Long-term cultured human umbilical cord neural-like cells transplanted into the striatum of NOD SCID mice.

The use of stem cells and other cells as therapies is still in its infancy. One major setback is the limited survival of the grafts, possibly due to immune rejection. Studies were therefore performed with human umbilical cord blood cells (HUCB) to determine the ability of these cells to survive in vivo and the effect of the immune response on their survival by transplantation into the normal striatum of immunodeficient NOD SCID mice. Long-term culture of HUCB cells resulted in several different populations of cells, including one that possessed fine processes and cell bodies that resembled neurons. Their neuronal phenotype was confirmed by immunohistochemical staining for the early neuronal marker TuJ1 and the potentially neural marker Nestin. Five days after cell transplantation of this neuronal phenotype, immunohistochemical staining for human mitochondria confirmed the presence of living HUCB cells in the mouse striatum, with cells localized at the site of injection, expressing early neural and neuronal markers (Nestin and TuJ1) as well as exhibiting neuronal morphology. However, no evidence of surviving cells was apparent 1 month postgrafting. The absence of signs of T cell-mediated rejection, such as CD4 and CD8 lymphocytes and minimal changes in microglia and astrocytes, suggest that cell loss was not due to a T cell-mediated immune response. In conclusion HUCB cells can survive long-term in vitro and undergo neuron-like differentiation. In mice, these cells do not survive a month. This may relate to the differentiated state of the cells transplanted into the unlesioned striatum, rather than T cell-mediated immunological rejection.

Trophic factor induction of human umbilical cord blood cells in vitro and in vivo.

The mononuclear fraction of human umbilical cord blood (HUCBmnf) is a mixed cell population that multiple research groups have shown contains cells that can express neural proteins. In these studies, we have examined the ability of the HUCBmnf to express neural antigens after in vitro exposure to defined media supplemented with a cocktail of growth and neurotrophic factors. It is our hypothesis that by treating the HUCBmnf with these developmentally-relevant factors, we can expand the population, enhance the expression of neural antigens and increase cell survival upon transplantation. Prior to growth factor treatment in culture, expression of stem cell antigens is greater in the non-adherent HUCBmnf cells compared to the adherent cells (p < 0.05). Furthermore, treatment of the non-adherent cells with growth factors, increases BrdU incorporation, especially after 14 days in vitro (DIV). In HUCBmnf-embryonic mouse striata co-culture, a small number of growth factor treated HUCBmnf cells were able to integrate into the growing neural network and express immature (nestin and TuJ1) and mature (GFAP and MAP2) neural markers. Treated HUCBmnf cells implanted in the subventricular zone predominantly expressed GFAP although some grafted HUCBmnf cells were MAP2 positive. While short-term treatment of HUCBmnf cells with growth and neurotrophic factors enhanced proliferative capacity in vitro and survival of the cells in vivo, the treatment regimen employed was not enough to ensure long-term survival of HUCBmnf-derived neurons necessary for cell replacement therapies for neurodegenerative diseases.

Human umbilical cord blood progenitors: the potential of these hematopoietic cells to become neural.

The mononuclear fraction from human umbilical cord blood (HUCB) contains a significant number of stem/progenitor cells that in theory could be come any cell in the body, including neurons. Taking into consideration that transdifferentiation would be a very rare event and also knowing that overlapping genetic programs for hematopoiesis and neuropoiesis exist, we undertook a characterization of the HUCB mononuclear fraction, including analysis of cellular subpopulations and their morphology, cell viability, proliferation, and expression of neural and hematopoietic antigens. Two cell populations were apparent-adherent and floating fractions. The adherent fraction was mainly lymphocytes (~53%) expressing hematopoietic antigens. Upon replate, the floating population had many cells that expressed stem cell antigens. More of the cells in this subfraction expressed neural proteins. Neurotrophin receptors trkB and trkC were present in both cell fractions, although expression was higher in the floating fraction. Our initial characterization suggests that a subpopulation of cells exists within the HUCB mononuclear fraction that seems to have the potential to become neural cells, which could then be used in the development of cell-based therapies for brain injuries and diseases.

Neutrophil-specific chemokines are produced by astrocytic cells but not by neuronal cells.

BACKGROUND: Neutrophils have a central role in the inflammatory conditions of the central nervous system (CNS). ELR chemokines direct neutrophil migration, but the source of chemokines in the CNS is unclear. We quantified chemokine production using cell-line models of astrocytic and neuronal cells, specifically NT2.N cells, a human line with characteristics of immature neurons, and NT2.A cells, a line with characteristics of astrocytes. OBJECTIVE: In NT2.N and NT2.A cells, and their parent cell line NT2, we sought to: (1) quantify ELR chemokines, (2) determine receptor (CXCR-1 and CXCR-2) expression, and (3) measure the function of the chemokines generated from these cells. DESIGN/METHODS: NT2 cells were differentiated into NT2.N cells and NT2.A cells with all trans retinoic acid and mitosis inhibitors. Chemokine concentrations in culture supernatants were determined by ELISA. Immunofluorescence was used to detect CXCR-1 and CXCR-2. RT-PCR was used to determine chemokine and chemokine receptor mRNA. Chemotaxis assays were used to assess function. RESULTS: ELR chemokines were not detected in supernatants of NT2 or NT2.N cells, although mRNA for GRO-gamma/CXCL3 was found in both. In contrast, in NT2.A cells, mRNA and protein were present for GCP-2/CXCL6, GRO-alpha/CXCL1, GRO-gamma/CXCL3, and IL-8/CXCL8. CXCR-1 and CXCR-2 were expressed on NT2, NT2.N, and NT2.A cells detected by immunofluorescent staining and RT-PCR. Supernatants of NT2.A cells resulted in neutrophil chemotactic function of 30.5 +/- 3.9%, greater than NT2 cells (12.3 +/- 1.6%, mean +/- SEM, P < 0.01). CONCLUSIONS: We speculate that astrocytes are a source of ELR chemokines in the human CNS and that neurons and astrocytes can respond to those chemokines.

Tumorigenicity issues of embryonic carcinoma-derived stem cells: relevance to surgical trials using NT2 and hNT neural cells.

Cell therapy is a rapidly moving field with new cells, cell lines, and tissue-engineered constructs being developed globally. As these novel cells are further developed for transplantation studies, it is important to understand their safety profiles both prior to and posttransplantation in animals and humans. Embryonic carcinoma-derived cells are considered an important alternative to stem cells. The NTera2/D1 teratocarcinoma cell-line (or NT2-N cells) gives rise to neuron-like cells called hNT neurons after exposure to retinoic acid. NT2 cells form tumors upon transplantation into the rodent. However, when the NT2 cells are treated with retinoic acid to produce hNT cells, they terminally differentiate into post-mitotic neurons with no sign of tumorigenicity. Preliminary human transplantation studies in the brain of stroke patients also demonstrated a lack of tumorigenicity of these cells. This review focuses on the use of hNT neurons in cell transplantation for the treatment in central nervous system (CNS) diseases, disorders, or injuries and on the mechanism involved in retinoic acid exposure, final differentiation state, and subsequent tumorigenicity issues that must be considered prior to widespread clinical use.

Infusion of human umbilical cord blood cells in a rat model of stroke dose-dependently rescues behavioral deficits and reduces infarct volume.

BACKGROUND AND PURPOSE: Intravenously delivered human umbilical cord blood cells (HUCBC) have been previously shown to improve functional recovery of stroked rats. To extend these findings, we examined the behavioral recovery and stroke infarct volume in the presence of increasing doses of HUCBC after permanent middle cerebral artery occlusion (MCAO). METHODS: Rats were subjected to MCAO and allowed to recover for 24 hours before intravenous infusion of 10(4) up to 3 to 5x10(7) HUCBC. Behavioral tests (spontaneous activity, step test, elevated body swing test) were performed 1 week before MCAO and at 2 and 4 weeks after HUCBC infusion. On completion of behavioral testing, animals were euthanized and brain infarct volumes quantified. HUCBC were identified by immunofluorescence for human nuclei and by polymerase chain reaction (PCR) using primers specific for human glycerol 3-phosphate dehydrogenase. RESULTS: At 4 weeks after infusion, there was a significant recovery in behavioral performance when 10(6) or more HUCBC were delivered (p=0.001 to p=0.05). Infarct volume measurements revealed an inverse relationship between HUCBC dose and damage volume, which reached significance at the higher HUCBC doses (10(7) cells, p<0.01; 3 to 5x10(7) cells, p<0.05). Moreover, HUCBC were localized by immunohistochemistry and PCR analysis only in the injured brain hemisphere and spleen. CONCLUSIONS: These results extend previous observations of HUCBC infusion in the MCAO rat stroke model by demonstrating a dose relationship between HUCBC, behavioral improvement, and neuronal sparing.

The transcription factor Nurr1 in human NT2 cells and hNT neurons.

Human, neuronally committed hNT or NT2-N cells, originally derived from the Ntera2/D1 (NT2) clone after exposure to retinoic acid (RA), represent a potentially important source of cells to treat neurodegenerative diseases. Our previous in vitro experiments showed that hNT cells possess immunocytochemically detectable markers typical of dopaminergic (DA) ventral mesencephalic (VM) neurons, including tyrosine hydroxylase (TH), dopamine transporter (DAT), dopamine receptor (D2), and aldehyde dehydrogenase (AHD-2). In the current study, we sought to examine whether Nurr1, an orphan receptor of the nuclear receptor superfamily shown to be essential for the development, differentiation and survival of midbrain DA neurons, would be expressed in 3, 4, or 5 week RA-induced hNT neurons and their NT2 precursors. Our immunocytochemical analyses indicate that NT2 cells as well as hNT neurons independent of the length of RA-driven differentiation were Nurr1-immunoreactive. RT-PCR analysis confirmed the expression of Nurr1-specific mRNA in both NT2 precursors and the hNT neurons. Furthermore, immunocytochemical co-expression of Nurr1 and TH was detected in hNT neurons. The findings of this study suggest that Nurr1 may be important during the development of hNT neurons and involved in their differentiation into the dopaminergic phenotype.

Intravenous administration of human umbilical cord blood cells in a mouse model of amyotrophic lateral sclerosis: distribution, migration, and differentiation.

Amyotrophic lateral sclerosis (ALS), a multifactorial disease characterized by diffuse motor neuron degeneration, has proven to be a difficult target for stem cell therapy. The primary aim of this study was to determine the long-term effects of intravenous mononuclear human umbilical cord blood cells on disease progression in a well-defined mouse model of ALS. In addition, we rigorously examined the distribution of transplanted cells inside and outside the central nervous system (CNS), migration of transplanted cells to degenerating areas in the brain and spinal cord, and their immunophenotype. Human umbilical cord blood (hUCB) cells (10(6)) were delivered intravenously into presymptomatic G93A mice. The major findings in our study were that cord blood transfusion into the systemic circulation of G93A mice delayed disease progression at least 2-3 weeks and increased lifespan of diseased mice. In addition, transplanted cells survived 10-12 weeks after infusion while they entered regions of motor neuron degeneration in the brain and spinal cord. There, the cells migrated into the parenchyma of the brain and spinal cord and expressed neural markers [Nestin, III Beta-Tubulin (TuJ1), and glial fibrillary acidic protein (GFAP)]. Infused cord blood cells were also widely distributed in peripheral organs, mainly the spleen. Transplanted cells also were recovered in the peripheral circulation, possibly providing an additional cell supply. Our results indicate that cord blood may have therapeutic potential in this noninvasive cell-based treatment of ALS by providing cell replacement and protection of motor neurons. Replacement of damaged neurons by progeny of cord blood stem cells is probably not the only mechanism by which hUCB exert their effect, since low numbers of cells expressed neural antigens. Most likely, cord blood efficacy is partially due to neuroprotection by modulation of the autoimmune process.

Lithium exposure enhances survival of NT2N cells (hNT neurons) in the hemiparkinsonian rat.

Lithium (Li +) treatment of NTera2/D1 (or hNT Neurons) in culture increases tyrosine hydroxylase (TH) expression in this cell-line [Zigova et al., (1999) Exp. Neurol., 157, 251-258]. It is not known if these Li + treated cells maintain TH expression once transplanted into the striatum of the hemiparkinsonian rats. hNT neurons were either treated with 1 mm LiCl or left untreated and then transplanted into the striatum of Sprague-Dawley rats. Some cells were exposed to the lithium for 24 h in culture while others were exposed only briefly (2-3 h) just prior to transplantation. We also examined whether Li + treatment of the animal after transplantation (0.24% w/w lithium carbonate in chow) was effective in increasing neuronal survival. One week after transplantation, the animals were perfused with 4% paraformaldehyde and immunocytochemistry was performed on 30 micro m sections through the transplant. Human nuclear matrix antigen immunostaining demonstrated that there was significantly better survival of cells in the group treated briefly with lithium compared to all other groups. Brief exposure to lithium resulted in a greater expression of TH in situ as well. Neuron specific enolase immunohistochemistry showed that there was extensive fibre outgrowth in all groups. These results suggest that brief Li + exposure may enhance survival to over 60% and increase TH expression of hNT Neurons transplanted in the hemiparkinsonian rat nearly three-fold.

Nicotinic acetylcholine receptors on NT2 precursor cells and hNT (NT2-N) neurons.

This is the first report, to our knowledge, of prominent, natural expression of nAChR alpha4, alpha6 and alpha9 subunits in a human, neuronally-committed cell line. We performed studies with specific reference to the expression of nicotinic acetylcholine receptors (nAChR) to further characterize a human, postmitotic, transplantable, with a neuronal phenotype, cell line called hNT (also called NT2-N). hNT cells acquire a distinctive neuronal phenotype upon differentiation from their NT2 precursors. Immunocytochemical studies showed that NT2 cells were strongly immunopositive for alpha4 or alpha7 subunits, moderately immunopositive for alpha3/alpha5 subunits, and weakly immunopositive for beta2 or beta4 subunits, whereas hNT neurons showed positive, strong-to-moderate immunostaining for all of these nAChR subunits. Reverse transcription-polymerase chain reaction (RT-PCR) mRNA analyses indicated that levels of alpha7 subunit messages were similar in both NT2 and hNT cells, whereas alpha2, alpha10, and beta3 subunit transcripts were not detected. Levels of alpha3, alpha5, and beta4 subunit messages were lower in hNT neurons than in NT2 precursors. However, alpha4 and beta2 subunit messages were present in NT2 precursors but were greatly induced in hNT neurons. Levels of alpha6 and alpha9 subunit messages, not detectable in NT2 precursors, rose to high levels in hNT neurons. hNT cell nAChR subunit message levels were comparable to (alpha4, alpha5, beta4) or higher than (alpha6, alpha9, beta2) levels in adult human brain. NT2 and hNT cells may provide an excellent model for studies of neurogenesis, roles played by nAChR in differentiation and neurodegeneration, and effects of neuronal differentiation on nAChR expression.

Human umbilical cord blood cells express neural antigens after transplantation into the developing rat brain.

Recently, our laboratory began to characterize the mononuclear cells from human umbilical cord blood (HUCB) both in vitro and in vivo. These cryopreserved human cells are available in unlimited quantities and it is believed that they may represent a source of cells with possible therapeutic and practical value. Our previous molecular and immunocytochemical studies on cultured HUCB cells revealed their ability to respond to nerve growth factor (NGF) by increased expression of neural markers typical for nervous system-derived stem cells. In addition, the DNA microarray detected downregulation of several genes associated with development of blood cell lines. To further explore the survival and phenotypic properties of HUCB cells we transplanted them into the developing rat brain, which is known to provide a conducive environment for development of neural phenotypes. Prior to transplantation, HUCB cells were either cultured with DMEM and fetal bovine serum or were exposed to retinoic acid (RA) and nerve growth factor (NGF). Neonatal pups (1 day old) received unilateral injection of cell suspension into the anterior part of subventricular zone. One month after transplantation animals were perfused, their brains cryosectioned, and immunocytochemistry was performed for identification of neural phenotypes. Our results clearly demonstrated that approximately 20% of transplanted HUCB survived (without immunosuppression) within the neonatal brain. Additionally, double-labeling with cell-type-specific markers revealed that some HUCB-derived cells (recognized by anti-human nuclei labeling) were immunopositive for glial fibrillary acidic protein (GFAP) and few donor cells expressed the neuronal marker TuJ1 (class III beta-tubulin). These findings suggest that at least some of the transplanted HUCB cells differentiated into cells with distinct glial or neuronal phenotypes after being exposed to instructive signals from the developing brain.