Proof-of Concept that an Acute Trophic Factors Intervention After Spinal Cord Injury Provides an Adequate Niche for Neuroprotection, Recruitment of Nestin-Expressing Progenitors and Regeneration.

Trophic factor treatment has been shown to improve the recovery of brain and spinal cord injury (SCI). In this study, we examined the effects of TSC1 (a combination of insulin-like growth factor 1 and transferrin) 4 and 8 h after SCI at the thoracic segment level (T12) in nestin-GFP transgenic mice. TSC1 treatment for 4 and 8 h increased the number of nestin-expressing cells around the lesion site and prevented Wallerian degeneration. Treatment with TSC1 for 4 h significantly increased heat shock protein (HSP)-32 and HSP-70 expression 1 and 2 mm from lesion site (both, caudal and rostral). Conversely, the number of HSP-32 positive cells decreased after an 8-h TSC1 treatment, although it was still higher than in both, non-treated SCI and intact spinal cord animals. Furthermore, TSC1 increased NG2 expressing cell numbers and preserved most axons intact, facilitating remyelination and repair. These results support our hypothesis that TSC1 is an effective treatment for cell and tissue neuroprotection after SCI. An early intervention is crucial to prevent secondary damage of the injured SC and, in particular, to prevent Wallerian degeneration.

White matter loss in a mouse model of periventricular leukomalacia is rescued by trophic factors.

Periventricular leukomalacia (PVL) is the most frequent cause of cerebral palsy and other intellectual disabilities, and currently there is no treatment. In PVL, glutamate excitotoxicity (GME) leads to abnormal oligodendrocytes (OLs), myelin deficiency, and ventriculomegaly. We have previously identified that the combination of transferrin and insulin growth factors (TSC1) promotes endogenous OL regeneration and remyelination in the postnatal and adult rodent brain. Here, we produced a periventricular white matter lesion with a single intracerebral injection of N-methyl-d-aspartate (NMDA). Comparing lesions produced by NMDA alone and those produced by NMDA + TSC1 we found that: NMDA affected survival and reduced migration of OL progenitors (OLPs). In contrast, mice injected with NMDA + TSC1 proliferated twice as much indicating that TSC1 supported regeneration of the OLP population after the insult. Olig2-mRNA expression showed 52% OLP survival in mice receiving a NMDA injection and increased to 78% when TSC1 + NMDA were injected simultaneously and ventricular size was reduced by TSC1. Furthermore, in striatal slices TSC1 reduced the inward currents induced by NMDA in medium-sized spiny neurons, demonstrating neuroprotection. Thus, white matter loss after excitotoxicity can be partially rescued as TSC1 conferred neuroprotection to preexisting OLP and regeneration via OLP proliferation. Furthermore, we showed that early TSC1 administration maximizes neuroprotection.

Strategies for endogenous spinal cord repair: HPMA hydrogel to recruit migrating endogenous stem cells.

Injury to the spinal cord disrupts ascending and descending axonal pathways and causes tissue damage with a subsequent limited cellular regeneration. Successful treatment would encompass the restoration of the cytoarchitecture, homeostasis and function all in dear need. Transplantation-based treatments using exogenous cells are the most favoured approach. Yet, with the advent of the stem cell concept and continuous progress in the field it became clear that the endogenous potential for repair is greater than previously thought. As an alternative to neural grafting, we and other researchers have aimed at understanding what are the elements needed for a successful repair with self progenitors that would give rise to the cell types needed to restore function of the central nervous system. Some studies involve both scaffolds and cell grafts. Here we describe studies on spinal cord repair using what we call "endogenous tissue engineering for regenerative medicine". The approach involves a hydrogel that mimics the natural milieu where endogenous pre-existing and newly formed cells populate the gel progressively allowing for the integration of CNS self populations leading to a successful recovery of function. Highlight aspects learned from this type of studies are that: Endogenous reconstruction of the injured spinal cord is possible by using the adequate support. The contribution of nestin-expressing progenitors to spinal cord regeneration is continuous and substantial both, in the reconstructed segment as well as, along the distal and caudal segments of the reconstructed spinal cord. Most of these cells appear to have been in a quiescent state until the injury occurred and only a small fraction of these neural progenitors was produced via cell proliferation. The hydrogel combined with exercise was necessary and sufficient to restore locomotor function in cats that underwent spinal transaction followed by reconstructive surgery. This recovery of function was first seen 28 days after surgery and continued to improve for at least 21 months. Therefore, endogenous pre-existing and newly formed cells populated the gel scaffold established contact with the non injured tissue and lead to recovery of function.

Stem/progenitor cells in the postnatal inner ear of the GFP-nestin transgenic mouse.

Nestin promoter-GFP (green fluorescent protein) transgenic mice were used to determine the presence of stem/progenitor cells in the mouse inner ear. We examined the inner ear of mice at the following postnatal days (P): P0, P4, P5, P15 and P60. Hair cells stereocilia were identified with the use of the histochemical marker phalloidin. Whole endorgans or cryosections were analyzed under epi-fluorescent or confocal microscopy. From P0 to P5, GFP expressing cells were found in the vestibular sensory epithelia of the macula utricle, but not in the crista ampullaris. Cells within the stroma (tissue underneath the sensory epithelia), utricle, and crista were also GFP-positive. Satellite cells in the vestibular ganglia were GFP-positive, while vestibular ganglia neurons were not. In the organ of Corti, GFP signal was found in inner border and inner phalangeal cells that surround the inner hair cells (GFP-negative), Dieters cells and cells in the great epithelial ridge. Outer hair cells were mildly positive for GFP. Satellite cells in the spiral ganglia were GFP-positive, while spiral ganglia neurons were not. Similar GFP expression was found in the vestibule and cochlea of animals at P15, however, outer hair cells showed no GFP expression. The inner ear of P60 animals contained moderate GFP expression in the stroma of the crista ampullaris and utricle, but not within the sensory epithelia. In the organ of Corti, moderate GFP expression was found in a few Deiters cells. The present data indicates that the expression of nestin in the mouse inner ear is developmentally regulated; yet in the adult inner ear there are some nestin expressing cells, suggesting an intrinsic repair potential, although to a more limited extent than during early post-natal life.

Selective specification of CNS stem cells into oligodendroglial or neuronal cell lineage: cell culture and transplant studies.

Neural stem cells (NSCs) were isolated from embryonic day 16 Sprague-Dawley rats and cultured in a novel serum-free stem cell medium that selected for the growth of NSCs and against the growth of GFAP(+) cells (astrocytes). NSCs maintained in culture for extended periods of time retained immunoreactivity for both nestin and PSA-NCAM, two markers characteristic of the stem cell phenotype. Moreover, using an oligodendrocyte (OL) specification medium, NSCs differentiated into OL as evidenced by their morphology and expression of multiple oligodendrocyte/myelin-specific markers. In addition, NSCs are capable of acquiring a neuronal phenotype as evidenced by expressing neuronal markers, such as neurofilament (NF) and NeuN when cultured in a defined medium for neurons indicating that these cells are also a good source of neuroblasts, which could be used to replace neuronal populations in the brain. We also showed successful propagation and differentiation of NSCs into OL after cryostorage, allowing for the later use of stored NSCs. The long-term goal of culturing NSCs and committed oligodendrocyte progenitors (OLP) is to obtain homogeneous populations for transplantation with the goal of remyelinating the myelin-deficient CNS. Our preliminary experiments carried out on normal and myelin deficient rats demonstrate that these cells survive and migrate extensively in both types of hosts. NSCs grafted as such, as well as cells derived from NSCs exposed to selective specification before grafting, are able to differentiate within the host brain. As expected, NSCs are capable of giving rise to astrocytes in a medium favoring this phenotype.

Tumor necrosis factor modulates transcription of myelin basic protein gene through nuclear factor kappa B in a human oligodendroglioma cell line.

Tumor necrosis factor-alpha (TNF-alpha) is a major mediator of inflammation and it is involved in many neurological disorders such as multiple sclerosis. Levels of TNF-alpha and lymphotoxin-alpha have been found elevated in plaques, bloods, and cerebral spinal fluids from multiple sclerosis patients. The expression of myelin basic protein (MBP), a major protein of the myelin sheath, is affected by cytokines secreted by activated immune cells. To determine the signal transduction pathway involving tumor necrosis factor's action in myelination and demyelination, we have cloned and analyzed cis-elements on promoters of the human and mouse MBP genes. There are two putative nuclear factors kappa-B (NF-kappaB) cis-elements on the human and one on the mouse gene promoter. In an electrophoretic mobility shift assay, all three NF-kappaB cis-elements showed binding to a protein, which was recognized by an antibody against NF-kappaB P65 component. The specificity of the binding was demonstrated in a competitive assay using NF-kappaB consensus oligonucleotides. A two base pair site-directed mutation on the mouse NF-kappaB cis-element abolished its binding activity. We created a DNA construct by linking the mouse MBP gene promoter containing the NF-kappaB cis-element to luciferase gene. Transfection of this construct into a human oligodendroglioma cell line showed TNF-alpha increased the transgene expression. Furthermore the mutation of NF-kappaB site abolished TNF-alpha -induction of the transgene. The data demonstrate that NF-kappaB is the mediator between tumor necrosis factor's action and MBP gene expression. Elucidating the molecular mechanisms underlying TNF-alpha regulation of MBP gene expression provides new scientific bases for the development of therapy against oligodendrocyte-specific and myelin-related disorders such as multiple sclerosis.