Rescue from lethal acute radiation syndrome (ARS) with severe weight loss by secretome of intramuscularly injected human placental stromal cells

Background Most current cell‐based regenerative therapies are based on the indirect induction of the affected tissues repair. Xenogeneic cell‐based treatment with expanded human placenta stromal cells, predominantly from fetal origin (PLX‐RAD cells), were shown to mitigate significantly acute radiat...

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Bibliographic Details
Published in:Journal of cachexia, sarcopenia and muscle sarcopenia and muscle, 2018-12, Vol.9 (6), p.1079-1092
Main Authors: Pinzur, Lena, Akyuez, Levent, Levdansky, Lilia, Blumenfeld, Michal, Volinsky, Evgenia, Aberman, Zami, Reinke, Petra, Ofir, Racheli, Volk, Hans‐Dieter, Gorodetsky, Raphael
Format: Article
Language:English
Subjects:
Acute radiation syndrome
Acute Radiation Syndrome - diagnosis
Acute Radiation Syndrome - metabolism
Acute Radiation Syndrome - therapy
Animal welfare
Animals
Blood
Cell Transplantation
Cytokines
Disease Models, Animal
Experiments
Failure
Female
Granulocytes
Growth factors
Hematopoiesis
Humans
Injections, Intramuscular
Intramuscular injection
ISO standards
Male
Mice
Original
Placenta
Placenta - cytology
Placental stromal cells
Pregnancy
Secretome
Stromal Cells - metabolism
Stromal Cells - transplantation
Studies
Weight Loss
Whole-Body Irradiation
X‐ray irradiation
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Summary:Background Most current cell‐based regenerative therapies are based on the indirect induction of the affected tissues repair. Xenogeneic cell‐based treatment with expanded human placenta stromal cells, predominantly from fetal origin (PLX‐RAD cells), were shown to mitigate significantly acute radiation syndrome (ARS) following high dose irradiation in mice, with expedited regain of weight loss and haematopoietic function. The current mechanistic study explores the indirect effect of the secretome of PLX‐RAD cells in the rescue of the irradiated mice. Methods The mitigation of the ARS was investigated following two intramuscularly (IM) injected 2 × 106 PLX‐RAD cells, 1 and 5 days following 7.7 Gy irradiation. The mice survival rate and their blood or bone marrow (BM) cell counts were followed up and correlated with multiplex immunoassay of a panel of related human proteins of PLX‐RAD derived secretome, as well as endogenous secretion of related mouse proteins. PLX‐RAD secretome was also tested in vitro for its effect on the induction of the migration of BM progenitors. Results A 7.7 Gy whole body mice irradiation resulted in ~25% survival by 21 days. Treatment with two IM injections of 2 × 106 PLX‐RAD cells on days 1 and 5 after irradiation mitigated highly significantly the subsequent lethal ARS, with survival rate increase to nearly 100% and fast regain of the initial weight loss (P < 0,0001). This was associated with a significant faster haematopoiesis recovery from day 9 onwards (P < 0.01). Nine out of the 65 human proteins tested were highly significantly elevated in the mouse circulation, peaking on days 6–9 after irradiation, relative to negligible levels in non‐irradiated PLX‐RAD injected mice (P < 0.01). The highly elevated proteins included human G‐CSF, GRO, MCP‐1, IL‐6 and lL‐8, reaching >500 pg/mL, while MCP‐3, ENA, Eotaxin and fractalkine levels ranged between ~60–160pg/mL. The detected radiation‐induced PLX‐RAD secretome correlated well with the timing of the fast haematopoiesis regeneration. The radiation‐induced PLX‐RAD secretome seemed to reinforce the delayed high levels secretion of related mouse endogenous cytokines, including GCSF, KC, MCP‐1 and IL‐6. Additional supportive in vitro studies also confirmed the ability of cultured PLX‐RAD secretome to induce accelerated migration of BM progenitors. Conclusions A well‐regulated and orchestrated secretion of major pro‐regenerative BM supporting secretome in high dose irradiated mice, treated
ISSN:2190-5991
2190-6009
DOI:10.1002/jcsm.12342