Local irradiation not only induces homing of human mesenchymal stem cells at exposed sites but promotes their widespread engraftment to multiple organs: a study of their quantitative distribution after irradiation damage

Mesenchymal stem cells (MSCs) have been shown to migrate to various tissues. There is little information on the fate and potential therapeutic efficacy of the reinfusion of MSCs following total body irradiation (TBI). We addressed this question using human MSC (hMSCs) infused to nonobese diabetic/ severe combined immunodeficient (NOD/SCID) mice submitted to TBI. Further, we tested the impact of additional local irradiation (ALI) superimposed to TBI, as a model of accidental irradiation. NOD/SCID mice were transplanted with hM-SCs. Group 1 was not irradiated before receiving hMSC infusion. Group 2 received only TBI at a dose of 3.5 Gy, group 3 received local irradiation to the abdomen at a dose of 4.5 Gy in addition to TBI, and group 4 received local irradiation to the leg at 26.5 Gy in addition to TBI. Fifteen days after irradiation, quantitative and spatial distribution of the hMSCs were studied. Histological analysis of mouse tissues confirmed the presence of radio-induced lesions in the irradiated fields. Following their infusion into nonirradiated animals, hMSCs homed at a very low level to various tissues (lung, bone marrow, and muscles) and no significant engraftment was found in other organs. TBI induced an increase of engraftment levels of hMSCs in the brain, heart, bone marrow, and muscles. Abdominal irradiation (AI) as compared with leg irradiation (LI) increased hMSC engraftment in the exposed area (the gut, liver, and spleen). Hind LI as compared with AI increased hMSC engraftment in the exposed area (skin, quadriceps, and muscles). An increase of hMSC engraftment in organs outside the fields of the ALI was also observed. Conversely, following LI, hMSC engraftment was increased in the brain as compared with AI. This study shows that engraftment of hMSCs in NOD/ SCID mice with significantly increased in response to tissue injuries following TBI with or without ALI. ALI induced an increase of the level of engraftment at sites outside the local irradiation field, thus suggesting a distant (abscopal) effect of radiation damage. This work supports the use of MSCs to repair damaged normal tissues following accidental irradiation and possibly in patients submitted to radiotherapy.

Human mesenchymal stem cells home specifically to radiation-injured tissues in a non-obese diabetes/severe combined immunodeficiency mouse model

The therapeutic potential of bone marrow-derived human mesenchymal stem cells (hMSC) has recently been brought into the spotlights of many fields of research. One possible application of the approach is the repair of tissue injuries related to side effects of radiotherapy. The first challenge in cell therapy is to assess the quality of the cell and the ability to retain their differentiation potential during the expansion process. Efficient delivery to the sites of intended action is also necessary. We addressed both challenges using hMSC cultured and then infused to non-obese diabetes/severe combined immunodeficiency (NOD/SCID) mice submitted to total body irradiation. Furthermore, we tested the impact of additional abdominal irradiation superimposed to total body irradiation (TBI), as a model of local therapeutic irradiation. Our results showed that the hMSC used for transplant have been expanded without significant loss in their differentiation capacities. After transplantation into adult unconditioned mice, hMSC not only migrate in bone marrow but also into other tissues. Total body irradiation increased hMSC implantation in bone marrow and muscle and further led to engraftment in brain, heart and liver. Local irradiation in addition to TBI, increased homing of injected cells to the injured tissues and to other tissues outside the local irradiation field. Morphological recovery of irradiated tissues after MSC transplantation and/or differentiation of MSC into specific organ cell types needs to be investigated. This study suggests that using the potential of hMSC to home to various organs in response to tissue injuries might be a strategy to repair the radiation-induced damages.

Human mesenchymal stem cells favour healing of the cutaneous radiation syndrome in a xenogenic transplant model

It has been suggested that human mesenchymal stem cells (hMSC) could be used to repair numerous injured tissues. We have studied the potential use of hMSC to limit radiation-induced skin lesions. Immunodeficient NOD/SCID mice were locally irradiated to the leg (30 Gy, dose rate 2.7 Gy/min) using a (60)Co source to induce a severe skin lesion. Cultured bone marrow hMSC were delivered intravenously to the mice. The irradiated skin samples were studied for the presence of the human cells, the severity of the lesions and the healing process. Macroscopic analysis and histology results showed that the lesions were evolving to a less severe degree of radiation dermatitis after hMSC transplant when compared to irradiated non-transplanted controls. Clinical scores for the studied skin parameters of treated mice were significantly improved. A faster healing was observed when compared to untreated mouse. Immunohistology and polymerase chain reaction analysis provided evidence that the human cells were found in the irradiated area. These results suggest a possible use of hMSC for the treatment of the early phase of the cutaneous radiation syndrome. A successful transplant of stem cells and subsequent reduction in radiation-induced complication may open the road to completely new strategies in cutaneous radiation syndrome therapy.

Involvement of p53 and Fas/CD95 in murine neural progenitor cell response to ionizing irradiation

We investigated the role of tumor suppressor p53 and Fas (CD95/APO-1), a member of the tumor necrosis factor receptor family, in neural progenitors response to gamma-irradiation exposure. Telencephalic cells were obtained from wild-type C57Bl/6, or p53-/- or fas-/-, 15-day-old mouse embryos. They were cultured in conditions allowing neural progenitors to form proliferating clusters (neurospheres). A 2 Gy gamma-irradiation induced a G1 cell cycle arrest and triggered apoptosis in wild-type neural progenitor cultures in correlation with an enhanced expression of p53 and of its downstream target p21(WAF1), both of them acquiring a nuclear localization. These effects did not occur in p53-/- neural progenitors demonstrating the central role played by p53 in their response to ionizing radiation. Furthermore, the monoclonal antibody Jo2 directed against Fas induced apoptosis of wild type but not of fas-/- neural progenitors, indicating the existence of a functional Fas signaling pathway in neural progenitors. Ionizing radiation induced an increase of Fas membrane expression related to a p53-dependent increase of fas mRNA expression in wild-type neural progenitors. Moreover, fas-/- neural progenitors exhibited delayed radiation-induced apoptosis compared to wild-type cells. Therefore, these findings establish a role for Fas/CD95 related to p53 in the response of neural progenitors to gamma-radiation exposure. Similar mechanisms could be triggered in neural progenitors in case of different stresses during brain development or in the course of various diseases affecting the adult brain.

Effect of serotonin inhibition on glucocorticoid and mineralocorticoid expression in various brain structures

Many studies have shown the existence of functional interactions between central neurotransmitter systems and the hypothalamo-pituitary adrenal axis. Mineralocorticoid receptors (MR) and glucocorticoid receptors (GR) are regulated by multiple factors including glucocorticoids themselves. Neurotransmitters such as serotonin (5-hydroxytryptamine: 5-HT) can regulate brain corticosteroid receptors in a complex way. The present study examined the short-term (48 h) effects of parachlorophenylalanine (PCPA), a drug which specifically inhibits 5-HT synthesis, on corticosteroid receptor levels and on the expression of their respective messenger ribonucleic acids (mRNA) in the rat hippocampus, hypothalamus and brain stem. The study was performed in bilaterally adrenalectomized animals, in order to avoid potential drug-induced changes in plasma corticosterone levels, which could secondarily regulate MR and GR. Short-term inhibition of 5-HT synthesis by PCPA significantly increased the number of hippocampal MR-binding sites. PCPA treatment did not alter the number of GR-binding sites in the hippocampus, hypothalamus and brain stem. We observed no change in the affinities of GR and MR sites in all the structures studied. In PCPA-treated rats, restoration of control 5-HT levels by injection of its immediate precursor, 5-hydroxytryptophan (5-HTP) brings the number of hippocampal MR-binding sites back to control levels. It can therefore be concluded that the increase in number of MR-binding sites induced by acute PCPA treatment is dependent on the decrease in 5-HT levels. The increase in hippocampal MR binding sites was correlated with an induction of their messengers, suggesting that 5-HT modulates the synthesis of MR protein. Although PCPA did not modify the number of hippocampal GR-binding sites, a decrease in hippocampal GR mRNA expression was observed. This study shows that 5-HT inhibits hippocampal mineralocorticoid receptor synthesis and that this effect is not mediated by changes in corticosterone hormone secretion, and illustrates the existence of complex mechanisms for corticosteroid receptor regulation in the hippocampus.

[Vestibular toxicity of gentamycin: value of the galvanic test (author's transl)]

A total of 6 cases of bilateral vestibular areflexia due to Gentamycin are reported. Vestibular destruction was associated with deafness in only 3 of the patients. Two patients had no signs of renal insufficiency. Galvanic vestibular exploration showed complete and bilateral lack of excitability in 3 out of 4 cases, which could be due to the co-existence of nerve or nuclei lesions. In one case, galvanic excitability was within normal limits, and severe equilibrium problems presisted. The presence of an asymmetry on galvanic examination could be an unfavourable prognostic sign in vestibular toxicity due to Gentamycin.