Protein kinase M (PKM) 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. PKM is the independent catalytic domain of the atypical PKC isoform and produces long term effects at synapses because it is persistently active, lacking autoinhibition from the regulatory domain of PKC. PKM has been thought of as a proteolytic fragment of PKC. Here we report that brain PKM is a new PKC isoform, synthesized from a PKM mRNA encoding a PKC catalytic domain without a regulatory domain. Multiple -specific antisera show that PKM is expressed in rat forebrain as the major form of in the near absence of full-length PKC. A PKC knockout mouse, in which the regulatory domain was disrupted and catalytic domain spared, still expresses brain PKM, indicating that this form of PKM is not a PKC proteolytic fragment. Furthermore, the distribution of brain PKM does not correlate with PKC mRNA but instead with an alternate RNA transcript thought incapable of producing protein. In vitro translation of this RNA, however, generates PKM of the same molecular weight as that in brain. Metabolic labeling of hippocampal slices shows increased de novo synthesis of PKM in LTP. Because PKM 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. LTP1 is a persistent enhancement of synaptic transmission widely studied as a physiological model of memory (1). LTP can be divided into two phases: induction, which triggers the potentiation, and maintenance, which sustains it over time. Many molecules have been implicated in LTP induction, which is initiated by the activation of N-methyl-D-aspartate (NMDA) receptors and involves several protein kinases (2). In contrast, very little is known about the molecular mechanism of maintenance. Recently, however, a specific, autonomously active form of the atypical PKC isozyme (3, 4), PKM, has been found both necessary and sufficient for maintaining LTP (5-7). Overexpression of PKM also prolongs memory in Drosophila melanogaster, suggesting it is part of an evolutionarily conserved molecular mechanism for memory storage (8).The unique role of PKM in LTP maintenance is due, in part, to its unusual structural and enzymatic properties as an autonomously active kinase. PKM consists of the independent catalytic domain of a PKC isoform (5). PKC isoforms are divided into three classes: conventional, novel, and atypical (reviewed in Refs. 9 -11). Each isoform is a single polypeptide consisting of an N-terminal regulatory domain and a C-terminal catalytic domain linked by a hinge (Fig. 1A, left). The regulatory domain contains binding sites for second messengers and an autoinhibitory pseudosubstrate sequence, which interacts with and blocks the active site of the catalytic domain. Second messengers stimulate PKC by binding to the regulatory domain, translocating th...
The dendritic and axonal morphology of rat subicular neurons was studied in single cells labeled with Neurobiotin. Electrophysiological classification of cells as intrinsic burst firing or regular spiking neurons was correlated with morphologic patterns and cell locations. Every cell had dendritic branches that reached the outer molecular layer, with most cells having branches that reached the hippocampal fissure. All but two pyramidal cells had axon collaterals that entered the deep white matter (alveus). Branching patterns of apical dendrites varied as a function of the cell's soma location along the fissure-alveus axis of the cell layer. The first major dendritic branch point for most cells occurred at the superficial edge of the cell layer giving deep cells long primary apical dendrites and superficial cells short or absent primary apical dendrites. In contrast, basal dendritic arbors were similar across cells regardless of cell position. Apical and basal dendrites of all cells had numerous spines. Superficial and deep cells also differed in axonal collateralization. Deep cells (mostly intrinsically bursting [IB] class) had one or more ascending axon collaterals that typically remained within the region circumscribed by their apical dendrites. Superficial cells (mostly regular spiking [RS] class) tended to have axon collaterals that reached longer distances in the cell layer. Numerous varicosities and axonal extensions were present on axon collaterals in the cell layer and in the apical dendritic region, suggesting intrinsic connectivity. Axonal varicosities and extensions were found on axons that entered presubiculum, entorhinal cortex or CA1, supporting the notion that these were projection cells. Local collaterals were distinctly thinner than collaterals that would leave the subiculum, suggesting little or no myelin on local collaterals and some myelin on efferent fibers. We conclude that both IB and RS classes of subicular principal cells make synaptic contacts in and apical to the cell layer. Based on the patterns of axonal arborization, we suggest that subiculum has at least a crude columnar and laminar architecture, with ascending collaterals of deep cells forming columns and broader axonal arbors of superficial cells serving to distribute activity across multiple columns.
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