximately 3.4 kilobase cDNA clone encoding the putative full-length myosin-IB gene product was isolated from an adult head library. Its deduced amino acid sequence predicts a protein of 1026 residues (117,741 Da) with a canonical head, three IQ motifs constituting the neck, and a distinct tail. Although both are myosins-I from fly, myosin-IA at cytological locus 31D-F and myosin-IB at cytological locus 61F appear to be more similar to their vertebrate homologs than they are to each other. Primary sequence analyses of both the head and tail domains of the known class I myosins illustrate a division of the metazoan myosin-I family into four distinct subclasses with myosin-IA and myosin-IB as members of two of these groups. Just as the sequence comparisons demonstrate a disparity between myosin-IA and myosin-IB, Northern blot analysis of these two unconventional myosins indicates distinct patterns of temporal expression.