Bone marrow-derived mesenchymal stem cells (MSCs) account for a small population of cells of the non-hematopoietic component of bone marrow. MSCs are multipotent stem cells endowed with neurotrophic potential combined to immunological properties, making them a promising therapeutic tool for neurodegenerative disorders. Although the mechanisms by which they act are still largely unknown, trans-differentiation, paracrine and autocrine actions have been hypothesized. Here we focus on the study of the effects exerted by rat MSCs on CNS neurons and oligodendrocytes by using a simplified in vitro co-culture system that precludes any direct contact between different cell types. The analysis of hippocampal synaptogenesis, synaptic vesicle recycling and electrical activity show that MSCs by themselves, efficiently support morphological and functional neuronal differentiation. Our observations demonstrate that MSCs selectively and directly increased hippocampal GABAergic presynapses and inhibitory transmission. In fact, this increment correlated to a higher expression of the potassium/chloride KCC2 cotransporter and to an enhancement of both the frequency and the amplitude of mIPSC and sIPSC. The decreased of GABA synapses following the treatment with a widely used Trk-neurotrophin receptor blocker, K252a, and the more specific TrkB receptor bodies prompt for the involvement of the brain derived neurotrophic factor (BDNF) in mediating such effects. The involvement of this neurotrophin is also strengthened by test ELISA on the culture medium collected from MSC-neuron co-cultures in which an higher BDNF concentration was detected, when compared to astrocyte-neuron co-cultures. The results obtained indicate that MSC-secreted factors induce glial-dependent neuronal survival and directly trigger an augmented GABAergic transmission in hippocampal cultures, highlighting a new effect by which MSCs could cooperate in CNS repair. Additionally, MSCs have been described to improve the clinical course of some demyelinating pathologies and to promote tissue repair through immunological mechanisms and neuroprotective effects. Following these evidences we performed in vitro and in vivo experiments to assess whether MSCs exert their actions through the support of oligodendrocytes (OLs), the myelinating CNS cells, and participate in the regulation of their proliferation and maturation. Through the analysis of specific proteins typically used as markers of the different stages of proliferation, maturation and differentiation (specifically, the membrane glycoprotein O4, the proteoglycan NG2 and myelin basic protein MBP, respectively), it has been noticed that MSCs are capable to prolong the proliferation phase of OPCs and also to anticipate OL differentiation, with respect to standard astrocyte/OL co-cultures. Moreover we investigated a possible molecular mechanism underlying these phenomena focusing on neurotrophin pathways. Trk receptors activation was analyzed in order to find out a possible role of neurotrophins in MSC-mediated effects on OLs, as it happens in neuronal cultures. We focused on the changes in the phosphorylation level of ERK (Extracellular signaling-regulated kinases), one of the activated effectors by TrK receptors. Our observations show that, in OLs co-cultured with MSCs, ERK is highly phosphorylated with respect to astrocyte/OL co-cultures, suggesting a MSC-induced activation of the pathways regulated by this protein. These data, although preliminary, suggest that MSCs positively act on the regulation of proliferation and maturation of OLs and, due to the observed effects on the regulation of synaptogenesis (see above), make these cells an interesting model for the identification of molecules involved in MSC neuroprotective processes. This may open new therapeutic approaches in the treatment of neurodegenerative diseases involving not only a synaptic imbalance, as it happens in various forms of epilepsy, but also in demyelinating diseases. Thus, in this research project, we aimed at characterising the molecular mechanisms underlying MSC actions that could participate in the recovery of neurological disorders or demyelinating pathologies.
(2012). Cellule staminali mesenchimali: potenziali modulatori del sistema nervoso centrale. (Tesi di dottorato, Università degli Studi di Milano-Bicocca, 2012).
Cellule staminali mesenchimali: potenziali modulatori del sistema nervoso centrale
MAURI, MARIO
2012
Abstract
Bone marrow-derived mesenchymal stem cells (MSCs) account for a small population of cells of the non-hematopoietic component of bone marrow. MSCs are multipotent stem cells endowed with neurotrophic potential combined to immunological properties, making them a promising therapeutic tool for neurodegenerative disorders. Although the mechanisms by which they act are still largely unknown, trans-differentiation, paracrine and autocrine actions have been hypothesized. Here we focus on the study of the effects exerted by rat MSCs on CNS neurons and oligodendrocytes by using a simplified in vitro co-culture system that precludes any direct contact between different cell types. The analysis of hippocampal synaptogenesis, synaptic vesicle recycling and electrical activity show that MSCs by themselves, efficiently support morphological and functional neuronal differentiation. Our observations demonstrate that MSCs selectively and directly increased hippocampal GABAergic presynapses and inhibitory transmission. In fact, this increment correlated to a higher expression of the potassium/chloride KCC2 cotransporter and to an enhancement of both the frequency and the amplitude of mIPSC and sIPSC. The decreased of GABA synapses following the treatment with a widely used Trk-neurotrophin receptor blocker, K252a, and the more specific TrkB receptor bodies prompt for the involvement of the brain derived neurotrophic factor (BDNF) in mediating such effects. The involvement of this neurotrophin is also strengthened by test ELISA on the culture medium collected from MSC-neuron co-cultures in which an higher BDNF concentration was detected, when compared to astrocyte-neuron co-cultures. The results obtained indicate that MSC-secreted factors induce glial-dependent neuronal survival and directly trigger an augmented GABAergic transmission in hippocampal cultures, highlighting a new effect by which MSCs could cooperate in CNS repair. Additionally, MSCs have been described to improve the clinical course of some demyelinating pathologies and to promote tissue repair through immunological mechanisms and neuroprotective effects. Following these evidences we performed in vitro and in vivo experiments to assess whether MSCs exert their actions through the support of oligodendrocytes (OLs), the myelinating CNS cells, and participate in the regulation of their proliferation and maturation. Through the analysis of specific proteins typically used as markers of the different stages of proliferation, maturation and differentiation (specifically, the membrane glycoprotein O4, the proteoglycan NG2 and myelin basic protein MBP, respectively), it has been noticed that MSCs are capable to prolong the proliferation phase of OPCs and also to anticipate OL differentiation, with respect to standard astrocyte/OL co-cultures. Moreover we investigated a possible molecular mechanism underlying these phenomena focusing on neurotrophin pathways. Trk receptors activation was analyzed in order to find out a possible role of neurotrophins in MSC-mediated effects on OLs, as it happens in neuronal cultures. We focused on the changes in the phosphorylation level of ERK (Extracellular signaling-regulated kinases), one of the activated effectors by TrK receptors. Our observations show that, in OLs co-cultured with MSCs, ERK is highly phosphorylated with respect to astrocyte/OL co-cultures, suggesting a MSC-induced activation of the pathways regulated by this protein. These data, although preliminary, suggest that MSCs positively act on the regulation of proliferation and maturation of OLs and, due to the observed effects on the regulation of synaptogenesis (see above), make these cells an interesting model for the identification of molecules involved in MSC neuroprotective processes. This may open new therapeutic approaches in the treatment of neurodegenerative diseases involving not only a synaptic imbalance, as it happens in various forms of epilepsy, but also in demyelinating diseases. Thus, in this research project, we aimed at characterising the molecular mechanisms underlying MSC actions that could participate in the recovery of neurological disorders or demyelinating pathologies.File | Dimensione | Formato | |
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