Chondroitin sulphate proteoglycans in the central nervous system: changes and synthesis after injury.

Chondroitin sulphate proteoglycans (CSPGs) are up-regulated in the central nervous system after injury, specifically around the lesion site where the glial scar forms. This structure contains astrocytes, oligodendrocyte precursor cells, microglia and meningeal cells, and forms an inhibitory substrate for axon re-growth. CSPGs have been shown to be closely involved in this neuronal growth inhibition, specifically through their sugar chains. These chains are composed of repeats of the same disaccharide unit carrying sulphate groups in different positions. The sulphation pattern directly influences the CSPG binding properties and function; the specific sulphation pattern required for the inhibitory activity of these molecules on axon growth is unknown at present. The expression of the chondroitin sulphotransferases, which sulphate the disaccharide residues of CSPGs and thus are responsible for the structural diversity of the chondroitin sulphate sugar chains, is regulated differently in central nervous system during development and after injury, suggesting the implication of a specific sulphation pattern in the inhibitory activity of CSPGs.

Nerve growth factor and asthma.

An increasing body of evidence shows that nerve growth factor (NGF) exerts biological activity not only on the central and peripheral nervous system, but also on the immune system thereby influencing allergic diseases and asthma. (1) NGF circulating levels are increased in patients with allergic diseases and asthma, and are related to the severity of the inflammatory process and disease. In vernal keratoconjunctivitis, NGF plasma levels correlate with the number of mast cells infiltrating the conjunctiva, and NGF mRNA is increased in nasal mucosal scrapings of patients with allergic rhinitis who have high levels of NGF in serum and nasal fluids; NGF is further increased in nasal fluids after specific allergen challenge. (2) NGF is produced and released by several modulatory and effector cells of allergic inflammation and asthma, for example T-helper 2 lymphocytes, mast cells and eosinophils. (3) NGF receptors are expressed on the conjunctival epithelium of patients with allergic conjunctivitis and the number of NGF-receptor positive cells is increased in the conjunctiva of these patients. Indeed, local administration of NGF induces fibroblast activation and healing processes of human corneal ulcers, which suggests that NGF plays a role in tissue remodelling processes occurring in asthma. (4) NGF increases airway hyperreactivity to histamine in an animal model of asthma, while anti-NGF treatment reduces airway hyperreactivity induced by ovalbumin topical challenge in the sensitized mouse.

Nerve growth factor antibody exacerbates neuropathological signs of experimental allergic encephalomyelitis in adult lewis rats.

In this study, experimental allergic encephalomyelitis (EAE) rats and rats exhibiting EAE expressing high circulating anti-nerve growth factor antibody were daily monitored for clinical signs and chronic relapses. Eighty-five days after EAE induction, blood, spinal cord and brain stem were used for histological examination, nerve growth factor (NGF) and brain derived neurotrophic factor (BDNF) evaluation. The results showed that NGF-deprived rats display more severe clinical signs of disease. These effects were associated with a significant reduction of NGF in the brain stem and spinal cord but not of BDNF, which decreased only in spinal cord. These observations provide additional support to the hypothesis of a protective NGF role in rats exhibiting EAE.

Patients treated with antitumor drugs displaying neurological deficits are characterized by a low circulating level of nerve growth factor.

The aim of our study was to explore whether nerve growth factor (NGF) plays any role in the development of peripheral neuropathy induced by anticancer treatment. We measured the circulating NGF levels in 23 cancer patients before and after chemotherapy. We evaluated whether the development of peripheral neurotoxicity was associated with changes in basal NGF concentrations in patients studied with a comprehensive neurological and neurophysiological examination. The results of these studies showed that the circulating levels of NGF, which are about 20 pg/ml in plasma of controls, decrease during chemotherapy and in some cases completely disappeared after prolonged treatment with antitumor agents. The decrease in NGF levels seems to be correlated with the severity of neurotoxicity. These results clearly suggest that NGF might become a useful agent to prevent neuropathies induced by antineoplastic drugs and restore peripheral nerve dysfunction induced by these pharmacological compounds.

Evidence that nerve growth factor promotes the recovery of peripheral neuropathy induced in mice by cisplatin: behavioral, structural and biochemical analysis.

In this study we investigate the neurotoxic action of Cisplatin (6 micrograms/g body weight for 5 treatment cycles during 15 weeks with a total dose of 30 micrograms/g), an antitumor drug, and its effect on the level of nerve growth factor (NGF) and brain-derived neurotrophic factor (BDNF) in peripheral tissues. We found that Cisplatin in adult rodents impairs peripheral sensory function and both sympathetic and sensory peripheral innervation as shown by the hot-plate response, catecholamine distribution and substance P immunoreactivity respectively. These changes are associated with decreased NGF in intestine, paws, and bladder while NGF increased in the spinal cord. Also BDNF decreased in bladder and paws and increased in spinal cord and intestine. To further investigate the role of NGF in the pathogenesis of Cisplatin-induced peripheral neuropathies a group of animals was injected with NGF (1 microgram/g every 4 days for 4 times) following Cisplatin treatment and evaluated for sensory function, sympathetic and sensory innervation and BDNF levels. Data demonstrated that exogenous NGF administration is able to restore biochemical, structural and functional changes induced by Cisplatin. These findings suggest that the reduction of NGF availability could be a cause of Cisplatin-induced peripheral neuropathies and that NGF exogenous administration could prevent or reduce Cisplatin neurotoxicity also in cancer patients, reducing the side effects of chemotherapy.

Learning abilities, NGF and BDNF brain levels in two lines of TNF-alpha transgenic mice, one characterized by neurological disorders, the other phenotypically normal.

In this study we used two lines of transgenic mice overexpressing tumor necrosis factor alpha (TNF-alpha) in the central nervous system (CNS), one characterized by reactive gliosis, inflammatory demyelination and neurological deficits (Tg6074) the other showing no neurological or phenotypical alterations (TgK3) to investigate the effect of TNF-alpha on brain nerve growth factor (NGF) and brain-derived neurotrophic factor (BDNF) levels and learning abilities. The results showed that the amount of NGF in the brain of Tg6074 and TgK3 transgenic mice is low in the hippocampus and in the spinal cord, increases in the hypothalamus of Tg6074 and showed no significant changes in the cortex. BDNF levels were low in the hippocampus and spinal cord of TgK3. BDNF increased in the hypothalamus of TgK3 and Tg6074 while in the cortex, BDNF increased only in Tg6074 mice. Transgenic mice also had memory impairments as revealed by the Morris Water Maze test. These findings indicate that TNF-alpha significantly influences BDNF and NGF synthesis, most probably in a dose-dependent manner. Learning abilities were also differently affected by overexpression of TNF-alpha, but were not associated with inflammatory activity. The possible functional implications of our findings are discussed.

Nerve growth factor: a neurotrophin with activity on cells of the immune system.

Numerous studies published in the last two decades provide evidence that nerve growth factor (NGF), a polypeptide originally discovered because of its neurotrophic activity, acts on a variety of cells of the immune system, including mast cells, eosinophils, and B and T lymphocytes. NGF has been shown to increase during inflammatory responses, autoimmune disorders, parasitic infections, and allergic diseases. Moreover, stress, which is characterized also by activation of a variety of immune cells, causes a significant increase in basal plasma NGF levels. Recently published studies reveal that hematopoietic progenitor cells seem to be able to produce and/or respond to NGF. We report these data and discuss the hypothesis of the possible implication of NGF on the functional activities of immune cells.

Disassembly of the cholinergic postsynaptic apparatus induced by axotomy in mouse sympathetic neurons: the loss of dystrophin and beta-dystroglycan immunoreactivity precedes that of the acetylcholine receptor.

In mouse sympathetic superior cervical ganglion (SCG), cortical cytoskeletal proteins such as dystrophin (Dys) and beta1sigma2 spectrin colocalize with beta-dystroglycan (beta-DG), a transmembrane dystrophin-associated protein, and the acetylcholine receptor (AChR) at the postsynaptic specialization. The function of the dystrophin-dystroglycan complex in the organization of the neuronal cholinergic postsynaptic apparatus was studied following changes in the immunoreactivity of these proteins during the disassembly and subsequent reassembly of the postsynaptic specializations induced by axotomy of the ganglionic neurons. After axotomy, a decrease in the number of intraganglionic synapses was observed (t1/2 8 h 45'), preceded by a rapid decline of postsynaptic specializations immunopositive for beta-DG, Dys, and alpha3 AChR subunit (alpha3AChR) (t1/2 3 h 45', 4 h 30' and 6 h, respectively). In contrast, the percentage of postsynaptic densities immunopositive for beta1sigma2 spectrin remained unaltered. When the axotomized neurons began to regenerate their axons, the number of intraganglionic synapses increased, as did that of postsynaptic specializations immunopositive for beta-DG, Dys, and alpha3AChR. The latter number increased more slowly than that of Dys and beta-DG. These observations suggest that in SCG neurons, the dystrophin-dystroglycan complex might play a role in the assembly-disassembly of the postsynaptic apparatus, and is probably involved in the stabilization of AChR clusters.