Unraveling the role of zinc in memory.

D ietary zinc deficiency has been associated with memory impairment but the mechanisms underlying this effect remain unclear. The divalent cation zinc is one of the most abundant trace elements in the body and plays myriad functional roles (1). Although the vast majority of zinc is tightly bound to proteins, a pool of zinc in the mammalian forebrain is selectively stored in and released from glutamatergic neurons. This chelatable zinc is sequestered in synaptic vesicles and coreleased with glutamate during neuronal activity. Synaptically released zinc has the potential to interact with and modulate many different synaptic targets, including glutamate receptors and voltage-gated channels (2). Zinc can also modulate synaptic plasticity. The ability of zinc to modulate both ion channels and synaptic plasticity predicts that it plays a key role in learning and memory. This prediction was previously tested using mice in which the zinc transporter-3 (ZnT3) had been genetically deleted. ZnT3 is essential for loading zinc into synaptic vesicles (3). Targeted deletion of this transporter ablates vesicular zinc uptake and synaptic release of zinc and causes zinc in the forebrain to fall to undetectable levels (4). However, despite lacking chelatable zinc, ZnT3 KO mice did not exhibit impairments in spatial learning, memory, or sensorimotor functions (5). These findings suggested that vesicular zinc (and hence, ZnT3) was not essential for cognitive function. However, recent studies have forced a rethinking of the role of zinc in cognition. In particular, detailed examination has now revealed that ZnT3 KO mice exhibit impaired fear memory (6) as well as accelerated aging related decline of spatial memory (7). Despite these advances, the functional role of synaptic zinc in learning and memory remains largely a mystery. In PNAS, Sindreu et al. (8) provide a compelling and thorough study demonstrating an essential role for ZnT3 and thus vesicular zinc in memory formation in mice. Furthermore, they show that zinc and ZnT3 regulate memory formation by acting through the Erk1/2-dependent signaling pathway. In examining the role of zinc in memory, Sindreu et al. (8) focus on the Erk signaling pathway of the MAPK family because of its well established role in the regulation of synaptic plasticity, learning, and memory (9). Furthermore, zinc can activate Erk in neurons (10), raising the possibility that zinc could influence learning and memory by acting on the Erk signaling pathway. However, earlier studies examining the interaction between zinc and Erk had used exogenously applied zinc, making it unclear whether synaptically released zinc acted as an endogenous regulator of Erk. Therefore, in the first set of experiments, Sindreu et al. (8) used ZnT3 KO mice to explore the role of endogenous zinc in Erk signaling. They found that the phosphorylated form of pErk (pErk) was selectively reduced in synaptic membranes from hippocampal mossy fibers (MFs) of ZnT3 KO mice. These studies were performed in the MFs because this pathway expresses high levels of zinc and is enriched in pErk. Their findings suggest that vesicular zinc is required to maintain normal levels of Erk activation. However, the possibility that developmental compensation in the ZnT3 KO mice was responsible for the loss of pErk could not be excluded. To address this limitation, Sindreu et al. (8) demonstrated that ZnT3 KO mice exhibit normal expression of Erk protein, normal development of MFs, and normal density of MF boutons. The authors then show that acute injection of the zinc chelators diethyldithiocarbamate or N,N,N′,N′tetrakis(2-pyridylmethyl)ethylenediamine (TPEN) decreased the levels of MF pErk in WT mice, reproducing the pErk phenotype of ZnT3 KO mice. Together, these studies elegantly show that endogenous zinc (and ZnT3) is necessary for Erk activation. Is extracellular release of zinc necessary for modulation of pErk? A requirement for extracellular release of vesicular zinc would tie pErk activation to neuronal activity of the MFs. Sindreu et al. (8) examine this possibility by assaying MF pErk after toxin-induced blockade of vesicular exocytosis in vivo. They hypothesized that, if released zinc were necessary for pErk activation, blockade of vesicular exocytosis at MF synapses should reduce MF pErk. This is precisely what they observed. Furthermore, in ZnT3 KO mice in which zinc exocytosis is ablated, toxin block of exocytosis had little additional effect on MF pErk. These experiments demonstrate a critical role for zinc exocytosis and ZnT3 in the regulation of MF pErk. What is the mechanism through which pErk is reduced in ZnT3 KOmice? Sindreu et al. (8) show in ZnT3 KO mice that activation of a host of other signaling molecules implicated in synaptic plasticity is unaffected, indicating that Erk signaling is special in its sensitivity to ZnT3. Importantly, they found that phosphorylation of the MAPK kinase MEK1/2 was intact in ZnT3 KO mice, despite a reduction of pErk in the same animals. As MEK1/2 is the immediate upstream kinase for Erk, this finding precludes changes upstream of Erk in ZnT3 KO mice. Furthermore, in an in vitro kinase assay, zinc failed to stimulate Erk2 activity. Together, these findings point to an indirect action of zinc on Erk. One possible indirect mechanism through which zinc could enhance pErk is by inhibiting its dephosphorylation by protein tyrosine phosphatases (PTPs). PTPs terminate Erk activity by dephosphorylation, and it is well established that zinc inhibits the activity of these PTPs (11). Sindreu et al. (8) report that Fig. 1. ZnT3 and zinc in MF synaptic function. Synaptic vesicles in MF terminals contain both glutamate and zinc that is released upon MF activity. Glutamate acts on postsynaptic receptors on CA3 pyramidal cells. Zinc can modulate activity at some glutamate receptors and is recycled into the presynaptic terminal by reuptake transporters of the SLC39 family. Zinc is repackaged into synaptic vesicles through the action of ZnT3. Cytoplasmic zinc inhibits PTP, thereby preventing dephosphorylation of pErk and prolonging pErk activity. Among its actions, pErk phosphorylates synapsin I, thereby regulating synaptic plasticity. The absence of ZnT3 leads to a loss of zinc from the terminal, removal of zinc inhibition of tyrosine phosphatase, and a reduction of Erk signaling.