A new method for the rapid and long term growth of human neural precursor cells.

A reliable source of human neural tissue would be of immense practical value to both neuroscientists and clinical neural transplantation trials. In this study, human precursor cells were isolated from the developing human cortex and, in the presence of both epidermal and fibroblast growth factor-2, grew in culture as sphere shaped clusters. Using traditional passaging techniques and culture mediums the rate of growth was extremely slow, and only a 12-fold expansion in total cell number could be achieved. However, when intact spheres were sectioned into quarters, rather than mechanically dissociated, cell cell contacts were maintained and cellular trauma minimised which permitted the rapid and continual growth of each individual quarter. Using this method we have achieved a 1.5 million-fold increase in precursor cell number over a period of less than 200 days. Upon differentiation by exposure to a substrate, cells migrated out from the spheres and formed a monolayer of astrocytes and neurons. No oligodendrocytes were found to develop from these human neural precursor cells at late passages when whole spheres were differentiated. This simple and novel culture method allows the rapid expansion of large numbers of non-transformed human neural precursor cells which may be of use in drug discovery, ex vivo gene therapy and clinical neural transplantation.

Long-term survival of human central nervous system progenitor cells transplanted into a rat model of Parkinson's disease.

Progenitor cells were isolated from the developing human central nervous system (CNS), induced to divide using a combination of epidermal growth factor and fibroblast growth factor-2, and then transplanted into the striatum of adult rats with unilateral dopaminergic lesions. Large grafts were found at 2 weeks survival which contained many undifferentiated cells, some of which were migrating into the host striatum. However, by 20 weeks survival, only a thin strip of cells remained at the graft core while a large number of migrating astrocytes labeled with a human-specific antibody could be seen throughout the striatum. Fully differentiated graft-derived neurons, also labeled with a human-specific antibody, were seen close to the transplant site in some animals. A number of these neurons expressed tyrosine hydroxylase and were sufficient to partially ameliorate lesion-induced behavioral deficits in two animals. These results show that expanded populations of human CNS progenitor cells maintained in a proliferative state in culture can migrate and differentiate into both neurons and astrocytes following intracerebral grafting. As such these cells may have potential for development as an alternative source of tissue for neural transplantation in degenerative diseases.

Restricted growth potential of rat neural precursors as compared to mouse.

Epidermal growth factor (EGF) responsive precursors isolated from the developing mouse striatum could be continually expanded in culture as free-floating spheres of cells for over 50 days. Under identical conditions, EGF-responsive precursors from the developing rat striatum could only be expanded for between 21 and 28 days, after which crisis ensued and there was a reduction in cell number at each passage. The outer regions of 28-day-old rat spheres contained a heterogeneous population of both dividing and dying cells while the cores were full of dying cells, many of which showed features consistent with apoptosis. Fibroblast growth factor-2 (FGF-2) alone did not lead to an expansion in rat striatal precursor cell number under the conditions used here. EGF combined with FGF-2 acted synergistically on cell growth, but did not prevent the final senescence and death of the rat precursors.

Mutational analysis of the cucumber necrosis virus coat protein gene.

A series of frameshift, deletion, and inversion mutations were made in the coat protein (CP) gene of the icosahedral cucumber necrosis tombusvirus (CNV) to investigate the role of the CP protruding (P) domain in the production of virus particles and, also, to investigate the basis for the accumulation of CP deletion derivatives previously reported in plants inoculated with PD(-), a P-domainless CNV CP mutant. P-domainless coat protein subunit could be detected in extracts of CP mutant-infected plants; however, virus-like particles could not, suggesting that the P domain is essential for tombusvirus particle assembly and/or stability. In addition, each of the P-domain mutants analyzed invariably produced coat protein deletion derivatives in infected plants whereas shell domain mutants rarely produced deletion derivatives. Finally, P-domain inversion and deletion mutants accumulated deletion derivatives very rapidly in comparison to P-domain frameshift mutants. Protoplast studies show that PD(-) RNA inoculum does not undergo further deletion in infected protoplasts, suggesting that PD(-) CP deletion derivatives preferentially accumulate in plants because they have a greater capacity for cell-to-cell movement.