Browsing by Subject "CaMKII"

Now showing 1 - 6 of 6
  • Thumbnail Image
    Item
    Autoregulatory and structural control of CaMKII substrate specificity
    (2016-09) Johnson, Derrick Ethan; Hudmon, Andy; Hurley, Thomas D.; Hoang, Quyen Q.; Gallagher, Patricia
    Calcium/calmodulin (CaM)-dependent protein kinase II (CaMKII) is a multimeric holoenzyme composed of 8–14 subunits from four closely related isoforms (α, β, γ, δ). CaMKII plays a strategic, multifunctional role in coupling the universal second messenger calcium with diverse cellular processes including metabolism, cell cycle control, and synaptic plasticity. CaMKII exhibits broad substrate specificity, targeting numerous substrates with diverse phosphorylation motifs. Binding of the calcium sensor CaM to the autoregulatory domain (ARD) of CaMKII functions to couple kinase activation with calcium signaling. Important sites of autophosphorylation, namely T287 and T306/7 (δ isoform numbering), reside within the ARD and control either CaM dependence or ability to bind to CaMKII respectively, thus determining various activation states of the kinase. Because autophosphorylation is critical to the function of CaMKII in vivo, we sought to determine the relationship between the activation state of the kinase and substrate selectivity. We show that the ARD of activated CaMKII tunes substrate selectivity by competing for substrate binding to the catalytic domain, thus functioning as a selectivity filter. Specifically, in the absence of T287 autophosphorylation, substrate phosphorylation is limited to high-affinity, consensus substrates. T287 autophosphorylation restores maximal kinase activation and broad substrate selectivity by disengaging ARD filtering. The unique multimeric architecture of CaMKII is an ideal sensor which encodes calcium-spike frequency into graded levels of subunit activation/autophosphorylation within the holoenzyme. We find that differential activation states of the holoenzyme produce distinct substrate phosphorylation profiles. Maximal holoenzyme activation/autophosphorylation leads to further broadening of substrate specificity beyond the effect of autophosphorylation alone, which is consistent with multivalent avidity. Thus, the ability of calcium-spike frequency to regulate T287 autophosphorylation and holoenzyme activation permits cellular activity to dictate switch-like behavior in substrate selectivity that is required for diverse cellular responses by CaMKII.
  • Thumbnail Image
    Item
    Calcium/Calmodulin-Dependent Protein Kinase II Regulation of IKs during Sustained Beta-Adrenergic Receptor Stimulation
    (Elsevier, 2018) Shugg, Tyler; Johnson, Derrick E.; Shao, Minghai; Lai, Xianyin; Witzmann, Frank; Cummins, Theodore R.; Rubart-Von der Lohe, Michael; Hudmon, Andy; Overholser, Brian R.; Biochemistry and Molecular Biology, School of Medicine
    Background Sustained β-adrenergic receptor (β-AR) stimulation causes pathophysiological changes during heart failure (HF), including inhibition of the slow component of the delayed rectifier potassium current (IKs). Aberrant calcium handling, including increased activation of calcium/calmodulin-dependent protein kinase II (CaMKII), contributes to arrhythmia development during HF. Objective The purpose of this study was to investigate CaMKII regulation of KCNQ1 (pore-forming subunit of IKs) during sustained β-AR stimulation and associated functional implications on IKs. Methods KCNQ1 phosphorylation was assessed using LCMS/MS after sustained β-AR stimulation with isoproterenol (ISO). Peptide fragments corresponding to KCNQ1 residues were synthesized to identify CaMKII phosphorylation at the identified sites. Dephosphorylated (alanine) and phosphorylated (aspartic acid) mimics were introduced at identified residues. Whole-cell, voltage-clamp experiments were performed in human endothelial kidney 293 cells coexpressing wild-type or mutant KCNQ1 and KCNE1 (auxiliary subunit) during ISO treatment or lentiviral δCaMKII overexpression. Results Novel KCNQ1 carboxy-terminal sites were identified with enhanced phosphorylation during sustained β-AR stimulation at T482 and S484. S484 peptides demonstrated the strongest δCaMKII phosphorylation. Sustained β-AR stimulation reduced IKs activation (P = .02 vs control) similar to the phosphorylated mimic (P = .62 vs sustained β-AR). Individual phosphorylated mimics at S484 (P = .04) but not at T482 (P = .17) reduced IKs function. Treatment with CN21 (CaMKII inhibitor) reversed the reductions in IKs vs CN21-Alanine control (P < .01). δCaMKII overexpression reduced IKs similar to ISO treatment in wild type (P < .01) but not in the dephosphorylated S484 mimic (P = .99). Conclusion CaMKII regulates KCNQ1 at S484 during sustained β-AR stimulation to inhibit IKs. The ability of CaMKII to inhibit IKs may contribute to arrhythmogenicity during HF.
  • Thumbnail Image
    Item
    CaMKII Inhibition Attenuates Distinct Gain-of-Function Effects Produced by Mutant Nav1.6 Channels and Reduces Neuronal Excitability
    (MDPI, 2022-07-04) Zybura, Agnes S.; Sahoo, Firoj K.; Hudmon, Andy; Cummins, Theodore R.; Biology, School of Science
    Aberrant Nav1.6 activity can induce hyperexcitability associated with epilepsy. Gain-of-function mutations in the SCN8A gene encoding Nav1.6 are linked to epilepsy development; however, the molecular mechanisms mediating these changes are remarkably heterogeneous and may involve post-translational regulation of Nav1.6. Because calcium/calmodulin-dependent protein kinase II (CaMKII) is a powerful modulator of Nav1.6 channels, we investigated whether CaMKII modulates disease-linked Nav1.6 mutants. Whole-cell voltage clamp recordings in ND7/23 cells show that CaMKII inhibition of the epilepsy-related mutation R850Q largely recapitulates the effects previously observed for WT Nav1.6. We also characterized a rare missense variant, R639C, located within a regulatory hotspot for CaMKII modulation of Nav1.6. Prediction software algorithms and electrophysiological recordings revealed gain-of-function effects for R639C mutant channel activity, including increased sodium currents and hyperpolarized activation compared to WT Nav1.6. Importantly, the R639C mutation ablates CaMKII phosphorylation at a key regulatory site, T642, and, in contrast to WT and R850Q channels, displays a distinct response to CaMKII inhibition. Computational simulations demonstrate that modeled neurons harboring the R639C or R850Q mutations are hyperexcitable, and simulating the effects of CaMKII inhibition on Nav1.6 activity in modeled neurons differentially reduced hyperexcitability. Acute CaMKII inhibition may represent a promising mechanism to attenuate gain-of-function effects produced by Nav1.6 mutations.
  • Thumbnail Image
    Item
    CaMKII Phosphorylation of the Voltage-Gated Sodium Channel Nav1.6 Regulates Channel Function and Neuronal Excitability
    (2021-01) Zybura, Agnes Sara; Cummins, Theodore R.; Hudmon, Andy; Baucum II, Anthony J.; Sheets, Patrick L.
    Voltage-gated sodium channels (Navs) undergo remarkably complex modes of modulation to fine tune membrane excitability and neuronal firing properties. In neurons, the isoform Nav1.6 is highly enriched at the axon initial segment and nodes, making it critical for the initiation and propagation of neuronal impulses. Thus, Nav1.6 modulation and dysfunction may profoundly impact the input-output properties of neurons in normal and pathological conditions. Phosphorylation is a powerful and reversible mechanism that exquisitely modulates ion channels. To this end, the multifunctional calcium/calmodulin-dependent protein kinase II (CaMKII) can transduce neuronal activity through phosphorylation of diverse substrates to serve as a master regulator of neuronal function. Because Nav1.6 and CaMKII are independently linked to excitability disorders, I sought to investigate modulation of Nav1.6 function by CaMKII signaling to reveal an important mechanism underlying neuronal excitability. Multiple biochemical approaches show Nav1.6 is a novel substrate for CaMKII and reveal multi-site phosphorylation within the L1 domain; a hotspot for post-translational regulation in other Nav isoforms. Consistent with these findings, pharmacological inhibition of CaMKII reduces transient and persistent sodium currents in Purkinje neurons. Because Nav1.6 is the predominant sodium current observed in Purkinje neurons, these data suggest that Nav1.6 may be modulated through CaMKII signaling. In support of this, my studies demonstrate that CaMKII inhibition significantly attenuates Nav1.6 transient and persistent sodium currents and shifts the voltage-dependence of activation to more depolarizing potentials in heterologous cells. Interestingly, I show that these functional effects are likely mediated by CaMKII phosphorylation of Nav1.6 at S561 and T642, and that each phosphorylation site regulates distinct biophysical characteristics of the channel. These findings are further extended to investigate CaMKII modulation of disease-linked mutant Nav1.6 channels. I show that different Nav1.6 mutants display distinct responses to CaMKII modulation and reveal that acute CaMKII inhibition attenuates gain-of-function effects produced by mutant channels. Importantly, computational simulations modeling the effects of CaMKII inhibition on WT and mutant Nav1.6 channels demonstrate dramatic reductions in neuronal excitability in Purkinje and cortical pyramidal cell models. Together, these findings suggest that CaMKII modulation of Nav1.6 may be a powerful mechanism to regulate physiological and pathological neuronal excitability.
  • Thumbnail Image
    Item
    Differential expression of CaMKII isoforms and overall kinase activity in rat dorsal root ganglia after injury.
    (Elsevier, 2015-08-06) Bangaru, Madhavi Latha Yadav; Meng, Jingwei; Kaiser, Derek J.; Yu, Hongwei; Fischer, Greg; Hogan, Quinn H.; Hudmon, Andy; Department of Biochemistry & Molecular Biology, IU School of Medicine
    Ca(2+)/calmodulin-dependent protein kinase II (CaMKII) decodes neuronal activity by translating cytoplasmic Ca(2+) signals into kinase activity that regulates neuronal functions including excitability, gene expression, and synaptic transmission. Four genes lead to developmental and differential expression of CaMKII isoforms (α, β, γ, δ). We determined mRNA levels of these isoforms in the dorsal root ganglia (DRG) of adult rats with and without nerve injury in order to determine if differential expression of CaMKII isoforms may contribute to functional differences that follow injury. DRG neurons express mRNA for all four isoforms, and the relative abundance of CaMKII isoforms was γ>α>β=δ, based on the CT values. Following ligation of the 5th lumbar (L5) spinal nerve (SNL), the β isoform did not change, but mRNA levels of both the γ and α isoforms were reduced in the directly injured L5 neurons, and the α isoform was reduced in L4 neurons, compared to their contemporary controls. In contrast, expression of the δ isoform mRNA increased in L5 neurons. CaMKII protein decreased following nerve injury in both L4 and L5 populations. Total CaMKII activity measured under saturating Ca(2+)/CaM conditions was decreased in both L4 and L5 populations, while autonomous CaMKII activity determined in the absence of Ca(2+) was selectively reduced in axotomized L5 neurons 21days after injury. Thus, loss of CaMKII signaling in sensory neurons after peripheral nerve injury may contribute to neuronal dysfunction and pain.
  • Thumbnail Image
    Item
    The effects of CaMKII signaling on neuronal viability
    (2013-12-10) Ashpole, Nicole M.; Hudmon, Andrew; Brustovetsky, Nickolay; Hurley, Thomas D., 1961-; Russell, Weihua Lee, 1956-; Oxford, G. S.
    Calcium/calmodulin-dependent protein kinase II (CaMKII) is a critical modulator of synaptic function, plasticity, and learning and memory. In neurons and astrocytes, CaMKII regulates cellular excitability, cytoskeletal structure, and cell metabolism. A rapid increase in CaMKII activity is observed within the first few minutes of ischemic stroke in vivo; this calcium-dependent process is also observed following glutamate stimulation in vitro. Activation of CaMKII during pathological conditions is immediately followed by inactivation and aggregation of the kinase. The extent of CaMKII inactivation is directly correlated with the extent of neuronal damage. The studies presented here show that these fluctuations in CaMKII activity are not correlated with neuronal death; rather, they play a causal role in neuronal death. Pharmacological inhibition of CaMKII in the time immediately surrounding glutamate insult protects cultured cortical neurons from excitotoxicity. Interestingly, pharmacological inhibition of CaMKII during excitotoxic insult also prevents the aggregation and prolonged inactivation of the kinase, suggesting that CaMKII activity during excitotoxic glutamate signaling is detrimental to neuronal viability because it leads to a prolonged loss of CaMKII activity, culminating in neuronal death. In support of this, CaMKII inhibition in the absence of excitotoxic insult induces cortical neuron apoptosis by dysregulating intracellular calcium homeostasis and increasing excitatory glutamate signaling. Blockade of the NMDA-receptors and enzymatic degradation of the extracellular glutamate signal affords neuroprotection from CaMKII inhibition-induced toxicity. Co-cultures of neurons and glutamate-buffering astrocytes also exhibit this slow-induced excitotoxicity, as CaMKII inhibitors reduce glutamate uptake within the astrocytes. CaMKII inhibition also dysregulates calcium homeostasis in astrocytes and leads to increased ATP release, which was neurotoxic when applied to naïve cortical neurons. Together, these findings indicate that during aberrant calcium signaling, the activation of CaMKII is toxic because it supports aggregation and prolonged inactivation of the kinase. Without CaMKII activity, neurons and astrocytes release stores of transmitters that further exacerbate neuronal toxicity.