Ann Tsukamoto

Engraftment of sorted/expanded human central nervous system stem cells from fetal brain

Direct isolation of human central nervous system stem cells (CNS‐SC) based on cell surface markers yields a highly purified stem cell population that can extensively expand in vitro and exhibit multilineage differentiation potential both in vitro and in vivo. The CNS‐SC were isolated from fetal brain tissue using the cell surface markers CD133+, CD34–, CD45–, and CD24–/lo (CD133+ cells). Fluorescence‐activated cell sorted (FACS) CD133+ cells continue to expand exponentially as neurospheres while retaining multipotential differentiation capacity for >10 passages. CD133–, CD34–, and CD45– sorted cells (∼95% of total fetal brain tissue) fail to initiate neurospheres. Neurosphere cells transplanted into neonatal immunodeficient NOD‐SCID mice proliferated, migrated, and differentiated in a site‐specific manner. However, it has been difficult to evaluate human cell engraftment, because many of the available monoclonal antibodies against neural cells (β‐tubulin III and glial fibrillary acidic protein) are not species specific. To trace the progeny of human cells after transplantation, CD133+‐derived neurosphere cells were transduced with lentiviral vectors containing enhanced green fluorescent protein (eGFP) expressed downstream of the phosphoglycerate kinase promoter. After transduction, GFP+ cells were enriched by FACS, expanded, and transplanted into the lateral ventricular space of neonatal immunodeficient NOD‐SCID brain. The progeny of transplanted cells were detected by either GFP fluorescence or antibody against GFP. GFP+ cells were present in the subventricular zone‐rostral migrating stream, olfactory bulb, and hippocampus as well as nonneurogenic sites, such as cerebellum, cerebral cortex, and striatum. Antibody against GFP revealed that some of the cells displayed differentiating dendrites and processes with neurons or glia cells. Thus, marking human CNS‐SC with reporter genes introduced by lentiviral vectors is a useful tool with which to characterize migration and differentiation of human cells in this mouse transplantation model.

Human Neural Stem Cells Induce Functional Myelination in Mice with Severe Dysmyelination

Transplanted banked human neural stem cells produce functional myelin detected by MRI in juvenile mice with severe dysmyelination. Bringing Insulation Up to Code Faulty insulation around household wiring is an electric shock and fire hazard; likewise, defects in the insulation around nerve fibers—the myelin sheath—can have destructive effects. Because of myelin’s crucial roles in promoting the rapid transmission of nerve impulses and in axon integrity, mutations that affect myelin formation in the central nervous system cause severe neurological decline. Uchida et al. and Gupta et al. now investigate the use of neural stem cells—which can differentiate into myelin-producing oligodendrocytes—as a potential treatment for such disorders. Previous work showed that transplantation of human oligodendrocyte progenitors into newborn shiverer (Shi) mice, a hypomyelination model, could prolong survival. In the new work, Uchida et al. transplanted human neural stem cells, which had been expanded and banked, into the brains of newborn and juvenile Shi mice. Whereas the newborn mice were asymptomatic, the juvenile mice were already symptomatic and displayed advanced dysmyelination. These transplanted cells preferentially differentiated into oligodendrocytes that generated myelin, which ensheathed axons and improved nerve conduction in both categories of mice. In an open-label phase 1 study, Gupta et al. then tested the safety and efficacy of such cells in four young boys with a severe, fatal form of Pelizaeus-Merzbacher disease (PMD), a rare X-linked condition in which oligodendrocytes cannot myelinate axons. Human neural stem cells were transplanted directly into the brain; the procedure and transplantation were well tolerated. Magnetic resonance imaging techniques, performed before transplant and five times in the following year, were used to assess myelination. The imaging results were consistent with donor cell–derived myelination in the transplantation region in three of the four patients. These results support further study of potential clinical benefits of neural stem cell transplantation in PMD and other dysmyelination disorders. Shiverer-immunodeficient (Shi-id) mice demonstrate defective myelination in the central nervous system (CNS) and significant ataxia by 2 to 3 weeks of life. Expanded, banked human neural stem cells (HuCNS-SCs) were transplanted into three sites in the brains of neonatal or juvenile Shi-id mice, which were asymptomatic or showed advanced hypomyelination, respectively. In both groups of mice, HuCNS-SCs engrafted and underwent preferential differentiation into oligodendrocytes. These oligodendrocytes generated compact myelin with normalized nodal organization, ultrastructure, and axon conduction velocities. Myelination was equivalent in neonatal and juvenile mice by quantitative histopathology and high-field ex vivo magnetic resonance imaging, which, through fractional anisotropy, revealed CNS myelination 5 to 7 weeks after HuCNS-SC transplantation. Transplanted HuCNS-SCs generated functional myelin in the CNS, even in animals with severe symptomatic hypomyelination, suggesting that this strategy may be useful for treating dysmyelinating diseases.

Clinical translation of human neural stem cells

Human neural stem cell transplants have potential as therapeutic candidates to treat a vast number of disorders of the central nervous system (CNS). StemCells, Inc. has purified human neural stem cells and developed culture conditions for expansion and banking that preserve their unique biological properties. The biological activity of these human central nervous system stem cells (HuCNS-SC®) has been analyzed extensively in vitro and in vivo. When formulated for transplantation, the expanded and cryopreserved banked cells maintain their stem cell phenotype, self-renew and generate mature oligodendrocytes, neurons and astrocytes, cells normally found in the CNS. In this overview, the rationale and supporting data for pursuing neuroprotective strategies and clinical translation in the three components of the CNS (brain, spinal cord and eye) are described. A phase I trial for a rare myelin disorder and phase I/II trial for spinal cord injury are providing intriguing data relevant to the biological properties of neural stem cells, and the early clinical outcomes compel further development.

Non-immortalized human neural stem (NS) cells as a scalable platform for cellular assays

The utilization of neural stem cells and their progeny in applications such as disease modelling, drug screening or safety assessment will require the development of robust methods for consistent, high quality uniform cell production. Previously, we described the generation of adherent, homogeneous, non-immortalized mouse and human neural stem cells derived from both brain tissue and pluripotent embryonic stem cells (Conti et al., 2005; Sun et al., 2008). In this study, we report the isolation or derivation of stable neurogenic human NS (hNS) lines from different regions of the 8-9 gestational week fetal human central nervous system (CNS) using new serum-free media formulations including animal component-free conditions. We generated more than 20 adherent hNS lines from whole brain, cortex, lobe, midbrain, hindbrain and spinal cord. We also compared the adherent hNS to some aspects of the human CNS-stem cells grown as neurospheres (hCNS-SCns), which were derived from prospectively isolated CD133(+)CD24(-/lo) cells from 16 to 20 gestational week fetal brain. We found, by RT-PCR and Taqman low-density array, that some of the regionally isolated lines maintained their regional identity along the anteroposterior axis. These NS cells exhibit the signature marker profile of neurogenic radial glia and maintain neurogenic and multipotential differentiation ability after extensive long-term expansion. Similarly, hCNS-SC can be expanded either as neurospheres or in extended adherent monolayer with a morphology and marker expression profile consistent with radial glia NS cells. We demonstrate that these lines can be efficiently genetically modified with standard nucleofection protocols for both protein overexpression and siRNA knockdown of exogenously expressed and endogenous genes exemplified with GFP and Nestin. To investigate the functional maturation of neuronal progeny derived from hNS we (a) performed Agilent whole genome microarray gene expression analysis from cultures undergoing neuronal differentiation for up to 32 days and found increased expression over time for a number of drugable target genes including neurotransmitter receptors and ion channels and (b) conducted a neuropharmacology study utilizing Fura-2 Ca(2+) imaging which revealed a clear shift from an initial glial reaction to carbachol to mature neuron-specific responses to glutamate and potassium after prolonged neuronal differentiation. Fully automated culture and scale-up of select hNS was achieved; cells supplied by the robot maintained the molecular profile of multipotent NS cells and performed faithfully in neuronal differentiation experiments. Here, we present validation and utility of a human neural lineage-restricted stem cell-based assay platform, including scale-up and automation, genetic engineering and functional characterization of differentiated progeny.

CD34+THY-1+LIN- STEM CELLS FROM MOBILIZED PERIPHERAL BLOOD

Over the last ten years there has been increasing use of mobilized peripheral blood (MPB) progenitor cells as grafts for autologous transplantation. Among the cells comprising these MPB autografts is a subpopulation of CD34+Thy-1+Lineage (Lin)- cells, which is enriched for hematopoietic stem cell (HSC) activity. The percentage of CD34+ cells which express Thy-1 is higher in some samples of MPB than in bone marrow (BM). Using myeloid and erythroid cell depletion prior to high speed cell sorting, it is possible to purify sufficient numbers of CD34+Thy-1+Lin-HSCs from a MPB leukapheresis sample for use as an autograft. CD34+Thy-1+Lin-cells will potentially provide a tumor-depleted autograft for cancer patients. This HSC population is also being studied as a potential target for gene transfer for the treatment of patients with HIV, cancer and a variety of genetic disorders.