Imaging microglial activation and glucose consumption in a mouse model of Alzheimer's disease

In Alzheimer's disease (AD), persistent microglial activation as sign of chronic neuroinflammation contributes to disease progression. Our study aimed to in vivo visualize and quantify microglial activation in 13- to 15-month-old AD mice using [¹¹C]-(R)-PK11195 and positron emission tomography (PET). We attempted to modulate neuroinflammation by subjecting the animals to an anti-inflammatory treatment with pioglitazone (5-weeks' treatment, 5-week wash-out period). [¹¹C]-(R)-PK11195 distribution volume values in AD mice were significantly higher compared with control mice after the wash-out period at 15 months, which was supported by immunohistochemistry data. However, [¹¹C]-(R)-PK11195 μPET could not demonstrate genotype- or treatment-dependent differences in the 13- to 14-month-old animals, suggesting that microglial activation in AD mice at this age and disease stage is too mild to be detected by this imaging method.     

Microglial activation in healthy aging

Healthy brain aging is characterized by neuronal loss and decline of cognitive function. Neuronal loss is closely associated with microglial activation and postmortem studies have indeed suggested that activated microglia may be present in the aging brain. Microglial activation can be quantified in vivo using (R)-[(11)C]PK11195 and positron emission tomography. The purpose of this study was to measure specific binding of (R)-[(11)C]PK11195 in healthy subjects over a wide age range. Thirty-five healthy subjects (age range 19-79 years) were included. In all subjects 60-minute dynamic (R)-[(11)C]PK11195 scans were acquired. Specific binding of (R)-[(11)C]PK11195 was calculated using receptor parametric mapping in combination with supervised cluster analysis to extract the reference tissue input function. Increased binding of (R)-[(11)C]PK11195 with aging was found in frontal lobe, anterior and posterior cingulate cortex, medial inferior temporal lobe, insula, hippocampus, entorhinal cortex, thalamus, parietal and occipital lobes, and cerebellum. This indicates that activated microglia appear in several cortical and subcortical areas during healthy aging, suggesting widespread neuronal loss.     

High-performance liquid chromatographic determination of [11C]1-(2-chlorophenyl)-N-methyl-N-(1-methylpropyl)-3-isoquinoline carboxamide in mouse plasma and tissue and in human plasma

The high-performance liquid chromatographic determination of 1-(2-chlorophenyl)-N-methyl-N-(1-methylpropyl)-3-isoquinoline carboxamide ([11C]PK 11195) is described. The method was successfully applied for plasma and tissue analysis after i.v. injection of [11C]PK 11195 in mice and for plasma analysis after administration of [11C]PK 11195 to humans. Separation is effected on a RP-C18 column, using a mixture of acetonitrile-water-triethylamine (65:35:0.5, v/v). Quantitative measurements of radioactivity are performed on a one-channel gamma-ray spectrometer equipped with a 2 x 2 in. NaI(Tl) detector. For humans rapid metabolisation of [11C]PK 11195 was observed. At 5, 20 and 35 min post injection 5%, 22% and 32%, respectively, of the plasma activity consisted of at least two more polar metabolites. Despite the extensive metabolisation rate in mice (up to 42% at 10 min post injection of [11C]PK 11195), no 11C-labelled metabolites could be detected in the extracts of brain and heart.     

PK11195 labels activated microglia in Alzheimer's disease and in vivo in a mouse model using PET

Activated microglia may promote neurodegeneration in Alzheimer's disease (AD) and may also help in amyloid clearance in immunization therapies. In vivo imaging of activated microglia using positron emission tomography (PET) could assist in defining the role of activated microglia during AD progression and therapeutics. We hypothesized that PK11195, a ligand that binds activated microglia, could label these cells in postmortem AD tissues and in vivo in an animal model of AD using PET. [(3)H](R)-PK11195 binding was significantly higher in AD frontal cortex compared to controls and correlated mainly with the abundance of immunohistochemically labeled activated microglia. With age, the brains of APP/PS1 transgenic mice showed progressive increase in [(3)H](R)-PK11195 binding and [(11)C](R)-PK11195 retention in vivo assessed using microPET, which correlated with the histopathological abundance of activated microglia. These results suggest that PK11195 binding in AD postmortem tissue and transgenic mice in vivo correlates with the extent of microglial activation and may help define the role of activated microglia in the pathogenesis and treatment of AD.     

Loss of serotonin 2A receptors exceeds loss of serotonergic projections in early Alzheimer's disease: a combined [C]DASB and [F]altanserin-PET study

In patients with Alzheimer's disease (AD), postmortem and imaging studies have revealed early and prominent reductions in cerebral serotonin 2A (5-HT_2A) receptors. To establish if this was due to a selective disease process of the serotonin system, we investigated the cerebral 5-HT_2A receptor and the serotonin transporter binding, the latter as a measure of serotonergic projections and neurons. Twelve patients with AD (average Mini Mental State Examination [MMSE]: 24) and 11 healthy age-matched subjects underwent positron emission tomography (PET) scanning with [¹⁸F]altanserin and [¹¹C]N,N-Dimethyl-2-(2-amino-4-cyanopheylthio)benzylamine ([¹¹C]DASB). Overall [¹⁸F]altanserin binding was markedly reduced in AD by 28%-39% (p = 0.02), whereas the reductions in [¹¹C]DASB binding were less prominent and mostly insignificant, except for a marked reduction of 33% in mesial temporal cortex (p = .0005). No change in [¹¹C]DASB binding was found in the midbrain. We conclude that the prominent reduction in neocortical 5-HT_2A receptor binding in early AD is not caused by a primary loss of serotonergic neurons or their projections.     

In vivo receptor labeling of peripheral benzodiazepine receptor by ex vivo binding of [3H]PK11195

In vivo receptor labeling of the peripheral benzodiazepine receptor was investigated using ex vivo binding of [3H]-(2-chlorophenyl)-N-methyl-N-(1-methylpropyl)-3-isoquinoline-carb ox-amide ([3H]PK11195). In autoradiographic studies, high level specific binding of [3H]PK11195 was observed in the olfactory bulb. Intravenous administration of PK11195 dose-dependently (0.03-3 mg/kg) inhibited ex vivo binding of [3H]PK11195 in the olfactory bulb. Likewise, N-(2,5-dimethoxybenzyl)-N-(5-fluoro-2-phenoxyphenyl)acetamide (DAA1106), a newly identified peripheral benzodiazepine receptor-specific ligand, dose-dependently (0.1-100 mg/kg) reduced ex vivo binding of [3H]PK11195, when administered intraperitoneally. In contrast, clonazepam, a central benzodiazepine receptor-specific agonist, had negligible effects on ex vivo binding of [3H]PK11195. We propose that the ex vivo receptor binding technique we used will facilitate determination of in vivo receptor occupancy of the peripheral benzodiazepine receptor.     

Mitochondria in activated microglia in vitro

In the CNS, microglia become activated, i.e. change their functional state and phenotype, in response to a wide variety of pathological stimuli. Since this activation is triggered at a very low threshold and at the same time remains territorially restricted, the spatial distribution of activated microglia can be used as a sensitive, generic measure of the anatomical localisation of ongoing disease processes. One protein complex, undetectable in resting microglia but highly up-regulated upon activation in vivo and in vitro, is the peripheral benzodiazepine binding site, as measured by binding of the isoquinoline derivate PK11195. Particularly numerous in the outer membrane of mitochondria, this binding site has also been referred to as the mitochondrial benzodiazepine receptor. The de novo expression of this receptor by activated microglia suggests that the process of activation may be associated with important qualitative changes in the state of mitochondria. Here, we provide confocal light- and electron microscopic evidence that the activation of microglia indeed entails conspicuous mitochondrial alterations. In cultured rat microglia stained with the fluorescent probe, JC-1, a sensitive indicator of mitochondrial membrane potential, we demonstrate that stimulation by bacterial lipopolysaccharide and interferon- increases the number of microglial mitochondrial profiles and leads to marked changes in their morphology. Prominent elongated, needle-like mitochondria are a characteristic feature of activated microglia in vitro. Electron microscopically, an abundance of abnormal profiles, including circular cristae or ring- and U-shaped membranes, are found. Our observations support the notion that the previously reported increase in microglial binding of PK11195, that labelled with carbon-11 ([¹¹C] (R)-PK11195) has clinical use for the visualisation of activated microglia in vivo by positron emission tomography, may at least in part relate to an increased number and altered functional state of microglial mitochondria.     

In vivo evaluation of amyloid deposition and brain glucose metabolism of 5XFAD mice using positron emission tomography

Positron emission tomography (PET) has been used extensively to evaluate the neuropathology of Alzheimer's disease (AD) in vivo. Radiotracers directed toward the amyloid deposition such as [¹⁸F]-FDDNP (2-(1-{6-[(2-[F]Fluoroethyl)(methyl)amino]-2-naphthyl}ethylidene)malononitrile) and [¹¹C]-PIB (Pittsburg compound B) have shown exceptional value in animal models and AD patients. Previously, the glucose analogue [¹⁸F]-FDG (2-[(18)F]fluorodeoxyglucose) allowed researchers and clinicians to evaluate the brain glucose consumption and proved its utility for the early diagnosis and the monitoring of the progression of AD. Animal models of AD are based on the transgenic expression of different human mutant genes linked to familial AD. The novel transgenic 5XFAD mouse containing 5 mutated genes in its genome has been proposed as an AD model with rapid and massive cerebral amyloid deposition. PET studies performed with animal-dedicated scanners indicate that PET with amyloid-targeted radiotracers can detect the pathological amyloid deposition in transgenic mice and rats. However, in other studies no differences were found between transgenic mice and their wild type littermates. We sought to investigate in 5XFAD mice if the radiotracers [¹¹C]-PIB, and [¹⁸F]-Florbetapir could quantify the amyloid deposition in vivo and if [¹⁸F]-FDG could do so with regard to glucose consumption. We found that 5XFAD animals presented higher cerebral binding of [¹⁸F]-Florbetapir, [¹¹C]-PIB, and [¹⁸F]-FDG. These results support the use of amyloid PET radiotracers for the evaluation of AD animal models. Probably, the increased uptake observed with [¹⁸F]-FDG is a consequence of glial activation that occurs in 5XFAD mice.     

Activated macrophages in HIV encephalitis and a macaque model show increased [H](R)-PK11195 binding in a PI3-kinase-dependent manner

HIV encephalitis (HIVE) is a neurodegenerative disease seen in approximately one in four terminally infected patients. Macaques infected with the simian immunodeficiency virus develop encephalitis (SIVE) very similar to the human disease. Neurodegeneration in both these conditions occurs from the effects of toxic viral proteins and neurotoxins derived from activated brain macrophages. Activated macrophages in the brain of macaques with SIVE can be labeled in vivo using positron emission tomography (PET) using PK11195, a ligand that binds the peripheral benzodiazepine receptor (PBR). However, the functional significance and mechanisms mediating increased PK11195 binding in activated brain macrophages are not known. Using post mortem tissues from macaques with SIVE and macrophages cell cultures activated with lipopolysaccharide (LPS), we show that [³H](R)-PK11195 binding is increased in activated macrophages. Increased [³H](R)-PK11195 binding in LPS-activated macrophages was reversed by pharmacologically inhibiting class III phosphatidylinositol-3 kinase (PI3-kinase), but was not altered by inhibiting the mitogen-activated protein kinase (MAP-kinase) pathway. Our results suggest that activated macrophages in lentiviral encephalitis show increased [³H](R)-PK11195 binding in a PI3-kinase-dependent fashion which may help elucidate the function of PBR in activated brain macrophages in HIVE and other neuroinflammatory diseases.     

A Phenotypic Change But Not Proliferation Underlies Glial Responses in Alzheimer Disease

Classical immunohistochemical studies in the Alzheimer disease (AD) brain reveal prominent glial reactions, but whether this pathological feature is due primarily to cell proliferation or to a phenotypic change of existing resting cells remains controversial. We performed double-fluorescence immunohistochemical studies of astrocytes and microglia, followed by unbiased stereology-based quantitation in temporal cortex of 40 AD patients and 32 age-matched nondemented subjects. Glial fibrillary acidic protein (GFAP) and major histocompatibility complex II (MHC2) were used as markers of astrocytic and microglial activation, respectively. Aldehyde dehydrogenase 1 L1 and glutamine synthetase were used as constitutive astrocytic markers, and ionized calcium-binding adaptor molecule 1 (IBA1) as a constitutive microglial marker. As expected, AD patients had higher numbers of GFAP⁺ astrocytes and MHC2⁺ microglia than the nondemented subjects. However, both groups had similar numbers of total astrocytes and microglia and, in the AD group, these total numbers remained essentially constant over the clinical course of the disease. The GFAP immunoreactivity of astrocytes, but not the MHC2 immunoreactivity of microglia, increased in parallel with the duration of the clinical illness in the AD group. Cortical atrophy contributed to the perception of increased glia density. We conclude that a phenotypic change of existing glial cells, rather than a marked proliferation of glial precursors, accounts for the majority of the glial responses observed in the AD brain.The role of glial cells in Alzheimer disease (AD), particularly the role of astrocytes and microglia, is a matter of growing interest. Pioneering immunohistochemical studies revealed an increased immunoreactivity for astrocytes and microglial cells in the cortex of AD patients, compared with that of nondemented elderly people, with the vast majority of these cells clustering around dense-core plaques.^1,2 Astrocytes are usually visualized with immunohistochemistry for glial fibrillary acidic protein (GFAP), but recent data suggest that only a subset of all astrocytes, labeled with aldehyde dehydrogenase 1 L1 (ALDH1L1), are also GFAP immunopositive.^3,4 Similarly, a number of microglial markers are available that do not completely overlap with one another and that also label blood and bone marrow mononuclear phagocytes,⁵ including major histocompatibility complex II [MHC2 (alias HLA-DP-DQ-DR)],⁶ CD11b (alias Mac-1, CR3),⁷ CD45 [alias leukocyte common antigen (LCA)],⁸ ionized calcium-binding adaptor molecule 1 [IBA1; alias allograft inflammatory factor 1 (AIF-1)],⁹ and CD68.¹⁰In AD, in various other neurodegenerative disorders, and in acute brain injuries such as stroke, trauma or infection, the terms reactive astrocytes and activated microglia are widely used to describe the characteristic morphology (ie, hypertrophy of soma and retraction and thickening of processes) of these glial cells. However, the astrocytic and microglial reactions observed in these conditions have also been often referred to as glial proliferation or glial hyperplasia.^11,12 To understand the role of glial cells in AD and their relationship to amyloid plaques and neurofibrillary tangles (NFTs), the pathological hallmarks of AD, it is important to know whether glial responses involve proliferation of glia or are due mainly to a phenotypic change in existing glia. With the present study, we sought to understand the relative contribution of cell proliferation versus phenotypic change to the increased number of astrocytes and microglial cells described in the AD brain by classical immunohistochemistry.To this end, we performed double-fluorescence immunohistochemical studies and unbiased stereology-based analyses on the temporal cortex of a large sample of AD patients and age-matched nondemented individuals. Double-labeling of astrocytes with GFAP and glutamine synthetase (GS) or ALDH1L1 enabled the visualization of many astrocytes that were not identifiable with GFAP immunohistochemistry alone, particularly in nondemented subjects. Stereology-based counts revealed that the total number of astrocytes does not differ between AD brain and normal aging brain, and that the number of astrocytes remains essentially constant through the clinical course of AD (although astrocytes increasingly become GFAP⁺ as the disease progresses). Double-labeling of microglia with IBA1 and MHC2 revealed that there are distinct subpopulations of microglial cells in the cortex, and that the number of MHC2⁺ activated microglia, but not the total number of microglial cells, is significantly increased in the AD brain. Thus, we conclude that glial responses in AD are largely due to a phenotypic change of resting glial cells, rather than to cell proliferation.     

MyD88 Is Dispensable for Cerebral Amyloidosis and Neuroinflammation in APP/PS1 Transgenic Mice

Activated microglia are associated with amyloid plaques in transgenic mouse models of cerebral amyloidosis and in human Alzheimer disease; yet, their implication in Alzheimer disease pathogenesis remains unclear. It has been suggested that microglia play dual roles depending on the context of activation, contributing negatively to disease pathogenesis by secreting proinflammatory innate cytokines or performing a beneficial role via phagocytosis of amyloid beta (Aβ) deposits. Toll-like receptors, most of which signal through the adaptor protein myeloid differentiation factor 88 (MyD88), have been suggested as candidate Aβ innate pattern recognition receptors. It was recently reported that MyD88 deficiency reduced brain amyloid pathology and microglial activation. To assess a putative role of MyD88 in cerebral amyloidosis and glial activation in APPswe/PS1ΔE9 (APP/PS1) mice, we crossed MyD88-deficient (MyD88^−/−) mice with APP/PS1 mice, interbred first filial offspring, and studied APP/PS1 MyD88^+/+, APP/PS1 MyD88^+/−, and APP/PS1 MyD88^−/− cohorts. Biochemical analysis of detergent-soluble and detergent-insoluble Aβ_1-40 or Aβ_1-42 in brain homogenates did not reveal significant between-group differences. Furthermore, no significant differences were observed on amyloid plaque load or soluble fibrillar Aβ by quantitative immunohistochemical analysis. In addition, neither activated microglia nor astrocytes differed among the three groups. These data suggest that MyD88 signaling is dispensable for Aβ-induced glial activation and does not significantly affect the nature or extent of cerebral β-amyloidosis in APP/PS1 mice.Alzheimer disease (AD) is an insidious public health threat characterized by deposition of β-amyloid as senile plaques, formation of neurofibrillary tangles, and large-scale cortical neuronal loss leading to dementia. In addition to these pathognomonic features of the disease, AD patients exhibit low-level chronic neuroinflammation. This is hallmarked by the spatial and temporal occurrence of activated microglia with amyloid beta (Aβ) deposits. Yet, the mechanisms by which microglia recognize and respond to Aβ accumulation remain unclear. Current evidence suggests that there are varied forms of activated microglia in AD, some of which are detrimental and others beneficial.¹ Because microglial activation is a complex continuum of varied responses,² it stands to reason that a wide array of immune molecules may orchestrate microglial responses to Aβ. Ultimately, a clearer understanding of the pathways leading to beneficial microglial responses and clearance of misfolded proteins could open new avenues for AD treatment.Numerous recent studies have proposed that Toll-like receptors (TLRs) play a role in the microglial response to Aβ and, more specifically, that aggregated Aβ can activate microglia via TLRs.^3–11 Most TLRs (except TLR3) signal through the adaptor protein myeloid differentiation factor 88 (MyD88), suggesting that it may play an important role in microglial activation in response to cerebral amyloid accumulation. To test this possibility, two recent studies crossed MyD88 knockout mice with APP/PS1 mouse models of cerebral amyloid deposition and examined effects on cognitive deficits and AD-like pathology. In one study, it was reported that MyD88 deficiency of the doubly transgenic APPswe/PS1dE9 mouse reduced cerebral amyloid pathology and microglial activation and decreased expression of CX3CR1 in 10-month-old animals.¹² Lim and coworkers¹² suggested that inhibiting MyD88-associated TLR signaling would alter the microglial activation state, and they reported less cerebral amyloid deposition in this cross. However, their findings were perplexing given previous reports showing that activation of TLRs leads to decreased amyloid load and increased Aβ phagocytosis, leading to the hypothesis that MyD88 deficiency would either cause buildup of amyloid or have no effect on amyloid levels in APP/PS1 mice.^{4,6,11,13–15} Another recent study published findings more consistent with this hypothesis, demonstrating that APPswe/PS1A246E mice heterozygous for MyD88 had accelerated spatial learning and memory deficits and increased levels of soluble Aβ oligomers. These results led the authors to conclude that MyD88-mediated activation of microglia was protective in the context of cerebral amyloid deposition.¹⁶ In an attempt to clarify the uncertainty surrounding this critical question, we crossed APPswe/PS1dE9 (APP/PS1) mice with MyD88 knockout (MyD88^−/−) mice (both on a C57BL/6 background) and analyzed APP/PS1 MyD88^+/+, APP/PS1 MyD88^+/−, and APP/PS1 MyD88^−/− cohorts for Alzheimer-like pathology at 15 months of age.     

PET imaging with [11C]PBR28 can localize and quantify upregulated peripheral benzodiazepine receptors associated with cerebral ischemia in rat

Peripheral benzodiazepine receptors (PBRs) are upregulated on activated microglia. We recently developed a promising positron emission tomography (PET) ligand, [11C]PBR28, with high affinity and excellent ratio of specific to nonspecific binding. We assessed the ability of [11C]PBR28 PET to localize PBRs in a rat permanent middle cerebral artery occlusion (MCAO) model of neuroinflammation. [11C]PBR28 was intravenously administered to rats at 4 and 7 days after permanent MCAO. In all experiments, arterial blood was sampled for compartmental modeling of regional distribution volumes, and rat brains were sampled after imaging for in vitro [3H]PK 11195 autoradiography and histological evaluation. [11C]PBR28 PET and [3H]PK 11195 autoradiography showed similar areas of increased PBRs, especially in the peri-ischemic core. Results from these in vivo and in vitro methods were strongly correlated. In this first study to demonstrate neuroinflammation in vivo with small animal PET, [11C]PBR28 had adequate sensitivity to localize and quantify the associated increase in PBRs.     

Synthesis of two potential NK<Subscript>1</Subscript>-receptor ligands using [1-<Superscript>11</Superscript>C]ethyl iodide and [1-<Superscript>11</Superscript>C]propyl iodide and initial PET-imaging

Background

The previously validated NK₁-receptor ligand [O-methyl-¹¹C]GR205171 binds with a high affinity to the NK₁-receptor and displays a slow dissociation from the receptor. Hence, it cannot be used in vivo for detecting concentration changes in substance P, the endogenous ligand for the NK₁-receptor. A radioligand used for monitoring these changes has to enable displacement by the endogenous ligand and thus bind reversibly to the receptor. Small changes in the structure of a receptor ligand can lead to changes in binding characteristics and also in the ability to penetrate the blood-brain barrier. The aim of this study was to use carbon-11 labelled ethyl and propyl iodide with high specific radioactivity in the synthesis of two new and potentially reversible NK₁-receptor ligands with chemical structures based on [O-methyl-¹¹C]GR205171.

Methods

[1-¹¹C]Ethyl and [1-¹¹C]propyl iodide with specific radioactivities of 90 GBq/μmol and 270 GBq/μmol, respectively, were used in the synthesis of [O-methyl-¹¹C]GR205171 analogues by alkylation of O-desmethyl GR205171. The brain uptake of the obtained (2S,3S)-N-(1-(2- [1-¹¹C]ethoxy-5-(3-(trifluoromethyl)-4H-1,2,4-triazol-4-yl)phenyl)ethyl)-2-phenylpiperidin-3-amine (I) and (2S,3S)-2-phenyl-N-(1-(2- [1-¹¹C]propoxy-5-(3-(trifluoromethyl)-4H-1,2,4-triazol-4-yl)phenyl)ethyl)piperidin-3-amine (II) was studied with PET in guinea pigs and rhesus monkeys and compared to the uptake of [O-methyl-¹¹C]GR205171.

Results

All ligands had similar uptake distribution in the guinea pig brain. The PET-studies in rhesus monkeys showed that (II) had no specific binding in striatum. Ligand (I) had moderate specific binding compared to the [O-methyl-¹¹C]GR205171. The ethyl analogue (I) displayed reversible binding characteristics contrary to the slow dissociation rate shown by [O-methyl-¹¹C]GR205171.

Conclusion

The propyl-analogue (II) cannot be used for detecting changes in NK₁-ligand levels, while further studies should be performed with the ethyl-analogue (I).

     

In silico modification of oseltamivir as neuraminidase inhibitor of influenza A virus subtype H1N1

This research focused on the modification of the functional groups of oseltamivir as neuraminidase inhibitor against influenza A virus subtype H1N1.Interactions of three of the best ligands were evaluated in the hydrated state using molecular dynamics simulation at two different temperatures.The docking result showed that AD3BF2 D ligand(N-[(1S,6R)-5-amino-5-{[(2R,3S,4S)-3,4-dihydroxy-4-(hydroxymethyl) tetrahydrofuran-2-yl]oxy}-4-formylcyclohex-3-en-1-yl]acetamide-3-(1-ethylpropoxy)-1-cyclohexene-1-carboxylate) had better binding energy values than standard oseltamivir.AD3BF2 D had several interactions,including hydrogen bonds,with the residues in the catalytic site of neuraminidase as identified by molecular dynamics simulation.The results showed that AD3BF2 D ligand can be used as a good candidate for neuraminidase inhibitor to cope with influenza A virus subtype H1N1.     

Study of thyroid hormone receptor alpha gene polymorphisms on Alzheimer's disease

Because the action of thyroid hormone (T3) is involved in adult cognitive functions, we wanted to assess the association between THRA gene polymorphisms, which encodes the T3 nuclear receptor TRα1, and Alzheimer's disease (AD) risk.We analysed 5 single nucleotide polymorphisms (SNPs) of THRA, covering the known common genetic variability of the gene, in the Lille AD case-control study (710 cases/597 controls). We observed that subjects bearing the rs939348 TT genotype had a tendency to have a higher risk of developing AD (adjusted OR [95%CI] = 1.71 [0.99-2.95] p = 0.06). We extended our finding to three other independent AD case-control studies and observed similar trends. When combining the 4 studies (1749 cases/1339 controls), we observed an overall significant higher risk of AD in TT subjects (adjusted OR [95%CI] = 1.42 [1.03-1.96], p = 0.03) compared with C allele bearers. However, when combining our data with the available data coming from 2 American genome wide association studies on AD, we observed a weak and not significant association (OR = 1.19 [0.97-1.45], p = 0.10).The relationship between the genetic variability of the THRA gene and AD risk remains uncertain but cannot be entirely excluded.     

Para-chloro-2-[18F]fluoroethyl-etomidate: A promising new PET radiotracer for adrenocortical imaging

Introduction: [¹¹C]Metomidate ([¹¹C]MTO), the methyl ester analogue of etomidate, was developed as a positron emission tomography (PET) radiotracer for adrenocortical tumours and has also been suggested for imaging in primary aldosteronism (PA). A disadvantage of [¹¹C]MTO is the rather high non-specific binding in the liver, which impacts both visualization and quantification of the uptake in the right adrenal gland. Furthermore, the short 20-minute half-life of carbon-11 is a logistic challenge in the clinical setting.Objectives: The aim of this study was to further evaluate the previously published fluorine-18 (T_1/2=109.5 min) etomidate analogue, para-chloro-2-[¹⁸F]fluoroethyl etomidate; [¹⁸F]CETO, as an adrenal PET tracer.Methods: In vitro experiments included autoradiography on human and cynomolgus monkey (non-human primate, NHP) tissues and binding studies on adrenal tissue from NHPs. In vivo studies with [¹⁸F]CETO in mice, rats and NHP, using PET and CT/MRI, assessed biodistribution and binding specificity in comparison to [¹¹C]MTO.Results: The binding of [¹⁸F]CETO in the normal adrenal cortex, as well as in human adrenocortical adenomas and adrenocortical carcinomas, was shown to be specific, both in vitro (in humans) and in vivo (in rats and NHP) with an in vitro K_d of 0.66 nM. Non-specific uptake of [¹⁸F]CETO in NHP liver was found to be low compared to that of [¹¹C]MTO.Conclusions: High specificity of [¹⁸F]CETO to the adrenal cortex was demonstrated, with in vivo binding properties qualitatively surpassing those of [¹¹C]MTO. Non-specific binding to the liver was significantly lower than that of [¹¹C]MTO. [¹⁸F]CETO is a promising new PET tracer for imaging of adrenocortical disease and should be evaluated further in humans.     

Evidence of the association of BIN1 and PICALM with the AD risk in contrasting European populations

Recent genome-wide association studies have identified 5 loci (BIN1, CLU, CR1, EXOC3L2, and PICALM) as genetic determinants of Alzheimer's disease (AD). We attempted to confirm the association between these genes and the AD risk in 3 contrasting European populations (from Finland, Italy, and Spain). Because CLU and CR1 had already been analyzed in these populations, we restricted our investigation to BIN1, EXO2CL3, and PICALM. In a total of 2816 AD cases and 2706 controls, we unambiguously replicated the association of rs744373 (for BIN1) and rs541458 (for PICALM) polymorphisms with the AD risk (odds ratio [OR] = 1.26, 95% confidence interval [CI] [1.15-1.38], p = 2.9 × 10⁻⁷, and OR = 0.80, 95% CI [0.74-0.88], p = 4.6 × 10⁻⁷, respectively). In a meta-analysis, rs597668 (EXOC3L2) was also associated with the AD risk, albeit to a lesser extent (OR = 1.19, 95% CI [1.06-1.32], p = 2.0 × 10⁻³). However, this signal did not appear to be independent of APOE. In conclusion, we confirmed that BIN1 and PICALM are genetic determinants of AD, whereas the potential involvement of EXOC3L2 requires further investigation.     

Selective detection of adenosine A1 receptor-dependent G-protein activity in basal and stimulated conditions of rat brain [35S]guanosine 5′-(γ-thio)triphosphate autoradiography

[³⁵S]Guanosine 5′-(γ-thio)triphosphate autoradiography is a novel technique to detect receptor-dependent activation of G-proteins in brain tissue sections. While an increasing number of reports using this approach are beginning to appear, little effort has been directed to the identification of factors responsible for the heterogeneously distributed [³⁵S]guanosine 5′-(γ-thio)triphosphate signal in basal conditions. The present study demonstrates that endogenously formed adenosine generates a widespread and prominent adenosine A₁ receptor-dependent signal in basal conditions using this technique. Treatment of rat brain tissue sections with the A₁-selective antagonist 8-cyclopentyl-1,3-dipropylxanthine dose-dependently (ec₅₀<10 nM) suppressed basal [³⁵S]guanosine 5′-(γ-thio)triphosphate binding in a region-specific manner, an effect fully mimicked by the adenosine-depleting enzyme adenosine deaminase, and less so by the A₁ antagonist cirsimarin and by caffeine. That adenosine was continuously formed during the incubation is supported by the constant requirements of adenosine deaminase in order to suppress basal radioligand binding and further by the fact that low micromolar concentrations of adenine nucleotides evoked only adenosine-mimicking and fully 8-cyclopentyl-1,3-dipropylxanthine-sensitive binding responses. In the presence of adenosine deaminase, all responses to adenine nucleotides were abolished, indicating that prior conversion to adenosine was required. Upon stimulation, this technique selectively detected A₁ receptor-activated G-proteins, as the non-selective agonists adenosine and 2-chloroadenosine and the A₁-selective agonist N⁶-p-sulfophenyladenosine all evoked only 8-cyclopentyl-1,3-dipropylxanthine-sensitive responses in identical gray matter areas, and also in several white matter areas such as the corpus callosum, anterior commissure, optic tract and cerebellar white matter. Dose–response studies revealed region-specific differences in the magnitude of A₁ receptor-stimulated G-protein activation, with the highest response (nine-fold over basal) detectable in the hippocampus. No response to the A_2A-selective agonist 2-[(2-aminoethylamino)carbonylethylphenylethylamino]-5′-N-ethylcarboxamidoadenosine or the A₃-selective agonist 2-chloro-N⁶-(3-iodobenzyl)-adenosine-5′-N-methyluronamide was detected in any region.These data reveal that a significant amount of noise inherent to [³⁵S]guanosine 5′-(γ-thio)triphosphate autoradiography can be eliminated by removal of the adenosine signal, a step likely facilitating detection of responses to other receptors. Furthermore, the data establish [³⁵S]guanosine 5′-(γ-thio)triphosphate autoradiography as a novel and selective approach to directly assess A₁ receptor–G-protein coupling in anatomically defined regions of the central nervous system.     

Suppressed Accumulation of Cerebral Amyloid β Peptides in Aged Transgenic Alzheimer’s Disease Mice by Transplantation with Wild-Type or Prostaglandin E2 Receptor Subtype 2-Null Bone Marrow

A complex therapeutic challenge for Alzheimer’s disease (AD) is minimizing deleterious aspects of microglial activation while maximizing beneficial actions, including phagocytosis/clearance of amyloid β (Aβ) peptides. One potential target is selective suppression of microglial prostaglandin E₂ receptor subtype 2 (EP2) function, which influences microglial phagocytosis and elaboration of neurotoxic cytokines. To test this hypothesis, we transplanted bone marrow cells derived from wild-type mice or mice homozygous deficient for EP2 (EP2^−/−) into lethally irradiated 5-month-old wild-type or APPswe-PS1ΔE9 double transgenic AD mouse model recipients. We found that cerebral engraftment by bone marrow transplant (BMT)-derived wild-type or EP2^−/− microglia was more efficient in APPswe-PS1ΔE9 than in wild-type mice, and APPswe-PS1ΔE9 mice that received EP2^−/− BMT had increased cortical microglia compared with APPswe-PS1ΔE9 mice that received wild-type BMT. We found that myeloablative irradiation followed by bone marrow transplant-derived microglia engraftment, rather than cranial irradiation or BMT alone, was responsible for the approximate one-third reduction in both Aβ plaques and potentially more neurotoxic soluble Aβ species. An additional 25% reduction in cerebral cortical Aβ burden was achieved in mice that received EP2^−/− BMT compared with mice that received wild-type BMT. Our results provide a foundation for an adult stem cell-based therapy to suppress soluble Aβ peptide and plaque accumulation in the cerebrum of patients with AD.Alzheimer’s disease (AD), the most common dementing neurodegenerative disease,¹ is a major public health burden for older Americans.² Amyloid β (Aβ) peptides are pleotropic molecules that are directly neurotoxic and stimulate liberation of cytotoxic cytokines through activation of microglia innate immune response.³ However, activated microglia phagocytosis and degradation of Aβ species is key to cerebral Aβ homeostasis.⁴ Thus, an important but complex therapeutic challenge is balancing deleterious and beneficial aspects of microglial activation in AD.⁵ One proposed mechanism of microglial modulation is prostaglandin E₂ signaling, especially through activation of the E prostanoid receptor subtype 2 (EP2).⁶ Cultured microglia lacking EP2 (EP2^−/−) show enhanced phagocytosis of Aβ from human brain explants and reduced paracrine neurotoxicity.⁷ In vivo experiments with EP2^−/− mice have shown reduced accumulation of cerebral Aβ in a transgenic mouse model of AD,^7,8,9 as well as suppressed oxidative damage to neurons following innate immune activation.^7,10,11,12 However, because EP2 is expressed by several cell types in brain, including microglia and neurons, the importance of microglial-specific EP2 has not been established. To address this gap in our knowledge, bone marrow cells from EP2^−/− mice were transplanted into APPswe-PS1ΔE9 mice.Circulating bone marrow transplant (BMT)-derived cells can selectively replace resident microglia,¹³ and up to 30% of microglia can be derived from donor marrow in wild-type mice recipients up to a year after transplantation.^14,15 Moreover, engraftment of brain appears qualitatively more efficient in recipient AD mice than in wild-type controls.^16,17 The reasons for the apparent higher engraftment are not clear, but may be in response to chronic low level immune activation in AD mouse brains.^16,17 Some investigators have shown BMT-derived microglia associated with Aβ deposits in vivo, and that transgenic AD mouse BMT recipients have reduced Aβ plaque burden.¹⁷ Although previous data addressed potential mechanisms by which BMT-derived microglia might promote clearance of Aβ peptides,¹⁸ the results of these studies were confounded by the effects of preconditioning brain irradiation; it is possible that the reduced Aβ plaque burden was caused by irradiation-induced alteration of Aβ production or clearance rather than BMT-derived microglia. In the current studies, we robustly quantify microglial engraftment in brains of APPswe-PS1ΔE9 mice. In addition, we control for the potential confounder of irradiation-mediated Aβ peptide suppression by evaluating Aβ in mice that received cranial-specific irradiation with or without BMT. Finally, we test the hypothesis that BMT with cells from EP2^−/− mice would enhance cerebral bone marrow derived microglia engraftment and clearance of Aβ peptides from cerebrum of APPswe-PS1ΔE9 mice.