Periodic Reporting for period 1 - Neurotoxic (An Ultra-sensitive Assay to Measure Oligomer Induced Toxicity in Human Cerebrospinal Fluid)
Periodo di rendicontazione: 2016-08-01 al 2018-07-31
I have developed a high-throughput biophysical assay which identifies oligomers as the most toxic form of protein aggregates in the complex aggregation mixtures of Aβ42 peptide. For that fabricated nanosized single vesicles as an optochemical probe consists of a native-like model system. Small encapsulation of these vesicles (10-18 L) makes the effective concentrations of encapsulated molecules very high which enables to study protein aggregate induced toxicity study in picomolar protein concentration.
Therefore, thousands of surface immobilize single vesicles have been tethered to the surface of glass coverslides using biotin-neutravidin linkage. Tethering of single vesicles have been shown to maintain their ion permeability, spherical morphology and diffusivity of membranes. In this single vesicle assay to quantify protein aggregate induced toxicity, the fellow has imaged the membrane permeabilization by visualizing Calcium influx into hundreds of these individual vesicles per field of view (2500 µm2) in a high throughput manner using highly sensitive Total internal reflection fluorescence microscopy (TIRFM) approach.
This work has been published in Angewandte Chemie 2017, 56, 7750
Measurement of oligomer induced Ca2+ influx for oligomers - aβ, αS, tau and PrP
Using this assay can identify the most toxic species formed during a protein aggregation reaction. Monomeric Aβ42 was added to the vesicles and no notable membrane disruption was detected, suggesting that the monomeric protein has no toxic effect. Then, monomeric amyloid beta with 42 residues was incubated at 37 °C and an aggregation mixture has been taken at the end of the lag-phase to test its potential toxic effect. At that time of the aggregation the presence of both small protein aggregates and monomeric protein has been shown. After addition and incubation of this aggregation mixture, localized fluorescence increase was detected due to aggregate induced membrane disruption and calcium influx. This suggest membrane disruption suggesting that the aggregated protein gained a toxic function compared to the monomeric protein. The fellow also has tested an aggregation reaction that reached the plateau phase for which most of the monomeric protein has been reported to be converted into fibrils and detected a decreased toxic effect compared with the aggregation reaction at the end of the lag phase. Similarly, we have used this to measure a-Synuclein, tau and PrP oligomer induced membrane permeation.
Part of this work has been published in ACS Chemical biology 2018, 13, 636 and Angewandte Chemie 2018, 57, 4886; ACS NANO 2018 (10.1021/acsnano.8b03575) and Nano Letters 2018 (10.1021/acs.nanolett.8b02916)
Screening of inhibitor to block the Ca2+ influx:
Using protein aggregate specific antibody we are able block protein aggregate induced membrane permeation. I test the effect of different antibodies/nanobodies which are effective at reducing the Calcium influx by inhibiting the membrane permeating effect as a function of antibody concentration. This assay serves as a powerful screening platform for antibodies and nanobodies and also contribute significantly to the development of novel diagnostic tools.
Part of this work has been published in ACS Chemical biology 2018, 13, 636 and Cell Reports 218, 23, 3492.
Translation of this assay to measure toxicity induced by protein aggregate present in human CSF
I have translated this study to the protein aggregate present in CSF of individual affected with Alzheimer’s disease and shown the presence amyloid beta aggregate. I have used various antibodies and nanobodies and compare their inhibition potency using membrane permeation assay. This work is extremely interesting for screening therapeutic agent with target toxic protein aggregates associated with Alzheimer’s diseases.
This work has been published in Cell Reports 20