Quantitative measurements of Ca(2+)/calmodulin binding and activation of myosin light chain kinase in cells

Myosin II regulatory light chain (RLC) phosphorylation by Ca(2+)/calmodulin (CaM)-dependent myosin light chain kinase (MLCK) is implicated in many cellular actin cytoskeletal functions. We examined MLCK activation quantitatively with a fluorescent biosensor MLCK where Ca(2+)-dependent increases in kinase activity were coincident with decreases in fluorescence resonance energy transfer (FRET) in vitro. In cells stably transfected with CaM sensor MLCK, increasing [Ca(2+)](i) increased MLCK activation and RLC phosphorylation coincidently. There was no evidence for CaM binding but not activating MLCK at low [Ca(2+)](i). At saturating [Ca(2+)](i) MLCK was not fully activated probably due to limited availability of cellular Ca(2+)/CaM.     

Enhanced dynamic range in a genetically encoded Ca2+ sensor

Genetically encoded fluorescence resonance energy transfer (FRET) indicators are powerful tools for real-time detection of second messenger molecules and activation of signal proteins. However, these fluorescent protein-based sensors typically display marginal FRET efficiency. To improve their FRET efficiency for optical imaging and screening, we developed a number of fluorescent protein mutants based on cyan fluorescent protein (CFP) and yellow fluorescent protein (YFP). To improve FRET ratios, which were initially within a narrow dynamic range, we used DNA shuffling to develop a new FRET pair called 3xCFP/Venus. The optimized 3xCFP/Venus pair exhibited higher FRET ratios than CyPet/YPet, which has one of the greatest dynamic ranges of protein-based FRET pairs. We converted this FRET pair to a Ca(2+) FRET indicators using circular permutation Venus (cpVenus) linked with 3xCFP to form 3xCFP/cpVenus, which displayed an ～11-fold change in dynamic range in response to Ca(2+) binding. The enhanced dynamic range for Ca(2+) concentration detection using 3xCFP/cpVenus was confirmed in PC12 cells using previously established indicators (TN-XXL, ECFP/cpCitrine). To our knowledge, this FRET pair displays the largest dynamic range so far among genetically-encoded sensors, and can be used for sensitive FRET detection.     

Differential binding of calmodulin domains to constitutive and inducible nitric oxide synthase enzymes

Calmodulin (CaM) is a Ca2+ signal transducing protein that binds and activates many cellular enzymes with physiological relevance, including the mammalian nitric oxide synthase (NOS) isozymes: endothelial NOS (eNOS), neuronal NOS (nNOS), and inducible NOS (iNOS). The mechanism of CaM binding and activation to the iNOS enzyme is poorly understood in part due to the strength of the bound complex and the difficulty of assessing the role played by regions outside of the CaM-binding domain. To further elucidate these processes, we have developed the methodology to investigate CaM binding to the iNOS holoenzyme and generate CaM mutant proteins selectively labeled with fluorescent dyes at specific residues in the N-terminal lobe, C-terminal lobe, or linker region of the protein. In the present study, an iNOS CaM coexpression system allowed for the investigation of CaM binding to the holoenzyme; three different mutant CaM proteins with cysteine substitutions at residues T34 (N-domain), K75 (central linker), and T110 (C-domain) were fluorescently labeled with acrylodan or Alexa Fluor 546 C5-maleimide. These proteins were used to investigate the differential association of each region of CaM with the three NOS isoforms. We have also N-terminally labeled an iNOS CaM-binding domain peptide with dabsyl chloride in order to perform FRET studies between Alexa-labeled residues in the N- and C-terminal domains of CaM to determine CaM's orientation when associated to iNOS. Our FRET results show that CaM binds to the iNOS CaM-binding domain in an antiparallel orientation. Our steady-state fluorescence and circular dichroism studies show that both the N- and C-terminal EF hand pairs of CaM bind to the CaM-binding domain peptide of iNOS in a Ca2+-independent manner; however, only the C-terminal domain showed large Ca2+-dependent conformational changes when associated with the target sequence. Steady-state fluorescence showed that Alexa-labeled CaM proteins are capable of binding to holo-iNOS coexpressed with nCaM, but this complex is a transient species and can be displaced with the addition of excess CaM. Our results show that CaM does not bind to iNOS in a sequential manner as previously proposed for the nNOS enzyme. This investigation provides additional insight into why iNOS remains active even under basal levels of Ca2+ in the cell.     

Quantitative measurement of Ca(2+)-dependent calmodulin-target binding by Fura-2 and CFP and YFP FRET imaging in living cells

Calcium dynamics and its linked molecular interactions cause a variety of biological responses; thus, exploiting techniques for detecting both concurrently is essential. Here we describe a method for measuring the cytosolic Ca(2+) concentration ([Ca(2+)](i)) and protein-protein interactions within the same cell, using Fura-2 and superenhanced cyan and yellow fluorescence protein (seCFP and seYFP, respectively) FRET imaging techniques. Concentration-independent corrections for bleed-through of Fura-2 into FRET cubes across different time points and [Ca(2+)](i) values allowed for an effective separation of Fura-2 cross-talk signals and seCFP and seYFP cross-talk signals, permitting calculation of [Ca(2+)](i) and FRET with high fidelity. This correction approach was particularly effective at lower [Ca(2+)](i) levels, eliminating bleed-through signals that resulted in an artificial enhancement of FRET. By adopting this correction approach combined with stepwise [Ca(2+)](i) increases produced in living cells, we successfully elucidated steady-state relationships between [Ca(2+)](i) and FRET derived from the interaction of seCFP-tagged calmodulin (CaM) and the seYFP-fused CaM binding domain of myosin light chain kinase. The [Ca(2+)](i) versus FRET relationship for voltage-gated sodium, calcium, and TRPC6 channel CaM binding domains (IQ domain or CBD) revealed distinct sensitivities for [Ca(2+)](i). Moreover, the CaM binding strength at basal or subbasal [Ca(2+)](i) levels provided evidence of CaM tethering or apoCaM binding in living cells. Of the ion channel studies, apoCaM binding was weakest for the TRPC6 channel, suggesting that more global Ca(2+) and CaM changes rather than the local CaM-channel interface domain may be involved in Ca(2+)CaM-mediated regulation of this channel. This simultaneous Fura-2 and CFP- and YFP-based FRET imaging system will thus serve as a simple but powerful means of quantitatively elucidating cellular events associated with Ca(2+)-dependent functions.     

Activation of multifunctional Ca2+/calmodulin-dependent protein kinase in GH3 cells.

We report that the rat pituitary cell line GH3 contains a Ca2(+)- and calmodulin-dependent protein kinase with properties characteristic of multifunctional Ca2+/calmodulin-dependent protein kinase (CaM kinase) from rat brain. The GH3 kinase exhibits the hallmark of authentic CaM kinase: conversion from Ca2(+)-dependent to Ca2(+)-independent activity following a brief initial phosphorylation in vitro. This phosphorylation occurs at a site which is similar or identical to that of the "autonomy" site of the rat brain enzyme and thus may be an autophosphorylation event. GH3 CaM kinase is phosphorylated and becomes Ca2(+)-independent in situ. Depolarization of intact cells with K+ opens calcium channels and leads to the phosphorylation of CaM kinase at the autonomy site, and the kinase becomes significantly and persistently Ca2(+)-independent. Treatment of cells with thyrotropin-releasing hormone (TRH), which activates the phosphatidylinositol signaling pathway, also generates a Ca2(+)-independent CaM kinase in situ. The primary effect of TRH on CaM kinase activity is transient and correlates with the spike of Ca2+ released from intracellular stores and the rapid phase of prolactin release from GH3 cells. This study demonstrates that CaM kinase is able to detect and respond to both calcium that enters the cell through voltage-sensitive Ca2+ channels and calcium released from internal stores via the phosphatidylinositol pathway. We find that TRH, a hormone that causes release of prolactin and was previously believed to activate primarily protein kinase C, also significantly activates CaM kinase in intact cells.     

In vivo interaction between RGS4 and calmodulin visualized with FRET techniques: possible involvement of lipid raft

Regulators of G-protein signaling (RGS) are a family of proteins which accelerate intrinsic GTP-hydrolysis on heterotrimeric G-protein-alpha-subunits. Although it has been suggested that the function of RGS4 is reciprocally regulated by competitive binding of the membrane phospholipid, phosphatidylinositol-3,4,5,-trisphosphate(PtdIns(3,4,5)P(3)), and Ca(2+)/calmodulin (CaM), it remains to be shown that these interactions occur in vivo. Here, using fluorescence resonance energy transfer (FRET) techniques, we show that an elevation of intracellular Ca(2+) concentration by ionomycin increased the FRET efficiency from ECFP (a variant of cyan fluorescent protein)-labeled calmodulin to Venus (a variant of yellow fluorescent protein)-labeled RGS4. The increase in FRET efficiency was greatly attenuated by pre-treating the cells with methyl-beta-cyclodextrin, which depletes membrane cholesterol and thus disrupts lipid rafts. These results provide the first demonstration of a Ca(2+)-dependent interaction between RGS4 and CaM in vivo and show that association in lipid rafts of the plasma membrane might be involved in this physiological regulation of RGS proteins.     

Phosphorylation of myosin light chain kinase by the multifunctional calmodulin-dependent protein kinase II in smooth muscle cells.

Stimulation of tracheal smooth muscle cells in culture with ionomycin resulted in a rapid increase in cytosolic free Ca2+ concentration ([Ca2+]i) and an increase in both myosin light chain kinase and myosin light chain phosphorylation. These responses were markedly inhibited in the absence of extracellular Ca2+. Pretreatment of cells with 1-[N-O-bis(5-isoquinolinesulfonyl)-N- methyl-L-tyrosyl]-4-phenylpiperazine (KN-62), a specific inhibitor of the multifunctional calmodulin-dependent protein kinase II (CaM kinase II), did not affect the increase in [Ca2+]i but inhibited ionomycin-induced phosphorylation of myosin light chain kinase at the regulatory site near the calmodulin-binding domain. KN-62 inhibited CaM kinase II activity toward purified myosin light chain kinase. Phosphorylation of myosin light chain kinase decreased its sensitivity to activation by Ca2+ in cell lysates. Pretreatment of cells with KN-62 prevented this desensitization to Ca2+ and potentiated myosin light chain phosphorylation. We propose that the Ca(2+)-dependent phosphorylation of myosin light chain kinase by CaM kinase II decreases the Ca2+ sensitivity of myosin light chain phosphorylation in smooth muscle.     

Calmodulin- and protein phosphorylation-independent release of catecholamines from PC-12 cells

Catecholamine secretion from PC-12 cells can be triggered by agents that increase intracellular Ca2+ and is enhanced by phorbol esters and agents that elevate intracellular cAMP concentrations. In mutant PC-12 cells lacking cAMP-dependent protein kinase (PK-A) in which protein kinase C (PK-C) was down-regulated, Ca2+-dependent secretion occurred normally but was no longer enhanced by cAMP or phorbol esters. In digitonin-permeabilized PC-12 cells that lacked PK-C and PK-A, a range of calmodulin (CaM) inhibitors failed to block Ca2+-triggered catecholamine release. Moreover, Mn2+, a CaM activator, failed to trigger catecholamine release whereas Ba2+, which does not activate CaM, supported secretion. These results indicate that the basic mechanism of stimulus/secretion coupling in PC-12 cells does not absolutely require a regulated protein phosphorylation- or calmodulin-dependent step.     

Measuring calcium signaling using genetically targetable fluorescent indicators

Genetically encoded Ca2+ indicators allow researchers to quantitatively measure Ca2+ dynamics in a variety of experimental systems. This protocol summarizes the indicators that are available, and highlights those that are most appropriate for a number of experimental conditions, such as measuring Ca2+ in specific organelles and localizations in mammalian tissue-culture cells. The protocol itself focuses on the use of a cameleon, which is a fluorescence resonance-energy transfer (FRET)-based indicator comprising two fluorescent proteins and two Ca2+-responsive elements (a variant of calmodulin (CaM) and a CaM-binding peptide). This protocol details how to set up and conduct a Ca2+-imaging experiment, accomplish offline data processing (such as background correction) and convert the observed FRET ratio changes to Ca2+ concentrations. Additionally, we highlight some of the challenges in observing organellar Ca2+ and the alternative strategies researchers can employ for effectively calibrating the genetically encoded Ca2+ indicators in these locations. Setting up and conducting an initial calibration of the microscope system is estimated to take approximately 1 week, assuming that all the component parts are readily available. Cell culture and transfection is estimated to take approximately 3 d (from the time of plating cells on imaging dishes). An experiment and calibration will probably take a few hours. Finally, the offline data workup can take approximately 1 d depending on the extent of analysis.     

FRET detection of calmodulin binding to the cardiac RyR2 calcium release channel

Calmodulin (CaM) binding to the type 2 ryanodine receptor (RyR2) regulates Ca release from the cardiac sarcoplasmic reticulum (SR). However, the structural basis of CaM regulation of the RyR2 is poorly defined, and the presence of other potential CaM binding partners in cardiac myocytes complicates resolution of CaM's regulatory interactions with RyR2. Here, we show that a fluorescence-resonance-energy-transfer (FRET)-based approach can effectively resolve RyR2 CaM binding, both in isolated SR membrane vesicles and in permeabilized ventricular myocytes. A small FRET donor was targeted to the RyR2 cytoplasmic assembly via fluorescent labeling of the FKBP12.6 subunit. Acceptor fluorophore was attached at discrete positions within either the N- or the C-lobe of CaM. FRET between FKBP12.6 and CaM bound to SR vesicles indicated CaM binding at a single high-affinity site within 60 Å of FKBP12.6. Micromolar Ca increased the apparent affinity of CaM binding and slowed CaM dissociation, but did not significantly affect maximal FRET efficiency at saturating CaM. FRET was strongest when the acceptor was attached at either of two positions within CaM's N-lobe versus sites in CaM's C-lobe, providing CaM orientation information. In permeabilized ventricular myocytes, FKBP12.6 and CaM colocalized to Z-lines, and the efficiency of energy transfer to both the N- and C-lobes of CaM was comparable to that observed in SR vesicle experiments. Results also indicate that both the location and orientation of CaM binding on the RyR2 are very similar to the skeletal muscle RyR1 isoform. Specific binding of CaM to functional RyR2 channels in the cardiac myocyte environment can be monitored using FKBP biosensors and FRET.     

Proteomic and biochemical studies of calcium- and phosphorylation-dependent calmodulin complexes in Mammalian cells

Protein conformational changes due to cofactor binding (e.g., metal ions, heme) and/or post-translational modifications (e.g., phosphorylation) modulate dynamic protein complexes. Calmodulin (CaM) plays an essential role in regulating calcium signaling and homeostasis. Herein, we report a straightforward and systematic approach to identify potential calcium- and phosphorylation-dependent CaM complexes in a proteome-wide manner. We have identified over 120 CaM-associated proteins encompassing four different classes of CaM binding in HeLa cells, namely, calcium-dependent and phosphorylation-dependent (e.g., EDD1), calcium-dependent and phosphorylation-independent (e.g., myosin IE), calcium-independent and phosphorylation-dependent (e.g., DDX3), and calcium-independent and phosphorylation-independent (e.g., DDX5). To demonstrate the utility of our method in understanding biological pathways, we showed that in vivo phosphorylation of inositol 1,4,5-triphosphate receptor type 1 (IP3R1) at Ser1598 significantly reduced the affinity of its Ca2+-dependent CaM binding. However, phosphorylation of IP3R1 did not substantially affect its Ca2+-independent CaM binding. These results shed new lights on the mechanism underlying the marked increase of Ca2+ release due to IP3R1 phosphorylation. We further showed that staurosporine-sensitive kinase(s) and phosphatase PP1 play a critical role in modulating the phosphorylation-dependent CaM binding of IP3R1. Our method may serve as a general strategy to identify and characterize phosphorylation-dependent protein complexes, to pinpoint the phosphorylation sites and associated kinase(s) and phosphatase(s) involved in the protein-protein interactions, and to functionally characterize these complexes in mammalian cells.     

Decoding calcium signals by multifunctional CaM kinase.

Multifunctional Ca2+/calmodulin-dependent protein kinase (CaM kinase) is one of the three major protein kinases coordinating cellular responses to hormones and neurotransmitters. It mediates the action of Ca2+ on neurotransmitter synthesis and release, on carbohydrate metabolism and on the cytoskeleton. CaM kinase has structural/functional properties that facilitate its response to distinctive attributes of Ca2+ signals which often involve transient increases that span a narrow concentration range and increases that are pulsatile rather than persistent. The kinase responds to the narrow working range of Ca2+ signals by the use of calmodulin as the Ca2+ sensor. It is activated by the binding of calmodulin to an autoinhibitory domain that keeps the kinase inactive in the basal state. The transient nature of the signal is accommodated by autophosphorylation of this autoinhibitory domain which allows the kinase to remain partially active after calmodulin dissociates and thereby switches it to a Ca(2+)-independent species. The pulsatile nature of Ca2+ signals may also be decoded by CaM kinase. Autophosphorylation traps calmodulin on autophosphorylated subunits by greatly reducing its off-rate. At high frequency of stimulation, calmodulin would remain trapped during the brief interval between Ca2+ oscillations and each successive rise in Ca2+ would recruit more calmodulin. This may enable a stimulus frequency dependent activation of CaM kinase.     

Multiple Ca2+ signaling pathways converge on CaM kinase in PC12 cells.

The role of multifunctional Ca2+/calmodulin-dependent protein kinase (CaM kinase) in mediating various Ca2+ signaling pathways was examined in PC12 cells. Conversion of the kinase to a Ca(2+)-independent form was used to monitor which neurotransmitters activate the enzyme in situ. CaM kinase responds to Ca2+ influx elicited by ligand-gated Ca2+ channels for ATP and acetylcholine. It also responds to Ca2+ mobilization of IP3-sensitive stores elicited by phospholipase C-linked receptors for ATP and acetylcholine as well as by caffeine. CaM kinase mediates the actions of many neurotransmitters and Ca2+ signaling pathways.     

Differential integration of Ca2+-calmodulin signal in intact ventricular myocytes at low and high affinity Ca2+-calmodulin targets

Cardiac myocyte intracellular calcium varies beat-to-beat and calmodulin (CaM) transduces Ca2+ signals to regulate many cellular processes (e.g. via CaM targets such as CaM-dependent kinase and calcineurin). However, little is known about the dynamics of how CaM targets process the Ca2+ signals to generate appropriate biological responses in the heart. We hypothesized that the different affinities of CaM targets for the Ca2+-bound CaM (Ca2+-CaM) shape their actions through dynamic and tonic interactions in response to the repetitive Ca2+ signals in myocytes. To test our hypothesis, we used two fluorescence resonance energy transfer-based biosensors, BsCaM-45 (Kd = approximately 45 nm) and BsCaM-2 (Kd = approximately 2 nm), to monitor the real time Ca2+-CaM dynamics at low and high affinity CaM targets in paced adult ventricular myocytes. Compared with BsCaM-2, BsCaM-45 tracks the beat-to-beat Ca2+-CaM alterations more closely following the Ca2+ oscillations at each myocyte contraction. When pacing frequency is raised from 0.1 to 1.0 Hz, the higher affinity BsCaM-2 demonstrates significant elevation of diastolic Ca2+-CaM binding compared with the lower affinity BsCaM-45. Biochemically detailed computational models of Ca2+-CaM biosensors in beating cardiac myocytes revealed that the different Ca2+-CaM binding affinities of BsCaM-2 and BsCaM-45 are sufficient to predict their differing kinetics and diastolic integration. Thus, data from both experiments and computational modeling suggest that CaM targets with low versus high Ca2+-CaM affinities (like CaM-dependent kinase versus calcineurin) respond differentially to the same Ca2+ signal (phasic versus integrating), presumably tuned appropriately for their respective and distinct Ca2+ signaling pathways.     

Enhanced dynamic range in a genetically encoded Ca sensor

Genetically encoded fluorescence resonance energy transfer (FRET) indicators are powerful tools for real-time detection of second messenger molecules and activation of signal proteins. However, these fluorescent protein-based sensors typically display marginal FRET efficiency. To improve their FRET efficiency for optical imaging and screening, we developed a number of fluorescent protein mutants based on cyan fluorescent protein (CFP) and yellow fluorescent protein (YFP). To improve FRET ratios, which were initially within a narrow dynamic range, we used DNA shuffling to develop a new FRET pair called 3xCFP/Venus. The optimized 3xCFP/Venus pair exhibited higher FRET ratios than CyPet/YPet, which has one of the greatest dynamic ranges of protein-based FRET pairs. We converted this FRET pair to a Ca²⁺ FRET indicators using circular permutation Venus (cpVenus) linked with 3xCFP to form 3xCFP/cpVenus, which displayed an ∼11-fold change in dynamic range in response to Ca²⁺ binding. The enhanced dynamic range for Ca²⁺ concentration detection using 3xCFP/cpVenus was confirmed in PC12 cells using previously established indicators (TN-XXL, ECFP/cpCitrine). To our knowledge, this FRET pair displays the largest dynamic range so far among genetically-encoded sensors, and can be used for sensitive FRET detection.     

Ca2+/calmodulin-dependent protein kinase II is an essential mediator in the coordinated regulation of electrocyte Ca2+-ATPase by calmodulin and protein kinase A

The aim of this study was to investigate (a) whether Ca2+/calmodulin-dependent protein kinase II (CaM kinase II) participates in the regulation of plasma membrane Ca2+-ATPase and (b) its possible cross-talk with other kinase-mediated modulatory pathways of the pump. Using isolated innervated membranes of the electrocytes from Electrophorus electricus L., we found that stimulation of endogenous protein kinase A (PKA) strongly phosphorylated membrane-bound CaM kinase II with simultaneous substantial activation of the Ca2+ pump (approximately 2-fold). The addition of cAMP (5-50 pM), forskolin (10 nM), or cholera toxin (10 or 100 nM) stimulated both CaM kinase II phosphorylation and Ca2+-ATPase activity, whereas these activation processes were cancelled by an inhibitor of the PKA alpha-catalytic subunit. When CaM kinase II was blocked by its specific inhibitor KN-93, the Ca2+-ATPase activity decreased to the levels measured in the absence of calmodulin; the unusually high Ca2+ affinity dropped 2-fold; and the PKA-mediated stimulation of Ca2+-ATPase was no longer seen. Hydroxylamine-resistant phosphorylation of the Ca2+-ATPase strongly increased when the PKA pathway was activated, and this phosphorylation was suppressed by inhibition of CaM kinase II. We conclude that CaM kinase II is an intermediate in a complex regulatory network of the electrocyte Ca2+ pump, which also involves calmodulin and PKA.     

Localization, purification, and characterization of the rabbit sarcoplasmic reticulum associated calmodulin-dependent protein kinase

The Ca2+/calmodulin dependent protein kinase associated with the sarcoplasmic reticulum membranes (SR CaM kinase) plays a specific and important role in the modulation of both Ca2+ uptake and release functions of the sarcoplasmic reticulum itself. In this work we have localized a 60 kD SR CaM kinase in slow and fast twitch rabbit skeletal muscle fractions; the kinase was present in both the longitudinal and the junctional sarcoplasmic reticulum. We then developed a procedure for the purification of the active kinase from the longitudinal sarcoplasmic reticulum and performed biochemical and functional characterization of the enzyme. Differently from what was previously suggested, our analysis shows that the biochemical properties of the purified SR CaM kinase (Ca2+ sensitivity, K0.5 for calmodulin, Km for ATP, IC50 for the specific inhibitory peptide (290-309), autophosphorylation properties) are not significantly different from those of the soluble multifunctional CaM kinase II. Moreover, we show that the purified SR CaM kinase retains the ability to autophosphorylate in a Ca2+/calmodulin-dependent manner, becoming a Ca2+-independent enzyme. In the light of the knowledge of the rabbit SR CaM kinase biochemical properties, we propose and discuss the possibility that, under physiological conditions, the activity of the autophosphorylated kinase persists when the Ca2+ transient is over.     

Cross-talk between protein kinase C and multifunctional Ca2+/calmodulin-dependent protein kinase.

Protein kinase C (PKC) exhibits both negative and positive cross-talk with multifunctional Ca2+/calmodulin-dependent protein kinase (CaM kinase) in PC12 cells. PKC effects negative cross-talk by inhibiting the mobilization of intracellular Ca2+ stores and by inhibiting Ca2+ influx through voltage-sensitive Ca2+ channels. In the absence of cross-talk, Ca2+ influx induced by depolarization with 56 mM K+ stimulates CaM kinase and its autophosphorylation and converts up to 50% of the enzyme to a Ca(2+)-independent or autonomous species. Acute treatment with phorbol myristate acetate (PMA) elicits a parallel reduction in depolarization-induced Ca2+ influx and in generation of autonomous CaM kinase. Negative cross-talk also occurs during stimulation of the phosphatidylinositol signaling system with bradykinin, which activates both PKC and CaM kinase. The extent of CaM kinase activation is attenuated by the simultaneous activation of PKC; it is enhanced by prior down-regulation of PKC. PKC also exhibits positive cross-talk with CaM kinase. Submaximal activation of CaM kinase by ionomycin is potentiated by concurrent activation of PKC with PMA. Such PMA treatment is found to increase the level of cytosolic calmodulin. Enhanced activation of CaM kinase by PKC may result from PKC-mediated phosphorylation of calmodulin-binding proteins, such as neuromodulin and MARCKS, and the subsequent increase in the availability of previously bound calmodulin for activation of CaM kinase.     

Preassociation of calmodulin with voltage-gated Ca(2+) channels revealed by FRET in single living cells

Among the most intriguing forms of Ca(2+) channel modulation is the regulation of L-type and P/Q-type channels by intracellular Ca(2+), acting via unconventional channel-calmodulin (CaM) interactions. In particular, overexpressing Ca(2+)-insensitive mutant CaM abolishes Ca(2+)-dependent modulation, hinting that Ca(2+)-free CaM may "preassociate" with these channels to enhance detection of local Ca(2+). Despite the far-reaching consequences of this proposal, in vitro experiments testing for preassociation provide conflicting results. Here, we develop a three filter-cube fluorescence resonance energy transfer method (three-cube FRET) to directly probe for constitutive associations between channel subunits and CaM in single living cells. This FRET assay detects Ca(2+)-independent associations between CaM and the pore-forming alpha(1) subunit of L-type, P/Q-type, and, surprisingly, R-type channels. These results now definitively demonstrate channel-CaM preassociation in resting cells and underscore the potential of three-cube FRET for probing protein-protein interactions.     

Single molecule analyses of the conformational substates of calmodulin bound to the phosphorylase kinase complex

The four integral delta subunits of the phosphorylase kinase (PhK) complex are identical to calmodulin (CaM) and confer Ca(2+) sensitivity to the enzyme, but bind independently of Ca(2+). In addition to binding Ca(2+), an obligatory activator of PhK's phosphoryltransferase activity, the delta subunits transmit allosteric signals to PhK's remaining alpha, beta, and gamma subunits in activating the enzyme. Under mild conditions about 10% of the delta subunits can be exchanged for exogenous CaM. In this study, a CaM double-mutant derivatized with a fluorescent donor-acceptor pair (CaM-DA) was exchanged for delta to assess the conformational substates of PhKdelta by single molecule fluorescence resonance energy transfer (FRET) +/-Ca(2+). The exchanged subunits were determined to occupy distinct conformations, depending on the absence or presence of Ca(2+), as observed by alterations of the compact, mid-length, and extended populations of their FRET distance distributions. Specifically, the combined predominant mid-length and less common compact conformations of PhKdelta became less abundant in the presence of Ca(2+), with the delta subunits assuming more extended conformations. This behavior is in contrast to the compact forms commonly observed for many of CaM's Ca(2+)-dependent interactions with other proteins. In addition, the conformational distributions of the exchanged PhKdelta subunits were distinct from those of CaM-DA free in solution, +/-Ca(2+), as well as from exogenous CaM bound to the PhK complex as delta'. The distinction between delta and delta' is that the latter binds only in the presence of Ca(2+), but stoichiometrically and at a different location in the complex than delta.