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48-602MAG
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Anti-Amyloid β 1-40, clone mHJ2, Cat. No. MABN2422, is a mouse monoclonal antibody that detects Amyloid β 1-40 and is tested for use in ELISA.
More>>Anti-Amyloid β 1-40, clone mHJ2, Cat. No. MABN2422, is a mouse monoclonal antibody that detects Amyloid β 1-40 and is tested for use in ELISA. Less<<
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Übersicht
Replacement Information
Description
Catalogue Number
MABN2422-100UG
Description
Anti-Amyloid β 1-40 Antibody, clone mHJ2
Alternate Names
Amyloid peptide 1-40
Ab40
Background Information
Amyloid-beta A4 protein (UniProt: P05067; also known as ABPP, APPI, APP, Alzheimer disease amyloid protein, Amyloid precursor protein, Amyloid-beta precursor protein, Cerebral vascular amyloid peptide, CVAP, PreA4, Protease nexin-II, PN-II) is encoded by the APP (also known as A4, AD1) gene (Gene ID: 351) in human. Deposition of Aβ peptides is an early event in the pathogenesis of Alzheimer s disease (AD) that precedes the formation of Tau-positive paired helical filaments (PHFs) in NFTs. AD is also characterized by a progressive deposition of the Aβ peptide in senile plaques. Aβ peptides originate from the proteolytic cleavage of the amyloid precursor protein (APP). Processing of APP occurs by two major pathways cleavage of APP by a-secretase is a non-amyloidogenic pathway and does not produce Aβ peptides. Cleavage of APP at the N-terminus of the Aβ region by β-secretase and at the C-terminus by g-secretase represents the amyloidogenic pathway. The β-secretase cleaves APP between residues Met671 and Asp672 and yields sAPPβ and C99. Following the β-secretase cleavage, a second cleavage occurs at the C-terminus of Aβ peptide that releases Aβ from C99. This cleavage occurs in the vicinity of residue 712 of the C-terminus. The g-secretase can cleave the C-terminal region at either Val711 or Ile713 to produce the shorter Aβ peptide (Aβ1-40) or the longer Aβ peptide (Aβ1-42), respectively. The predominant form of Aβ found in the cerebrospinal fluid is the shorter Aβ1-40 peptide. Despite its lower rate of synthesis, Aβ1-42 is the peptide that is initially deposited within the extracellular plaques of AD patients. In addition, Aβ1-42 is more hydrophobic and aggregates at much lower concentration than the Aβ1-40 form. The abnormal accumulation of Aβ peptides can result in neuronal damage and loss by increasing free radical production and activation of inflammatory pathways by enhancing microglial secretion of inflammatory cytokines. Interaction between Aβ and ApoE3 or E4 is also an important determinant of amyloidosis. ApoE3 is shown to inhibit Aβ aggregation in vitro by decreasing Aβ multimers, whereas ApoE4 is reported to accelerate the rate of amyloid fibril formation.
References
Product Information
Format
Purified
Presentation
Purified mouse monoclonal antibody IgG in buffer containing 0.1 M Tris-Glycine (pH 7.4), 150 mM NaCl with 0.05% sodium azide.
Note: Actual optimal working dilutions must be determined by end user as specimens, and experimental conditions may vary with the end user
Biological Information
Immunogen
A linear peptide corresponding to 6 amino acids (35-40) from the C-terminal region of human Amyloid β 1-40 peptide.
Epitope
C-terminal of Amyloid β 1-40 peptide.
Clone
mHJ2
Concentration
1.0 mg/mL. Please refer to guidance on suggested starting dilutions and/or titers per application and sample type.
Host
Mouse
Specificity
Clone mHJ2 is a mouse monoclonal antibody that detects Amyloid β 1-40. It targets an epitope within 6 amino acids from the C-terminal region of the peptide.
4.33 kDa for Ab 1-40 peptide calculated; 86.94 kDa for Amyloid Precursor Protein.
Physicochemical Information
Dimensions
Materials Information
Toxicological Information
Safety Information according to GHS
Safety Information
Product Usage Statements
Quality Assurance
Evaluated by ELISA with human Amyloid β 1-40 peptide ELISA Analysis: Various dilutions (starting at 0.2 mg/mL, two-fold serial dilution; 11 pts) of this antibody detected human Amyloid β 1-40 peptide.
Usage Statement
Unless otherwise stated in our catalog or other company documentation accompanying the product(s), our products are intended for research use only and are not to be used for any other purpose, which includes but is not limited to, unauthorized commercial uses, in vitro diagnostic uses, ex vivo or in vivo therapeutic uses or any type of consumption or application to humans or animals.
Storage and Shipping Information
Storage Conditions
Stable for 1 year at +2°C to +8°C from date of receipt.
Rapid in vivo measurement of β-amyloid reveals biphasic clearance kinetics in an Alzheimer's mouse model Carla M Yuede 1 , Hyo Lee 2 , Jessica L Restivo 2 , Todd A Davis 2 , Jane C Hettinger 2 , Clare E Wallace 2 , Katherine L Young 2 , Margaret R Hayne 2 , Guojun Bu 3 , Chen-Zhong Li 4 , John R Cirrito J Exp Med
213(5)
677-85
2015
Findings from genetic, animal model, and human studies support the observation that accumulation of the β-amyloid (Aβ) peptide in the brain plays a central role in the pathogenic cascade of Alzheimer's disease (AD). Human studies suggest that one key factor leading to accumulation is a defect in brain Aβ clearance. We have developed a novel microimmunoelectrode (MIE) to study the kinetics of Aβ clearance using an electrochemical approach. This is the first study using MIEs in vivo to measure rapid changes in Aβ levels in the brains of living mice. Extracellular, interstitial fluid (ISF) Aβ levels were measured in the hippocampus of APP/PS1 mice. Baseline levels of Aβ40 in the ISF are relatively stable and begin to decline within minutes of blocking Aβ production with a γ-secretase inhibitor. Pretreatment with a P-glycoprotein inhibitor, which blocks blood-brain barrier transport of Aβ, resulted in significant prolongation of Aβ40 half-life, but only in the latter phase of Aβ clearance from the ISF.
TREM2 lipid sensing sustains the microglial response in an Alzheimer's disease model Yaming Wang 1 , Marina Cella 2 , Kaitlin Mallinson 3 , Jason D Ulrich 3 , Katherine L Young 3 , Michelle L Robinette 2 , Susan Gilfillan 2 , Gokul M Krishnan 2 , Shwetha Sudhakar 3 , Bernd H Zinselmeyer 2 , David M Holtzman 3 , John R Cirrito 3 , Marco Colonna Cell
160(6)
1061-71
2015
Triggering receptor expressed on myeloid cells 2 (TREM2) is a microglial surface receptor that triggers intracellular protein tyrosine phosphorylation. Recent genome-wide association studies have shown that a rare R47H mutation of TREM2 correlates with a substantial increase in the risk of developing Alzheimer's disease (AD). To address the basis for this genetic association, we studied TREM2 deficiency in the 5XFAD mouse model of AD. We found that TREM2 deficiency and haploinsufficiency augment β-amyloid (Aβ) accumulation due to a dysfunctional response of microglia, which fail to cluster around Aβ plaques and become apoptotic. We further demonstrate that TREM2 senses a broad array of anionic and zwitterionic lipids known to associate with fibrillar Aβ in lipid membranes and to be exposed on the surface of damaged neurons. Remarkably, the R47H mutation impairs TREM2 detection of lipid ligands. Thus, TREM2 detects damage-associated lipid patterns associated with neurodegeneration, sustaining the microglial response to Aβ accumulation.
Serotonin signaling is associated with lower amyloid-β levels and plaques in transgenic mice and humans John R Cirrito 1 , Brianne M Disabato, Jessica L Restivo, Deborah K Verges, Whitney D Goebel, Anshul Sathyan, Davinder Hayreh, Gina D'Angelo, Tammie Benzinger, Hyejin Yoon, Jungsu Kim, John C Morris, Mark A Mintun, Yvette I Sheline Proc Natl Acad Sci U S A
108(36)
14968-73
2010
Aggregation of amyloid-β (Aβ) as toxic oligomers and amyloid plaques within the brain appears to be the pathogenic event that initiates Alzheimer's disease (AD) lesions. One therapeutic strategy has been to reduce Aβ levels to limit its accumulation. Activation of certain neurotransmitter receptors can regulate Aβ metabolism. We assessed the ability of serotonin signaling to alter brain Aβ levels and plaques in a mouse model of AD and in humans. In mice, brain interstitial fluid (ISF) Aβ levels were decreased by 25% following administration of several selective serotonin reuptake inhibitor (SSRI) antidepressant drugs. Similarly, direct infusion of serotonin into the hippocampus reduced ISF Aβ levels. Serotonin-dependent reductions in Aβ were reversed if mice were pretreated with inhibitors of the extracellular regulated kinase (ERK) signaling cascade. Chronic treatment with an SSRI, citalopram, caused a 50% reduction in brain plaque load in mice. To test whether serotonin signaling could impact Aβ plaques in humans, we retrospectively compared brain amyloid load in cognitively normal elderly participants who were exposed to antidepressant drugs within the past 5 y to participants who were not. Antidepressant-treated participants had significantly less amyloid load as quantified by positron emission tomography (PET) imaging with Pittsburgh Compound B (PIB). Cumulative time of antidepressant use within the 5-y period preceding the scan correlated with less plaque load. These data suggest that serotonin signaling was associated with less Aβ accumulation in cognitively normal individuals.
Opposing synaptic regulation of amyloid-β metabolism by NMDA receptors in vivo Deborah K Verges 1 , Jessica L Restivo, Whitney D Goebel, David M Holtzman, John R Cirrito J Neurosci
31(31)
11328-37
2010
The concentration of amyloid-β (Aβ) within the brain extracellular space is one determinant of whether the peptide will aggregate into toxic species that are important in Alzheimer's disease (AD) pathogenesis. Some types of synaptic activity can regulate Aβ levels. Here we demonstrate two distinct mechanisms that are simultaneously activated by NMDA receptors and regulate brain interstitial fluid (ISF) Aβ levels in opposite directions in the living mouse. Depending on the dose of NMDA administered locally to the brain, ISF Aβ levels either increase or decrease. Low doses of NMDA increase action potentials and synaptic transmission which leads to an elevation in synaptic Aβ generation. In contrast, high doses of NMDA activate signaling pathways that lead to ERK (extracellular-regulated kinase) activation, which reduces processing of APP into Aβ. This depression in Aβ via APP processing occurs despite dramatically elevated synaptic activity. Both of these synaptic mechanisms are simultaneously active, with the balance between them determining whether ISF Aβ levels will increase or decrease. NMDA receptor antagonists increase ISF Aβ levels, suggesting that basal activity at these receptors normally suppresses Aβ levels in vivo. This has implications for understanding normal Aβ metabolism as well as AD pathogenesis.
Overexpression of low-density lipoprotein receptor in the brain markedly inhibits amyloid deposition and increases extracellular A beta clearance Jungsu Kim 1 , Joseph M Castellano, Hong Jiang, Jacob M Basak, Maia Parsadanian, Vi Pham, Stephanie M Mason, Steven M Paul, David M Holtzman Neuron
64(5)
632-44
2009
Apolipoprotein E (APOE) is the strongest genetic risk factor for Alzheimer's disease (AD). Previous studies suggest that the effect of apoE on amyloid-beta (A beta) accumulation plays a major role in AD pathogenesis. Therefore, understanding proteins that control apoE metabolism may provide new targets for regulating A beta levels. LDLR, a member of the LDL receptor family, binds to apoE, yet its potential role in AD pathogenesis remains unclear. We hypothesized that LDLR overexpression in the brain would decrease apoE levels, enhance A beta clearance, and decrease A beta deposition. To test our hypothesis, we created several transgenic mice that overexpress LDLR in the brain and found that apoE levels in these mice decreased by 50%-90%. Furthermore, LDLR overexpression dramatically reduced A beta aggregation and enhanced A beta clearance from the brain extracellular space. Plaque-associated neuroinflammatory responses were attenuated in LDLR transgenic mice. These findings suggest that increasing LDLR levels may represent a novel AD treatment strategy.