Generation of an immortalized mesenchymal stem cell line producing a secreted biosensor protein for glucose monitoring.

Generation of an immortalized mesenchymal stem cell line producing a secreted biosensor protein for glucose monitoring.

Diabetes is a chronic disease characterized by high levels of blood glucose. Diabetic patients should normalize these levels in order to avoid short and long term clinical complications. Presently, blood glucose monitoring is dependent on frequent finger pricking and enzyme based systems that analyz...

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Main Authors: Evangelia K Siska, Itamar Weisman, Jacob Romano, Zoltán Ivics, Zsuzsanna Izsvák, Uriel Barkai, Spyros Petrakis, George Koliakos
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2017-01-01
Series:PLoS ONE
Online Access:http://europepmc.org/articles/PMC5614622?pdf=render
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spelling doaj-9b59acb1fe8348dc940a56077e7845672020-11-25T02:27:28ZengPublic Library of Science (PLoS)PLoS ONE1932-62032017-01-01129e018549810.1371/journal.pone.0185498Generation of an immortalized mesenchymal stem cell line producing a secreted biosensor protein for glucose monitoring.Evangelia K SiskaItamar WeismanJacob RomanoZoltán IvicsZsuzsanna IzsvákUriel BarkaiSpyros PetrakisGeorge KoliakosDiabetes is a chronic disease characterized by high levels of blood glucose. Diabetic patients should normalize these levels in order to avoid short and long term clinical complications. Presently, blood glucose monitoring is dependent on frequent finger pricking and enzyme based systems that analyze the drawn blood. Continuous blood glucose monitors are already on market but suffer from technical problems, inaccuracy and short operation time. A novel approach for continuous glucose monitoring is the development of implantable cell-based biosensors that emit light signals corresponding to glucose concentrations. Such devices use genetically modified cells expressing chimeric genes with glucose binding properties. MSCs are good candidates as carrier cells, as they can be genetically engineered and expanded into large numbers. They also possess immunomodulatory properties that, by reducing local inflammation, may assist long operation time. Here, we generated a novel immortalized human MSC line co-expressing hTERT and a secreted glucose biosensor transgene using the Sleeping Beauty transposon technology. Genetically modified hMSCs retained their mesenchymal characteristics. Stable transgene expression was validated biochemically. Increased activity of hTERT was accompanied by elevated and constant level of stem cell pluripotency markers and subsequently, by MSC immortalization. Furthermore, these cells efficiently suppressed PBMC proliferation in MLR transwell assays, indicating that they possess immunomodulatory properties. Finally, biosensor protein produced by MSCs was used to quantify glucose in cell-free assays. Our results indicate that our immortalized MSCs are suitable for measuring glucose concentrations in a physiological range. Thus, they are appropriate for incorporation into a cell-based, immune-privileged, glucose-monitoring medical device.http://europepmc.org/articles/PMC5614622?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Evangelia K Siska
Itamar Weisman
Jacob Romano
Zoltán Ivics
Zsuzsanna Izsvák
Uriel Barkai
Spyros Petrakis
George Koliakos
spellingShingle Evangelia K Siska
Itamar Weisman
Jacob Romano
Zoltán Ivics
Zsuzsanna Izsvák
Uriel Barkai
Spyros Petrakis
George Koliakos
Generation of an immortalized mesenchymal stem cell line producing a secreted biosensor protein for glucose monitoring.
PLoS ONE
author_facet Evangelia K Siska
Itamar Weisman
Jacob Romano
Zoltán Ivics
Zsuzsanna Izsvák
Uriel Barkai
Spyros Petrakis
George Koliakos
author_sort Evangelia K Siska
title Generation of an immortalized mesenchymal stem cell line producing a secreted biosensor protein for glucose monitoring.
title_short Generation of an immortalized mesenchymal stem cell line producing a secreted biosensor protein for glucose monitoring.
title_full Generation of an immortalized mesenchymal stem cell line producing a secreted biosensor protein for glucose monitoring.
title_fullStr Generation of an immortalized mesenchymal stem cell line producing a secreted biosensor protein for glucose monitoring.
title_full_unstemmed Generation of an immortalized mesenchymal stem cell line producing a secreted biosensor protein for glucose monitoring.
title_sort generation of an immortalized mesenchymal stem cell line producing a secreted biosensor protein for glucose monitoring.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2017-01-01
description Diabetes is a chronic disease characterized by high levels of blood glucose. Diabetic patients should normalize these levels in order to avoid short and long term clinical complications. Presently, blood glucose monitoring is dependent on frequent finger pricking and enzyme based systems that analyze the drawn blood. Continuous blood glucose monitors are already on market but suffer from technical problems, inaccuracy and short operation time. A novel approach for continuous glucose monitoring is the development of implantable cell-based biosensors that emit light signals corresponding to glucose concentrations. Such devices use genetically modified cells expressing chimeric genes with glucose binding properties. MSCs are good candidates as carrier cells, as they can be genetically engineered and expanded into large numbers. They also possess immunomodulatory properties that, by reducing local inflammation, may assist long operation time. Here, we generated a novel immortalized human MSC line co-expressing hTERT and a secreted glucose biosensor transgene using the Sleeping Beauty transposon technology. Genetically modified hMSCs retained their mesenchymal characteristics. Stable transgene expression was validated biochemically. Increased activity of hTERT was accompanied by elevated and constant level of stem cell pluripotency markers and subsequently, by MSC immortalization. Furthermore, these cells efficiently suppressed PBMC proliferation in MLR transwell assays, indicating that they possess immunomodulatory properties. Finally, biosensor protein produced by MSCs was used to quantify glucose in cell-free assays. Our results indicate that our immortalized MSCs are suitable for measuring glucose concentrations in a physiological range. Thus, they are appropriate for incorporation into a cell-based, immune-privileged, glucose-monitoring medical device.
url http://europepmc.org/articles/PMC5614622?pdf=render
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