Transplanting Mesenchymal Stem Cells for Treatment of Ischemic Stroke

Immunomodulation and Post-Stroke Inflammation

Although it is well accepted that immune response is important in the pathogenesis of ischemic stroke, the current knowledge on immune response in focal cerebral ischemia is far from sufficient ²⁴ . The immune system becomes active in response to neuronal damage in the event of focal cerebral ischemia or transient ischemia. After stroke, immediate activation of innate immunity triggers inflammation ²⁵ . Inflammatory mediators recruit more immune cells both in the central nervous system and from the periphery. The production of more inflammatory mediators will further activate the adaptive immunity ²⁶ . Inflammation, regression of inflammation, and repair of nerve damage are key successions after stroke. Although the inflammatory response is initially beneficial for limiting and resolving ischemic stress, an unrestricted inflammatory response by the continuous infiltration of immune cells such as neutrophils, macrophages, natural killer (NK) cells and T cells, can cause significant damage to the penumbra after cerebral ischemic injury ^27,28 .

In vivo and in vitro examination showed that after studying hypoxic stroke neuronal cells and animal models of ischemic stroke, researchers found that MSCs reduced the expression of tumor necrosis factor-α and NF-kB through the vascular endothelial growth factor (VEGF) signaling as well as the interleukin-6 (IL-6) signaling ²⁹ . The inhibition of NF-kB is associated with the anti-inflammatory and anti-apoptotic effects of MSCs ³⁰ . Human umbilical cord blood MSCs remarkably attenuated the expression of IL-23 and IL-17 in infarcts and serum ³¹ , reduced the infarct size, and alleviated neurological deficits in the middle cerebral artery occlusion (MCAO) model. MSCs secrete transforming growth factor-β (TGF-β) by attenuating the upregulation of monocyte chemoattractant protein-1 (MCP-1) as well as the penetration of CD68⁺ immune cells via the compromised blood–brain barrier (BBB) to prevent the peripheral immune cells from exacerbating the inflammatory response in the ischemic rat brain ³² . In the ischemic stroke rat model, human MSCs reduced microglia activation, as indicated by lower expression of ED1 and Iba-1. They also attenuated astrogliosis, as indicated by lower GFAP level. These beneficial effects involved the noncanonical JAK-STAT signaling with unphosphorylated STAT3 in the immune cells ³³ .

Impact on Astrocyte, Microglia, Oligodendrocyte, and Axon

In the event of cerebral ischemia, astrocytes release neurotrophic factors and growth factors upon the simulation of MSCs administration. These factors include insulin-like growth factor 1 (IGF-1), VEGF, epidermal growth factor (EGF), and basic fibroblast growth factor (bFGF) ³⁴ . Astrocytic apoptosis is attenuated and ischemic-induced aquaporin-4 upregulation is normalized by MSCs, which contributes to maintaining BBB integrity after cerebral infarction ³⁵ . MSCs reduce the TGFβ1 expressing in microglia/macrophages at the border of the ischemic area and promote down-regulation of the levels of plasminogen activator inhibitor 1 (PAI-1) in astroglia cells. After stroke, ingrown tPA and depressor PAI-1 are connected to neurite reconstruction ³⁶ .

Oligodendrocytes play an important role in the restoration after ischemia ³⁷ . The oligodendrocyte precursor cells (OPCs) appear in the corpus callosum, corpus striatum and subventricular zone (SVZ) of adult mouse brain, differentiating into mature oligodendroglia cells (OLs). OLs are very sensitive to the ischemic stress since the white matter blood flow is lower than that in gray matter; the blood supply for deep white matter is even less ³⁸ . Myelin sheaths in the form of mature oligodendrocytes are used to sprout axons in ischemic tissues. The transplantation of bone marrow (BM)-MSCs increased the number of oligodendrocyte progenitor cells in the ischemic hemisphere as well as the number of mature oligodendrocytes surrounding the lesion ³⁹ .

During the experimental stroke, BM-MSCs increased the axonal density in the surrounding area, which persisted for at least 1 year after stroke ⁴⁰ . MSCs decrease the protein expression of reticulin (Rtn4 or Nogo) and induced neurocan (Ncan), an inhibitor of axonal growth ⁴⁰ . According to Alder et al. ⁴¹ , umbilical cord tissue-derived cells (hUTC) and MSCs of human secret the brain-derived neurotrophic factor (BDNF), leading to increased amount and size of main dendrites.

Increased Neurogenesis

Ischemic stroke injury causes a dramatic increase in the proliferation of NSCs, triggering gliogenesis and neurogenesis in SVZ and circumventricular organs (CVOs). Down the third and fourth ventricles, some niches of new stem cell are detected in the context of stroke. It is important that all niches share a common feature – rich in vasculature with high permeability ⁴² . The incremental post-stroke neurogenesis was observed in elderly patients ⁴³ . Hypoxic preconditioning of transplanted BMSCs could promote their regenerative capability for the treatment of ischemic stroke ⁴⁴ . BDNF-modified hBM-MSCs (MSCs-BDNF) promoted endogenous neurogenesis and functional recovery in MCAO rat models ⁴⁵ . Systemic administration of exosomes released from mesenchymal stromal cells promoted endogenous neurogenesis after stroke in rats ⁴⁶ . It was found that the ultrasound promoted neurogenesis when the mouse stroke models were exposed to 0.04 MHz ultrasound after hBM-MSCs injection ⁴⁷ .

Although post-stroke neurogenesis has been largely described, its role on restoration is still unknown ⁴⁸ . The cellular therapy triggers the phosphatidylinositol-3-kinase (PI3 K)/Akt pathway in neural precursor cells, promoting cell survival, proliferation, and differentiation, as well as migration ⁴⁹ . Upon the stimulation by BM-MSCs, brain parenchymal cells release neurotrophic factors, such as fibroblast growth factor and BDNF, to activate Akt/PI3 k pathway ⁵⁰ . A study showed that transplanting hBMSCs into the ipsilateral brain parenchyma of MCAO rats could increase the expression of BDNF, neurotrophin-3 (NT-3) and VEGF in ischemic brain tissue, reduce infarct volume, and improve neurological function. Possibly, mechanisms for these beneficial effects were increased proliferation of neuronal progenitor cells in SVZ and in the subgranular zone (SGZ), accelerated migration of newborn neuroblasts to the ischemic border region (IBZ), diminished apoptosis, and increased differentiation of these cells into mature neurons ⁵¹ . Wharton’s jelly (WJ-MSC) induced better neurogenesis via a paracrine mechanism, WJ-MSC expressed more genes involved in angiogenesis and neurogenesis, especially secretory factors ⁵² .

Angiogenesis

Intravenous administration of BM-MSCs leads to releasing angiogenic growth factors as well as neurotrophic factors in time order, which includes angiogenin, hepatocyte growth factor (HGF), BDNF, fibroblast growth factor-2 (FGF-2), IGF-1, neutrophil activating protein 2 (NAP-2), and VEGF, to stimulate post-stroke neuronal growth and vascular formation ⁵³ . These growth factors and neurotrophins all function in a paracrine or autocrine manner ⁵⁴ , which can regulate the cell differentiation, proliferation, and survival. In the peri-infarct area, some researchers found that the expression of these factors has been elevated by BM-MSCs, including stromal cell-derived factor-1 (SDF-1), BDNF, platelet-derived growth factor-AA (PDGF-AA), basic fibroblast growth factor, angiopoietin-2, CXCL-16, neutrophil-activating protein-2, and vascular endothelial growth factor receptor-3 ⁵⁵ . Furthermore, the expression of the axonal growth linked protein-43 (GAP-43) was also increased significantly in the brain tissues treated with BM-MSCs, while the axonal growth inhibitory protein ROCK II and NG2 were inhibited.

In the cerebral infarction region, the transplantation of BM-MSCs enhances the directed immigration and survival of neuroblasts as well ⁵⁶ . The level of VEGF, phosphorylated ERK1/2 and RAF1 increases notably due to BM-MNC treatment, which also decreases the damage by white matter, stimulates angiogenesis, and facilitates a cognitive recovery in rats having bilateral common carotid arteries occlusion ⁵⁶ .

Other studies have compared various sources of MSCs based on biologically active molecular secretion, the effects of angiogenesis and functional recovery after experimental stroke, as well as different routes of administration. In the rat stroke model, BM-MSCs through intravenous and intra-arterial delivery improved brain perfusion and metastasis by the assessment of SPECT and PET, particularly in rats treated with arterial perfusion delivery. No micro-strokes have been found after intra-arterial injection ⁵⁷ . In another research, it was found that MSCs from adipose tissue (AD-MSCs) had the same effect as BM-MSCs in facilitating functional recovery, reducing necrosis and increasing neurogenesis, cell proliferation, and the markers of angiogenesis (e.g. VEGF) expression at 14 days after infarction in the model of rat stroke ⁵⁸ . As to cellular MSCs-created exosomes post-stroke and traumatic brain injury, intravenous administration can improve functional recovery and enhance neurite reconstruction, angiogenesis as well as neurogenesis ^46,59,60 .

To improve growth factors delivery, some groups used transgenic stem cells of mesenchyme to overexpress growth factors that are known to trigger the survival as well as the differentiation of neurons. According to Van Velthoven et al. ⁶¹ , the over-expressed BDNF on MSCs have an advantage over regular MSCs in the rat MCAO model in improving dyskinesia. Via intravenous or intracranial administration, Kurozumi et al ⁶² used MSCs transgene with fiber-mutant adenovirus vector having BDNF or GDNF (glial cell derived neurotrophic factor). Both decreased the infarct volume by 6% to 40% with equal efficacy. With herpes simplex virus type 1 (HSV-1) vector transgenic MSCs carrying VEGF, Miki et al. ⁶³ found that it reduced infarct volume by 10% and improved functional deficits. Onda et al. ⁶⁴ used an adenoviral vector-modified MSCs having angiopoietin 1, which reduced the infarct size by 30% and alleviated motor deficits.

Novel Mechanisms of MSCs

Several novel mechanisms of MSCs have been studied, for example, mitochondrial or exosomal transfer from transplanted MSCs or the use of gene therapy of MSCs. Currently, there are few research studies on mitochondrial or exosomal transfer from transplanted MSCs in ischemic stroke.

It has been shown that mitochondrial transfer can rescue stressed cells ⁶⁵ and restore the loss of mitochondrial function in recipient cells ⁶⁶ . Han et al. ⁶⁷ found BM-MSCs rescued injured H9c2 cells via transferring mitochondria through tunneling nanotubes in an in vitro simulated ischemia/reperfusion model. A similar study showed that MSCs rescued injured endothelial cells in an in vitro ischemia-reperfusion model via tunneling nanotube like structure-mediated mitochondrial transfer ⁶⁸ . Exosomes are microvesicles released by cells ranging from 40 to 100 nanometers ⁶⁹ . They are produced by the endocytosis of cell membranes and the subsequent formation of intracellular vesicles, which are released into the extracellular space by exocytosis ⁶⁹ . They exist in any biological fluid such as urine, cerebrospinal fluid, or blood. They are surrounded by a lipid bilayer. They contain nucleic acids such as messenger RNA (mRNA) and microRNA (miRNA) and other different molecules ⁷⁰ . Thus, they represent a new kind of intercellular communication mechanism. There is growing evidence that exosomes play an important role in cell-cell communication ⁷¹ . MSCs also release exosomes, and data shows that exosomes released by MSCs mediate communication between the MSCs and other cells ⁷² . Xin et al. ⁶⁰ suggested that exosomes from MSCs mediated the transfer of miR-133b to neurons and astrocytes that regulated gene expression, subsequently contributing to neurite remodeling and functional recovery following ischemic stroke. A review outlines the role of exosomes from MSCs in the recovery of ischemic stroke ⁷³ .

MSC-based gene therapy represents a novel potential therapeutic strategy for ischemic stroke in future. The current strategy based on cell therapy emphasizes the introduction of beneficial genes, which will improve the therapeutic ability of MSCs and have better homing efficiency. It has a wide range of implications in stem cell biology. The methods of MSC gene delivery include physical methods, chemical methods, and the use of viral vectors. Several physical methods such as nuclear transfection ⁷⁴ , electroporation ⁷⁵ , nanoparticle ⁷⁶ , and ultrasound transfection ⁷⁷ were used to deliver the beneficial genes into MSCs. In addition to physical methods of gene delivery, several chemotherapeutics mediated by cationic lipids ⁷⁸ , calcium phosphates ⁷⁹ , cationic polymers ⁸⁰ , cationic polysaccharides ⁸¹ , and cationic peptides ⁸² have been used for gene delivery. The main advantage of these non-virus-mediated (physical and chemical) gene delivery techniques is that they could be easily performed. However, the use of physical and chemical methods is limited due to low efficiency, not being suitable for transfection of large numbers of cells, and the use of chemical drugs possibly leading to higher concentrations of toxicity ⁸³ . In addition, safety concerns have been considered, due to the non-degradable nature of certain polymers: for example, polyethylenimine (PEI) is a cationic non-degradable synthetic polymer, which is the most commonly used polymer for the development of nanocarriers for siRNA delivery, but at the expense of cytotoxicity, due to limited degradability ⁸⁴ . Due to the limitations and disadvantages of the non-viral methods of gene delivery described above, some studies have used viral vectors to improve gene delivery. The viruses currently used as vectors are lentiviruses, adenoviruses, adeno-associated viruses, retroviruses, and baculoviruses ⁸⁵ . Huang et al. ⁸⁶ found that lentiviral vector-mediated BDNF gene-modified MSCs could enhance its therapeutic effect in ischemic stroke. Zhao et al. ⁸⁷ introduced a novel strategy for combining transfer of MSCs and ex vivo HGF gene with multiple mutant herpes simplex virus type 1 vectors in a rat model of transient MCAO; the study showed that combination therapy was more effective than treatment with MSCs alone and might extend the treatment window from hyperacute to acute. At present, viral vector-based cytogenetic modification is widely used. However, low transduction efficiency and transgene potential limit its application in clinical trials.