Transduction of Neural Precursor Cells with TAT-Heat Shock Protein 70 Chaperone: Therapeutic Potential Against Ischemic Stroke after Intrastriatal and Systemic Transplantation

Doeppner, Thorsten R.; Ewert, Tobias A. S.; Tönges, Lars; Herz, Josephine; Zechariah, Anil; ElAli, Ayman; Ludwig, Anna‐Kristin; Giebel, Bernd; Nagel, Florian; Dietz, Gunnar P.H.; Weise, Jens; Hermann, Dirk M.; Bähr, Mathias

doi:10.1002/stem.1098

Cited by 73 publications

(113 citation statements)

References 62 publications

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“…12 Adult Subventricular Zone-Derived Neural Precursor Cells Neural precursor cells were isolated from the SVZ of 6 to 8-week old male transgenic green fluorescence protein positive (GFP þ ) animals (C57BL/6-Tg ACTB-EGFP, 1Osb/J; JAX Laboratory, Bar Harbor, ME, USA) as described. 14 The SVZ was microdissected under stereomicroscopic control (Zeiss, Jena, Germany) and minced into small pieces, followed by mechanical trituration and dissociation into a single-cell suspension. Thereafter, cells were cultured in serum-free basic DMEM (Dulbecco's Modified Eagle Medium)-F12 (PAA, Pasching, Austria) supplemented with epidermal growth factor (2 mg/mL), basic fibroblast growth factor (2 mg/mL), and penicillin-streptomycin (Invitrogen, Darmstadt, Germany).…”

Section: Preparation Of Recombinant Proteinsmentioning

confidence: 99%

TAT-Hsp70 Induces Neuroprotection Against Stroke Via Anti-Inflammatory Actions Providing Appropriate Cellular Microenvironment for Transplantation of Neural Precursor Cells

Doeppner

Kaltwasser

Jin

et al. 2013

J Cereb Blood Flow Metab

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Heat-shock protein 70 (Hsp70) protects against cerebral ischemia, which is attributed to its chaperone activity. However, recent reports also describe pro-inflammatory actions of Hsp70 via activation of Toll-like receptors (TLR). Using membrane-permeable transactivator of transcription (TAT)-Hsp70, we analyzed TAT-Hsp70-induced neuroprotection and its underlying mechanism after cerebral ischemia in mice. Infusion of TAT-Hsp70 reduced infarct volume and enhanced blood-brain barrier integrity on day 3 poststroke, when given no later than 12 hours. The latter was associated with reduction of microglial activation, although upregulation of pro-inflammatory TLR-2/4 was observed both in verum and in control animals. Nevertheless, protein abundance and nuclear translocation of downstream nuclear factor kappa B (NF-kB) as well as proteasomal degradation of the NF-kB regulator Ikappa B alpha (IkB-a) were significantly reduced by TAT-Hsp70. TAT-Hsp70-induced neuroprotection and functional recovery were restricted to 4 weeks only. However, TAT-Hsp70 provided an appropriate extracellular milieu for delayed intravenous transplantation of adult neural precursor cells (NPCs). Thus, NPCs that were grafted 28 days poststroke induced long-term neuroprotection for at least 3 months, which was not due to integration of grafted cells but rather due to paracrine effects of transplanted NPCs. Conclusively, TAT-Hsp70 ameliorates postischemic inflammation via proteasome inhibition, thus providing an appropriate extracellular milieu for delayed NPC transplantation and culminating in long-term neuroprotection.

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Section: Preparation Of Recombinant Proteinsmentioning

confidence: 99%

TAT-Hsp70 Induces Neuroprotection Against Stroke Via Anti-Inflammatory Actions Providing Appropriate Cellular Microenvironment for Transplantation of Neural Precursor Cells

Doeppner

Kaltwasser

Jin

et al. 2013

J Cereb Blood Flow Metab

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“…According with this study in the first stage of stroke when we need to prevent BBB leakage and ROS formation systemic transplantation of NPCs can be the best route. Later in the subacute stage, when we need to enhance endogenous neurogenesis and promote long-term neuroprotection intracerebral transplantation seems to be the best route of delivery, which is followed by increased production of growth factors [24].…”

Section: Discussionmentioning

confidence: 99%

“…However, exogenous NSCs cells appear to have different mechanisms of action depending on delivery route. In this light, systemic delivery of NPCs in the acute phase (first 24h) of stroke in adult mice (11-13 weeks) has neuroprotective effect by preventing Blood-Brain-Barrier (BBB) damage, decrease matrix metalloprotease 9(MMP9) overexpression and Reactive Oxygen Species (ROS) [24].…”

Section: Neural Progenitor Cell Therapy In Ischemia-reperfusion Injurymentioning

confidence: 99%

Current Stage and Future Perspective of Stem Cell Therapy in Ischemic Stroke

Ana-Maria¹,

Carmen²,

Tudorică³

2017

J Stem Cell Res Ther

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“…Хорошие результаты пока-зало применение дефинитивных стволовых и прогениторных клеток, полученных из раз-личных тканевых источников, которые были трансплантированы локально или системно животным, с моделированной фокальной це-ребральной ишемией [9]. Хотя прижившиеся клетки, как полагают, и не интегрировались в существующие нейронные сети, зато они спо-собствовали неврологическому восстановле-нию через непрямые паракринные механизмы, которые включают в себя стимуляцию эндо-генного ангионейрогенеза и пластичности ней-ронов, стабилизацию гематоэнцефалического барьера, а также модуляцию периферического и центрального иммунного ответа [10].…”

Section: стволовые и прогениторные клетки в экс-периментальных моделяunclassified

“…В частности, НПК, полученные из СВЗ боковых желудочков мозга, индуцируют мощный ней-ропротекторный эффект и ремоделирование головного мозга, как при системном, так и при локальном (интрацеребральном) введении. Этот аспект заслуживает особого внимания, так как по отношению к НПК до сих пор досто-верно не показана возможность их интеграции в нейронные сети, действие в основном проис-ходит через паракринные механизмы [9,10].…”

Section: нейральные прогениторные клетки и дру-гие стволовые клетки дunclassified

Cell Therapy of Stroke and Spinal Cord Injury Complications

Konoplyannikov¹,

Baklaushev²,

Kalsin³

et al. 2015

Journal of Clinical Practice

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е!ь …%" В обзоре анализируется современное состояние проблемы клеточной терапии неврологи-ческих осложнений ишемического инсульта и позвоночно-спинномозговой травмы (ПСМТ). Приводятся современные данные по использованию различных типов стволовых клеток для терапии данных тяжелых нарушений, полученные как в экспериментальных исследованиях на животных моделях, так и в результате клинических исследований. Наиболее подробно рассма-тривается применение мезенхимальных стволовых клеток (МСК) и нейральных стволовых/ прогениторных клеток (НСК/НПК) для терапии инсульта и ПСМТ. Обсуждаются дальнейшие перспективы развития клеточной терапии указанных заболеваний.Ключевые слова: ишемический инсульт, позвоночно-спинномозговая травма, стволовые клет-ки, мезенхимальные стволовые клетки, нейральные стволовые/прогениторные клетки. CELL THERAPY OF STROKE AND SPINAL CORD INJURY COMPLICATIONSThe review analyzes the current advances of cell therapy for neurological complications of ischemic stroke and spinal cord injury (SCI). We demonstrate the most recent data on the use of different types of stem cells for the treatment of these severe damages, obtained both in experimental studies using animal models and in clinical studies. We particularly discuss the use of mesenchymal stem cells (MSC) and neural stem/progenitor cells (NSC/NPC) for the treatment of stroke and SCI. We also discuss the prospects for a further development of cell therapy of these diseases.

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Transduction of Neural Precursor Cells with TAT-Heat Shock Protein 70 Chaperone: Therapeutic Potential Against Ischemic Stroke after Intrastriatal and Systemic Transplantation

Cited by 73 publications

References 62 publications

TAT-Hsp70 Induces Neuroprotection Against Stroke Via Anti-Inflammatory Actions Providing Appropriate Cellular Microenvironment for Transplantation of Neural Precursor Cells

TAT-Hsp70 Induces Neuroprotection Against Stroke Via Anti-Inflammatory Actions Providing Appropriate Cellular Microenvironment for Transplantation of Neural Precursor Cells

Current Stage and Future Perspective of Stem Cell Therapy in Ischemic Stroke

Cell Therapy of Stroke and Spinal Cord Injury Complications

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