Effect of zinc supplementation on neuronal precursor proliferation in the rat hippocampus after traumatic brain injury.

There is great deal of debate about the possible role of adult-born hippocampal cells in the prevention of depression and related mood disorders. We first showed that zinc supplementation prevents the development of the depression-like behavior anhedonia associated with an animal model of traumatic brain injury (TBI). This work then examined the effect of zinc supplementation on the proliferation of new cells in the hippocampus that have the potential to participate in neurogenesis. Rats were fed a zinc adequate (ZA, 30ppm) or zinc supplemented (ZS, 180ppm) diet for 4wk followed by TBI using controlled cortical impact. Stereological counts of EdU-positive cells showed that TBI doubled the density of proliferating cells 24h post-injury (p<0.05), and supplemental zinc significantly increased this by an additional 2-fold (p<0.0001). While the survival of these proliferating cells decreased at the same rate in ZA and in ZS rats after injury, the total density of newly born cells was approximately 60% higher in supplemented rats 1wk after TBI. Furthermore, chronic zinc supplementation resulted in significant increases in the density of new doublecortin-positive neurons one week post-TBI that were maintained for 4wk after injury (p<0.01). While the effect of zinc supplementation on neuronal precursor cells in the hippocampus was robust, use of targeted irradiation to eliminate these cells after zinc supplementation and TBI revealed that these cells are not the sole mechanism through which zinc acts to prevent depression associated with brain injury, and suggest that other zinc dependent mechanisms are needed for the anti-depressant effect of zinc in this model of TBI.

Zinc deficiency induces apoptosis via mitochondrial p53- and caspase-dependent pathways in human neuronal precursor cells.

Previous studies have shown that zinc deficiency leads to apoptosis of neuronal precursor cells in vivo and in vitro. In addition to the role of p53 as a nuclear transcription factor in zinc deficient cultured human neuronal precursors (NT-2), we have now identified the translocation of phosphorylated p53 to the mitochondria and p53-dependent increases in the pro-apoptotic mitochondrial protein BAX leading to a loss of mitochondrial membrane potential as demonstrated by a 25% decrease in JC-1 red:green fluorescence ratio. Disruption of mitochondrial membrane integrity was accompanied by efflux of the apoptosis inducing factor (AIF) from the mitochondria and translocation to the nucleus with a significant increase in reactive oxygen species (ROS) after 24h of zinc deficiency. Measurement of caspase cleavage, mRNA, and treatment with caspase inhibitors revealed the involvement of caspases 2, 3, 6, and 7 in zinc deficiency-mediated apoptosis. Down-stream targets of caspase activation, including the nuclear structure protein lamin and polyADP ribose polymerase (PARP), which participates in DNA repair, were also cleaved. Transfection with a dominant-negative p53 construct and use of the p53 inhibitor, pifithrin-µ, established that these alterations were largely dependent on p53. Together these data identify a cascade of events involving mitochondrial p53 as well as p53-dependent caspase-mediated mechanisms leading to apoptosis during zinc deficiency.

Zinc deficiency regulates hippocampal gene expression and impairs neuronal differentiation.

OBJECTIVES: Proliferating adult stem cells in the subgranular zone of the dentate gyrus have the capacity not only to divide, but also to differentiate into neurons and integrate into the hippocampal circuitry. The present study identifies several hippocampal genes putatively regulated by zinc and tests the hypothesis that zinc deficiency impairs neuronal stem cell differentiation. METHODS: Genes that regulate neurogenic processes were identified using microarray analysis of hippocampal mRNA isolated from adult rats fed zinc-adequate or zinc-deficient (ZD) diets. We directly tested our hypothesis with cultured human neuronal precursor cells (NT2), stimulated to differentiate into post-mitotic neurons by retinoic acid (RA), along with immunocytochemistry and western analysis. RESULTS: Microarray analysis revealed the regulation of genes involved in cellular proliferation. This analysis also identified a number of genes known to be involved in neuronal differentiation, including the nuclear RA receptor, retinoid X receptor (RXR), doublecortin, and a transforming growth factor-beta (TGF-ß) binding protein (P < 0.05). Zinc deficiency significantly reduced RA-induced expression of the neuronal marker proteins doublecortin and ß-tubulin type III (TuJ1) to 40% of control levels (P < 0.01). This impairment of differentiation may be partially mediated by alterations in TGF-ß signaling. The TGF-ß type II receptor, responsible for binding TGF-ß during neuronal differentiation, was increased 14-fold in NT2 cells treated with RA (P < 0.001). However, this increase was decreased by 60% in ZD RA-treated cells (P < 0.001). DISCUSSION: This research identifies target genes that are involved in governing neurogenesis under ZD conditions and suggests an important role for TGF-ß and the trace metal zinc in regulating neuronal differentiation.

Zinc in the central nervous system: From molecules to behavior.

The trace metal zinc is a biofactor that plays essential roles in the central nervous system across the lifespan from early neonatal brain development through the maintenance of brain function in adults. At the molecular level, zinc regulates gene expression through transcription factor activity and is responsible for the activity of dozens of key enzymes in neuronal metabolism. At the cellular level, zinc is a modulator of synaptic activity and neuronal plasticity in both development and adulthood. Given these key roles, it is not surprising that alterations in brain zinc status have been implicated in a wide array of neurological disorders including impaired brain development, neurodegenerative disorders such as Alzheimer's disease, and mood disorders including depression. Zinc has also been implicated in neuronal damage associated with traumatic brain injury, stroke, and seizure. Understanding the mechanisms that control brain zinc homeostasis is thus critical to the development of preventive and treatment strategies for these and other neurological disorders.