The effects of ciliary neurotrophic factor on murine spinal cord neurons subjected to dendrite transection injury

Effect of ciliary neurotrophic factor on neural differentiation of stem cells of human exfoliated deciduous teeth

The stem cells of human exfoliated deciduous teeth (SHEDs) are considered to be one of the main sources of seed cells in stem cell therapy. The aim of this study was to examine the effect of ciliary neurotrophic factor (CNTF) on neurogenic differentiation of SHEDs. With the consent of parents, SHEDs from 6 to 8 year old children were isolated and cultured. The mesenchymal stemness and the potential of multidirectional (adipogenic and osteogenic) differentiation for the isolated SHEDs were firstly determined. The effect of CNTF on specific neurogenic differentiation of SHEDs was then examined by detecting the expression of marker genes and proteins via RT-PCR, immunoblotting, and immunofluorescence microscopy. The isolated SHEDs expressed specific surface markers of mesenchymal stem cells, and their potential of osteogenic and adipogenic differentiation were confirmed. CNTF promoted the differentiation of SHEDs into neuron-like cells with a high expression of acetylcholine transferase (CHAT), a marker of cholinergic neurons. The expression of other neuron markers including nestin, microtubule-associated protein 2 (MAP 2), and β-tublin III was also detected. Interestingly, the expression of neurogenic markers was maintained at a high level after neurogenic induction. SHEDs can be induced by CNTF to differentiate into cholinergic neuron-like cells under appropriate culture conditions. Our findings have laid a foundation for future use of SHEDs to treat neurological diseases.

Cell Therapeutic Strategies for Spinal Cord Injury

Significance: Spinal cord injury (SCI) is a neurological disorder that resulted from destroyed long axis of spinal cord, affecting thousands of people every year. With the occurrence of SCI, the lesions can form cystic cavities and produce glial scar, myelin inhibitor, and inflammation that negatively impact repair of spinal cord. Therefore, SCI remains a difficult problem to overcome with present therapeutics. This review of cell therapeutics in SCI provides a systematic review of combinatory therapeutics of SCI and helps the realization of regeneration of spinal cord in the future. Recent Advances: With major breakthroughs in neurobiology in recent years, present therapeutic strategies for SCI mainly aim at nerve regeneration or neuroprotection. For nerve regeneration, the application approaches are tissue engineering and cell transplantation, while drug therapeutics is applied for neuroprotection. Cell therapeutics is a new approach that treats SCI by cell transplantation. Cell therapeutics possesses advantages of neuroprotection, immune regulation, axonal regeneration, neuron relay formation, and remyelination. Critical Issues: Neurons cannot regenerate at the site of injury. Therefore, it is essential to find a repair strategy for remyelination, axon regeneration, and functional recovery. Cell therapeutics is emerging as the most promising approach for treating SCI. Future Directions: The future application of SCI therapy in clinical practice may require a combination of multiple strategies. A comprehensive treatment of injury of spinal cord is the focus of the present research. With the combination of different cell therapy strategies, future experiments will achieve more dramatic success in spinal cord repair.

STAT3 activation protects retinal ganglion cell layer neurons in response to stress

STAT3 is a major signaling molecule for many neurotrophic factors but its direct role in the protection of neurons in response to stress has not been addressed. We have studied the role of STAT3 in protecting retinal neurons from damage induced by ischemia/reperfusion and glutamate excitotoxicity by using adenovirus constructs to introduce active, normal or inactive STAT3 into retinal ganglion cells in culture and cells of the ganglion cell layer in the intact retina. Transient ischemia/reperfusion was induced in adult CD1 mice by elevating the intraocular pressure to the equivalent of 120mmHg for 60min, followed by a return to normal pressure. The levels, activation and distribution of STAT3 protein were evaluated by Western blot and immunocytochemistry. A transient peak of STAT3 activation was seen at 24h post ischemia and a strong increase in STAT3 protein levels 24h later. The increase in levels of STAT3 was detected in both ganglion cell bodies and processes in the plexiform layers by immunocytochemistry. The time course of STAT3 increase was slower than the time course of ganglion cell death as measured by TUNEL assay. Intravitreal injection of NMDA led to peak increases in activated STAT3 and STAT3 at 12 and 24h post insult respectively. Purified RGCs were infected with recombinant wild-type STAT3, constitutively active and dominant negative forms of STAT3 adenoviruses or control empty virus and then treated with glutamate. Surviving infected cells were counted 24 and 48h later. Infection with constitutively active STAT3 gave substantial protection when compared to the other constructs. Similarly, intravitreal injection of constitutively active STAT3 adenovirus one day before ischemia-reperfusion resulted in a decreased neural cell death in the ganglion cell layer compared with GFP adenovirus control. Our results suggest that persistent activation of STAT3 by neurotrophic factors provides strong neuroprotection and will be an effective strategy in a number of chronic retinal diseases.

Mechanical heterogeneity of the rat hippocampus measured by atomic force microscope indentation

Knowledge of brain tissue mechanical properties may be critical for formulating hypotheses about traumatic brain injury (TBI) mechanisms and for accurate TBI simulations. To determine the local mechanical properties of anatomical subregions within the rat hippocampus, the atomic force microscope (AFM) was adapted for use on living brain tissue. The AFM provided advantages over alternative methods for measuring local mechanical properties of brain because of its high spatial resolution, high sensitivity, and ability to measure live samples under physiologic conditions. From AFM indentations, a mean pointwise or depth-dependent apparent elastic modulus, E, was determined for the following hippocampal subregions: CA1 pyramidal cell layer (CA1P) and stratum radiatum (CA1SR), CA3 pyramidal cell layer (CA3P) and stratum radiatum (CA3SR), and the dentate gyrus (DG). For all regions, E was indentation-depth-dependent, reflecting the nonlinearity of brain tissue. At an indentation depth of 3microm, E was 234 +/- 152 Pa for CA3P, 308 +/- 184 Pa for CA3SR, 137 +/- 97 Pa for CA1P, 169 +/- 52 Pa for CA1SR, and 201 +/- 133 Pa for DG (mean +/- SD). Our results demonstrate for the first time that the hippocampus is mechanically heterogeneous. Based on our findings, we discuss hypotheses accounting for experimentally observed patterns of hippocampal cell death, which can be tested with biofidelic finite element models of TBI.

Ciliary neurotrophic factor protects rat retina cells in vitro and in vivo via PI3 kinase

PURPOSE

Neurotrophic factors and neurotrophins are well-known to have neuroprotective efficacy against retinal injury. The aim of this experiment is to investigate the signal transduction pathway of ciliary neurotrophic factor (CNTF) on the upregulation of viability of retinal primary culture and retinal protection against constant light damage in vivo. CNTF is known to enhance the viability of retinal culture and provide protection under constant light exposure conditions, but little is known about how the signal transduction pathways of CNTF affect retina function.

METHODS

Primary retinal cultures were prepared from 7-day-old Wistar rats. Brain-derived neurotrophic factor (BDNF) (0.1, 1, 10 ng/ml), CNTF (0.1, 1, 10 ng/ml), PD98059 (10, 100, 1000 nM), or LY294002 (10, 100, 1000 nM) was added to these cultures at the time of cell preparation. After 3 days, the percentage of cells surviving was assessed using alamarBlue. For the in vivo experiment, inhibitors for the MAPKK (PD98059, 10 microg/eye) or PI3K (LY294002, 10 microg/eye) pathways were injected into the vitreous together with CNTF (1 microg/eye) 2 days before constant light exposure. Electroretinogram (ERG) analysis was performed to investigate which pathway was used by CNTF.

RESULTS

CNTF at 1, 10, or 100 ng/ml enhanced cell viability in retinal cultures. The cell-survival activity of CNTF was blocked by 10 ng/ml LY294002 (Dunnet's test, p < 0.05). In vivo, the neuroprotective activity of CNTF in constant-light conditions was attenuated by 10 microg/eye LY294002 (Dunnet's test, p < 0.05).

CONCLUSIONS

These data suggest that CNTF promotes cell survival via the PI3K signaling pathway in vitro and in vivo.

Ciliary neurotrophic factor enhances the expression of NGF and p75 low-affinity NGF receptor in astrocytes

A functional interactions between ciliary neurotrophic factor (CNTF) and NGF has recently been demonstrated. We found that the exposure of rat cortical astrocytes to human recombinant CNTF for 3 h increased the level of mRNA for NGF as determined by reverse transcription-polymerase chain reaction (RT-PCR). The increase in NGF message was followed by corresponding increase in NGF protein secreted from the astrocytes into the culture medium as determined 6 h later. C-fos seemed to be involved in the mechanism of NGF induction since the expression of c-fos gene preceded NGF mRNA elevation. Furthermore, we found that in cultured astrocytes exogenous CNTF increased the level of mRNA coding for p75(NTR), the low affinity receptor for NGF and other neurotrophins. CNTF is highly expressed in the lesioned brain and CNTF-induced upregulation of NGF synthesis could be involved in the endogenous repair mechanisms.

Ciliary neurotrophic factor protects hippocampal neurons from excitotoxic damage

The loss of neurons is responsible for many acute neurological disorders as well as chronic neurodegenerative diseases. This cell loss might be prevented by a direct delivery of neurotrophic factors. Therefore, we investigated the capacity of ciliary neurotrophic factor (CNTF) and nerve growth factor (NGF) as well as the combination of both growth factors on the glutamate-induced excitotoxic damage in hippocampal cultures. The exposure of hippocampal neuronal/glial co-cultures to 0.5 mM L-glutamate for 1 h induced pronounced neurotoxicity evaluated 18 h later by trypan blue staining and morphological criteria. The damaged neurons showed both apoptotic and necrotic features. However, CNTF (1-1000 pg/ml) reduced neuronal degeneration when administered 6 and 24 h before induction of injury and remained in contact with the cells until evaluation of neuronal damage. Furthermore, NGF (1 ng/ml) also rescued the hippocampal neurons under the same experimental conditions and with a similar to CNTF potency. However, the co-administration of NGF and CNTF (but not either factor alone) restored the neuronal survival to control levels. Our results support the hypothesis that administering neurotrophic factors could represent an alternative strategy for the treatment of acute and chronic brain disorders.