Todd Charlton Sacktor

Storage of spatial information by the maintenance mechanism of LTP.

Analogous to learning and memory storage, long-term potentiation (LTP) is divided into induction and maintenance phases. Testing the hypothesis that the mechanism of LTP maintenance stores information requires reversing this mechanism in vivo and finding out whether long-term stored information is lost. This was not previously possible. Recently however, persistent phosphorylation by the atypical protein kinase C isoform, protein kinase Mzeta (PKMz), has been found to maintain late LTP in hippocampal slices. Here we show that a cell-permeable PKMz inhibitor, injected in the rat hippocampus, both reverses LTP maintenance in vivo and produces persistent loss of 1-day-old spatial information. Thus, the mechanism maintaining LTP sustains spatial memory.

Protein kinase Mζ is necessary and sufficient for LTP maintenance

Long-term potentiation (LTP), a persistent synaptic enhancement thought to be a substrate for memory, can be divided into two phases: induction, triggering potentiation, and maintenance, sustaining it over time. Many postsynaptic events are implicated in induction, including N-methyl-D-aspartate receptor (NMDAR) activation, calcium increases and stimulation of several protein kinases; in contrast, the mechanism maintaining LTP is not yet characterized. Here we show the constitutively active form of an atypical protein kinase C (PKC) isozyme, protein kinase M zeta (PKMζ), is necessary and sufficient for LTP maintenance.

How does PKMζ maintain long-term memory?

Most of the molecular mechanisms contributing to long-term memory have been found to consolidate information within a brief time window after learning, but not to maintain information during memory storage. However, with the discovery that synaptic long-term potentiation is maintained by the persistently active protein kinase, protein kinase Mζ (PKMζ), a possible mechanism of memory storage has been identified. Recent research shows how PKMζ might perpetuate information both at synapses and during long-term memory.

Protein Kinase Mζ Synthesis from a Brain mRNA Encoding an Independent Protein Kinase Cζ Catalytic Domain IMPLICATIONS FOR THE MOLECULAR MECHANISM OF MEMORY

Protein kinase Mζ (PKMζ) is a newly described form of PKC that is necessary and sufficient for the maintenance of hippocampal long term potentiation (LTP) and the persistence of memory in Drosophila. PKMζ is the independent catalytic domain of the atypical PKCζ isoform and produces long term effects at synapses because it is persistently active, lacking autoinhibition from the regulatory domain of PKCζ. PKM has been thought of as a proteolytic fragment of PKC. Here we report that brain PKMζ is a new PKC isoform, synthesized from a PKMζ mRNA encoding a PKCζ catalytic domain without a regulatory domain. Multiple ζ-specific antisera show that PKMζ is expressed in rat forebrain as the major form of ζ in the near absence of full-length PKCζ. A PKCζ knockout mouse, in which the regulatory domain was disrupted and catalytic domain spared, still expresses brain PKMζ, indicating that this form of PKM is not a PKCζ proteolytic fragment. Furthermore, the distribution of brain PKMζ does not correlate with PKCζ mRNA but instead with an alternate ζ RNA transcript thought incapable of producing protein. In vitro translation of this RNA, however, generates PKMζ of the same molecular weight as that in brain. Metabolic labeling of hippocampal slices shows increased de novo synthesis of PKMζ in LTP. Because PKMζ is a kinase synthesized in an autonomously active form and is necessary and sufficient for maintaining LTP, it serves as an example of a link coupling gene expression directly to synaptic plasticity.

PKMζ maintains spatial, instrumental, and classically conditioned long-term memories

How long-term memories are stored is a fundamental question in neuroscience. The first molecular mechanism for long-term memory storage in the brain was recently identified as the persistent action of protein kinase Mzeta (PKMζ), an autonomously active atypical protein kinase C (PKC) isoform critical for the maintenance of long-term potentiation (LTP). PKMζ maintains aversively conditioned associations, but what general form of information the kinase encodes in the brain is unknown. We first confirmed the specificity of the action of zeta inhibitory peptide (ZIP) by disrupting long-term memory for active place avoidance with chelerythrine, a second inhibitor of PKMζ activity. We then examined, using ZIP, the effect of PKMζ inhibition in dorsal hippocampus (DH) and basolateral amygdala (BLA) on retention of 1-d-old information acquired in the radial arm maze, water maze, inhibitory avoidance, and contextual and cued fear conditioning paradigms. In the DH, PKMζ inhibition selectively disrupted retention of information for spatial reference, but not spatial working memory in the radial arm maze, and precise, but not coarse spatial information in the water maze. Thus retention of accurate spatial, but not procedural and contextual information required PKMζ activity. Similarly, PKMζ inhibition in the hippocampus did not affect contextual information after fear conditioning. In contrast, PKMζ inhibition in the BLA impaired retention of classical conditioned stimulus–unconditioned stimulus (CS-US) associations for both contextual and auditory fear, as well as instrumentally conditioned inhibitory avoidance. PKMζ inhibition had no effect on postshock freezing, indicating fear expression mediated by the BLA remained intact. Thus, persistent PKMζ activity is a general mechanism for both appetitively and aversively motivated retention of specific, accurate learned information, but is not required for processing contextual, imprecise, or procedural information.

PKMζ maintains memories by regulating GluR2-dependent AMPA receptor trafficking

The maintenance of long-term memory in hippocampus, neocortex and amygdala requires the persistent action of the atypical protein kinase C isoform, protein kinase Mζ (PKMζ). We found that inactivating PKMζ in the amygdala impaired fear memory in rats and that the extent of the impairment was positively correlated with a decrease in postsynaptic GluR2. Blocking the GluR2-dependent removal of postsynaptic AMPA receptors abolished the behavioral impairment caused by PKMζ inhibition and the associated decrease in postsynaptic GluR2 expression, which correlated with performance. Similarly, blocking this pathway for removal of GluR2-containing receptors from postsynaptic sites in amygdala slices prevented the reversal of long-term potentiation caused by inactivating PKMζ. Similar behavioral results were obtained in the hippocampus for unreinforced recognition memory of object location. Together, these findings indicate that PKMζ maintains long-term memory by regulating the trafficking of GluR2-containing AMPA receptors, the postsynaptic expression of which directly predicts memory retention.

PKMζ Maintains Late Long-Term Potentiation by N-Ethylmaleimide-Sensitive Factor/GluR2-Dependent Trafficking of Postsynaptic AMPA Receptors

Although the maintenance mechanism of late long-term potentiation (LTP) is critical for the storage of long-term memory, the expression mechanism of synaptic enhancement during late-LTP is unknown. The autonomously active protein kinase C isoform, protein kinase Mζ (PKMζ), is a core molecule maintaining late-LTP. Here we show that PKMζ maintains late-LTP through persistent N-ethylmaleimide-sensitive factor (NSF)/glutamate receptor subunit 2 (GluR2)-dependent trafficking of AMPA receptors (AMPARs) to the synapse. Intracellular perfusion of PKMζ into CA1 pyramidal cells causes potentiation of postsynaptic AMPAR responses; this synaptic enhancement is mediated through NSF/GluR2 interactions but not vesicle-associated membrane protein-dependent exocytosis. PKMζ may act through NSF to release GluR2-containing receptors from a reserve pool held at extrasynaptic sites by protein interacting with C-kinase 1 (PICK1), because disrupting GluR2/PICK1 interactions mimic and occlude PKMζ-mediated AMPAR potentiation. During LTP maintenance, PKMζ directs AMPAR trafficking, as measured by NSF/GluR2-dependent increases of GluR2/3-containing receptors in synaptosomal fractions from tetanized slices. Blocking this trafficking mechanism reverses established late-LTP and persistent potentiation at synapses that have undergone synaptic tagging and capture. Thus, PKMζ maintains late-LTP by persistently modifying NSF/GluR2-dependent AMPAR trafficking to favor receptor insertion into postsynaptic sites.

Persistent Phosphorylation by Protein Kinase Mζ Maintains Late-Phase Long-Term Potentiation

Protein kinase Mζ (PKMζ), an autonomously active atypical PKC isoform, is both necessary and sufficient for enhanced synaptic transmission during long-term potentiation (LTP) maintenance. LTP, however, evolves through several temporal phases, which may be mediated by distinct molecular mechanisms of potentiation. Here, we determined the specific phase of LTP maintained by PKMζ. Using a selective, cell-permeable ζ-pseudosubstrate inhibitor at concentrations that block potentiation produced by postsynaptic perfusion of PKMζ, we inhibited PKMζ activity at various times after tetanization of Schaffer collateral/commissural-CA1 synapses. Inhibition of PKMζ did not affect baseline AMPA receptor-mediated synaptic transmission or an early phase of LTP. In contrast, the inhibitor reversed established LTP when applied 1, 3, or 5 h after tetanic stimulation. Control nontetanized pathways within the hippocampal slices were unaffected. An inactive scrambled version of the peptide had no effect on LTP. Thus, persistent, increased phosphorylation by PKMζ specifically maintains the late phase of LTP.

Chapter 2 PKMζ, LTP maintenance, and the dynamic molecular biology of memory storage

How memories persist is a fundamental neurobiological question. The most commonly studied physiological model of memory is long-term potentiation (LTP). The molecular mechanisms of LTP can be divided into two phases: induction, triggering the potentiation; and maintenance, sustaining the potentiation over time. Although many molecules participate in induction, very few have been implicated in the mechanism of maintenance. Understanding maintenance, however, is critical for testing the hypothesis that LTP sustains memory storage in the brain. Only a single molecule has been found both necessary and sufficient for maintaining LTP--the brain-specific, atypical PKC isoform, protein kinase Mzeta (PKMzeta). Although full-length PKC isoforms respond to transient second messengers, and are involved in LTP induction, PKMzeta is a second messenger-independent kinase, consisting of the independent catalytic domain of PKCzeta, and is persistently active to sustain LTP maintenance. PKMzeta is produced by a unique PKMzeta mRNA, which is generated by an internal promoter within the PKCzeta gene and transported to the dendrites of neurons. LTP induction increases new PKMzeta synthesis, and the increased level of PKMzeta then enhances synaptic transmission by doubling the number of postsynaptic AMPA receptors (AMPAR) through GluR2 subunit-mediated trafficking of the receptors to the synapse. PKMzeta mediates synaptic potentiation specifically during the late-phase of LTP, as PKMzeta inhibitors can reverse established LTP when applied several hours after tetanization in hippocampal slices or 1 day after tetanization in vivo. These studies set the stage for testing the hypothesis that the mechanism of LTP maintenance sustains memory storage. PKMzeta inhibition in the hippocampus after learning eliminates the retention of spatial memory. Once the PKMzeta inhibitor has been eliminated, the memory is still erased, but new spatial memories can be learned and stored. Similar results are found for conditioned taste aversion when the inhibitor is injected in the insular neocortex. Thus PKMzeta is the first molecule found to be a component of the long-term memory trace.

Protein synthesis-dependent formation of protein kinase Mzeta in long- term potentiation

The maintenance of long-term potentiation (LTP) in the CA1 region of the hippocampus has been reported to require both a persistent increase in phosphorylation and the synthesis of new proteins. The increased activity of protein kinase C (PKC) during the maintenance phase of LTP may result from the formation of PKMzeta, the constitutively active fragment of a specific PKC isozyme. To define the relationship among PKMzeta, long-term EPSP responses, and the requirement for new protein synthesis, we examined the regulation of PKMzeta after sub-threshold stimulation that produced short-term potentiation (STP) and after suprathreshold stimulation by single and multiple tetanic trains that produced LTP. We found that, although no persistent increase in PKMzeta followed STP, the degree of long-term EPSP potentiation was linearly correlated with the increase of PKMzeta. The increase was first observed 10 min after a tetanus that induced LTP and lasted for at least 2 hr, in parallel with the persistence of EPSP enhancement. Both the maintenance of LTP and the long-term increase in PKMzeta++ were blocked by the protein synthesis inhibitors anisomycin and cycloheximide. These results suggest that PKMzeta is a component of a protein synthesis-dependent mechanism for persistent phosphorylation in LTP.