Generation and Characterization of Neural Stem Cells Derived from Embryonic Stem Cells using the Default Mechanism

Rowland, James W.

20 December 2011

In embryonic stem cells (ESCs) neural differentiation is elicited in the absence of extrinsic signaling in minimal conditions. This ‘default mechanism’ in ESCs produces neural stem cells termed primitive neural stem cells, which can subsequently yield FGF2-dependent definitive neural stem cells (dNSCs). We hypothesized that dNSCs have properties similar to neural stem/progenitor cells derived from the adult brain (aNPCs). The neural differentiation profile of the cell-types was characterized in vitro and in vivo following transplantation into the Shiverer mouse. The dNSCs produced a differentiation profile similar to that of aNPCs and both cell-types produced oligodendrocytes. This is the first demonstration of the in vivo differentiation of neural stem cells, derived from ESCs through the default mechanism, into the oligodendrocyte lineage. We conclude that dNSCs are a similar cell population to aNPCs. The default mechanism is a promising approach to generate neural stem cells and their progeny from pluripotent cell populations.

Neural Stem Cells

Oligodendrocytes

Myelin

Differentiation

0317

0379

Potential Use of Umbilical Cord Blood Cells in Spinal Cord Injury

Chua, Shawn Julian

30 August 2011

Spinal cord injury (SCI) pathophysiology occurs as a primary traumatic event followed by secondary injury, resulting in the loss of neurons, oligodendrocytes and demyelination of residual axons. Unfortunately, endogenous spontaneous regeneration of oligodendrocytes is minimal. Previously, a method to generate multi-potential stem cells (MPSC) from umbilical cord blood (UCB) has been reported using lineage negative cells (Linneg) grown in fibroblast growth factor 4 (FGF4), stem cell factor (SCF) and fms-like tyrosine kinase receptor-3 ligand (Flt-3l) supplemented serum free medium. These MPSC have the ability to differentiate into bone, muscle and endothelial cells. In this thesis, the ability of MPSC to differentiate into oligodendrocytes was investigated as a potential treatment for SCI. Culturing MPSC under conditions that mimic normal timing of oligodendrocyte differentiation resulted in cells that expressed oligodendrocyte markers in vitro and were morphologically similar to them. I next investigated the ability of MPSC to improve functional recovery in a SCI compression injury model. Although the cells did not differentiate into oligodendrocytes in vivo as we initially hypothesised, a modest but significant improvement in hindlimb function was observed. A cytokine assay revealed that MPSC secrete elevated levels of anti-inflammatory, angiogenic and neurotrophic factors, possibly contributing to indirect mechanisms of repair by reducing secondary injury. Shiverer mouse neonates were next used as an alternative non-injury model to investigate the differentiation potential of MPSC. We hypothesised that transplanting MPSC into a host with an immature immune system and an actively myelinating environment would lead to engraftment and differentiation into oligodendrocytes. However no MPSC that differentiated into oligodendrocytes could be detected. Altogether, our in vitro data adds support for the reprogramming of cells, with further studies needed to test the functionality of resulting oligodendrocyte-like cells. Although MPSC failed to differentiate in both in vivo models, several potential therapeutic targets to treat SCI were found.

Umbilical Cord Blood

Oligodendrocytes

Spinal Cord Injury

0379

Potential Use of Umbilical Cord Blood Cells in Spinal Cord Injury

Chua, Shawn Julian

30 August 2011

Spinal cord injury (SCI) pathophysiology occurs as a primary traumatic event followed by secondary injury, resulting in the loss of neurons, oligodendrocytes and demyelination of residual axons. Unfortunately, endogenous spontaneous regeneration of oligodendrocytes is minimal. Previously, a method to generate multi-potential stem cells (MPSC) from umbilical cord blood (UCB) has been reported using lineage negative cells (Linneg) grown in fibroblast growth factor 4 (FGF4), stem cell factor (SCF) and fms-like tyrosine kinase receptor-3 ligand (Flt-3l) supplemented serum free medium. These MPSC have the ability to differentiate into bone, muscle and endothelial cells. In this thesis, the ability of MPSC to differentiate into oligodendrocytes was investigated as a potential treatment for SCI. Culturing MPSC under conditions that mimic normal timing of oligodendrocyte differentiation resulted in cells that expressed oligodendrocyte markers in vitro and were morphologically similar to them. I next investigated the ability of MPSC to improve functional recovery in a SCI compression injury model. Although the cells did not differentiate into oligodendrocytes in vivo as we initially hypothesised, a modest but significant improvement in hindlimb function was observed. A cytokine assay revealed that MPSC secrete elevated levels of anti-inflammatory, angiogenic and neurotrophic factors, possibly contributing to indirect mechanisms of repair by reducing secondary injury. Shiverer mouse neonates were next used as an alternative non-injury model to investigate the differentiation potential of MPSC. We hypothesised that transplanting MPSC into a host with an immature immune system and an actively myelinating environment would lead to engraftment and differentiation into oligodendrocytes. However no MPSC that differentiated into oligodendrocytes could be detected. Altogether, our in vitro data adds support for the reprogramming of cells, with further studies needed to test the functionality of resulting oligodendrocyte-like cells. Although MPSC failed to differentiate in both in vivo models, several potential therapeutic targets to treat SCI were found.

Umbilical Cord Blood

Oligodendrocytes

Spinal Cord Injury

0379

Investigation of myelin membrane adhesion and compaction in the central nervous system

Bakhti, Mostafa

23 October 2012

Myelin ist eine mehrschichtige Membran, die die Axone in peripheren (PNS) und Zentrale Nervensystem (ZNS) umhüllt. Die Bildung und Anordnung dieser Struktur ist ein mehrstufiger Prozess, der durch eine Vielzahl extrazellulärer Faktoren reguliert wird. Im ZNS wird Myelin von Oligodendrozyten gebildet. Während der Entwicklung differenzieren die Vorläufer dieser Zellen zu reifen Oligodendrozyten aus. Nachdem sie das geeignete Signal aus ihrer Umgebung erhalten haben, beginnen die Oligodendrozyten die Axone mit Myelinmembranen einzuhüllen.  Allerdings sind die Signale, die diesen Prozess initiieren unbekannt. Mit dieser Arbeit zeigen wir, dass Oligodendrozyten kleine Mikrovesikel - so genannte Exosomen - in den extrazellulären Raum freisetzen, welche die terminale Differenzierung von Oligodendrozyten und die anschließende Myelinbildung verhindern. Es konnte gezeigt werden, dass diese inhibitorische Wirkung durch die Aktivität der RhoA-ROCK-Signalkaskade vermittelt wird. Bemerkenswerterweise war die Exosomenfreisetzumg durch Oligodendrozyten signifikant reduziert, wenn die Zellen mit konditioniertem Medium von Neuronen inkubiert wurden. Unsere Ergebnisse legen nahe, dass Exosomen, die von Oligodendrozyten produziert werden,  Zellen in einem pre-myelinisierten Stadium halten, während die Sekretion von Exosomen in Gegenwart neuronaler Signale reduziert wird und autoinhibitorische Signale aufgehoben werden. Somit können Neuronen die Bildung und Freisetzung von Exosomen regulieren, welche von Oligodendrozyten freigesetzt werden, um die Biogenese und Assemblierung der Myelinmembran zu koordinieren.  Im zweiten Teil der Arbeit wurde die Frage, wie die Kompaktierung des Myelins vermittelt wird, erörtert. Während bekannt ist, dass MBP die Interaktion zwischen Myelinmembranen von cytoplasmatischer Seite aus organisiert, ist der zugrundeliegende molekulare Mechanismus der Interaktion zwischen den äußeren Membranen nach wie vor unklar. Im Allgemeinen erfordert die Interaktion zwischen zwei gegenüberliegenden Membranen die Expression von Adhäsionsmolekülen und die Entfernung von repulsiven Komponenten. Daher untersuchten wir die Rolle des Proteolipid-Proteins (PLP), als mutmaßliches Adhäsionsmolekül, und die Glykocalix, als repulsive Struktur während der Myelinkompaktierung im ZNS. Wir analysierten die Adhäsion von aufgereinigten Myelinpartikeln mit den primären Oligodendrozyten, um die Wechselwirkung zwischen den Myelinschichten zu imitieren. Mit diesem System haben wir gezeigt, dass PLP die Adhäsionsfähigkeit der Myelinmembran erhöht. Mittels Single Particle Force-Spektroskopie fanden wir außerdem heraus, dass PLP die physikalische Stabilität von Myelin verbessert. Zusätzlich beobachteten wir eine signifikante Reduzierung in der Glykokalix während der Oligodendrozytenreifung, die mit einer Zunahme in ihrer Oberflächenaffinität gegenüber den Myelinpartikeln korreliert. Weitere Analysen zeigten, dass die negative Ladung der Zuckeranteile, hauptsächlich der Sialinsäure, für die Verringerung der Myelinadhäsion verantwortlich ist. Daher schlagen wir vor, dass die Adhäsionseigenschaften von PLP zusammen mit der Reduzierung der Glykokalyx, die Adhäsion der Myelinmembran und die  Kompaktierung im ZNS organisieren.

570

150

Myelin

Exosomes

Oligodendrocytes

Adhesion

Glycocalyx

Biologie (PPN619462639)

CX3CR1/CX3CL1 axis drives the migration and maturation of oligodendroglia in the central nervous system

Ford, Catriona Barbara

January 2017

In the central nervous system, the axons of neurons are protected from damage and aided in electrical conductivity by the myelin sheath, a complex of proteins and lipids formed by oligodendrocytes. Loss or damage to the myelin sheath may result in impairment of electrical axonal conduction and eventually to neuronal death. Such demyelination is responsible, at least in part, for the disabling neurodegeneration observed in pathologies such as Multiple Sclerosis (MS) and Spinal Cord Injury. In the regenerative process of remyelination, oligodendrocyte precursor cells (OPCs), the resident glial stem cell population of the adult CNS, migrate toward the injury site, proliferate and differentiate into adult oligodendrocytes which subsequently reform the myelin sheath. Existing research indicates that OPC migration is directed by chemomigratory signals released from the site of injury and that the absence of OPCs is a feature of some MS lesions, suggesting that increased recruitment of OPCs to injury sites might improve remyelination, eventually leading to treatments of patient pathologies. I hypothesized that as yet undiscovered migration cues for OPCs might be released at sites of demyelination, diffuse through the CNS tissue, activate distal OPCs and guide them back to sites of demyelination. In this thesis, I performed bioinformatics analysis of gene expression arrays and identified upregulated cell surface receptors on OPCs activated in a cuprizone model, and upregulated secreted factors in whole lesion sites from an LPC induced MS type injury model and a Spinal Cord Injury model. I then optimised the X-celligence system for the quantification of OPC migration in response to secreted factors identified in my bioinformatics screen. By combination of these techniques with immunofluorescent staining I discovered novel expression of the cell surface receptor CX3CR1 on OPCs, increased expression of the corresponding ligand CX3CL1 in both MS type injury and Spinal Cord Injury, increased directional migration of OPCs in response to low concentrations of CX3CL1, and increased maturation of OPCs into adult oligodendrocytes at high concentrations of CX3CL1. Taken together these results propose a system in which an increasing gradient of CX3CL1 released from the site of injury directs the recruitment, then maturation of OPCs, making CX3CL1 a master regulator of OPC led CNS regeneration.

Oxidative Stress Susceptibility of Oligodendrocytes in Major Depressive Disorder is Widespread in the Brain

Coulthard, Jacob, Ongtengco, Westley, Garst, Jacob, Chandley, Michelle, Wang-Heaton, Hui, Ordway, Gregory A.

05 April 2018

Over 10 million people are affected by major depressive disorder (MDD) in the U.S. annually. Unfortunately, about 1/3 of these people do not achieve adequate remission of symptoms with current antidepressant drugs. It is expected that an improved understanding of the pathobiology of depression will result in the development of more effective antidepressant treatments. Research by this lab in recent years has provided evidence of elevated DNA damage in brain white matter in MDD, discovered by studying brain tissues from human brain donors that had an active diagnosis of MDD at the time of death and age-matched control donors who had no psychiatric illness. Accompanying this DNA damage was an elevation of gene expression of DNA base excision repair enzymes in white matter oligodendrocytes, a major cell type in brain white matter. In addition, gene expression of antioxidant genes in these oligodendrocytes was significantly lower in MDD than in control donors, suggesting that these cells were especially susceptible to the damaging effects of oxidative stress in MDD. This initial data was generated by measuring gene expressions in oligodendrocytes captured from two specific regions of white matter in the brain, the frontal cortex, and amygdala. In the present study, we designed experiments to determine whether these effects are found in oligodendrocytes in other areas of the brain in MDD and to determine whether another cell type in the brain, neurons, are similarly affected. Towards these aims, oligodendrocytes from two other brain regions (occipital cortical white matter and brainstem locus coeruleus) were captured by laser microdissection from MDD and control donors. In addition, CA1 pyramidal neurons were captured from the anterior hippocampus of MDD and control donors. We chose to specifically study hippocampal CA1 pyramidal neurons because these neurons are normally sensitive to oxidative stress, and reasoned that these cells would be among brain neurons most likely affected by conditions of elevated oxidative stress in MDD. Approximately 500 cells were captured from each brain area using immunohistochemically-guided laser capture microdissection. RNA isolated from these cells was converted to cDNA by reverse transcription and subjected to quantitative polymerase chain reactions (PCR). Statistically significant reductions in antioxidant gene expression was observed in oligodendrocytes from MDD donors as compared to control donors regardless of the brain area from which the cells were captured. In contrast, no significant changes in antioxidant gene expression were observed in CA1 pyramidal neurons from MDD donors. Additionally in contrast to findings in oligodendrocytes, levels of gene expression of the DNA repair enzyme, poly(ADP-ribose) polymerase 1 (PARP1) in hippocampal CA1 pyramidal neurons from MDD donors was similar to that from control donors. These findings demonstrate that pathological DNA damage and repair mechanisms occur in brain oligodendrocytes throughout the brain, and similar mechanisms do not appear to affect hippocampal neurons. A better understanding of the cellular systems engaged by oxidative damage to oligodendrocytes in MDD has the potential to lead to the identification of unique targets for the development of novel antidepressant drugs.

Oligodendrocytes

Oxidative stress

Major depressive disorder

Neuroscience and Neurobiology

Accelerated Glia Aging by Shortened Telomere Length in White Matter Oligodendrocytes and Astrocytes in Major Depression

Szebeni, Attila, Szebeni, Katalin, DiPeri, T., Stockmeier, Craig A., Ordway, Gregory A.

01 January 2012

No description available.

depression

astrocytes

oligodendrocytes

white matter

telomere

glia

aging

Biomedical Sciences

Shortened Telomere Length in White Matter Oligodendrocytes in Major Depression: Potential Role of Oxidative Stress

Szebeni, Attila, Szebeni, Katalin, DiPeri, Timothy, Chandley, Michelle J., Crawford, Jessica D., Stockmeier, Craig A., Ordway, Gregory A.

01 January 2014

Telomere shortening is observed in peripheral mononuclear cells from patients with major depressive disorder (MDD). Whether this finding and its biological causes impact the health of the brain in MDD is unknown. Brain cells have differing vulnerabilities to biological mechanisms known to play a role in accelerating telomere shortening. Here, two glia cell populations (oligodendrocytes and astrocytes) known to have different vulnerabilities to a key mediator of telomere shortening, oxidative stress, were studied. The two cell populations were separately collected by laser capture micro-dissection of two white matter regions shown previously to demonstrate pathology in MDD patients. Cells were collected from brain donors with MDD at the time of death and age-matched psychiatrically normal control donors (N=12 donor pairs). Relative telomere lengths in white matter oligodendrocytes, but not astrocytes, from both brain regions were significantly shorter for MDD donors as compared to matched control donors. Gene expression levels of telomerase reverse transcriptase were significantly lower in white matter oligodendrocytes from MDD as compared to control donors. Likewise, the gene expression of oxidative defence enzymes superoxide dismutases (SOD1 and SOD2), catalase (CAT) and glutathione peroxidase (GPX1) were significantly lower in oligodendrocytes from MDD as compared to control donors. No such gene expression changes were observed in astrocytes from MDD donors. These findings suggest that attenuated oxidative stress defence and deficient telomerase contribute to telomere shortening in oligodendrocytes in MDD, and suggest an aetiological link between telomere shortening and white matter abnormalities previously described in MDD.

astrocytes

major depression

oligodendrocytes

suicide

telomere

Biomedical Sciences

OLIG2 neural progenitor cell development and fate in Down syndrome

Klein, Jenny A.

24 January 2023

Down syndrome (DS) is caused by triplication of human chromosome 21 (HSA21) and is the most common genetic form of intellectual disability. It is unknown precisely how triplication of HSA21 results in the intellectual disability, but it is thought that the global transcriptional dysregulation caused by trisomy 21 perturbs multiple aspects of neurodevelopment that cumulatively contribute to its etiology. While the characteristics associated with DS can arise from any of the genes triplicated on HSA21, in this work we focus on oligodendrocyte transcription factor 2 (OLIG2). The progeny of neural progenitor cells (NPCs) expressing OLIG2 are likely to be involved in many of the cellular changes underlying the intellectual disability in DS. To explore the fate of OLIG2+ neural progenitors, we took advantage of two distinct models of DS, the Ts65Dn mouse model and induced pluripotent stem cells (iPSCs) derived from individuals with DS. Our results from these two systems identified multiple perturbations in development in the cellular progeny of OLIG2+ NPCs. In Ts65Dn, we identified alterations in neurons and glia derived from the OLIG2 expressing progenitor domain in the ventral spinal cord. There were significant differences in the number of motor neurons and interneurons present in the trisomic lumbar spinal cord depending on age of the animal pointing both to a neurodevelopment and a neurodegeneration phenotype in the Ts65Dn mice. Of particular note, we identified changes in oligodendrocyte (OL) maturation in the trisomic mice that are dependent on spatial location and developmental origin. In the dorsal corticospinal tract, there were significantly fewer mature OLs in the trisomic mice, and in the lateral funiculus we observed the opposite phenotype with more mature OLs being present in the trisomic animals. We then transitioned our studies into iPSCs where we were able to pattern OLIG2+ NPCs to either a spinal cord-like or a brain-like identity and study the OL lineage that differentiated from each progenitor pool. Similar to the region-specific dysregulation found in the Ts65Dn spinal cord, we identified perturbations in trisomic OLs that were dependent on whether the NPCs had been patterned to a brain-like or spinal cord-like fate. In the spinal cord-like NPCs, there was no difference in the proportion of cells expressing either OLIG2 or NKX2.2, the two transcription factors whose co-expression is essential for OL differentiation. Conversely, in the brain-like NPCs, there was a significant increase in OLIG2+ cells in the trisomic culture and a decrease in NKX2.2 mRNA expression. We identified a sonic hedgehog (SHH) signaling based mechanism underlying these changes in OLIG2 and NKX2.2 expression in the brain-like NPCs and normalized the proportion of trisomic cells expressing the transcription factors to euploid levels by modulating the activity of the SHH pathway. Finally, we continued the differentiation of the brain-like and spinal cord-like NPCs to committed OL precursor cells (OPCs) and allowed them to mature. We identified an increase in OPC production in the spinal cord-like trisomic culture which was not present in the brain-like OPCs. Conversely, we identified a maturation deficit in the brain-like trisomic OLs that was not present in the spinal cord-like OPCs. These results underscore the importance of regional patterning in characterizing changes in cell differentiation and fate in DS. Together, the findings presented in this work contribute to the understanding of the cellular and molecular etiology of the intellectual disability in DS and in particular the contribution of cells differentiated from OLIG2+ progenitors.

Neurosciences

Down syndrome

iPSCs

Neural precursor cells

OLIG2

Oligodendrocytes

Signaling Mechanisms Involved in the Regulation of Histone Deacteylase Activity in Oligodendrocyte Precursor Cells

Prox, Jordan Daniel

16 May 2014

No description available.

Biochemistry

Neurosciences

Multiple Sclerosis

histone deacetylase

glutamate

oligodendrocytes