Brendan B. McAllister

Zinc transporter 3 (ZnT3) and vesicular zinc in central nervous system function

Zinc transporter 3 (ZnT3) is the sole mechanism responsible for concentrating zinc ions within synaptic vesicles in a subset of the brains glutamatergic neurons. This vesicular zinc can then be released into the synaptic cleft in an activity-dependent fashion, where it can exert many signaling functions. This review provides a comprehensive discussion of the localization and function of ZnT3 and vesicular zinc in the central nervous system. We begin by reviewing the fundamentals of zinc homeostasis and transport, and the discovery of ZnT3. We then focus on four main topics. I) The anatomy of the zincergic system, including its development and its modulation through experience-dependent plasticity. II) The role of zinc in intracellular signaling, with a focus on how zinc affects neurotransmitter receptors and synaptic plasticity. III) The behavioural characterization of the ZnT3 KO mouse, which lacks ZnT3 and, therefore, vesicular zinc. IV) The roles of ZnT3 and vesicular zinc in health and disease.

Mice lacking the transcription factor SHOX2 display impaired cerebellar development and deficits in motor coordination

Purkinje cells of the developing cerebellum secrete the morphogen sonic hedgehog (SHH), which is required to maintain the proliferative state of granule cell precursors (GCPs) prior to their differentiation and migration to form the internal granule layer (IGL). Despite a wealth of knowledge regarding the function of SHH during cerebellar development, the upstream regulators of Shh expression during this process remain largely unknown. Here we report that the murine short stature homeobox 2 (Shox2) gene is required for normal Shh expression in dorsal-residing Purkinje cells. Using two different Cre drivers, we show that elimination of Shox2 in the brain results in developmental defects in the inferior colliculus and cerebellum. Specifically, loss of Shox2 in the cerebellum results in precocious differentiation and migration of GCPs from the external granule layer (EGL) to the IGL. This correlates with premature bone morphogenetic protein 4 (Bmp4) expression in granule cells of the dorsal cerebellum. The size of the neonatal cerebellum is reduced in Shox2-mutant animals, which is consistent with a reduction in the number of GCPs present in the EGL, and could account for the smaller vermis and thinner IGL present in adult Shox2mutants. Shox2-mutant mice also display reduced exploratory activity, altered gait and impaired motor coordination. Our findings are the first to show a role for Shox2 in brain development. We provide evidence that Shox2 plays an important role during cerebellar development, perhaps to maintain the proper balance of Shh and Bmp expression levels in the dorsal vermis, and demonstrate that in the absence of Shox2, mice display both cerebellar impairments and deficits in motor coordination, ultimately highlighting the importance of Shox2 in the cerebellum.

Effects of lighting condition on circadian behavior in 5-HT1A receptor knockout mice.

Serotonin (5-HT) is an important regulator of the mammalian circadian system, and has been implicated in modulating entrained and free-running rhythms, as well as photic and non-photic phase shifting. In general, 5-HT appears to oppose the actions of light on the circadian system of nocturnal rodents. As well, 5-HT mediates, at least in part, some non-photic responses. The 5-HT1A, 1B and 7 receptors regulate these acute responses to zeitgebers. 5-HT also regulates some entrained and free-running properties of the circadian clock. The receptors that contribute to these phenomena have not been fully examined. Here, we use 5-HT1A receptor knockout (KO) mice to examine the response of the mouse circadian system to a variety of lighting conditions, including a normal light-dark cycle (LD), T-cycles, phase advanced LD cycles, constant darkness (DD), constant light (LL) and a 6 hour dark pulse starting at CT5. Relative to wildtype mice, the 5-HT1A receptor KO mice have lower levels of activity during the first 8h of the night/subjective night in LD and LL, later activity onsets on transient days during re-entrainment, shorter free-running periods in LL when housed with wheels, and smaller phase shifts to dark pulses. No differences were noted in activity levels during DD, alpha under any light condition, free-running period in DD, or phase angle of entrainment in LD. While the 5-HT1A receptor plays an important role in regulating photic and non-photic phase shifting, its contribution to entrained and free-running properties of the circadian clock is relatively minor.

The effects of chronic fluoxetine treatment following injury of medial frontal cortex in mice.

Injury of the brain is a leading cause of long-term disability. Recent evidence indicates that the selective serotonin reuptake inhibitor drug fluoxetine may be beneficial when administered following brain injury. However, its potential to promote recovery and the mechanisms by which it might do so require further characterization. In the present experiment, fluoxetine was administered to mice for 4 weeks following injury of medial frontal cortex (MFC). MFC injury altered behavior, reducing locomotion, decreasing swim speed in the Morris water task, and decreasing anxiety-like behavior in the elevated plus maze. Fluoxetine treatment did not affect these behavioral alterations, but it did increase the social dominance of the injured mice, as assessed by the tube test. Fluoxetine treatment also hastened learning of a T-maze position discrimination task, independently of lesion condition. Anatomically, fluoxetine failed to decrease lesion size, increase the survival of cells born 1-week post injury in the hippocampal dentate gyrus, or reverse the reduction in spine density in layer II/III pyramidal neurons in cingulate cortex caused by the lesions. Fluoxetine did, however, increase the dendritic arborization of these cells, which was reduced in the mice with lesions. Thus, while not all the effects of MFC injury were ameliorated, the behavioral outcome of mice with MFC injuries was improved, and one of the neuroanatomical sequelae of the lesions counteracted, by chronic fluoxetine, further contributing to the evidence that fluoxetine could be a useful treatment following brain injury.

Behavioral characterization of female zinc transporter 3 (ZnT3) knockout mice

HighlightsFemale ZnT3 KO mice do not show normal improvement over time at skilled reaching.Female ZnT3 KO mice show decreased exploratory locomotion.Female ZnT3 KO mice perform normally on many tests of motor skill and cognition.Female ZnT3 KO mice do not exhibit the same behavioural deficits previously found in male ZnT3 KO mice.It is critical to conduct behavioural testing on mice of both sexes whenever possible. ABSTRACT Zinc is an important element in all cells of the body, having structural, enzymatic, and regulatory functions. In some neurons, zinc is loaded into synaptic vesicles by zinc transporter 3 (ZnT3) and released into the synaptic cleft, where it can modulate neuronal function. ZnT3 knockout (KO) mice lack ZnT3 and thus lack synaptic zinc. Previous studies have examined the behavioral phenotype of ZnT3 KO mice, mostly using mixed‐sex or male‐only groups. In the present study we focused specifically on the behavior of female ZnT3 KO mice (2–3 months old). An extensive battery of tests was administered to assess sensorimotor and cognitive behaviours, as well as to examine for a possible schizophrenia‐like phenotype. ZnT3 KO mice performed similarly to wild type controls in the majority of tests. However, they were less accurate in the skilled reach task, suggesting impaired skilled motor learning, and faster to descend a vertical pole. ZnT3 KO mice were also slower in the open field and made fewer chamber entries in the social preference test, suggesting decreased exploratory locomotion. No differences were observed in the Morris water task or fear conditioning test. This is the first study to show a behavioural phenotype specifically for female ZnT3 KO mice. Comparing our results to previous studies, it appears that there may be sex‐specific effects of eliminating ZnT3. Female ZnT3 KO mice exhibit abnormalities in locomotion and at skilled motor learning, but we were unable to detect spatial or fear learning deficits previously described in male ZnT3 KO mice.

Brain-derived neurotrophic factor and TrkB levels in mice that lack vesicular zinc: Effects of age and sex

In certain neurons, zinc ions are stored in synaptic vesicles by zinc transporter 3 (ZnT3). Vesicular zinc can then be released synaptically to modulate myriad targets. In vitro evidence indicates that these targets may include brain-derived neurotrophic factor (BDNF) and its receptor, tropomyosin receptor kinase B (TrkB). But the effects of vesicular zinc on BDNF and TrkB in the intact brain are unclear. Studies of mice that lack ZnT3 – and, as a result, vesicular zinc – have shown abnormalities in BDNF and TrkB levels, but results have been mixed and are therefore difficult to interpret. This might be caused by differences in the age or sex of mice tested. In the present study, we measured BDNF and TrkB levels in the hippocampus and neocortex, comparing wild type and ZnT3 knockout mice of both sexes at two ages (5 and 12 weeks). We also examined BDNF mRNA expression and protein levels at an intermediate age (8-10 weeks). We found that, regardless of age or sex, BDNF and TrkB protein levels did not differ between wild type and ZnT3 knockout mice. There were sex-specific differences in BDNF protein and mRNA expression, however. BDNF protein levels increased with age in female mice but not in males. And in females, but not males, ZnT3 KO mice exhibited great hippocampal BDNF mRNA expression than wild type mice. We conclude that, at least in naïve mice housed under standard laboratory conditions, elimination of vesicular zinc does not affect BDNF or TrkB protein levels.

Elimination of vesicular zinc alters the behavioural and neuroanatomical effects of social defeat stress in mice

Chronic stress can have deleterious effects on mental health, increasing the risk of developing depression or anxiety. But not all individuals are equally affected by stress; some are susceptible while others are more resilient. Understanding the mechanisms that lead to these differing outcomes has been a focus of considerable research. One unexplored mechanism is vesicular zinc – zinc that is released by neurons as a neuromodulator. We examined how chronic stress, induced by repeated social defeat, affects mice that lack vesicular zinc due to genetic deletion of zinc transporter 3 (ZnT3). These mice, unlike wild type mice, did not become socially avoidant of a novel conspecific, suggesting resilience to stress. However, they showed enhanced sensitivity to the potentiating effect of stress on cued fear memory. Thus, the contribution of vesicular zinc to stress susceptibility is not straightforward. Stress also increased anxiety-like behaviour but produced no deficits in a spatial Y-maze test. We found no evidence that microglial activation or hippocampal neurogenesis accounted for the differences in behavioural outcome. Volumetric analysis revealed that ZnT3 KO mice have larger corpus callosum and parietal cortex volumes, and that corpus callosum volume was decreased by stress in ZnT3 KO, but not wild type, mice.

Sound Processing: A new role for zinc in the brain

Certain neurons in the auditory cortex release zinc to influence how the brain processes sounds.