Aims:Mutations in DNA/RNA-binding factor (fused-in-sarcoma) FUS and superoxide dismutase-1 (SOD-1) cause amyotrophic lateral sclerosis (ALS). They were reproduced in SOD-1-G93A (SOD-1) and new FUS[1-359]-transgenic (FUS-tg) mice, where inflammation contributes to disease progression. The effects of standard disease therapy and anti-inflammatory treatments were investigated using these mutants. Methods: FUS-tg mice or controls received either vehicle, or standard ALS treatment riluzole (8 mg/kg/day), or anti-inflammatory drug a selective blocker of cyclooxygenase-2 celecoxib (30 mg/kg/day) for six weeks, or a single intracerebroventricular (i.c.v.) infusion of Neuro-Cells (a preparation of 1.39 × 10 6 mesenchymal and hemopoietic human stem cells, containing 5 × 10 5 of CD34 + cells), which showed antiinflammatory properties. SOD-1 mice received i.c.v.-administration of Neuro-Cells or vehicle.Results: All FUS-tg-treated animals displayed less marked reductions in weight gain, food/water intake, and motor deficits than FUS-tg-vehicle-treated mice. Neuro-Celltreated mutants had reduced muscle atrophy and lumbar motor neuron degeneration.This group but not celecoxib-FUS-tg-treated mice had ameliorated motor performance and lumbar expression of microglial activation marker, ionized calcium-binding adapter molecule-1 (Iba-1), and glycogen-synthase-kinase-3ß (GSK-3ß). The Neuro-Cells-treated-SOD-1 mice showed better motor functions than vehicle-treated-SOD-1 group. Conclusion:The neuropathology in FUS-tg mice is sensitive to standard ALS treatments and Neuro-Cells infusion. The latter improves motor outcomes in two ALS models possibly by suppressing microglial activation. | 505MUNTER ET al.
Neurodegenerative disorders share the final degenerative pathway, the inflammation-induced apoptosis and/or necrosis, irrespective of their etiology, be it of acute and chronic traumatic, vascular and idiopathic origin. Although disease-modifying strategies are an unmet need in these disorders, lately, (pre)clinical studies suggested favorable effects after an intervention with bone marrow-derived stromal cells (bm-SC). Recent interventions with intrathecal transplantation of these cells in preclinical rodent models improved the functional outcome and reduced the inflammation, but not anti-inflammatory drugs. The benefit of bm-SCs was demonstrated in rats with an acute (traumatic spinal cord injury, tSCI) and in mice with a chronic [amyotrophic lateral sclerosis (ALS)-like FUS 1-358 or SOD1-G93-A mutation] neurodegenerative process. Bm-SCs, were found to modify underlying disease processes, to reduce final clinical SCI-related outcome, and to slow down ALS-like clinical progression. After double-blind interventions with bm-SC transplantations, Vehicle (placebo), and (non) steroidal anti-inflammatory drugs (Methylprednisolone, Riluzole, Celecoxib), clinical, histological and histochemical findings, serum/spinal cytokines, markers for spinal microglial activation inclusive, evidenced the cell-to-cell action of bm-SCs in both otherwise healthy and immune-deficient tSCI-rats, as well as wild-type and FUS/SOD1-transgenic ALS-like mice. The multi-pathway hypothesis of the cell-to-cell action of bmSCs, presumably using extracellular vesicles (EVs) as carriers of messages in the form of RNAs, DNA, proteins, and lipids rather than influencing a single inflammatory pathway, could be justified by the reported differences of cytokines and other chemokines in the serum and spinal tissue. The mode of action of bm-SCs is hypothesized to be associated with its dedicated adjustment of the pro-apoptotic glycogen synthase kinase-3β level towards an anti-apoptotic level whereas their multi-pathway hypothesis seems to be confirmed by the decreased levels of the pro-inflammatory interleukin (IL)-1β and tumor necrosis factor (TNF) as well as the level of the marker of activated microglia, ionized calcium binding adapter (Iba)-1 level.
Stem cells seem very promising in the treatment of degenerative neurological diseases for which there are currently no or limited therapeutic strategies. However, their clinical application meets many regulatory hurdles. This article gives an overview of stem cells, their potential healing capacities as well as their identified and potential risks, such as tumor formation, unwanted immune responses and the transmission of adventitious agents. As there is no clinical experience with embryonic and induced pluripotent stem cells (as the result of their unacceptable risk on tumor formation), most attention will be paid to fresh autologous adult stem cells (ASCs). To evaluate eventual clinical benefits, preclinical studies are essential, though their value is limited as in these studies, various types of stem cells, with different histories of procurement and culturing, are applied in various concentrations by various routes of administration. On top of that, in most animal studies allogenic human, thus non-autologous, stem cells are applied, which might mask the real effects. More reliable, though small-sized, clinical trials with autologous ASCs did show satisfying clinical benefits in regenerative medicine, without major health concerns. One should wonder, though, why it is so hard to get compelling evidence for the healing and renewing capacities of these stem cells when these cells indeed are really essential for tissue repair during life. Why so many hurdles have to be taken before health authorities such as the European Medicine Agency (EMA) and/or the Food and Drug Administration (FDA) approve stem cells in the treatment of (especially no-option) patients.
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