EFFECTS OF GLIAL CELL LINE-DERIVED NEUROTROPHIC FACTOR (GDNF) ON STEM/PROGENITOR CELL PROLIFERATION AND DIFFERENTIATION

Chen, Yan

01 January 2005

Stem/progenitor cells are present in the adult brain; they undergo constantproliferation and differentiate into mature neurons in certain brain areas, a phenomenoncalled neurogenesis. This study investigated the effects of GDNF, a potent trophic factorof dopaminergic neurons, on neurogenesis in the brain. Nestin and 5-Bromo-2'-deoxyuridine (BrdU) were used as stem/progenitor cells markers.First, we observed extensive bilateral increases of stem/progenitor cells in thedentate gyrus and substantia nigra after continuous infusion of GDNF into the normal ratbrain. However, none of the BrdU+ cells showed neuronal features in the substantia nigraas characterized by immunocytochemical procedures. Next, we identified themorphology of BrdU+ cells after infusing the marker into the brain. While the proceduresincreased the BrdU labeling, neurogenesis was not observed in the basal ganglia. Underelectron microscope, the BrdU+ cells either were undifferentiated or showedcharacteristics of astrocytes. This observation is consistent with suggestions thatastrocytes serve as multipotent progenitors. Later, we repeated GDNF intrastriatalinfusion one month after a severe 6-hydroxydopamine (6-OHDA) lesion. The number ofBrdU+ cells was significantly higher in the GDNF recipients in the ipsilateral substantianigra and both sides of the dentate gyrus. However, no neurogenesis was observed. Inaddition, motor functions were not improved by GDNF treatment. Thus, we measured theeffects of GDNF administration directly into the substantia nigra six hours before apartial 6-OHDA lesion. HPLC measurements of dopamine and its metabolites showed asignificant increase of tissue level in the substantia nigra and striatum, respectively.Despite this, no newly generated dopaminergic neurons was detected in the basal ganglia.Taken together, our studies investigated the effects of GDNF on adultstem/progenitor cells in normal and lesioned rat brain. For the first time, we demonstratedthat GDNF promoted their proliferation in the dentate gyrus, suggesting it has a role inneurogenesis and the function of learning and memory. In each scenario, GDNFpromoted stem/progenitor cell proliferation, but failed to induce neurogenesis in thesubstantia nigra. We believed that the local microenvironment in the substantia nigra mayprevent the stem/progenitor cells to mature into functional neurons.

Biological Effects of Osteopontin on Endothelial Progenitor Cells

Altalhi, Wafa

03 October 2011

Endothelial Progenitor Cells (EPCs) are thought to participate in the healing of injured vascular endothelium by incorporating into the defect sites to mediate endothelial recovery. Recently, osteopontin (OPN) was shown to be fundamental in accelerating estrogen-dependent healing of injured blood vessels. Here, we are investigating the effect OPN has on EPC behavior. Late outgrowth human EPCs (LEPCs) were derived from circulating monocytes isolated by leukophoresis, and grown in culture until passage six. L-EPCs were then assayed for adhesion, spreading, chemotaxis, and haptotaxis, as well as resistance to detachment by flow electric cellsubstrate impedance sensing (ECIS). The results of standard and ECIS methods showed both dose and time dependent responses in cell adhesion and spreading. In addition, OPN promoted haptotactic migration of EPCs in Boyden chamber assays. LEPCs seeded onto 10μM OPN substrates and exposed to laminar flow had grater survival and higher resistance to detachment than OPN/static and flow only conditions. CD44 and !1 integrins were only responsible for approximately 50% of LEPCs adhesion to OPN compared to the unblocked condition. Western blots showed that Rho GTPases were activated in L-EPCs seeded on OPN. However, this activation could not be completely blocked by either CD44 or !1 integrin antagonists. These data confirm the direct effects of OPN on EPCs adhesion, and suggest that OPN works by mediating cell adhesion during vascular injury.

Endothelium

Integrins

EPC

OPN

Osteopontin

Endothelial progenitor cells

Mitofusin 1 and Mitofusin 2 Function in the Context of Brain Development

Hamze, Carmen

01 November 2011

Mitofusin 1 and 2 are outer-mitochondrial membrane proteins that have been shown to be involved in fusion. Mitofusin 2 has also been associated with apoptosis and development. When Mfn1 and Mfn2 were each conditionally knocked out from the cerebellum, Purkinje cells in Mfn2 deficient cerebellum during development had undergone neurodegeneration. Mutations in Mfn2 have also been associated with the Charcot Marie Tooth Type 2A (CMT2A). We want to asses the effect Mfn2 and Mfn1 might have on the development of other regions of the brain such as the telencephalon. We generated Mfn1 and Mfn2 conditional knockouts in the telencephalon by crossing them with Foxg1 Cre - a cre expressed in the telencephalon. We found that Mfn1 deficient mice have lost their corpus callosum at the midline, but survive over 6 months with a decrease in progenitor cells postnatally. Mfn2 deficient mice die between P9 and P12 with a decrease in progenitor cells postnatally and a decrease in number of neurons in the cortex. Therefore, our results suggest that Mfn1 and Mfn2 play a significant role in the development of the telencephalon.

Mfn1

Mfn2

progenitor cells

post-mitotic cortical neurons

development

telencephalon

In vitro hematopoietic stem/progenitor cell proliferation and labeling

Xu, Peng

06 1900

Hematopoietic stem/progenitor cells (HSPC) play main role in constituting the whole hematopoietic system. Furthermore, since recognized in 1960s, HSPC are utilized to protect patients from severe chemo and radio therapy. As time goes, they are also used to treat hematopoietic disorders such as leukemia. Bone marrow, peripheral blood and umbilical cord blood are now the three sources of HSPC. Umbilical cord blood seems optimal because it is easy to obtain, no risk to graft donor and low probability of infection transmission. However, low number of HSPCs in umbilical cord blood is the main limitation. My research focuses mainly on in-vitro proliferation of HSPCs. In addition, I also worked on labeling HSPC in-vitro for tracking these cells after transplantation. The experimental results indicated that HSPCs are effectively labeled and their proliferation rate is significantly enhanced in-vitro. / N/A

Hematopoietic stem/progenitor cell

in vtiro proliferation

labeling/tracking

Therapeutic potential of neural progenitor cell transplantation in a rat model of Huntington’s Disease

Vazey, Elena Maria

January 2009

Whole document restricted, see Access Instructions file below for details of how to access the print copy. / Huntington’s disease [HD] is a debilitating adult onset inherited neurodegenerative disorder with primary degeneration in the striatum and widespread secondary degeneration throughout the brain. There are currently no clinical treatments to prevent onset, delay progression or replace lost neurons. Striatal cell transplantation strategies under clinical evaluation appear viable and effective for the treatment of HD. However, the future of regenerative medicine lies in developing renewable, expandable multipotent neural cell sources for transplantation. This Thesis has investigated a range of novel developments for enhancing the therapeutic potential of neural progenitor cell transplantation in a quinolinic acid [QA] lesion rat model of HD using two cell sources, adult neural progenitor cells and human embryonic stem cell [hESC] derived neural progenitor cells. Chapter Three identified a novel method for in vitro lithium priming of adult neural progenitor cells which enhances their neurogenic potential at the expense of glial formation. Chapter Four demonstrated that lithium priming of adult neural progenitor cells altered their phenotypic fate in vivo after transplantation, enhancing regional specific differentiation and efferent projection formation. The therapeutic potential of this strategy was demonstrated by accelerated acquisition of motor function benefits in the QA model. Chapter Five then demonstrated the ability for post transplantation environmental enrichment to modify therapeutic functional outcomes in the QA lesion model, and through lithium priming and enrichment demonstrated that adult neural progenitors are amenable to combinatorial interventions which can alter their phenotypic fate and enhance anatomical integration. Chapter Six investigated the in vivo effects of in vitro noggin priming of hESC derived neural progenitor cells and identified enhanced safety and neuronal differentiation in the QA lesioned striatum after noggin priming. Furthermore Chapter Seven provided evidence for functional reconstruction and therapeutic functional benefits from transplantation of noggin primed hESC derived neural progenitor cells and also highlighted the need for systematic evaluations of hESC derived transplants to optimise their safety in vivo. These results are beneficial in demonstrating the realistic therapeutic potential held by these two cell sources. They demonstrate how transient interventions can enhance therapeutic outcomes of neural progenitor cell transplantation for HD and have developed the understanding of neural progenitor cell transplantation as a therapeutic tool, bringing transplantation from different cell sources closer to eventual translation for HD sufferers.

Neural progenitor cells

Cell transplantation

Huntington's disease

Lithium chloride

hESC

Therapeutic potential of neural progenitor cell transplantation in a rat model of Huntington’s Disease

Vazey, Elena Maria

January 2009

Whole document restricted, see Access Instructions file below for details of how to access the print copy. / Huntington’s disease [HD] is a debilitating adult onset inherited neurodegenerative disorder with primary degeneration in the striatum and widespread secondary degeneration throughout the brain. There are currently no clinical treatments to prevent onset, delay progression or replace lost neurons. Striatal cell transplantation strategies under clinical evaluation appear viable and effective for the treatment of HD. However, the future of regenerative medicine lies in developing renewable, expandable multipotent neural cell sources for transplantation. This Thesis has investigated a range of novel developments for enhancing the therapeutic potential of neural progenitor cell transplantation in a quinolinic acid [QA] lesion rat model of HD using two cell sources, adult neural progenitor cells and human embryonic stem cell [hESC] derived neural progenitor cells. Chapter Three identified a novel method for in vitro lithium priming of adult neural progenitor cells which enhances their neurogenic potential at the expense of glial formation. Chapter Four demonstrated that lithium priming of adult neural progenitor cells altered their phenotypic fate in vivo after transplantation, enhancing regional specific differentiation and efferent projection formation. The therapeutic potential of this strategy was demonstrated by accelerated acquisition of motor function benefits in the QA model. Chapter Five then demonstrated the ability for post transplantation environmental enrichment to modify therapeutic functional outcomes in the QA lesion model, and through lithium priming and enrichment demonstrated that adult neural progenitors are amenable to combinatorial interventions which can alter their phenotypic fate and enhance anatomical integration. Chapter Six investigated the in vivo effects of in vitro noggin priming of hESC derived neural progenitor cells and identified enhanced safety and neuronal differentiation in the QA lesioned striatum after noggin priming. Furthermore Chapter Seven provided evidence for functional reconstruction and therapeutic functional benefits from transplantation of noggin primed hESC derived neural progenitor cells and also highlighted the need for systematic evaluations of hESC derived transplants to optimise their safety in vivo. These results are beneficial in demonstrating the realistic therapeutic potential held by these two cell sources. They demonstrate how transient interventions can enhance therapeutic outcomes of neural progenitor cell transplantation for HD and have developed the understanding of neural progenitor cell transplantation as a therapeutic tool, bringing transplantation from different cell sources closer to eventual translation for HD sufferers.

Neural progenitor cells

Cell transplantation

Huntington's disease

Lithium chloride

hESC

Therapeutic potential of neural progenitor cell transplantation in a rat model of Huntington’s Disease

Vazey, Elena Maria

January 2009

Whole document restricted, see Access Instructions file below for details of how to access the print copy. / Huntington’s disease [HD] is a debilitating adult onset inherited neurodegenerative disorder with primary degeneration in the striatum and widespread secondary degeneration throughout the brain. There are currently no clinical treatments to prevent onset, delay progression or replace lost neurons. Striatal cell transplantation strategies under clinical evaluation appear viable and effective for the treatment of HD. However, the future of regenerative medicine lies in developing renewable, expandable multipotent neural cell sources for transplantation. This Thesis has investigated a range of novel developments for enhancing the therapeutic potential of neural progenitor cell transplantation in a quinolinic acid [QA] lesion rat model of HD using two cell sources, adult neural progenitor cells and human embryonic stem cell [hESC] derived neural progenitor cells. Chapter Three identified a novel method for in vitro lithium priming of adult neural progenitor cells which enhances their neurogenic potential at the expense of glial formation. Chapter Four demonstrated that lithium priming of adult neural progenitor cells altered their phenotypic fate in vivo after transplantation, enhancing regional specific differentiation and efferent projection formation. The therapeutic potential of this strategy was demonstrated by accelerated acquisition of motor function benefits in the QA model. Chapter Five then demonstrated the ability for post transplantation environmental enrichment to modify therapeutic functional outcomes in the QA lesion model, and through lithium priming and enrichment demonstrated that adult neural progenitors are amenable to combinatorial interventions which can alter their phenotypic fate and enhance anatomical integration. Chapter Six investigated the in vivo effects of in vitro noggin priming of hESC derived neural progenitor cells and identified enhanced safety and neuronal differentiation in the QA lesioned striatum after noggin priming. Furthermore Chapter Seven provided evidence for functional reconstruction and therapeutic functional benefits from transplantation of noggin primed hESC derived neural progenitor cells and also highlighted the need for systematic evaluations of hESC derived transplants to optimise their safety in vivo. These results are beneficial in demonstrating the realistic therapeutic potential held by these two cell sources. They demonstrate how transient interventions can enhance therapeutic outcomes of neural progenitor cell transplantation for HD and have developed the understanding of neural progenitor cell transplantation as a therapeutic tool, bringing transplantation from different cell sources closer to eventual translation for HD sufferers.

Neural progenitor cells

Cell transplantation

Huntington's disease

Lithium chloride

hESC

Mechanisms of erythroid proliferation and differentiation analysis of the role of erythropoietin receptor in the friend virus model /

Zhang, Ji,

January 2008

Thesis (Ph.D. )--University of Tennessee Health Science Center, 2008. / Title from title page screen (viewed on October 7, 2008 ). Research advisor: Paul A. Ney, M.D. Document formatted into pages (xi, 122 p. : ill.). Vita. Abstract. Includes bibliographical references (p. 78-110).

Cloning, expression, and characterization of a novel guanylate-binding protein, mGBP3 in the murine erythroid progenitor cells /

Han, Byung Hee,

January 1997

Thesis (Ph. D.)--University of Missouri--Columbia, 1997. / "May 1997." Typescript. Vita. Includes bibliographical references (leaves 147-162). Also available on the Internet.

The role of endothelial progenitor cells in the utero-placental vasculature

Sipos, Peter

January 2013

Fetal growth in utero depends on nutrient and oxygen reaching the fetus through the uterine and placental microcirculations, both undergoing massive expansion during pregnancy. Aberrations of the placental vasculature are associated with Intrauterine Growth Restriction (IUGR), a common pathological outcome of pregnancy; however, the cellular components responsible for vessel formation in the placenta and the uterus remain unknown. Endothelial Progenitor Cells (EPC) are a group of morphologically and functionally varied bone marrow derived vasculogenic cell types, divided into two major subsets: (i) Circulating Angiogenic Cells (CACs), which promote vessel formation by interfering with the extracellular matrix and (ii) Endothelial Colony Forming Cells (ECFCs), which provide the source for new endothelium. This role has been demonstrated in pathophysiological studies, but not in normal physiological events in vivo. Fetal ECFCs are more proficient than their adult counterparts, but it is unclear in what specific fetal or maternal physiological situations fetal ECFCs are involved. Based upon these considerations, it was hypothesised that: (i) fetal-derived ECFCs play a role in placental vasculogenesis, (ii) these cells transmigrate the placenta and home to loci of vessel formation in the pregnant uterus, and that (iii) intrinsic alterations in their capabilities are associated with fetal growth restriction during intrauterine life. To support these hypotheses the following experiments were performed;(i) EPCs in blood from pairs of human umbilical arteries and veins were counted by flow cytometry. Numbers of EPCs in these samples showed an arterio-venous gradient suggesting their placental sequestration. Furthermore, ECFCs were isolated from human umbilical blood using established culture techniques. Labelled human fetal ECFCs were transplanted into the circulation of murine fetuses using an ultrasound-guided intra-cardiac injection. Using a fluorescent imager and microscopy these cells were shown to home to the murine placenta and participate in vasculogenesis.(ii) Male mice ubiquitously expressing eGFP were crossbred with native females, and fetal (eGFP-positive) endothelial-like cells integrated into the uterine microvasculature. Human fetal ECFCs injected into murine fetuses were shown to migrate to the maternal uterus and became functionally involved with the microvasculature. In humans, microvessels were isolated from uterine biopsies of mothers with male offspring. Copies of the male specific SRY gene (quantified by RT-QPCR) indicated that cells of fetal origin constituted 12% of the endothelium in these vessels. In cross-sections, hybridisation of the Y-chromosome demonstrated the presence of fetal cells in the maternal endothelium of the human uterus. (iii) Using flow cytometry, fewer EPCs were defined within the peripheral circulation of growth-restricted babies. Functional assays showed that ECFCs derived from these growth-restricted cases had intrinsically impaired proliferation, migration, matrix-metalloproteinase (MMP-2) production, and generated fewer blood vessels in a murine vasculogenic bioassay. These results demonstrated the vasculogenic capacity of human fetal ECFCs in vivo and established them as key players in human placental vasculogenesis and uterine vessel expansion. Notably, these results also showed a link between impaired function of fetal ECFCs and IUGR, which is associated with increased cardiovascular risk of both the fetus as an adult, and mother in later life. From these findings it could be speculated, that intrinsic changes in ECFC-biology may be the causative link between IUGR and fetal and maternal cardiovascular susceptibility. Insight into these processes may contribute to early diagnosis, prevention and treatment of IUGR and associated conditions.