Novel hyperactive transposons for genetic modification of induced pluripotent and adult stem cells: A nonviral paradigm for coaxed differentiation

Eyayu Belay; Janka Mátrai; Abel Acosta-Sanchez; Ling Ma; Mattia Quattrocelli; Lajos Mátés; Pau Sancho-Bru; Martine Geraerts; Bing Yan; Joris Vermeesch; Melvin Yesid Rincón; Ermira Samara-Kuko; Zoltán Ivics; Catherine Verfaillie; Maurilio Sampaolesi; Zsuzsanna Izsvák; Thierry Vandendriessche; Marinee K.L. Chuah

doi:10.1002/stem.501

Novel hyperactive transposons for genetic modification of induced pluripotent and adult stem cells: A nonviral paradigm for coaxed differentiation

Eyayu Belay, Janka Mátrai, Abel Acosta-Sanchez, Ling Ma, Mattia Quattrocelli, Lajos Mátés, Pau Sancho-Bru, Martine Geraerts, Bing Yan, Joris Vermeesch, Melvin Yesid Rincón, Ermira Samara-Kuko, Zoltán Ivics, Catherine Verfaillie, Maurilio Sampaolesi, Zsuzsanna Izsvák^*, Thierry Vandendriessche, Marinee K.L. Chuah

^*Corresponding author for this work

Pharmacology

Research output: Contribution to journal › Article › peer-review

45 Scopus citations

Abstract

Adult stem cells and induced pluripotent stem cells (iPS) hold great promise for regenerative medicine. The development of robust nonviral approaches for stem cell gene transfer would facilitate functional studies and potential clinical applications. We have previously generated hyperactive transposases derived from Sleeping Beauty, using an in vitro molecular evolution and selection paradigm. We now demonstrate that these hyperactive transposases resulted in superior gene transfer efficiencies and expression in mesenchymal and muscle stem/progenitor cells, consistent with higher expression levels of therapeutically relevant proteins including coagulation factor IX. Their differentiation potential and karyotype was not affected. Moreover, stable transposition could also be achieved in iPS, which retained their ability to differentiate along neuronal, cardiac, and hepatic lineages without causing cytogenetic abnormalities. Most importantly, transposonmediated delivery of the myogenic PAX3 transcription factor into iPS coaxed their differentiation into MYOD+ myogenic progenitors and multinucleated myofibers, suggesting that PAX3 may serve as a myogenic "molecular switch" in iPS. Hence, this hyperactive transposon system represents an attractive nonviral gene transfer platform with broad implications for regenerative medicine, cell and gene therapy.

Original language	English (US)
Pages (from-to)	1760-1771
Number of pages	12
Journal	Stem Cells
Volume	28
Issue number	10
DOIs	https://doi.org/10.1002/stem.501
State	Published - Oct 2010

Keywords

Mesenchymal stem cell
Muscle
Myoblast
Sleeping beauty
Stem cell
Transposon
iPS

ASJC Scopus subject areas

Molecular Medicine
Developmental Biology
Cell Biology

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Belay, E., Mátrai, J., Acosta-Sanchez, A., Ma, L., Quattrocelli, M., Mátés, L., Sancho-Bru, P., Geraerts, M., Yan, B., Vermeesch, J., Rincón, M. Y., Samara-Kuko, E., Ivics, Z., Verfaillie, C., Sampaolesi, M., Izsvák, Z., Vandendriessche, T., & Chuah, M. K. L. (2010). Novel hyperactive transposons for genetic modification of induced pluripotent and adult stem cells: A nonviral paradigm for coaxed differentiation. Stem Cells, 28(10), 1760-1771. https://doi.org/10.1002/stem.501

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title = "Novel hyperactive transposons for genetic modification of induced pluripotent and adult stem cells: A nonviral paradigm for coaxed differentiation",

abstract = "Adult stem cells and induced pluripotent stem cells (iPS) hold great promise for regenerative medicine. The development of robust nonviral approaches for stem cell gene transfer would facilitate functional studies and potential clinical applications. We have previously generated hyperactive transposases derived from Sleeping Beauty, using an in vitro molecular evolution and selection paradigm. We now demonstrate that these hyperactive transposases resulted in superior gene transfer efficiencies and expression in mesenchymal and muscle stem/progenitor cells, consistent with higher expression levels of therapeutically relevant proteins including coagulation factor IX. Their differentiation potential and karyotype was not affected. Moreover, stable transposition could also be achieved in iPS, which retained their ability to differentiate along neuronal, cardiac, and hepatic lineages without causing cytogenetic abnormalities. Most importantly, transposonmediated delivery of the myogenic PAX3 transcription factor into iPS coaxed their differentiation into MYOD+ myogenic progenitors and multinucleated myofibers, suggesting that PAX3 may serve as a myogenic {"}molecular switch{"} in iPS. Hence, this hyperactive transposon system represents an attractive nonviral gene transfer platform with broad implications for regenerative medicine, cell and gene therapy.",

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author = "Eyayu Belay and Janka M{\'a}trai and Abel Acosta-Sanchez and Ling Ma and Mattia Quattrocelli and Lajos M{\'a}t{\'e}s and Pau Sancho-Bru and Martine Geraerts and Bing Yan and Joris Vermeesch and Rinc{\'o}n, {Melvin Yesid} and Ermira Samara-Kuko and Zolt{\'a}n Ivics and Catherine Verfaillie and Maurilio Sampaolesi and Zsuzsanna Izsv{\'a}k and Thierry Vandendriessche and Chuah, {Marinee K.L.}",

year = "2010",

month = oct,

doi = "10.1002/stem.501",

language = "English (US)",

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Belay, E, Mátrai, J, Acosta-Sanchez, A, Ma, L, Quattrocelli, M, Mátés, L, Sancho-Bru, P, Geraerts, M, Yan, B, Vermeesch, J, Rincón, MY, Samara-Kuko, E, Ivics, Z, Verfaillie, C, Sampaolesi, M, Izsvák, Z, Vandendriessche, T & Chuah, MKL 2010, 'Novel hyperactive transposons for genetic modification of induced pluripotent and adult stem cells: A nonviral paradigm for coaxed differentiation', Stem Cells, vol. 28, no. 10, pp. 1760-1771. https://doi.org/10.1002/stem.501

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T2 - A nonviral paradigm for coaxed differentiation

AU - Belay, Eyayu

AU - Mátrai, Janka

AU - Acosta-Sanchez, Abel

AU - Ma, Ling

AU - Quattrocelli, Mattia

AU - Mátés, Lajos

AU - Sancho-Bru, Pau

AU - Geraerts, Martine

AU - Yan, Bing

AU - Vermeesch, Joris

AU - Rincón, Melvin Yesid

AU - Samara-Kuko, Ermira

AU - Ivics, Zoltán

AU - Verfaillie, Catherine

AU - Sampaolesi, Maurilio

AU - Izsvák, Zsuzsanna

AU - Vandendriessche, Thierry

AU - Chuah, Marinee K.L.

PY - 2010/10

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N2 - Adult stem cells and induced pluripotent stem cells (iPS) hold great promise for regenerative medicine. The development of robust nonviral approaches for stem cell gene transfer would facilitate functional studies and potential clinical applications. We have previously generated hyperactive transposases derived from Sleeping Beauty, using an in vitro molecular evolution and selection paradigm. We now demonstrate that these hyperactive transposases resulted in superior gene transfer efficiencies and expression in mesenchymal and muscle stem/progenitor cells, consistent with higher expression levels of therapeutically relevant proteins including coagulation factor IX. Their differentiation potential and karyotype was not affected. Moreover, stable transposition could also be achieved in iPS, which retained their ability to differentiate along neuronal, cardiac, and hepatic lineages without causing cytogenetic abnormalities. Most importantly, transposonmediated delivery of the myogenic PAX3 transcription factor into iPS coaxed their differentiation into MYOD+ myogenic progenitors and multinucleated myofibers, suggesting that PAX3 may serve as a myogenic "molecular switch" in iPS. Hence, this hyperactive transposon system represents an attractive nonviral gene transfer platform with broad implications for regenerative medicine, cell and gene therapy.

AB - Adult stem cells and induced pluripotent stem cells (iPS) hold great promise for regenerative medicine. The development of robust nonviral approaches for stem cell gene transfer would facilitate functional studies and potential clinical applications. We have previously generated hyperactive transposases derived from Sleeping Beauty, using an in vitro molecular evolution and selection paradigm. We now demonstrate that these hyperactive transposases resulted in superior gene transfer efficiencies and expression in mesenchymal and muscle stem/progenitor cells, consistent with higher expression levels of therapeutically relevant proteins including coagulation factor IX. Their differentiation potential and karyotype was not affected. Moreover, stable transposition could also be achieved in iPS, which retained their ability to differentiate along neuronal, cardiac, and hepatic lineages without causing cytogenetic abnormalities. Most importantly, transposonmediated delivery of the myogenic PAX3 transcription factor into iPS coaxed their differentiation into MYOD+ myogenic progenitors and multinucleated myofibers, suggesting that PAX3 may serve as a myogenic "molecular switch" in iPS. Hence, this hyperactive transposon system represents an attractive nonviral gene transfer platform with broad implications for regenerative medicine, cell and gene therapy.

KW - Mesenchymal stem cell

KW - Muscle

KW - Myoblast

KW - Sleeping beauty

KW - Stem cell

KW - Transposon

KW - iPS

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Novel hyperactive transposons for genetic modification of induced pluripotent and adult stem cells: A nonviral paradigm for coaxed differentiation

Abstract

Keywords

ASJC Scopus subject areas

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