Neuronal plasticity or remodeling is most often discussed with regard to cellular and behavioral models of learning and memory. However, neuronal plasticity is a fundamental process by which the brain acquires information and makes the appropriate adaptive responses in future-related settings. Dysfunction of these fundamental processes could thereby contribute to the pathophysiology of mood disorders, and recovery could occur by induction of the appropriate plasticity or remodeling. These possibilities are supported by preclinical and clinical studies demonstrating that there are structural alterations that occur in response to stress and in patients with mood disorders. Moreover, antidepressant treatment may oppose these effects by regulation of signal transduction and gene expression pathways linked to neuronal plasticity. These findings comprise a novel conceptual framework for future studies of the etiology of mood disorders and for the development of novel therapeutic interventions.

Dorsal root ganglia (DRG) respond to peripheral nerve injury by up-regulating nitric oxide (NO) production by neurons and glia in addition to local fibroblasts, endothelium and macrophages. We hypothesise that NO produced from these cells has specific roles. We have shown that when neuronal NO synthase (nNOS) is blocked in axotomised DRG, neurons undergo degenerative changes (Thippeswamy et al., 2001, 2007a). Further, we demonstrated that increased neuronal NO production, in response to axotomy/growth factor-deprivation in vitro, signals glial cells to produce trophic factors to support neuronal survival (Thippeswamy et al., 2005a). Recently, we found that treating satellite glia–neuron co-cultures with nNOS inhibitor, 7-nitroindazole (7NI), decreases the number of nestin+ cells that show neuron-like morphology. Cultured/axotomised DRG also upregulate inducible NOS (iNOS) in non-neuronal cells. Therefore, it is plausible that degenerative changes following nNOS inhibition are also due to iNOS-mediated excessive NO production by non-neuronal cells, which indeed is cytotoxic. NG-nitro-l-arginine methylester (L-NAME), the pan NOS inhibitor did not significantly change nNOS+ neuron number in axotomised DRG compared to 7NI suggesting that iNOS-mediated NO contributes to the degenerative process. In this paper, these findings from our and others' past work on NO-mediated neuron–glia signalling in axotomised DRG are discussed.

Brain-derived neurotrophic factor (BDNF) is a preferred ligand for a member of the tropomyosin-related receptor family, trkB. Activation of trkB is implicated in various activity-independent as well as activity-dependent growth processes in many developing and mature neural systems. In the subcortical visual system, where electrical activity has been implicated in normal development, both differential survival, as well as remodeling of axonal arbors, have been suggested to contribute to eye-specific segregation of retinal ganglion cell inputs. Here, we tested whether BDNF is required for eye-specific segregation of visual inputs to the lateral geniculate nucleus and the superior colliculus, and two other major subcortical target fields in mice. We report that eye-specific patterning is normal in two mutants that lack BDNF expression during the segregation period: a germ-line knockout for BDNF, and a conditional mutant in which BDNF expression is absent or greatly reduced in the central nervous system. We conclude that the availability of BDNF is not necessary for eye-specific segregation in subcortical visual nuclei.

The recombinant human nerve growth factor (hNGF), brain-derived neurotrophic factor (BDNF), neurotrophin-3 (NT-3), neurotrophin 4/5 (NT4/5), and murine NGF (mNGF) dimers all undergo rapid unfolding and dissociation to monomer in GdnHCl. Fluorescence spectroscopy, reversed-phase high-performance liquid chromatography, and size-exclusion chromatography were used to show that this monomer M1 converts slowly to a more fully unfolded monomer, M2, by a first order process with half-lives of 22, 2.5, 1.6, and 0.73 h for hNGF, mNGF, NT-3, and BDNF, respectively, at 25 °C. Linear Arrhenius plots for the conversion of M1 to M2 yielded activation energies of 27, 22, 24, and 24 kcal/mol for hNGF, mNGF, NT-3, and BDNF, respectively. The refolding of these neurotrophins from 5 M GdnHCl was also first order with NT-3 the slowest to refold and BDNF the fastest. Threading of the N-terminus out through the cystine-knot loop present in each of these proteins is proposed as the slow step in unfolding. The number of amino acids in the cystine-knot loop (14 for hNGF, mNGF, NT-3, and BDNF; 21 for NT4/5), and the number and position of the proline residues in this loop (2 for hNGF; 1 for mNGF, NT-3, BDNF, and NT4/5) correlate with the relative rates of unfolding. The smaller the loop and the greater the number of prolines, the more hindered and slower the unfolding.