Calmodulin-dependent Kinase II Research Articles

Gastrodin inhibits glutamate-induced apoptosis of PC12 cells via inhibition of CaMKII/ASK-1/p38 MAPK/p53 signaling cascade.

Previous research demonstrated that glutamate induces neuronal injury partially by increasing intracellular Ca(2+) concentrations ([Ca(2+)]i), and inducing oxidative stress, leading to a neurodegenerative disorder. However, the mechanism of glutamate-induced injury remains elusive. Gastrodin, a major active component of the traditional herbal agent Gastrodia elata (GE) Blume, has been recognized as a potential neuroprotective drug. In the current study, a classical injury model based on glutamate-induced cell death of rat pheochromocytoma (PC12) cells was used to investigate the neuroprotective effect of gastrodin, and its potential mechanisms involved. In this paper, the presence of gastrodin inhibits glutamate-induced oxidative stress as measured by the formation of reactive oxygen species (ROS), the level of malondialdehyde (MDA), mitochondrial membrane potential (MMP), and superoxide dismutase (SOD); gastrodin also prevents glutamate-induced [Ca(2+)]i influx, blocks the activation of the calmodulin-dependent kinase II (CaMKII) and the apoptosis signaling-regulating kinase-1 (ASK-1), inhibits phosphorylation of p38 mitogen-activated kinase (MAPK). Additionally, gastrodin blocked the expression of p53 phosphorylation, caspase-3 and cytochrome C, reduced bax/bcl-2 ratio induced by glutamate in PC12 cells. All these findings indicate that gastrodin protects PC12 cells from the apoptosis induced by glutamate through a new mechanism of the CaMKII/ASK-1/p38 MAPK/p53-signaling pathway.

Dense Core Vesicle Release: Controlling the Where as Well as the When

Ca(2+)/calmodulin-dependent Kinase II (CaMKII) is a calcium-regulated serine threonine kinase whose functions include regulation of synaptic activity (Coultrap and Bayer 2012). A postsynaptic role for CaMKII in triggering long-lasting changes in synaptic activity at some synapses has been established, although the relevant downstream targets remain to be defined (Nicoll and Roche 2013). A presynaptic role for CaMKII in regulating synaptic activity is less clear with evidence for CaMKII either increasing or decreasing release of neurotransmitter from synaptic vesicles (SVs) (Wang 2008). In this issue Hoover et al. (2014) further expand upon the role of CaMKII in presynaptic cells by demonstrating a role in regulating another form of neuronal signaling, that of dense core vesicles (DCVs), whose contents can include neuropeptides and insulin-related peptides, as well as other neuromodulators such as serotonin and dopamine (Michael et al. 2006). Intriguingly, Hoover et al. (2014) demonstrate that active CaMKII is required cell autonomously to prevent premature release of DCVs after they bud from the Golgi in the soma and before they are trafficked to their release sites in the axon. This role of CaMKII requires it to have kinase activity as well as an activating calcium signal released from internal ER stores via the ryanodine receptor. Not only does this represent a novel function for CaMKII but also it offers new insights into how DCVs are regulated. Compared to SVs we know much less about how DCVs are trafficked, docked, and primed for release. This is despite the fact that neuropeptides are major regulators of human brain function, including mood, anxiety, and social interactions (Garrison et al. 2012; Kormos and Gaszner 2013; Walker and Mcglone 2013). This is supported by studies showing mutations in genes for DCV regulators or cargoes are associated with human mental disorders (Sadakata and Furuichi 2009; Alldredge 2010; Quinn 2013; Quinn et al. 2013). We lack even a basic understanding of DCV function, such as, are there defined DCV docking sites and, if so, how are DCVs delivered to these release sites? These results from Hoover et al. (2014) promise to be a starting point in answering some of these questions.

Homer is concentrated at the postsynaptic density and does not redistribute after acute synaptic stimulation

Homer is a postsynaptic density (PSD) scaffold protein that is involved in synaptic plasticity, calcium signaling and neurological disorders. Here, we use pre-embedding immunogold electron microscopy to illustrate the differential localization of three Homer gene products (Homer 1, 2, and 3) in different regions of the mouse brain. In cross-sectioned PSDs, Homer occupies a layer ∼30–100nm from the postsynaptic membrane lying just beyond the dense material that defines the PSD core (∼30-nm-thick). Homer is evenly distributed within the PSD area along the lateral axis, but not at the peri-PSD locations within 60nm from the edge of the PSD, where type I-metabotropic glutamate receptors (mGluR1 and 5) are concentrated. This distribution of Homer matches that of Shank, another major PSD scaffold protein, but differs from those of other two major binding partners of Homer, type I mGluR and IP3 receptors.Many PSD proteins rapidly redistribute upon acute (2min) stimulation. To determine whether Homer distribution is affected by acute stimulation, we examined its distribution in dissociated hippocampal cultures under different conditions. Both the pattern and density of label for Homer 1, the isoform that is ubiquitous in hippocampus, remained unchanged under high K+ depolarization (90mM for 2–5min), N-methyl-d-asparic acid (NMDA) treatment (50μM for 2min), and calcium-free conditions (EGTA at 1mM for 2min). In contrast, Shank and calcium/calmodulin-dependent kinase II (CaMKII) accumulate at the PSD upon NMDA treatment, and CaMKII is excluded from the PSD complex under low calcium conditions.

Activation-triggered subunit exchange between CaMKII holoenzymes facilitates the spread of kinase activity

The activation of the dodecameric Ca(2+)/calmodulin dependent kinase II (CaMKII) holoenzyme is critical for memory formation. We now report that CaMKII has a remarkable property, which is that activation of the holoenzyme triggers the exchange of subunits between holoenzymes, including unactivated ones, enabling the calcium-independent phosphorylation of new subunits. We show, using a single-molecule TIRF microscopy technique, that the exchange process is triggered by the activation of CaMKII, and that exchange is modulated by phosphorylation of two residues in the calmodulin-binding segment, Thr 305 and Thr 306. Based on these results, and on the analysis of molecular dynamics simulations, we suggest that the phosphorylated regulatory segment of CaMKII interacts with the central hub of the holoenzyme and weakens its integrity, thereby promoting exchange. Our results have implications for an earlier idea that subunit exchange in CaMKII may have relevance for information storage resulting from brief coincident stimuli during neuronal signaling. DOI: http://dx.doi.org/10.7554/eLife.01610.001.

Role of inhibitory autophosphorylation of calcium/calmodulin-dependent kinase II (αCAMKII) in persistent (>24 h) hippocampal LTP and in LTD facilitated by novel object-place learning and recognition in mice

Experience-dependent synaptic plasticity is widely expressed in the mammalian brain and is believed to underlie memory formation. Persistent forms of synaptic plasticity in the hippocampus, such as long-term potentiation (LTP) and long-term depression (LTD) are particularly of interest, as evidence is accumulating that they are expressed as a consequence of, or at the very least in association with, hippocampus-dependent novel learning events. Learning-facilitated plasticity describes the property of hippocampal synapses to express persistent synaptic plasticity when novel spatial learning is combined with afferent stimulation that is subthreshold for induction of changes in synaptic strength. In mice it occurs following novel object recognition and novel object-place recognition. Calmodulin-dependent kinase II (CAMKII) is strongly expressed in synapses and has been shown to be required for hippocampal LTP in vitro and for spatial learning in the water maze. Here, we show that in mice that undergo persistent inhibitory autophosphorylation of αCAMKII, object-place learning is intact. Furthermore, these animals demonstrate a higher threshold for induction of persistent (>24h) hippocampal LTP in the hippocampal CA1 region during unrestrained behaviour. The transgenic mice also express short-term depression in response to afferent stimulation frequencies that are ineffective in controls. Furthermore, they express stronger LTD in response to novel learning of spatial configurations compared to controls. These findings support that modulation of αCAMKII activity via autophosphorylation at the Thr305/306 site comprises a key mechanism for the maintenance of synaptic plasticity within a dynamic range. They also indicate that a functional differentiation occurs in the way spatial information is encoded: whereas LTP is likely to be critically involved in the encoding of space per se, LTD appears to play a special role in the encoding of the content or features of space.

PKA and CaMKII mediate PI3K activation in bovine sperm by inhibition of the PKC/PP1 cascade

To enable fertilization, spermatozoa must undergo several biochemical processes in the female reproductive tract, collectively called capacitation. These processes involve protein kinase A (PKA)-dependent protein tyrosine phosphorylation including phosphatidylinositol-3-kinase (PI3K). It is not known how PKA, a serine/threonine (S/T) kinase, mediates tyrosine phosphorylation of proteins. We recently showed that inhibition of S/T phosphatase 1 (PP1) causes a significant increase in phospho-PI3K. In this study, we propose a mechanism by which PKA and PP1 mediate an increase in PI3K tyrosine phosphorylation and implicate calmodulin-dependent kinase II (CaMKII) in this process. Inhibition of sperm PP1 or PKC, stimulated CaMKII phosphorylation/activation, and inhibition of PKC enhanced PP1 phosphorylation/inactivation. Inhibition of CaMKII, using KN-93, caused significant reduction in phospho-PP1, indicating its activation. Moreover, KN-93 prevented the dephosphorylation/inactivation of PKC. We therefore suggest that CaMKII inhibits PKC, leading to PP1 inhibition and the reciprocal auto-activation of CaMKII. Thus, CaMKII can regulate its own activation by inhibiting the PKC/PP1 cascade. Inhibition of Src family kinases (SFK) caused significant inhibition of CaMKII and PP1 phosphorylation, suggesting that SFK activity results in PP1 inhibition and CaMKII activation. Activation of sperm PKA by 8Br-cAMP revealed an increase in phospho-CaMKII, which was inhibited by PKA inhibitor. Tyrosine phosphorylation of PI3K was stimulated by 8Br-cAMP and by PKC or PP1 inhibition and was abrogated by CaMKII inhibition. Furthermore, phosphorylation/activation of the tyrosine kinase Pyk2 was enhanced by PP1 inhibition, and this activation is blocked by CaMKII inhibition. Thus, PKA activates Src, which inhibits PP1, leading to CaMKII and Pyk2 activation, resulting in PI3K tyrosine phosphorylation/activation.

Ankyrin-B Reduction Enhances Calcium Sparks via CamkII

Ankyrin-B (AnkB) is a scaffolding protein that tethers to the cytoskeleton and targets select membrane proteins, including the Na+/Ca2+ exchanger and Na+/K+-ATPase, key regulators of cardiac contractility and arrhythmogenesis. Humans with loss-of-function mutations in AnkB and mice heterozygous for a null mutation in AnkB (AnkB+/- mice) display a complex cardiac phenotype that includes ventricular arrhythmias and sudden cardiac death. We have previously shown that AnkB reduction alters cardiac Na+ and Ca2+ transport and enhances the coupled ryanodine receptor (RyR) openings, leading to more frequent Ca2+ sparks and waves although the total sarcoplasmic reticulum (SR) Ca2+ leak is unaffected. Here we tested the hypothesis that the bias toward more coordinated RyRs openings in AnkB+/- myocytes is due in part to enhanced RyR activation by the Ca2+/calmodulin-dependent kinase II (CaMKII). We found that spontaneous Ca2+ spark frequency (CaSpF) increases with rising the pre-conditioning frequency in intact myocytes from Ank+/- mice (by 50% from 0.5 to 2 Hz), although the amount of Ca2+ in the SR was practically unnchanged. This effect was significantly smaller in WT myocytes (only 5% CaSpF increase from 0.5 to 2 Hz). CaMKII inhibition with KN-93 reduced CaSpF in myocytes from Ank+/- mice (by 24%, 39% and 26% at 0.5, 1 and 2 Hz, respectively) and greatly attenuated the dependence of CaSpF on the pre-conditioning frequency. In contrast, KN-93 had no significant effect on CaSpF in WT myocytes. In fact, with KN-93 CaSpF was higher in WT vs. Ank+/- myocytes at all pre-conditioning frequencies. These data suggest that RyR activation by CaMKII plays an important role in the enhanced spark-mediated SR Ca2+ leak and may in part explain the higher propensity for triggered arrhythmias in AnkB deficiency.

Stretch-Dependent Regulation of Calcium Signaling in Heart - Who are the Key Players?

An acute physiologic stretch of a cardiomyocyte triggers an increase in the production of reactive oxygen species (ROS) by the membrane-localized enzyme complex NADPH oxidase 2 (Nox2, X-ROS signaling). The ROS act locally to sensitize nearby Ca2+ release channels in the sarcoplasmic reticulum, the ryanodine receptors type 2 (RyR2), resulting in a brief increase in the frequency of calcium sparks. During sustained, cyclical stretch the rate of ROS production remains elevated and is graded by both the degree and frequency of cyclic stretch. The elevated ROS production results in a sustained increase of calcium spark rate, thus coupling the mechanical load on the heart cell to its calcium signaling sensitivity. However, an increase in RyR2 sensitivity alone is insufficient to explain a persistent increase in Ca2+ sparks, implicating additional stretch-dependent players in the sustained elevation of calcium signaling sensitivity with increased mechanical stress. We initially investigated three potential players based on their previous links to mechanical stress and modulation by ROS signaling. Here we report on the contribution of nitric oxide (NO), Ca2+/Calmodulin-dependent kinase II (CaMKII), and mechano-sensitive channels (MSC) on stretch-dependent regulation of calcium signaling in ventricular myocytes. We find that both NO and CaMKII have little to no effect on the rapid acute increase in the Ca2+ spark rate with stretch (≤10s), but each contribute significantly to maintaining elevated calcium signaling sensitivity with prolonged cyclic stretch (≥1min). We also explore the role of ROS signaling in the stretch-dependent activation of these signaling pathways, and how this affects both diastolic calcium sparks as well as systolic calcium transients and contractility in electrically paced myocytes.

Regulation and functional roles of rebound potentiation at cerebellar stellate cell—Purkinje cell synapses

Purkinje cells receive both excitatory and inhibitory synaptic inputs and send sole output from the cerebellar cortex. Long-term depression (LTD), a type of synaptic plasticity, at excitatory parallel fiber–Purkinje cell synapses has been studied extensively as a primary cellular mechanism of motor learning. On the other hand, at inhibitory synapses on a Purkinje cell, postsynaptic depolarization induces long-lasting potentiation of GABAergic synaptic transmission. This synaptic plasticity is called rebound potentiation (RP), and its molecular regulatory mechanisms have been studied. The increase in intracellular Ca2+ concentration caused by depolarization induces RP through enhancement of GABAA receptor (GABAAR) responsiveness. RP induction depends on binding of GABAAR with GABAAR associated protein (GABARAP) which is regulated by Ca2+/calmodulin-dependent kinase II (CaMKII). Whether RP is induced or not is determined by the balance between phosphorylation and de-phosphorylation activities regulated by intracellular Ca2+ and by metabotropic GABA and glutamate receptors. Recent studies have revealed that the subunit composition of CaMKII has significant impact on RP induction. A Purkinje cell expresses both α- and β-CaMKII, and the latter has much higher affinity for Ca2+/calmodulin than the former. It was shown that when the relative amount of α- to β-CaMKII is large, RP induction is suppressed. The functional significance of RP has also been studied using transgenic mice in which a peptide inhibiting association of GABARAP and GABAAR is expressed selectively in Purkinje cells. The transgenic mice show abrogation of RP and subnormal adaptation of vestibulo-ocular reflex (VOR), a type of motor learning. Thus, RP is involved in a certain type of motor learning.

P600 stabilizes microtubules to prevent the aggregation of CaMKIIα during photoconductive stimulation.

The large microtubule-associated/Ca2+-signalling protein p600 (also known as UBR4) is required for hippocampal neuronal survival upon Ca2+ dyshomeostasis induced by glutamate treatment. During this process, p600 prevents aggregation of the Ca2+/calmodulin-dependent kinase IIα (CaMKIIα), a proxy of neuronal death, via direct binding to calmodulin in a microtubuleindependent manner. Using photoconductive stimulation coupled with live imaging of single neurons, we identified a distinct mechanism of prevention of CaMKIIα aggregation by p600. Upon direct depolarization, CaMKIIα translocates to microtubules. In the absence of p600, this translocation is interrupted in favour of a sustained self-aggregation that is prevented by the microtubule-stabilizing drug paclitaxel. Thus, during photoconductive stimulation, p600 prevents the aggregation of CaMKIIα by stabilizing microtubules. The effectiveness of this stabilization for preventing CaMKIIα aggregation during direct depolarization but not during glutamate treatment suggests a model wherein p600 has two modes of action depending on the source of cytosolic Ca2+.Electronic Supplementary MaterialSupplementary material is available for this article at 10.2478/s11658-014-0201-9 and is accessible for authorized users.

Upregulation of presynaptic proteins and protein kinases associated with enhanced glutamate release from axonal terminals (synaptosomes) of the medial prefrontal cortex in rats with neuropathic pain

Although nerve injury-induced long-term postsynaptic changes have been investigated, less is known regarding the molecular mechanisms within presynaptic axonal terminals. We investigated the molecular changes in presynaptic nerve terminals underlying chronic pain-induced plastic changes in the medial prefrontal cortex (mPFC). After neuropathic pain was induced by spared nerve injury (SNI) in rats, we assessed the release of the excitatory neurotransmitter glutamate by using in vitro synaptosomal preparations from the mPFC. We also measured the levels of synaptic proteins and protein kinases in synaptosomes using Western blotting. The results showed that unilateral long-term SNI augmented depolarization-evoked glutamate release from synaptosomes of the bilateral mPFC. This result was confirmed by a rapid destaining rate of FM1-43 dye in SNI-operated rats. Unilateral long-term nerve injury also significantly increased synaptic proteins (including synaptophysin, synaptotagmin, synaptobrevin, syntaxin, and 25-kDa synaptosome-associated protein) in synaptosomal fractions from the bilateral mPFC, and ultrastructure images demonstrated increased synaptic vesicular profiles in synaptosomes from SNI animals. Chronic pain upregulated the phosphorylation of endogenous protein kinases, including extracellular signal-regulated kinases 1 and 2 (ERK1/2) and Ca2+/calmodulin-dependent kinase II (CaMKII), and synapsin I, the primary presynaptic target of ERK1/2 and CaMKII. Both presynaptic proteins and protein kinases were upregulated after SNI in a time-dependent manner. These results indicate that the long-term neuropathic pain-induced enhancement of glutamate release in the mPFC is linked to increased synaptic vesicle proteins and the activation of the ERK1/2- and CaMKII-synapsin signaling cascade in presynaptic axonal terminals.

Synapsin Function in GABA-ergic Interneurons Is Required for Short-Term Olfactory Habituation

In Drosophila, short-term (STH) and long-term habituation (LTH) of olfactory avoidance behavior are believed to arise from the selective potentiation of GABAergic synapses between multiglomerular local circuit interneurons (LNs) and projection neurons in the antennal lobe. However, the underlying mechanisms remain poorly understood. Here, we show that synapsin (syn) function is necessary for STH and that syn(97)-null mutant defects in STH can be rescued by syn(+) cDNA expression solely in the LN1 subset of GABAergic local interneurons. As synapsin is a synaptic vesicle-clustering phosphoprotein, these observations identify a presynaptic mechanism for STH as well as the inhibitory interneurons in which this mechanism is deployed. Serine residues 6 and/or 533, potential kinase target sites of synapsin, are necessary for synapsin function suggesting that synapsin phosphorylation is essential for STH. Consistently, biochemical analyses using a phospho-synapsin-specific antiserum show that synapsin is a target of Ca(2+) calmodulin-dependent kinase II (CaMKII) phosphorylation in vivo. Additional behavioral and genetic observations demonstrate that CaMKII function is necessary in LNs for STH. Together, these data support a model in which CaMKII-mediated synapsin phosphorylation in LNs induces synaptic vesicle mobilization and thereby presynaptic facilitation of GABA release that underlies olfactory STH. Finally, the striking observation that LTH occurs normally in syn(97) mutants indicates that signaling pathways for STH and LTH diverge upstream of synapsin function in GABAergic interneurons.

The roles of protein kinases in learning and memory

In the adult mammalian brain, more than 250 protein kinases are expressed, but only a few of these kinases are currently known to enable learning and memory. Based on this information it appears that learning and memory-related kinases either impact on synaptic transmission by altering ion channel properties or ion channel density, or regulate gene expression and protein synthesis causing structural changes at existing synapses as well as synaptogenesis. Here, we review the roles of these kinases in short-term memory formation, memory consolidation, memory storage, retrieval, reconsolidation, and extinction. Specifically, we discuss the roles of calcium/calmodulin-dependent kinase II (CaMKII), the calcium/calmodulin kinase cascade, extracellular signal regulated kinase 1 and 2 (ERK1/2), cAMP-dependent protein kinase A (PKA), cGMP-dependent protein kinase G (PKG), the phosphatidylinositol 3-kinase (PI3K) pathway, and protein kinase M ζ (PKMζ). Although these kinases are important for learning and memory processes, much remains to be learned as to how they act. Therefore, it will be important to identify and characterize the critical phosphorylation substrates so that a sophisticated understanding of learning and memory processes will be achieved. This will also allow for a systematic analysis of dysfunctional kinase activity in mental disorders.

Pacemaker Gene Mutations, Bradycardia, Arrhythmias and the Coupled Clock Theory

To the Editor: In a recent paper, Nawathe et al.1 showed that M54T LQTS6 mutation in neonatal rat ventricular myoctes that were co-transfected with human HCN4, the dominate component of f-channels, is associated with bradycardia. The bradycardiac effects that were associated with these mutations, as claimed by the authors, are attributable soley to direct If inhibition. It is well established that normal automaticity of sinoatrial node cell (SANC) is regulated by integrated functions within a system of coupled-clocks. The sarcoplasmic reticulum (SR), traditionally defined as “Ca2+ clock”, spontaneously generates diastolic Ca2+ releases that activate an inward current (specifically Na+-Ca2+ exchanger current (INCX)), that accelerates the rate of diastolic membrane depolarization. The f-channel current (If) another member of the “Membrane clock” (i.e., the ensemble of sarcolemmal electrogenic molecules), concurrently drives the diastolic membrane depolarization with INCX.2 The two clocks are tightly coupled by a common chemical axes: Ca2+-calmodulin activated adenylyl cyclases that generates the second messenger cAMP, which activates protein kinase-A (PKA), and Ca2+ activated calmodulin-dependent kinase II (CaMKII). Both kinases phosphorylate different proteins of the M clock (e.g., L-type and K+ currents) and of the Ca2+ clock (phospholamban and ryanodine receptors). Additionally, cAMP positively shifts the f-channel activation curve. According to the coupled-clock theory, the membrane and Ca2+ clocks should crosstalk. Thus, a change in action potential (AP) firing rate in response to any disturbance signal that directly perturbs either clock entrains the function of the other clock. Consequently, the resultant steady-state AP cycle length change embodies contributions of both clocks. Therefore, the interpretation that bradycardia associated with mutation in HCN4 or with pharmacological blockade of If, occurs solely on the basis of direct inhibition of If function may not be correct. In this regard, a recent study demonstrated that ivabradine, at a concentration that specifically inhibits If, but does not directly suppress L-type current, SR Ca2+ cycling and other surface membrane ion channels, indirectly suppresses intracellular Ca2+ cycling.3 Similar clock coupling effects should occur in the presence of HCN4 mutations. A plausible, indirect effect on SR Ca2+ in response to HCN4 mutations or pharmacological blockade of If can be explained on the basis of this net reduction in Ca2+ influx associated with the bradycardic effect (fewer APs per unit time). A reduction in If initiates a small reduction in number of APs per unit time, which reduces the Ca2+ influx per unit time. This reduction in net Ca2+ influx results in a reduction in intracellular Ca2+, and Ca2+ available for pumping, reducing the SR Ca2+ load and prolonging the restitution time required for spontaneous diastolic Ca2+ releases to occur, i.e., the period of local Ca2+ release becomes prolonged. Consequently, the Ca2+ activation of INCX to a later time during diastolic depolarization, which further reduces the heart rate, leading to further reduction in Ca2+ influx per unit time. Moreover, as a result of reduced intracellular Ca2+, Ca2+ activated CaMKII and adenylyl cyclases-cAMP/PKA signaling axes become damped. The resultant reduction in phosphorylation of Ca2+ cycling proteins that further reduces the net Ca2+ influx, further reduces SR Ca2+ loading that further reduces AP rate and, in parallel, the resultant reduction in cAMP further shifts the If activation curve. Thus, the steady-state bradycardia measured experimentally in response to HCN4 mutations or pharmacological blockade of If is achieved when the induced reduced Ca2+ influx is balanced by a reduction in Ca2+ efflux via INCX. Similar to mutations in the f-channel within the membrane clock, mutations in the intracellular Ca2+ clock proteins are associated with bradicardia. A mutation in ryanodine receptor, axon-3, carried by patients with catecholaminergic polymorphic ventricular tachycardia, is associated with arrhythmias.4 Isolated SANC from mice that express this mutation have a slower spontaneous AP firing rate.5 Patients with a mutation in CACNA1D, which encodes the pore-forming α1 subunit of Cav1.3 (Cav1.3 is largely absent from the ventricles, but is highly expressed in atria, atrioventricular node and sinoatrial node6) experience pronounced bradycardia in 12–24-h ECG recordings, and their heart rate variability is increased.7 Similar to HCN4 mutations, the steady-state bradycardia associated with mutations in Ca2+ clock proteins may be mediated only in part by a reduction in available Ca2+ that inhibits Ca2+ cycling, and in part, by the resultant changes in cross-talk induced change in the membrane clock. In summary, crosstalk occurs between the Membrane and Ca2+ clocks whenever either the membrane or Ca2+ clock is directly perturbed the other clock is indirectly perturbed. Therefore, the steady-state bradycardia associated with different HCN4 mutations, ivabradine or Ca2+ regulatory protein is likely mediated, only in part by If inhibition, and in part, by change in Ca2+ clock due to clock cross-talk. Only an understanding of the full profile underling mechanisms of bradycardia that is associated with HCN4 mutations will promote the discovery of optionally effective treatments for bradycardia.

The Multifunctional Ca2+/Calmodulin-Dependent Kinase IIδ (CaMKIIδ) Regulates Arteriogenesis in a Mouse Model of Flow-Mediated Remodeling

ObjectiveSustained hemodynamic stress mediated by high blood flow promotes arteriogenesis, the outward remodeling of existing arteries. Here, we examined whether Ca2+/calmodulin-dependent kinase II (CaMKII) regulates arteriogenesis.Methods and ResultsLigation of the left common carotid led to an increase in vessel diameter and perimeter of internal and external elastic lamina in the contralateral, right common carotid. Deletion of CaMKIIδ (CaMKIIδ−/−) abolished this outward remodeling. Carotid ligation increased CaMKII expression and was associated with oxidative activation of CaMKII in the adventitia and endothelium. Remodeling was abrogated in a knock-in model in which oxidative activation of CaMKII is abolished. Early after ligation, matrix metalloproteinase 9 (MMP9) was robustly expressed in the adventitia of right carotid arteries of WT but not CaMKIIδ−/− mice. MMP9 mainly colocalized with adventitial macrophages. In contrast, we did not observe an effect of CaMKIIδ deficiency on other proposed mediators of arteriogenesis such as expression of adhesion molecules or smooth muscle proliferation. Transplantation of WT bone marrow into CaMKIIδ−/− mice normalized flow-mediated remodeling.ConclusionCaMKIIδ is activated by oxidation under high blood flow conditions and is required for flow-mediated remodeling through a mechanism that includes increased MMP9 expression in bone marrow-derived cells invading the arterial wall.

Melatonin ameliorates cognitive impairment induced by sleep deprivation in rats: Role of oxidative stress, BDNF and CaMKII

Sleep deprivation (SD) has been shown to induce oxidative stress which causes cognitive impairment. Melatonin, an endogenous potent antioxidant, protects neurons from oxidative stress in many disease models. The present study investigated the effect of melatonin against SD-induced cognitive impairment and attempted to define the possible mechanisms involved. SD was induced in rats using modified multiple platform model. Melatonin (15mg/kg) was administered to the rats via intraperitoneal injection. The open field test and Morris water maze were used to evaluate cognitive ability. The cerebral cortex (CC) and hippocampus were dissected and homogenized. Nitric oxide (NO) and malondialdehyde (MDA) levels and the superoxide dismutase (SOD) enzyme activity of hippocampal and cortical tissues (10% wet weight per volume) were performed to determine the level of oxidative stress. The expression of brain-derived neurotrophic factor (BDNF) and calcium-calmodulin dependent kinase II (CaMKII) proteins in CC and hippocampus was assayed by means of immunohistochemistry. The results revealed that SD impairs cognitive ability, while melatonin treatment prevented these changes. In addition, melatonin reversed SD-induced changes in NO, MDA and SOD in both of the CC and hippocampus. The results of immunoreactivity showed that SD decreased gray values of BDNF and CaMKII in CC and hippocamal CA1, CA3 and dentate gyrus regions, whereas melatonin improved the gray values. In conclusion, our results suggest that melatonin prevents cognitive impairment induced by SD. The possible mechanism may be attributed to its ability to reduce oxidative stress and increase the levels of CaMKII and BDNF in CC and hippocampus.

An elevated late INa increases the diastolic SR-Ca-leak in atrial cardiomyocytes via a CaMKII-dependent mechanism

The late Na current (late INa) is elevated in heart failure (HF) and atrial fibrillation (AF) and may induce cardiac arrhythmias. Similarly, SR-Ca-leak is increased in both pathologies. The aim of the study was to determine a crosstalk between late INa, Ca/calmodulin-dependent kinase II (CaMKII) and the SR-Ca-leak in atrial myocytes. We hypothesized that an increased late INa leads to diastolic Ca-overload (via Na/Ca-exchanger, NCX), which activates CaMKII in AF and triggers CaMKII-dependent phosophorylation of ryanodine-receptor type 2 (RyR2). Furthermore, CaMKII was found to phosphorylate cardiac Na-channles thereby elevating late INa. Thus, a vitious circle could take place maintaining arrhythmogenity in AF. We isolated atrial cardiomyocytes (CM) from mice, paced them at 3 Hz for 20 beats and scanned for diastolic Ca-sparks (confocal microscopy). The low basal Ca-spark-frequency (CaSpF) of atrial CM (22±8/s/10-4 m) could be increased by the late INa enhancer ATX-II (0.5 nM) to 169±28/s/10-4m (by 668±155%, n=43 vs. 43, P<0.001). Simultaneous CaMKII-inhibition by AIP (1 μM) completely prevented the ATX-II-induced 11-fold increase of the total calculated SR-Ca-leak (n=48 vs. 43, p<0.001) suggesting a CaMKII-dependent mechanism. Late INa inhibition using ranolazine (Ran 10 μM, n=32 vs. 43) as well as the specific Na+-channel blocker tetrodotoxin (TTX, n=28 vs. 26) also normalized the total SR-Ca-leak in ATX-II-treated atrial cardiomyocytes (P=0.001). The ATX-II mediated induction of the SR-Ca2+-leak could further neither be detected when the Na+-Ca2+-exchanger (NCX) was inhibited with KBr (n=35 vs. 20) nor in CaMKIIδc-knockout mice (n=34 vs. 27). To validate these data for human AF we freshly isolated human atrial CM from patients in sinus rhythm (SR) and permanent AF. There was a strong tendency towards a higher calculated SR-Ca-leak in AF compared to SR (338.4±88.9 vs. 148.6±31.5, n =31 vs. 38, p=0.07). Indeed, superfusion of atrial CM from AF patients with Ran (10 μM) could significantly reduce the diastolic SR-Ca-leak compared to untreated control (by 78±9%, n=27 vs. 30, p<0.05). Additionally, treatment with AIP (1 μM) significantly reduced Ca-spark-frequency by 63±12% (p<0.05, n =28 vs. 41). These data suggest that an increased late INa induces diastolic SR-Ca-leak in murine and human atrial CM via CaMKII-dependent ryanodine receptor regulation. This mechanism might constitute a trigger for the induction and perpetuation of atrial arrhythmias. Ran seems to exert antiarrhythmic effects by reducing the SR-Ca-leak and is currently evaluated for antiarrhythmic therapy in patients with AF.

Differential Control of Calcium Homeostasis and Vascular Reactivity by Ca 2+ /Calmodulin-Dependent Kinase II

The multifunctional Ca 2+ /calmodulin-dependent kinase II (CaMKII) is activated by vasoconstrictors in vascular smooth muscle cells (VSMC), but its impact on vasoconstriction remains unknown. We hypothesized that CaMKII inhibition in VSMC decreases vasoconstriction. Using novel transgenic mice that express the inhibitor peptide CaMKIIN in smooth muscle (TG SM-CaMKIIN), we investigated the effect of CaMKII inhibition on L-type Ca 2+ channel current ( I Ca ), cytoplasmic and sarcoplasmic reticulum Ca 2+ , and vasoconstriction in mesenteric arteries. In mesenteric VSMC, CaMKII inhibition significantly reduced action potential duration and the residual I Ca 50 ms after peak amplitude, indicative of loss of L-type Ca 2+ channel–dependent I Ca facilitation. Treatment with angiotensin II or phenylephrine increased the intracellular Ca 2+ concentration in wild-type but not TG SM-CaMKIIN VSMC. The difference in intracellular Ca 2+ concentration was abolished by pretreatment with nifedipine, an L-type Ca 2+ channel antagonist. In TG SM-CaMKIIN VSMC, the total sarcoplasmic reticulum Ca 2+ content was reduced as a result of diminished sarcoplasmic reticulum Ca 2+ ATPase activity via impaired derepression of the sarcoplasmic reticulum Ca 2+ ATPase inhibitor phospholamban. Despite the differences in intracellular Ca 2+ concentration, CaMKII inhibition did not alter myogenic tone or vasoconstriction of mesenteric arteries in response to KCl, angiotensin II, and phenylephrine. However, it increased myosin light chain kinase activity. These data suggest that CaMKII activity maintains intracellular calcium homeostasis but is not required for vasoconstriction of mesenteric arteries.

Intracellular Transactivation of Epidermal Growth Factor Receptor byα1A-Adrenoceptor Is Mediated by Phosphatidylinositol 3-Kinase Independently of Activation of Extracellular Signal Regulated Kinases 1/2 and Serine-Threonine Kinases in Chinese Hamster Ovary Cells

Transactivation of epidermal growth factor receptor (EGFR) by α1-adrenoceptor (α1-AR) is implicated in contraction and hypertrophy of vascular smooth muscle (VSM). We examine whether all α1-AR subtypes transactivate EGFR and explore the mechanism of transactivation. Chinese hamster ovary (CHO) cells stably expressing one subtype of α1-AR were transiently transfected with EGFR. The transactivation mechanism was examined both by coexpression of a chimeric erythropoietin (EPO)-EGFR with an extracellular EPO and intracellular EGFR domain, and by pharmacologic inhibition of external and internal signaling routes. All three α1-AR subtypes transactivated EGFR, which was dependent on the increase in intracellular calcium. The EGFR kinase inhibitor AG1478 [4-(3'-chloroanilino)-6,7-dimethoxyquinazoline] abrogated α1A-AR and α1D-AR induced phosphorylation of EGFR, but both the inhibition of matrix metalloproteinases by GM6001 [(R)-N4-hydroxy-N(1)-[(S)-2-(1H-indol-3-yl)-1-methylcarbamoyl-ethyl]-2-isobutyl-succinamide] or blockade of EGFR by cetuximab did not. Stimulation of α1A-AR and α1D-AR also induced phosphorylation of EPO-EGFR chimeric receptors. Moreover, α1A-AR stimulation enhanced phosphorylation of extracellular signal regulated kinase (ERK) 1/2 and serine-threonine kinases (Akt), which were both unaffected by AG1478, indicating that ERK1/2 and Akt phosphorylation is independent of EGFR transactivation. Accordingly, inhibitors of ERK1/2 or Akt did not influence the α1A-AR-mediated EGFR transactivation. Inhibition of calcium/calmodulin-dependent kinase II (CaMKII), phosphatidylinositol 3-kinase (PI3K), and Src, however, did block EGFR transactivation by α1A-AR and α1D-AR. These findings demonstrate that all α1-AR subtypes transactivate EGFR, which is dependent on an intracellular signaling route involving an increase in calcium and activation of CaMKII, PI3K, and Src, but not the of ERK1/2 and Akt pathways.

Increased Vesicular γ‐GABA Transporter and Decreased Phosphorylation of Synapsin I in the Rostral Preoptic Area is Associated with Decreased Gonadotrophin‐Releasing Hormone and c‐Fos Coexpression in Middle‐Aged Female Mice

Hypothalamic glutamate (Glu) and γ-GABA neurotransmission are involved in the ovarian hormone-induced gonadotrophin-releasing hormone (GnRH)/luteinising hormone (LH) surge in rodents. Studies have shown that reduced Glu and increased γ-GABA in the rostral preoptic area (rPOA) of the hypothalamus, where most activated GnRH neurones are located, play a key role in decreasing the reproductive function of female rats. However, the mechanism underlying the altered balance of these neurotransmitters is poorly understood. In the present study, we observed a decline in the function of GnRH neurones in the rPOA at the time of the GnRH/LH surge in middle-aged intact female mice with regular oestrous cycles. In young mice, there is an increase of vesicular Glu transporter 2 on the pro-oestrus afternoon, which is not observed in middle-aged mice. By contrast, vesicular γ-GABA transporter levels in young mice decrease at the time of the LH surge, whereas they increase in middle-aged mice. Of note, we found that, in middle-aged mice at the time of the GnRH/LH surge, the phosphorylation of synapsin I at Ser603 and Ca(2+) /calmodulin-dependent kinase IIα was significantly lower than in young mice. These data suggest that, in middle-aged mice, higher levels of presynaptic stores of GABA, a lack of increase of Glu and a decreased ability of synaptic vesicle mobilisation could account for the imbalance of Glu and GABA in the rPOA, which decreases the activation of GnRH neurones.