In a study where rats were treated with vitamin D in the neonatal period, it was found that dopamine levels remained elevated well beyond the period of exposure, with the effect being transmitted to the offspring of treated female rats [38, 39]. These data require replication, but are consistent with the concept of metabolic imprinting [40, 41]. Important features of Selleck Rapamycin metabolic imprinting include the presence of a critical
period during foetal development or early life during which the foetus is sensitive to environmental exposures, and that such exposures lead to changes that persist through adulthood. Recent evidence suggests that epigenetic regulation may be operative XAV-939 in vitro in vitamin D converting enzymes raising the intriguing possibility that early vitamin D exposure (or lack thereof) may induce epigenetic alterations that affect gene expression, and perhaps susceptibility to neurodegenerative diseases later in life [42]. There are several lines of evidence that suggest vitamin D may have a neuroprotective role. The administration of vitamin D or its
metabolites has been shown to reduce neurological injury and/or neurotoxicity in a variety of animal systems, including: (i) the attentuation of the size of cerebral infarction in rats through presumed GDNF upregulation [43]; (ii) the preservation of mechanical hyperalgesia in a streptozotocin-diabetic rat model through the prevention of NGF depletion [44]; (iii) the decrease in neuronal death in rat foetal hippocampal cultures elicited by calcium mediated neurotoxicity through downregulation of L-type voltage-sensitive Ca2+ selleck kinase inhibitor channels [45]; (iv) the attenuation of hypokinesia and dopamine neuronal toxicity in a rat model of 6-hydroxydopamine-induced neurotoxicity through the sequestration of free radical and reactive oxygen species (ROS) [46, 47]; (v) the protection of rat cultured mesencephalic dopaminergic neurones from glutamate and dopaminergic
toxins by facilitating cellular functions that reduce oxidative stress [48, 49]; and (vi) the reduction of glutamate-induced cell death in cultured rat cortical neurones [50]. These latter studies highlight vitamin D’s role in antioxidative metabolism, which is further supported by its ability to downregulate the expression of inducible nitric oxide synthase (iNOS) (and subsequently nitric oxide) in monocyte-derived cells [51], and to potentiate the production of γ-Glutamyl transpeptidase (γ-GT), an enzyme important in the glutathione pathway, in astrocytes exposed to a pro-inflammatory milieu [52]. While these experimental data demonstrate that vitamin D appears to exert its neuroprotective influence through diverse (and potentially overlapping) mechanisms, the extent of neuro-axis regional specificity of these effects is not clear.