A lasting change in protein phosphorylation associated with septal kindling

Variations of rat brain calmodulin content in dark and light phases: effect of pentylenetetrazol-induced kindling

Calmodulin (CaM) through activation of CaM-kinase II may be involved in the molecular mechanisms underlying the epileptogenic processes. Some evidence suggests that kindling responses change across the day-night cycle. In order to test if kindling stimulation modifies CaM content, we measured CaM concentrations in amygdala, hippocampus and hypothalamus obtained from control and kindled rats during light and darkness. Male Wistar rats (250-300 g), were injected i.p. with Pentylenetetrazol (PTZ) (35 mg/kg/24 h). Once chemical kindling was established, rats were sacrificed by decapitation at 10:30 a.m. and 01:30 a.m. The brains were obtained, and the amygdala, hippocampus and hypothalamus dissected. CaM content was measured in the cytosol and membrane fractions by radioimmunoassay. We found a significant increase in CaM content in cytosol and membrane fractions of both control and kindled rats during the dark phase. No significant differences in CaM concentrations were observed between control and experimental rats, whether during the light or the dark phase. The data suggest a well defined photoperiodic variation in CaM concentrations in limbic structures, despite the neuronal excitability produced by kindling. In addition, the observed CaM increases during the dark time may be related to a protective mechanism against enhanced sensitivity to seizures observed during the night.

Increased levels of mRNA for beta- but not alpha-subunit of calmodulin kinase II following kindled seizures

We studied levels of mRNA for the alpha- and beta-subunits of calmodulin (CaM) kinase II using the amygdaloid kindling model of epilepsy. There were significant increases in mRNA for the beta-subunit of CaM kinase II in the hippocampus 4-24 h after stage 5-kindled seizures. Moreover, this mRNA was significantly increased by 20.0-26.5% in the bilateral dentate gyrus 8 to 24 h after kindled seizures. The beta-subunit mRNA was also significantly increased by 13.5-19.0% in the CA3 on the side ipsilateral to the stimulation, 4 to 8 h after kindled seizures. mRNA for the alpha-subunit of CaM kinase II was not significantly changed in the regions examined for up to 24 h after the kindled seizures. These results suggest that CaM kinase II mediates the molecular processes that follow kindled seizures. It is possible that increases in CaM kinase II-dependent protein phosphorylation are associated with the plastic changes in kindling.

Amygdala kindling activates the phosphorylation of Ca2+/calmodulin-dependent protein kinase II in rat hippocampus

Wistar rats were kindled by electrical stimulations in the amygdala and autophosphorylation of Ca2+/calmodulin-dependent protein kinase II (CaMKII) at Thr-286 (alpha-subunit) was investigated immunocytochemically. In kindled rats strong immunoreactivity was detected in the somas and apical dendrites of pyramidal cells in CA1 area of the hippocampus. Immunoreactivity was also positive in the somas of CA2 to CA4 pyramidal cells, dentate granule cells, and some hilar cells. Only weak reaction was detected in the somas of these neurons in non-kindled rats. Data suggest the role in the development of kindling of CaMKII which is activated through its autophosphorylation.

Regulation of type-II calmodulin kinase: functional implications

Calmodulin-kinase II (CaM kinase) is a calcium/calmodulin-dependent protein kinase which is highly enriched in the nervous system and mediates many of calcium's actions. Regulation of CaM kinase activity plays an important role in modulating synaptic transmission, synaptic plasticity and in neuropathology. Primary regulation of CaM kinase occurs via changes in intracellular calcium concentrations. Increased calcium stimulates protein kinase activity and induces autophosphorylation. Autophosphorylation of CaM kinase at specific sites results in altered activity and responsiveness to subsequent changes in calcium concentrations. Intracellular translocation of CaM kinase also appears to result from autophosphorylation. These mechanisms of regulation play an important role in synaptic plasticity (e.g., Aplysia ganglia), status epilepticus and cerebral ischemia. Long-lasting alterations in the expression of CaM kinase have been demonstrated in the kindling model of epilepsy and in monocular deprivation and therefore modulation of gene expression, in addition to autophosphorylation and translocation, appears to be another important mechanism of regulating CaM kinase activity.

Ca2+/calmodulin-dependent protein phosphorylation is not altered by amygdaloid kindling

Kindling is a process in which episodic electrical stimulation permanently increases seizure susceptibility. One mechanism to account for a change in seizure susceptibility is some alteration in signal transduction, possibly at the level of second messenger systems. In this study, male Long-Evans rats were kindled in the amygdala, and Ca2+/calmodulin (Ca2+/CaM)-dependent protein phosphorylation was assessed at the site of the primary kindled focus using one- and two-dimensional gel electrophoresis. In vitro phosphorylation of membrane and cytosol fractions in the presence of absence of Ca2+/CaM did not differentiate kindled from nonkindled amygdaloid tissue. These results suggest that changes in Ca2+/CaM-dependent phosphorylation are not related to the mechanism(s) underlying the establishment of an amygdaloid kindled focus.

Alterations of GABA metabolism and seizure susceptibility in the substantia nigra of the kindled rat acclimating to changes in osmotic state

Seizure susceptibility and GABA metabolism were altered in the substantia nigra [SN] of adult male Sprague Dawley rats when these animals were acclimating to an altered plasma osmolality. Changes in GABA metabolism were measured in vivo in SN of the freely moving rat. Suitable precautions were taken to avoid any post-mortem flux of glutamate to GABA and to correct for the underestimation of GABA build up in SN due to the finite diffusion rate of gamma-vinyl GABA [GVG] after stereotaxic injection of small amounts into one side of the brain. Control experiments provided evidence that changes in osmolality, within a normal physiological range, did not affect significantly gamma-aminobutyric acid transaminase [GABA-T]. Also kindling via the medial septum [MS], in the absence of electrical stimulation did not alter GABA metabolism in SN, thus providing a stable baseline for studies of osmotic effects. Hyperosmolality was associated with a rise in seizure thresholds, with a marked reduction of the rate of GABA synthesis in SN, and with a substantial increase in turnover time of the GABA pool. Hypoosmolality, of a degree known to be associated with mild cerebral edema and swelling localized to astrocytes, markedly reduced seizure threshold, and reduced GABA pool size in SN, but did not alter the rate of GABA synthesis significantly. These results demonstrate by new and independent means the relationship between GABA metabolism in the SN and seizure susceptibility in vivo.

Effect of septal kindling on glutamate binding and calcium/calmodulin-dependent phosphorylation in a postsynaptic density fraction isolated from rat cerebral cortex

Postsynaptic density (PSD) fractions were isolated from the cerebral cortices of control and kindled rats and assayed for glutamate and gamma-aminobutyric acid-binding capacities and for the Ca2+/calmodulin-dependent protein kinase. Glutamate binding was found to be increased by approximately 50% in the PSDs isolated from kindled rats as compared to controls; this increase was almost completely from an increase in Bmax; Kd decreased only slightly. Studies with inhibitors indicate that the receptors involved were of the N-methyl-D-aspartate and quisqualate types. PSDs isolated from control and kindled rats did not differ in gamma-aminobutyric acid or flunitrazepam binding. The in vitro autophosphorylation of the Ca2+/calmodulin-dependent protein kinase was depressed by 45-76% in PSDs isolated from kindled rats as compared to controls, with little change in amount of the kinase. Therefore, we infer that (i) the kindled state is associated with an increase in glutamate activation of postsynaptic sites, allowing Ca2+ to enter dendritic spines, (ii) a change has occurred in activity of the protein kinase, which is the major cerebral cortex PSD protein, and (iii) perhaps major alterations in the PSD are a concomitant to the long-lasting nature of the kindled state.

Localization of retinal calmodulin kinase

The localization of calmodulin kinase II (CaM kinase) was studied in the retina by light and electron microscopic immunocytochemistry, and by enzymatic and immunoblot assay of cellular and subcellular tissue fractions. By light microscopy, both mono- and polyclonal antibodies revealed CaM kinase-like immunoreactivity in the inner and outer plexiform regions (synaptic layers), retinal pigment epithelium (RPE), and ganglion cells. The inner nuclear layer and photoreceptor outer segments stained much less intensely, and the outer nuclear layer did not stain. Electron microscopy confirmed the high concentration of immunoreactive protein in RPE and minimal outer segment staining. In addition, photoreceptor inner segments also contained CaM kinase-like immunoreactivity. Calcium and calmodulin stimulated phosphate incorporation into proteins of retinal cytosol and of isolated and cultured RPE. Calcium- and calmodulin-dependent kinase activity was present to a lesser degree in crude nuclei and synaptic membranes and was absent in isolated rod outer segments. Immunoblot analyses were consistent with enzymatic assays and immunocytochemistry. These data suggest that retinal CaM kinase is ideally located to play an important role in synaptic transmission and modulation of visual processes. Furthermore, its presence in RPE implies that CaM kinase may have a more ubiquitous role in regulating cellular processes than was previously recognized.

4-Aminopyridine affects synaptosomal protein phosphorylation in rat hippocampal slices

Rat brain hippocampal slices were incubated with or without the convulsant 4-aminopyridine (4-AP). From these slices a crude mitochondrial/synaptosomal membrane fraction was prepared and analyzed for endogenous protein phosphorylation. 4-AP (10(-5) M) stimulated the phosphorylation of a 50 kDa protein by 86%. The phosphorylation of this 50 kDa protein is Ca2+/calmodulin-dependent and we suggest that this protein is the lower molecular weight subunit of Ca2+/calmodulin-dependent protein kinase II (CaMK II).

Decreased phosphorylation of synaptic glycoproteins following hippocampal kindling

Rats with chronic electrode implants to region CA3 of the hippocampus were rapidly kindled by stimulation with a 10 s, 10 Hz train of biphasic square waves presented every 5 min, until generalized seizures developed (60-70 stimulations). The hippocampi were isolated from the brains of control animals (implanted but not stimulated), and experimental animals which had developed generalized seizures. Synaptic membranes (SM) were prepared. SM were incubated with [gamma-32P]ATP and the incorporation of 32P into proteins and glycoproteins isolated by affinity chromatography on concanavalin-A-agarose was investigated. There was no difference in the phosphorylation pattern of total SM proteins between groups. In contrast, the phosphorylation of a glycoprotein with an apparent molecular weight of 180,000 was decreased 20-40% in kindled animals. This result was replicated in three independent experiments. The results suggest that the phosphorylation of glycoprotein 180 may be related to neuroplastic events.

Effect of altered blood plasma osmolalities on regional brain amino acid concentrations and focal seizure susceptibility in the rat

Blood plasma hypo- or hyperosmolality alters significantly the concentration of some amino acids in brain tissues of the medial septum and hippocampus of adult Sprague-Dawley rats. With some notable exceptions, brain amino acid concentrations decreased under hypoosmotic conditions and increased under hyperosmotic conditions. Osmotic changes and brain amino acid changes appear to be related to each other in an almost linear fashion. A comparison of rats and toads indicates that the patterns of changes in brain amino acid concentrations in response to a hypoosmotic plasma osmolality were almost identical for both species. Changes achievable under hyperosmotic conditions were considerably greater in toads. When rats with kindled epileptogenic foci were made hypoosmotic by water-loading, seizure thresholds decreased dramatically. Our data suggest a possible relationship between the hypoosmotically induced biochemical changes in brain tissues (especially some amino acid neurotransmitters and neurotransmitter precursors) and the hypoosmotically induced increase in seizure susceptibility.

Kindling induces a long-lasting change in the activity of a hippocampal membrane calmodulin-dependent protein kinase system

Septal kindling has been shown to produce a long-lasting decrease in endogenous calcium/calmodulin-dependent phosphorylation of hippocampal synaptic plasma membrane proteins, including two major bands of approximately 50,000 and 60,000 Daltons. These two proteins differ from the B-50 protein and tubulin, as evidenced by differences in migration in SDS-PAGE gels and by lack of cross-immunoreactivity with specific antibodies. Identity of these two proteins with the rho and sigma subunits of purified calmodulin-dependent kinase (CaM Kinase II) is suggested by similar migration in SDS-PAGE and two-dimensional gels, by similar calmodulin binding in two-dimensional gels, and similar 125I-peptide mapping of the 50,000 Dalton protein. These results demonstrate that septal kindling is associated with changes in the activity of a major Ca2+/calmodulin-dependent kinase system in hippocampal synaptic plasma membrane. This long-lasting modulation of kinase activity may provide a molecular insight into some aspects of neuronal plasticity.

Cyclic nucleotide response of the hippocampal formation to septal stimulation in naive and kindled rats

Rats were kindled through nonmagnetic electrodes stereotaxically implanted into the medial septum. Concentrations of cyclic AMP and cyclic GMP were measured by radioimmunoassay in seven brain regions after microwave fixation during the development and expression of kindled seizures. Hippocampal concentrations were similar to untreated controls (cyclic GMP level in the left and right hippocampus, 0.66 +/- 0.04 and 0.68 +/- 0.07 pmol/mg of protein, respectively; cyclic AMP, 9.4 +/- 0.9 and 9.6 +/- 0.8 pmol/mg of protein, respectively), in kindled animals that were not stimulated, and in naive animals in response to septal stimulation, in spite of the presence in the latter group of bilateral hippocampal afterdischarges. Animals that failed to develop kindling and kindled animals that failed to have a seizure in response to stimulation also showed no change in cyclic nucleotide concentrations in any brain region. Kindled animals that developed a seizure following stimulation showed significant elevations in levels of both cyclic GMP and cyclic AMP in hippocampus and in several other brain regions. A single naive animal that had a seizure in response to its first stimulation also appeared to have elevated concentrations of both cyclic nucleotides in hippocampus. These data suggest that the elevation in levels of both cyclic GMP and cyclic AMP during kindled seizures is associated with seizure development rather than with the generation of afterdischarges or with the kindling engram.

Cholinergic kindling: what has it taught us about epilepsy?

We reviewed recent evidence that chemical kindling of epileptic seizures can be induced by injection into the amygdala of multiple cholinergic muscarinic agonists, and blocked by multiple muscarinic antagonists. The stereospecific induction of kindling by (+) but not by (-) acetyl-beta-methylcholine shows that some types of repeated synaptic activation can produce epilepsy, in the absence of specific brain damage. The failure of bicuculline (but not of carbachol) to produce kindling with amygdaloid injections, and its ability to produce a limited seizure spread in neocortex, suggest that repetitive seizure activity alone is not sufficient to produce kindling. A review of some recent neurochemical changes in the synaptic apparatus associated with some types of kindling suggests potential areas for future investigation, but no cause-and-effect relationship between neurochemical and behavioral changes can be inferred so far.

The postsynaptic density: a possible role in long-lasting effects in the central nervous system

A theory is proposed that biochemical changes at the synapse that occur as a result of stimulation of specific neuronal circuits can lead to long-term changes only if alterations occur in synaptic structures in these circuits. The main synaptic structure that is thought to undergo this alteration is the postsynaptic density (PSD). There are many reports in the literature of overall structural changes at the synapse, including the PSD, resulting from various neuronal stimuli. These structural changes are here envisaged to include those of concentration and conformation of PSD proteins, changes that could alter the neural physiology of dendritic spines and even that of the presynaptic terminal.

Transfer between chemical and electrical kindling in the septal-hippocampal system

We re-investigated the interaction between chemical and electrical kindling in two anatomical locations: the amygdaloid region and the septal-hippocampal complex. Amygdaloid animals were implanted with a chemitrode into the left basolateral amygdala, which could then be stimulated electrically (400 microA, 1 s, 60 Hz, AC) or chemically by injection of carbachol (1 microliter, 2.7 nmol, sterile, isotonic). Septal-hippocampal animals were implanted with an electrode high in the medial septum, a cannula in the dorsal hippocampus. In both groups, half the animals were kindled electrically, and after one week of rest chemical kindling was begun. The other half were kindled chemically first, then electrically. The result differed with the anatomical location. With amygdaloid implants, no significant transfer was observed. In the septal-hippocampal group, by contrast, significant interactions were observed in both directions. These results suggest that chemical and electrical kindling involves similar mechanisms, and that the extent to which transfer occurs reflects the degree to which they share a common chemical anatomy.

Kindling alters the calcium/calmodulin-dependent phosphorylation of synaptic plasma membrane proteins in rat hippocampus

Septal kindling was associated with an inhibition of the post hoc phosphorylation of several synaptic plasma membrane proteins of rat hippocampus. In control rats, the 32P incorporation into proteins of molecular weights 50,000, 58,000, and 60,000 was markedly stimulated by combined calcium/calmodulin, whereas in kindled animals, the response to combined calcium/calmodulin was reduced. Calcium alone, cAMP, or cGMP modulated 32P incorporation into several synaptic plasma membrane proteins but did not differentiate control from kindled tissues. Both control and kindled rats showed nonspecific inhibition of calcium/calmodulin-stimulated phosphorylation in the post hoc assay by corticotropin and by [Leu]enkephalin. The differences between control and kindled animals were most striking in hippocampus and in the amygdaloid-entorhinal area; less pronounced in cortex, basal ganglia, and brain stem; and not significant in cerebellum, a region where kindling cannot be elicited. An 8-wk period of rest after kindling did not reduce these changes, suggesting that they may be a persistent as the kindling behavior itself.

Kindling: an animal model of complex partial epilepsy

Kindling is an animal model of complex partial epilepsy induced by focal electrical stimulation of the brain. This paper describes the phenomenon and underscores the limited nature of current insights into its basic mechanisms. Anatomical delineation of the underlying neural network is a necessary first step for elucidating the basic cellular and molecular mechanisms. Recent evidence suggests that the substantia nigra may be a crucial component of the network underlying limbic kindled seizures and possibly kindling itself.