Pax3 induces target-specific reinnervation through axon collateral expression of PSA-NCAM.

Damaged or dysfunctional neural circuits can be replaced after a lesion by axon sprouting and collateral growth from undamaged neurons. Unfortunately, these new connections are often disorganized and rarely produce clinical improvement. Here we investigate how to promote post-lesion axonal collateral growth, while retaining correct cellular targeting. In the mouse olivocerebellar path, brain-derived neurotrophic factor (BDNF) induces correctly-targeted post-lesion cerebellar reinnervation by remaining intact inferior olivary axons (climbing fibers). In this study we identified cellular processes through which BDNF induces this repair. BDNF injection into the denervated cerebellum upregulates the transcription factor Pax3 in inferior olivary neurons and induces rapid climbing fiber sprouting. Pax3 in turn increases polysialic acid-neural cell adhesion molecule (PSA-NCAM) in the sprouting climbing fiber path, facilitating collateral outgrowth and pathfinding to reinnervate the correct targets, cerebellar Purkinje cells. BDNF-induced reinnervation can be reproduced by olivary Pax3 overexpression, and abolished by olivary Pax3 knockdown, suggesting that Pax3 promotes axon growth and guidance through upregulating PSA-NCAM, probably on the axon's growth cone. These data indicate that restricting growth-promotion to potential reinnervating afferent neurons, as opposed to stimulating the whole circuit or the injury site, allows axon growth and appropriate guidance, thus accurately rebuilding a neural circuit.

Age-related Purkinje cell death is steroid dependent: RORα haplo-insufficiency impairs plasma and cerebellar steroids and Purkinje cell survival.

A major problem of ageing is progressive impairment of neuronal function and ultimately cell death. Since sex steroids are neuroprotective, their decrease with age may underlie age-related neuronal degeneration. To test this, we examined Purkinje cell numbers, plasma sex steroids and cerebellar neurosteroid concentrations during normal ageing (wild-type mice, WT), in our model of precocious ageing (Rora(+/sg), heterozygous staggerer mice in which expression of the neuroprotective factor RORα is disrupted) and after long-term hormone insufficiency (WT post-gonadectomy). During normal ageing (WT), circulating sex steroids declined prior to or in parallel with Purkinje cell loss, which began at 18 months of age. Although Purkinje cell death was advanced in WT long-term steroid deficiency, this premature neuronal loss did not begin until 9 months, indicating that vulnerability to sex steroid deficiency is a phenomenon of ageing Purkinje neurons. In precocious ageing (Rora(+/sg)), circulating sex steroids decreased prematurely, in conjunction with marked Purkinje cell death from 9 months. Although Rora(+/sg) Purkinje cells are vulnerable through their RORα haplo-insufficiency, it is only as they age (after 9 months) that sex steroid failure becomes critical. Finally, cerebellar neurosteroids did not decrease with age in either genotype or gender; but were profoundly reduced by 3 months in male Rora(+/sg) cerebella, which may contribute to the fragility of their Purkinje neurons. These data suggest that ageing Purkinje cells are maintained by circulating sex steroids, rather than local neurosteroids, and that in Rora(+/sg) their age-related death is advanced by premature sex steroid loss induced by RORα haplo-insufficiency.

Differential expression of TrkB isoforms switches climbing fiber-Purkinje cell synaptogenesis to selective synapse elimination.

Correct neural function depends on precisely organized connectivity, which is refined from broader projections through synaptic/collateral elimination. In the rat, olivocerebellar topography is refined by regression of multiple climbing fiber (CF) innervation of Purkinje cells (PC) during the first two postnatal weeks. The molecules that initiate this regression are not fully understood. We assessed the role of cerebellar neurotrophins by examining tropomycin receptor kinase (Trk) receptor expression in the inferior olive and cerebellum between postnatal days (P)3-7, when CF-PC innervation changes from synapse formation to selective synapse elimination, and in a denervation-reinnervation model when synaptogenesis is delayed. Trks A, B, and C are expressed in olivary neurons; although TrkA was not transported to the cerebellum and TrkC was unchanged during innervation and reinnervation, suggesting that neither receptor is involved in CF-PC synaptogenesis. In contrast, both total and truncated TrkB (TrkB.T) increased in the olive and cerebellum from P4, whereas full-length and activated phosphorylated TrkB (phospho-TrkB) decreased from P4-5. This reveals less TrkB signaling at the onset of CF regression. This expression pattern was reproduced during CF-PC reinnervation: in the denervated hemicerebellum phospho-TrkB decreased as CF terminals degenerated, then increased in parallel with the delayed neosynaptogenesis as new CFs reinnervated the denervated hemicerebellum. In the absence of this signaling, CF reinnervation did not develop. Our data reveal that olivocerebellar TrkB activity parallels CF-PC synaptic formation and stabilization and is required for neosynaptogenesis. Furthermore, TrkB.T expression rises to reduce TrkB signaling and permit synapse elimination.

Cerebellar purkinje cell loss in heterozygous rora+/- mice: a longitudinal study.

The staggerer (sg) mutation is a spontaneous deletion in the Rora gene that prevents the translation of the ligand-binding domain (LBD), leading to the loss of RORalpha activity. The homozygous Rorasg/sg mutant mouse, whose most obvious phenotype is ataxia associated with cerebellar degeneration, also displays a variety of other phenotypes. The heterozygous Rora+/sg is able to develop a cerebellum that is qualitatively normal but which suffers a significant loss of cerebellar neuronal cells with advancing age. A truncated protein synthesized by the mutated allele may play a role both in Rorasg/sg and Rora+/sg. To determine the effects during life span of true haplo-insufficiency of the RORalpha protein, derived from the invalidation of the gene, we compared the evolution of Purkinje cell numbers in heterozygous Rora knock-out males (Rora+/-) and in their wild-type counterparts from 1 to 24 months of age. We also compared the evolution of Purkinje cell (PC) numbers in Rora+/- and Rora+/sg males from 1 to 9 months. The main finding is that in Rora+/- mice, for which only one-half the normal amount of protein is produced, the deficit was established as early as 1 month and did not change during the animals' adult lifespans. Thus, the effects of aging on PC number were apparent much earlier in Rora+/- than in Rora+/sg, although at 24 months of age the degrees of deficit were similar.

Human retinoic acid receptor-related orphan receptor alpha1 overexpression protects neurones against oxidative stress-induced apoptosis.

Retinoic acid receptor-related orphan receptor alpha (RORalpha) is a transcription factor belonging to the superfamily of nuclear receptors. Disruption of the Rora gene in the mouse results in a defect in the development of Purkinje cells leading to a cerebellar atrophy, which suggests a neuroprotective role for RORalpha. To test this hypothesis, the survival rate of lentiviral-mediated human RORalpha1-overexpressing neurones has been evaluated in response to different stressors disturbing the redox homeostasis, such as beta-amyloid peptide, c(2)-ceramide and H(2)O(2). We show that overexpression of human RORalpha1 provides neuroprotection by increasing the expression of the antioxidant proteins glutathione peroxidase 1 and peroxiredoxin 6, leading to a reduction in the accumulation of stress-induced reactive oxygen species. We further demonstrate that the neuroprotective effect of RORalpha is predominantly mediated by glutathione peroxidase 1 and peroxiredoxin 6. These results suggest a new role for RORalpha in the control of the neuronal oxidative stress and thus represents a new transcription factor of interest in the regulation of reactive oxygen species-induced neurodegenerative processes during ageing.

Smooth muscle dysfunction in resistance arteries of the staggerer mouse, a mutant of the nuclear receptor RORalpha.

Retinoic acid receptor-related orphan receptor alpha (RORalpha) is a member of the nuclear receptor superfamily. The mouse mutant staggerer (sg/sg) carries a deletion within the RORalpha gene. RORalpha plays a major role in cellular differentiation during development and growth. In the present study, we found a lower mean arterial blood pressure in sg/sg than in +/+ mice (80.1+/-1.2 and 87.0+/-0.9 mm Hg, respectively; P<0.0002) and a smaller increase in blood pressure after in vivo injections of phenylephrine. To elucidate the mechanisms responsible for this phenotype, we investigated the vascular reactivity of large vessels (aorta and carotid arteries) and small resistance mesenteric arteries in response to mechanical forces or vasoactive agents. Arteries from sg/sg and +/+ mice were studied in vitro in arteriographs. Vascular responses of large vessels to all stimuli were similar in both groups. However, we found a markedly altered vascular function in mesenteric arteries from sg/sg mice. Flow-induced dilation, pressure-induced myogenic tone, responses to endothelium-dependent or -independent vasodilators, and responses to vasoconstrictors were significantly reduced in sg/sg compared with +/+ mice. We also determined by Western blot analysis the expression of smooth muscle (SM)-myosin, calponin, and heavy (h)-caldesmon, in large and small arteries of sg/sg and +/+ mice, and found a marked decrease in the expression of these contractile proteins in mesenteric arteries of sg/sg mice. Our findings provide the first evidence that functional RORalpha is required for normal contractile phenotype of smooth muscle cells (SMCs) in small resistance arteries and suggest that RORalpha might be involved in the differentiation of SMCs in mesenteric arteries.