Klas Wictorin scite author profile

In aged rodents, impairments in learning and memory have been associated with an age-dependent decline in forebrain of cholinergic function, and recent evidence indicates that the cholinergic neurons in the nucleus basalis magnocellularis, the septal-diagonal band area and the striatum undergo age-dependent atrophy. Thus, as in Alzheimer-type dementia in man, degenerative changes in the forebrain cholinergic system may contribute to age-related cognitive impairments in rodents. The cause of these degenerative changes is not known. Recent studies have shown that the central cholinergic neurons in the septal-diagonal band area, nucleus basalis and striatum are sensitive to the neurotrophic protein nerve growth factor (NGF). In particular, intraventricular injections or infusions of NGF in young adult rats have been shown to prevent retrograde neuronal cell death and promote behavioural recovery after damage to the septo-hippocampal connections. It is so far not known, however, whether the atrophic cholinergic neurons in aged animals are responsive to NGF treatment. We report here that continuous intracerebral infusion of NGF over a period of four weeks can partly reverse the cholinergic cell body atrophy and improve retention of a spatial memory task in behaviourally impaired aged rats.

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Continuous infusion of nerve growth factor prevents basal forebrain neuronal death after fimbria fornix transection.

Williams¹,

Varon²,

Peterson³

et al. 1986

Proc. Natl. Acad. Sci. U.S.A.

820

330

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Neurons in the rat medial septum (MS) and vertical limb of the diagonal band of Broca (VDB) undergo a rapid and severe cell death after transection of their dorsal projection to the hippocampus by aspiration of the ipsilateral fimbria fornix and supracallosal striae. By 2 weeks posttransection, the extent of neuronal loss was 50% of the total neurons and 70% of the cholinergic neurons in the MS and 30% of the total neurons and 40% of the cholinergic neurons in the VDB.We hypothesized that (t) the death was due to the loss of a hippocampus-derived neuronotrophic factor, and (ii) exogenous nerve growth factor (NGF) might provide trophic support to the MS/VDB cholinergic neurons, in light of recent reports that the septal diagonal band cholinergic neurons are responsive to NGF and that NGF is present and produced in the hippocampus. In the present study, we attempted to prevent the transection-induced neuronal death by continuous infusion of exogenous 7S NGF (1 jag/wk) through an intraventricular cannula device. We report here that NGF treatment significantly reduces both the total neuronal and cholinergic neuronal death found 2 weeks after runbria fornix transection; there was a sparing of 50% of the neurons in the MS and essentially 100% of those in the VDB that otherwise would have died. We conclude that NGF also has a protective effect on noncholinergic neurons since calculations indicate that 80% of the NGFaffected neurons are noncholinergic.

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Grafted neural stem cells develop into functional pyramidal neurons and integrate into host cortical circuitry

Englund

Björklund

Wictorin

et al. 2002

Proc. Natl. Acad. Sci. U.S.A.

182

113

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In vitro expanded neural stem͞progenitor cells can undergo region-specific differentiation after transplantation to the developing or adult brain, and display morphologies and markers characteristic of mature neurons. Here we have used patch-clamp techniques to explore whether grafted stem cells also can develop physiological properties of mature neurons and become functionally integrated within host neural circuitry. The immortalized neural progenitor cell line, RN33B, prelabeled with GFP by using a lentiviral vector, was transplanted into the cortex or hippocampus of neonatal rats. We found that the grafted GFP-positive cells differentiated into cells with morphological features of cortical or hippocampal pyramidal neurons, and that many of them had established appropriate cortico-thalamic and contralateral hippocampal connections, respectively, as revealed by retrograde tracing. Whole-cell patch-clamp recordings from grafted cells with morphological characteristics of pyramidal neurons showed that they were able to generate action potentials, and received functional excitatory and inhibitory synaptic inputs from neighboring cells. These data provide evidence that grafted neural progenitors can differentiate into morphologically mature pyramidal projection neurons, establish appropriate long-distance axonal projections, exhibit normal electrophysiological properties, and become functionally integrated into host cortical circuitry.progenitor cells ͉ GFP ͉ electrophysiology ͉ whole-cell recording ͉ retrograde tracing M ultipotent neural stem or progenitor cell lines can differentiate to neuronal and glial phenotypes, both in vitro and after transplantation into the developing or adult brain (1-3). Immature progenitors possess the capability to migrate within the host brain parenchyma, and can, at least in some cases, adopt morphological features and express markers of mature neurons. It remains unclear, however, whether grafted neural stem͞ progenitor cell lines also can develop the physiological properties of mature neurons and become functionally integrated into host neural circuitry.In the present study, we have used whole-cell patch-clamp recording to analyze the electrophysiological properties and functional integration of intracerebrally grafted cells derived from a conditionally immortalized neural progenitor cell line, RN33B, generated from embryonic rat brainstem by retroviral transduction of the temperature-sensitive simian virus 40 large-T-antigen (4, 5). The RN33B cell line has a remarkable neurogenic capacity both in neonatal and adult recipients, and can differentiate into neuron-like cells with morphologies of pyramidal cells and interneurons after transplantation into cortex or hippocampus, and into medium-sized densely spiny neurons after transplantation into the striatum (5-9). The RN33B cells were first transduced with the GFP gene by using a lentiviral vector, and then implanted into the cortex and hippocampus. The GFP marker allows visualization of the grafted cells in their entirety, includ...

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Transplantation of Human Neural Progenitor Cells into the Neonatal Rat Brain: Extensive Migration and Differentiation with Long-Distance Axonal Projections

Englund

Fricker-Gates

Lundberg

et al. 2002

Experimental Neurology

174

109

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Reformation of long axon pathways in adult rat central nervous system by human forebrain neuroblasts

Wictorin

Brundin

Gustavii

et al. 1990

Nature

249

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The failure of lesioned axons to regenerate over long distances in the mammalian central nervous system (CNS) is not due to an inability of central neurons to regenerate, but rather to the non-permissive nature of the CNS tissue environment. Regenerating CNS axons, which grow well within a peripheral nerve, for example, fail to penetrate mature CNS tissue by more than about 1 mm. Recent evidence indicates that this may be due to inhibitory membrane proteins associated with CNS oligodendrocytes and myelin. We report here that human telencephalic neuroblasts implanted into the excitotoxically lesioned striatum of adult rats can escape or neutralize this inhibitory influence of the adult CNS environment and extend axons along major myelinated fibre tracts for distances of up to approximately 20 mm. The axons were seen to elongate along the paths of the striato-nigral and cortico-spinal tracts to reach the substantia nigra, the pontine nuclei and the cervical spinal cord, which are the normal targets for the striatal and cortical projection neurons likely to be present in these implants.

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Klas Wictorin

Amelioration of cholinergic neuron atrophy and spatial memory impairment in aged rats by nerve growth factor

Continuous infusion of nerve growth factor prevents basal forebrain neuronal death after fimbria fornix transection.

Grafted neural stem cells develop into functional pyramidal neurons and integrate into host cortical circuitry

Transplantation of Human Neural Progenitor Cells into the Neonatal Rat Brain: Extensive Migration and Differentiation with Long-Distance Axonal Projections

Reformation of long axon pathways in adult rat central nervous system by human forebrain neuroblasts

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