Cathy W. Levenson

ZINC DEFICIENCY INDUCES DEPRESSION-LIKE SYMPTOMS IN ADULT RATS

There is mounting evidence suggesting a link between serum zinc levels and clinical depression. Not only is serum zinc negatively correlated with the severity of symptoms, but zinc levels appear to be lowest in patients who do not respond to antidepressant drug therapy. It is not known if reduced zinc levels are contributing to depression, or the result of dietary or other factors associated with major depression. Thus, we designed this study to test the hypothesis that dietary zinc deficiency would induce depression-like behaviors in rats. Two-month-old male rats were fed zinc adequate (ZA, 30 ppm), deficient (ZD, 1 ppm), or supplemented (ZS, 180 ppm) diets for 3 weeks. Consistent with the development of depression, ZD rats displayed anorexia (p<0.001), anhedonia (reduced saccharin:water intake, p< 0.001), and increased anxiety-like behaviors in a light-dark box test (p<0.05). Furthermore, the antidepressant drug fluoxetine (10 mg/kg body wt) reduced behavioral despair, as measured by the forced swim test, in rats fed the ZA and ZS rats (p<0.05), but was ineffective in ZD rats. Together these studies suggest that zinc deficiency leads to the development of depression-like behaviors that may be refractory to antidepressant treatment.

Trace metal regulation of neuronal apoptosis: From genes to behavior

The genetically programmed form of neuronal death known as apoptosis plays a role in many neurodegenerative diseases including Alzheimers disease, Parkinsons disease, amyotrophic lateral sclerosis (ALS) and Huntingtons disease. Apoptosis is also responsible for neuronal death after traumatic brain and spinal cord injury, stroke, and seizures. The cognitive and behavioral consequences of all of these disorders can be devastating. Unfortunately the mechanisms that regulate neuronal apoptosis are complex. However, it is this very complexity that provides us with a wide array of potential targets for the development of anti-apoptotic strategies. Thus, our lab is currently exploring the molecular and cellular mechanisms responsible for neuronal apoptosis, with a particular focus on the role of the metals copper, zinc, and iron. Each of these metals is essential for normal central nervous system (CNS) development and function. However, imbalances, either excess or deficiency, can result in neuronal apoptosis. In this review, we show the relationship between these metals in neurodegenerative disorders and CNS injury, and the mechanisms that govern neuronal survival and apoptosis.

Zinc and Neurogenesis: Making New Neurons from Development to Adulthood

Stem cell proliferation, neuronal differentiation, cell survival, and migration in the central nervous system are all important steps in the normal process of neurogenesis. These mechanisms are highly active during gestational and early neonatal brain development. Additionally, in select regions of the brain, stem cells give rise to new neurons throughout the human lifespan. Recent work has revealed key roles for the essential trace element zinc in the control of both developmental and adult neurogenesis. Given the prevalence of zinc deficiency, these findings have implications for brain development, cognition, and the regulation of mood.

Dopamine transporters participate in the physiological regulation of prolactin

Three populations of hypothalamic neuroendocrine dopaminergic (NEDA) neurons, arising from the arcuate and periventricular nuclei of the hypothalamus release dopamine (DA) that acts at the pituitary gland to regulate the secretion of PRL. It is generally accepted that NEDA neurons lack functional DA transporters (DATs), which are responsible for uptake of DA from the synaptic cleft into the presynaptic axon terminal. This study localized DATs to the hypothalamo-pituitary axis and evaluated the effect of DAT blockade on the hypothalamo-pituitary regulation of PRL. After 7 days of treatment with cocaine (a nonspecific amine transporter blocker) or mazindol (a specific DAT blocker), the relative abundance of PRL messenger RNA (mRNA) in the anterior lobe (AL) of OVX rats was significantly decreased, whereas the relative abundance of tyrosine hydroxylase mRNA in the hypothalamus was significantly increased. The effect of cocaine or mazindol administration on DA turnover and serum PRL concentration was examined...

Role of zinc in the development and treatment of mood disorders.

Purpose of reviewThe present review is a critical examination of the most recent published work on the role of zinc in the development and treatment of mood disorders. Recent findingsClinical studies and experimental work using animal models have both revealed a link between zinc status and neuropsychological disorders such as depression and anxiety. Not only has zinc deficiency been shown to induce depression-like and anxiety-like behaviors, supplementation has been used as a treatment for major depression. Zinc administration improves the efficacy of antidepressant drugs in depressed patients and may have a particular role to play in treatment-resistant patients. Recent investigations into the molecular mechanisms responsible for these observations suggest a role for zinc in the regulation of neurotransmitter systems, antioxidant mechanisms, neurotrophic factors, and neuronal precursor cells. SummaryThe data reviewed here not only indicate a role for zinc deficiency in the development of mood disorders, but also show that zinc may also be important in their treatment. Given the prevalence of zinc deficiency in human populations, this work has the potential to influence strategies to prevent and treat these disorders.

Role of dietary iron restriction in a mouse model of Parkinson's disease

There is a growing body of evidence suggesting that iron chelation may be a useful therapy in the treatment of Parkinsons Disease (PD). Experiments were designed to test the impact of dietary iron availability on the pathogenic process and functional outcome in a mouse model of PD. Mice were fed diets containing low (4 ppm) or adequate (48 ppm) amounts of iron for 6 weeks before the administration of MPTP, a mitochondrial toxin that damages nigrostriatal dopaminergic neurons and induces Parkinson-like symptoms. Low dietary iron increased serum total iron binding capacity (P < 0.001). Consistent with neuronal protection, iron restriction increased sphingomyelin C16:0 and decreased ceramide C16:0. However, there was a 35% decrease in striatal dopamine (DA) in iron-restricted mice. Motor behavior was also impaired in these animals. In vitro studies suggested that severe iron restriction could lead to p53-mediated neuronal apoptosis. Administration of MPTP reduced striatal DA (P < 0.01) and impaired motor behavior in iron-adequate mice. However, in iron-restricted mice, striatal dopamine levels and motor behavior were unchanged compared to saline-treated mice. Thus, while reduced iron may provide protection against PD-inducing insults such as MPTP, the role of iron in the synthesis of DA and neuronal survival should be considered, particularly in the development of iron-chelating agents to be used chronically in the clinical setting.

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 Alzheimers 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.

Zinc supplementation provides behavioral resiliency in a rat model of traumatic brain injury.

Depression, anxiety, and impairments in learning and memory are all associated with traumatic brain injury (TBI). Because of the strong link between zinc deficiency, depression, and anxiety, in both humans and rodent models, we hypothesized that dietary zinc supplementation prior to injury could provide behavioral resiliency to lessen the severity of these outcomes after TBI. Rats were fed a marginal zinc deficient (5 ppm), zinc adequate (30 ppm), or zinc supplemented (180 ppm) diet for 4 weeks followed by a moderately-severe TBI using the well-established model of controlled cortical impact (CCI). Following CCI, rats displayed depression-like behaviors as measured by the 2-bottle saccharin preference test for anhedonia. Injury also resulted in evidence of stress and impairments in Morris water maze (MWM) performance compared to sham-injured controls. While moderate zinc deficiency did not worsen outcomes following TBI, rats that were fed the zinc supplemented diet for 4 weeks showed significantly attenuated increases in adrenal weight (p<0.05) as well as reduced depression-like behaviors (p<0.001). Supplementation prior to injury improved resilience such that there was not only significant improvements in cognitive behavior compared to injured rats fed an adequate diet (p<0.01), there were no significant differences between supplemented and sham-operated rats in MWM performance at any point in the 10-day trial. These data suggest a role for supplemental zinc in preventing cognitive and behavioral deficits associated with TBI.

Response of rat adrenal neuropeptide Y and tyrosine hydroxylase mRNA to acute stress is enhanced by long-term voluntary exercise

Neuropeptide Y (NPY) and catecholamines are synthesized in response to stress. Adrenal NPY mRNA and tyrosine hydroxylase (TH) mRNA were measured by Northern analysis 2 h after a single 20 min bout of shaker stress in exercised and sedentary male Sprague-Dawley rats. Long-term exercise (18 weeks of voluntary wheel running) alone did not significantly alter adrenal NPY mRNA or TH mRNA levels. However, increases in stress-induced NPY and TH mRNA abundances were significantly enhanced by long-term exercise (P < 0.01). These results suggest that long-term physical activity may enhance the ability to synthesize NPY and catecholamines under conditions of stress.

Chronic caloric restriction reduces tissue damage and improves spatial memory in a rat model of traumatic brain injury.

Although it has been known for some time that chronic caloric or dietary restriction reduces the risk of neurodegenerative disorders and injury following ischemia, the possible role of chronic restriction in improving outcomes after traumatic brain injury (TBI) has not been previously studied. Therefore, 2‐month‐old male Sprague‐Dawley rats were divided into two dietary groups, an ad libitum fed group (AL) and a caloric‐restriction group (CR) that was provided with 70% of the food intake of AL rats (n = 10/group). After 4 months, a weight‐drop device (300 g) was used to produce a 2‐mm bilateral medial frontal cortex contusion following craniotomy. Additional animals in each dietary group (n = 10) were used as sham‐operated controls. The CR diet resulted in body weights that were reduced by 30% compared with AL controls. Not only did CR decrease the size of the cortical lesion after injury, there were marked improvements in spatial memory as measured by Morris water maze that included an increase in the number of animals successfully finding the platform as well as significantly reduced time to finding the hidden platform. Western analysis, used to examine the expression of proteins that play a role in neuronal survival, revealed significant increases in brain‐derived neurotrophic factor (BDNF) in the cortical region around the site of injury and in the hippocampus in CR rats after injury. These findings suggest that molecular mechanisms involved in cell survival may play a role in reducing tissue damage and improving cognition after TBI and that these mechanisms can be regulated by dietary interventions.