Tau phosphorylation on threonine 217 as a potential biomarker for neurodegenerative diseases / Tau-fosforylering på treonin 217 som en potentiell biomarkör för neurodegenerativa sjukdomar

Omar Jama, Sukri

January 2019

Hyperfosforylering av biomarkörproteinet Tau förekommer i flera neurodegenerativa sjukdomar som kallas Taupathies. Proteinets huvudfunktion i människokroppen är att modulera flexibilitet och stabilitet för axonal-mikrotubulin. I Taupathies utlöser hyperfosforyleringen av Tau instabilitet och neurodegenerationen. I dagens läge kan hyperfosforylering av treonin 217 (P217) endast mätas i hjärnan. I den här studien undersöks hyperfosforyleringen av treonin 217 (P217). I syfte att se om nivåerna av P217 är mätbara i cerebrospinalvätska (CSV) och i blodet. Samt för att evaluera hur nivåer av P217 förändras i olika Taupathies, genom att testa hjärnprover från friska kontroller och olika Taupathies. Studien görs för att öka kunskapen om effekten av hyperfosforylering av treonin 217 i Taupathies och för att bidra med en ny provtagningsmetod för P217. Simoa HD-1 Analyzer var instrumentet som användes för analyserna av P217. Det är ett instrument som kan upptäcka onormala nivåer av biomarkörer genom kvantifiering, med hjälp av antikroppar och ett enzym. Enzymet kallas Streptavidin β-galaktosidas och omvandlar en befintlig P217-molekyl i proven till en fluorescerande produkt. Genom Simoa HD-1 Analyzer utvecklades en ultrasensitiv analys med antikropparna P217 och Tau 12, som kunde upptäcka mycket låga nivåer av P217 i hjärnan, CSF och i blod. Förändring av P217-nivåer hittades även i olika Taupathies. De Taupathies med de högsta nivåerna av P217 var Progressiv supranukleär pares, Corticobasal degeneration och Globular glial Taupathies. / Hyperphosphorylation of the biomarker protein Tau occurs in many neurodegenerative diseases called Taupathies. The proteins main function in the human body is to modulate flexibility and stability for axonal microtubules. In Taupathies the hyperphosphorylation of the Tau triggers instability and neurodegeneration. Nowdays hyperphoshorylation on threonine 217 (P217) can only be measured in the brain. In this study the hyperphoshorylation on the phosphorylation site of threonine 217 (P217) is examined. In aim to see if levels of P217 is measurable in cerebrospinal fluid (CSF) and in blood. As well to evaluate how P217 variate in different Taupathies, through the use of brain samples from healthy controls and different Taupathies. The study is made for the purpose of enhancing the pure knowledge about the effect of hyperphosphorylation on threonine 217 in Taupathies and to contribute with a new sampling method for P217. Simoa HD-1 Analyzer was the key instrument of the analyses of P217. It’s an instrument which can detect abnormal levels of biomarkers through quantification, with help of antibodies and an enzyme. The enzyme is called Streptavidin β-galactosidase and converts an existing P217 molecule in the samples to a fluoresce product. Through the use of Simoa HD-1 Analyzer an ultrasensitive assay with antibodies P217 and Tau 12 was developed which could detect very low levels of P217 in brain, CSF and in blood. Variation of P217 levels was also found in different Taupathies. The Taupathies with the highest levels of P217 was Progressive supranuclear palsy, Corticobasal Degeneration and Globular glial Taupathies.

P217

hyperphosphorylation

Taupathies

CSF

plasma

serum

Simoa

antibodies

assay

Progressive supranuclear palsy

P217

hyperfosforyrlering

Taupathies

CSF

plasma

serum

Simoa

antikroppar

analys

Progressiv supranukleär pares

Engineering and Technology

Teknik och teknologier

Detection and quantification of post-translational modifications in non-invasive samples : Phosphoproteins as biomarkers and a market analysis of protein quantification technologies

Baudin, Sammi, Fjellström, Hillevi, Kraft, Aron, Lamberg, Erica, Rosenbaum, Måns, Sjöstrand, Hanna

January 2023

Post-translational modifications (PTMs) of proteins can be a sign and/or cause of disease. These modified proteins have the potential to be used as biomarkers for diagnostic purposes. However, research in the field is limited. The challenge of having an accessible way of diagnosing patients in time and at a low cost is crucial to improve public health. Blood samples or other non-invasive methods to detect diseases such as Alzheimer’s disease, Parkinson’s disease, Amyotrophic lateral sclerosis and cancers are of urgent need. This report investigates PTMs as possible biomarkers measurable in biofluids, such as blood, for diagnosis and prognosis. Biomarkers like phospho-tau and amyloid-beta are examined in the context of neurodegenerative diseases, as well as phosphorylations on neurofilaments, TAR DNA-binding protein 43 and α-synuclein. All of these are detectable in blood. Several PTMs with connection to different types of cancers are also investigated, such as F3-phosphopeptide and AFP-L3. It was found that many biomarkers for the detection of cancers can potentially be found in extracellular vesicles in blood. Methods such as ELISA, PEA, SomaScan, xMAP, SIMOA and mass spectrometry (MS) are all now available on the market to quantify these PTMs. MS has revolutionized the fields of protein detection in the past and has further evolved to being capable of protein quantification. ELISA has been prevalent for decades and laid the groundwork for improved methods such as xMAP and SIMOA that are easy to use and provide adequate sensitivity. SomaScan and PEA lead the way in dynamic range and multiplexing capacity with around 7000 and 3000 protein assays. The soon-to-be-released technology NULISA, with promising values in sensitivity and dynamic range, is also investigated here. Additionally, a written ethical analysis regarding the process and consequences of biomarker quantification through these technologies was performed. Although the investigated biomarkers are detectable in biofluids, using them as clinical diagnostic markers still poses a challenge, which is why further research in the field is needed. Through an increased knowledge of PTMs of proteins and the right use of platforms, clinical diagnostics and population screenings can be done more efficiently improving public health around the world.

Phorphorylation

Proteomics

Biomarkers

Phosphoproteins

PTM

Amyotrophic lateral sclerosis

ALS

Alzheimer's disease

Parkinson's disease

Cancer

xMAP

SIMOA

NULISA

PEA

ELISA

Mass spectrometry

SomaScan

Engineering and Technology

Teknik och teknologier