Mechanism of activation of cyclic nucleotide phosphodiesterase: requirement of the binding of four Ca2+ to calmodulin for activation

Phosphodiesterase 5 inhibition ameliorates angiotensin II-dependent hypertension and renal vascular dysfunction

Changes in renal hemodynamics have a major impact on blood pressure (BP). Angiotensin (Ang) II has been shown to induce vascular dysfunction by interacting with phosphodiesterase (PDE)1 and PDE5. The predominant PDE isoform responsible for renal vascular dysfunction in hypertension is unknown. Here, we measured the effects of PDE5 (sildenafil) or PDE1 (vinpocetine) inhibition on renal blood flow (RBF), BP, and renal vascular function in normotensive and hypertensive mice. During acute short-term Ang II infusion, sildenafil decreased BP and increased RBF in C57BL/6 (WT) mice. In contrast, vinpocetine showed no effect on RBF and BP. Additionally, renal cGMP levels were significantly increased after acute sildenafil but not after vinpocetine infusion, indicating a predominant role of PDE5 in renal vasculature. Furthermore, chronic Ang II infusion (500 ng·kg^-1·min^-1) increased BP and led to impaired NO-dependent vasodilation in kidneys of WT mice. Additional treatment with sildenafil (100 mg·kg^-1·day^-1) attenuated Ang II-dependent hypertension and improved NO-mediated vasodilation. During chronic Ang II infusion, urinary nitrite excretion, a marker for renal NO generation, was increased in WT mice, whereas renal cGMP generation was decreased and restored after sildenafil treatment, suggesting a preserved cGMP signaling after PDE5 inhibition. To investigate the dependency of PDE5 effects on NO/cGMP signaling, we next analyzed eNOS-KO mice, a mouse model characterized by low vascular NO/cGMP levels. In eNOS-KO mice, chronic Ang II infusion increased BP but did not impair NO-mediated vasodilation. Moreover, sildenafil did not influence BP or vascular function in eNOS-KO mice. These results highlight PDE5 as a key regulator of renal hemodynamics in hypertension.

A novel calmodulin-β-PIX interaction and its implication in receptor tyrosine kinase regulation

Calmodulin (CaM), a ubiquitous calcium-binding protein, regulates numerous cellular processes, primarily in response to calcium flux. We have identified and characterized a novel interaction between CaM and β-p21-activated kinase interacting exchange factor (β-PIX), a putative guanine exchange factor implicated in cell signaling, using affinity pull-down assays, co-immunoprecipitation, co-localization and circular dichroism studies. Fluorescence-based titration and isothermal titration calorimetry experiments revealed a Ca(2+)-dependent binding mechanism (K(D)≤10μM). Further, we show that CaM participates in a multi-protein complex involving β-PIX and E3 ubiquitin ligase c-Cbl (casitas B-cell lymphoma), which may play a critical role in receptor tyrosine kinase regulation and downstream signaling.

Characterisation of Calmodulin Structural Transitions by Ion Mobility Mass Spectrometry

This study demonstrates the ability of travelling wave ion mobility-mass spectrometry to measure collision cross-sections of ions in the negative mode, using a calibration based approach. Here, negative mode ion mobility-mass spectrometry was utilised to understand structural transitions of calmodulin upon Ca2+ binding and complexation with model peptides melittin and the plasma membrane Ca2+ pump C20W peptide. Coexisting calmodulin conformers were distinguished on the basis of their mass and cross-section, and identified as relatively folded and unfolded populations, with good agreement in collision cross-section to known calmodulin geometries. Titration of calcium tartrate to physiologically relevant Ca2+ levels provided evidence for intermediately metalated species during the transition from apo- to holo-calmodulin, with collision cross-section measurements indicating that higher Ca2+ occupancy is correlated with more compact structures. The binding of two representative peptides which exemplify canonical compact (melittin) and extended (C20W) peptide-calmodulin binding models has also been interrogated by ion mobility mass spectrometry. Peptide binding to calmodulin involves intermediates with metalation states from 1–4 Ca2+, which demonstrate relatively collapsed structures, suggesting neither the existence of holo-calmodulin or a pre-folded calmodulin conformation is a prerequisite for binding target peptides or proteins. The biological importance of the different metal unsaturated calmodulin complexes, if any, is yet to be understood.

Decreased cGMP level contributes to increased contraction in arteries from hypertensive rats: role of phosphodiesterase 1

Recent evidence suggests that angiotensin II (Ang II) upregulates phosphodiesterase (PDE) 1A expression. We hypothesized that Ang II augmented PDE1 activation, decreasing the bioavailability of cyclic guanosine 3' 5'-monophosphate (cGMP), and contributing to increased vascular contractility. Male Sprague-Dawley rats received mini-osmotic pumps with Ang II (60 ng·min(-1)) or saline for 14 days. Phenylephrine (PE)-induced contractions were increased in aorta (E(max)168% ± 8% vs 136% ± 4%) and small mesenteric arteries (SMA; E(max)170% ± 6% vs 143% ± 3%) from Ang II-infused rats compared to control. PDE1 inhibition with vinpocetine (10 μmol/L) reduced PE-induced contraction in aortas from Ang II rats (E(max)94% ± 12%) but not in controls (154% ± 7%). Vinpocetine decreased the sensitivity to PE in SMA from Ang II rats compared to vehicle (-log of half maximal effective concentration 5.1 ± 0.1 vs 5.9 ± 0.06), but not in controls (6.0 ± 0.03 vs 6.1 ± 0.04). Sildenafil (10 μmol/L), a PDE5 inhibitor, reduced PE-induced maximal contraction similarly in Ang II and control rats. Arteries were contracted with PE (1 μmol/L), and concentration-dependent relaxation to vinpocetine and sildenafil was evaluated. Aortas from Ang II rats displayed increased relaxation to vinpocetine compared to control (E(max)82% ± 12% vs 445 ± 5%). SMA from Ang II rats showed greater sensitivity during vinpocetine-induced relaxation compared to control (-log of half maximal effective concentration 6.1 ± 0.3 vs 5.3 ± 0.1). No differences in sildenafil-induced relaxation were observed. PDE1A and PDE1C expressions in aorta and PDE1A expression in SMA were increased in Ang II rats. cGMP production, which is decreased in arteries from Ang II rats, was restored after PDE1 blockade. We conclude that PDE1 activation reduces cGMP bioavailability in arteries from Ang II, contributing to increased contractile responsiveness.

Spatial diffusivity and availability of intracellular calmodulin

Calmodulin (CaM) is the major pathway that transduces intracellular Ca2+ increases to the activation of a wide variety of downstream signaling enzymes. CaM and its target proteins form an integrated signaling network believed to be tuned spatially and temporally to control CaM's ability to appropriately pass signaling events downstream. Here, we report the spatial diffusivity and availability of CaM labeled with enhanced green fluorescent protein (eGFP)-CaM, at basal and elevated Ca2+,quantified by the novel fluorescent techniques of raster image scanning spectroscopy and number and brightness analysis. Our results show that in basal Ca2+ conditions cytoplasmic eGFP-CaM diffuses at a rate of 10 microm(2)/s, twofold slower than the noninteracting tracer, eGFP, indicating that a significant fraction of CaM is diffusing bound to other partners. The diffusion rate of eGFP-CaM is reduced to 7 microm(2)/s when a large (646 kDa) target protein Ca2+/CaM-dependent protein kinase II is coexpressed in the cells. In addition, the presence of Ca2+/calmodulin-dependent protein kinase II, which can bind up to 12 CaM molecules per holoenzyme, increases the stoichiometry of binding to an average of 3 CaMs per diffusive molecule. Elevating intracellular Ca2+ did not have a major impact on the diffusion of CaM complexes. These results present us with a model whereby CaM is spatially modulated by target proteins and support the hypothesis that CaM availability is a limiting factor in the network of CaM-signaling enzymes.

Regulation of the calcium signal by calmodulin

Stimulus-response coupling mediated by calmodulin involves several steps: a transitory increase in calcium concentration from 0.1 to 10 microM, induced by external stimuli; interaction of calcium with calmodulin, accompanied by stepwise structural transitions; the coordinated interaction with and activation of the many calmodulin-regulated enzymes and proteins. The binding of calcium to calmodulin is a cooperative and selective process that is modulated by magnesium. At physiological ionic strength, and only in the presence of magnesium, a large difference is seen between the affinities of sites III and IV (0.09 X 10(6) M-1) and sites I and II (0.0007 X 10(6) M-1) for calcium. This difference, together with the positive cooperativity previously observed, explains the stepwise conformational changes induced by calcium. The interaction of calmodulin with its target proteins requires the integrity of different portions of the calmodulin molecule. Calmodulin-regulated enzymes can be divided into three classes according to their abilities to bind with and to be activated by calmodulin fragments: enzymes which are activated by the C-terminal fragment, such as the Ca2+-ATPase and phosphorylase kinase; enzymes which require both halves of the molecule, such as cyclic AMP phosphodiesterase and myosin light chain kinase; and enzymes whose interaction with calmodulin fragments is too weak to be detected by activation, such as calcineurin and the multiprotein kinase. Thus different enzymes may be activated by different calmodulin conformers and the stepwise changes exhibited by calmodulin at different calcium levels can be used to regulate different metabolic pathways.

Cyclic nucleotide phosphodiesterase (PDE) superfamily: a new target for the development of specific therapeutic agents

Cyclic nucleotide phosphodiesterases (PDEs), which are ubiquitously distributed in mammalian tissues, play a major role in cell signaling by hydrolyzing cAMP and cGMP. Due to their diversity, which allows specific distribution at cellular and subcellular levels, PDEs can selectively regulate various cellular functions. Their critical role in intracellular signaling has recently designated them as new therapeutic targets for inflammation. The PDE superfamily represents 11 gene families (PDE1 to PDE11). Each family encompasses 1 to 4 distinct genes, to give more than 20 genes in mammals encoding the more than 50 different PDE proteins probably produced in mammalian cells. Although PDE1 to PDE6 were the first well-characterized isoforms because of their predominance in various tissues and cells, their specific contribution to tissue function and their regulation in pathophysiology remain open research fields. This concerns particularly the newly discovered families, PDE7 to PDE11, for which roles are not yet established. In many pathologies, such as inflammation, neurodegeneration, and cancer, alterations in intracellular signaling related to PDE deregulation may explain the difficulties observed in the prevention and treatment of these pathologies. By inhibiting specifically the up-regulated PDE isozyme(s) with newly synthesized potent and isozyme-selective PDE inhibitors, it may be potentially possible to restore normal intracellular signaling selectively, providing therapy with reduced adverse effects.

Alcohols increase calmodulin affinity for Ca2+ and decrease target affinity for calmodulin

It has been proposed that alcohols and anesthetics selectively inhibit proteins containing easily disrupted motifs, e.g., alpha-helices. In this study, the calcineurin/calmodulin/Ca(2+) enzyme system was used to examine the effects of alcohols on calmodulin, a protein with a predominantly alpha-helical structure. Calcineurin phosphatase activity and Ca(2+) binding were monitored as indicators of calmodulin function. Alcohols inhibited enzyme activity in a concentration-dependent manner, with two-, four- and five-carbon n-alcohols exhibiting similar leftward shifts in the inhibition curves for calmodulin-dependent and -independent activities; the former was slightly more sensitive than the latter. Ca(2+) binding was measured by flow dialysis as a direct measure of calmodulin function, whereas, with the addition of a binding domain peptide, measured calmodulin-target interactions. Ethanol increased the affinity of calmodulin for Ca(2+) in the presence and absence of the peptide, indicating that ethanol stabilizes the Ca(2+) bound form of calmodulin. An increase in Ca(2+) affinity was detected in a calmodulin binding assay, but the affinity of calmodulin for calcineurin decreased at saturating Ca(2+). These data demonstrate that although specific regions within proteins may be more sensitive to alcohols and anesthetics, the presence of alpha-helices is unlikely to be a reliable indicator of alcohol or anesthetic potency.

Calcium dependence of the interaction between calmodulin and anthrax edema factor

Edema factor (EF), a toxin from Bacillus anthracis (anthrax), possesses adenylyl cyclase activity and requires the ubiquitous Ca2+-sensor calmodulin (CaM) for activity. CaM can exist in three major structural states: an apo state with no Ca2+ bound, a two Ca2+ state with its C-terminal domain Ca2+-loaded, and a four Ca2+ state in which the lower Ca2+ affinity N-terminal domain is also ligated. Here, the interaction of EF with the three Ca2+ states of CaM has been examined by NMR spectroscopy and changes in the Ca2+ affinity of CaM in the presence of EF have been determined by flow dialysis. Backbone chemical shift perturbations of CaM show that EF interacts weakly with the N-terminal domain of apoCaM. The C-terminal CaM domain only engages in the interaction upon Ca2+ ligation, rendering the overall interaction much tighter. In the presence of EF, the C-terminal domain binds Ca2+ with higher affinity, but loses binding cooperativity, whereas the N-terminal domain exhibits strongly reduced Ca2+ affinity. As judged by chemical shift differences, the N-terminal CaM domain remains bound to EF upon subsequent Ca2+ ligation. This Ca2+ dependence of the EF-CaM interaction differs from that observed for most other CaM targets, which normally interact only with the Ca2+-bound CaM domains and become active following the transition to the four Ca2+ state.

Modulation of the Ras/Raf/MEK/ERK pathway by Ca(2+), and calmodulin

Ras activation induces a variety of cellular responses that depend on the specific activated effector, the intensity and amplitude of its activation, and the cellular type. Transient activation followed by a sustained but low signal of the Ras/Raf/MEK/ERK pathway is a common feature of cell proliferation in many systems. On the contrary, sustained, high activation is linked with either senescence or apoptosis in fibroblasts and to differentiation in neurones and PC12 cells. The temporal regulation of the pathway is relevant and not only depends on the specific receptor activated but also on the presence of diverse modulators of the pathway. We review here evidence showing that calcium (Ca(2+)) and calmodulin (CaM) are able to regulate the Ras/Raf/MEK/ERK pathway. CaM-binding proteins (CaMBPs) as Ras-GRF and CaM-dependent protein kinase IV (CaMKIV) positively modulate ERK1/2 activation induced by either NGF or membrane depolarisation in neurones. In fibroblasts, CaM binding to EGF receptor and K-Ras(B) may be involved in the downregulation of the pathway after its activation, allowing a proliferative signalling.

Bistability in the Ca(2+)/calmodulin-dependent protein kinase-phosphatase system

A mathematical model is presented of autophosphorylation of Ca(2+)/calmodulin-dependent protein kinase (CaMKII) and its dephosphorylation by a phosphatase. If the total concentration of CaMKII subunits is significantly higher than the phosphatase Michaelis constant, two stable steady states of the CaMKII autophosphorylation can exist in a Ca(2+) concentration range from below the resting value of the intracellular [Ca(2+)] to the threshold concentration for induction of long-term potentiation (LTP). Bistability is a robust phenomenon, it occurs over a wide range of parameters of the model. Ca(2+) transients that switch CaMKII from the low-phosphorylated state to the high-phosphorylated one are in the same range of amplitudes and frequencies as the Ca(2+) transients that induce LTP. These results show that the CaMKII-phosphatase bistability may play an important role in long-term synaptic modifications. They also suggest a plausible explanation for the very high concentrations of CaMKII found in postsynaptic densities of cerebral neurons.

The relationship between the free concentrations of Ca2+ and Ca2+-calmodulin in intact cells

Using stably expressed fluorescent indicator proteins, we have determined for the first time the relationship between the free Ca2+ and Ca2+-calmodulin concentrations in intact cells. A similar relationship is obtained when the free Ca2+ concentration is externally buffered or when it is transiently increased in response to a Ca2+-mobilizing agonist. Below a free Ca2+ concentration of 0.2 microM, no Ca2+-calmodulin is detectable. A global maximum free Ca2+-calmodulin concentration of approximately 45 nM is produced when the free Ca2+ concentration exceeds 3 microM, and a half-maximal concentration is produced at a free Ca2+ concentration of 1 microM. Data for fractional saturation of the indicators suggest that the total concentration of calmodulin-binding proteins is approximately 2-fold higher than the total calmodulin concentration. We conclude that high-affinity calmodulin targets (Kd </= 10 nM) are efficiently activated throughout the cell, but efficient activation of low-affinity targets (Kd >/= 100 nM) occurs only where free Ca2+-calmodulin concentrations can be locally enhanced.

Direct modulation of calmodulin targets by the neuronal calcium sensor NCS-1

Ca2+ and its ubiquitous intracellular receptor calmodulin (CaM) are required in the nervous system, among a host of cellular responses, for the modulation of several important enzymes and ion channels involved in synaptic efficacy and neuronal plasticity. Here, we report that CaM can be replaced by the neuronal calcium sensor NCS-1 both in vitro and in vivo. NCS-1 is a calcium binding protein with two Ca(2+)-binding domains that shares only 21% of homology with CaM. We observe that NCS-1 directly activates two Ca2+/CaM-dependent enzymes (3':5'-cyclic nucleotide phosphodiesterase and protein phosphatase calcineurin). Co-activation of nitric oxide synthase by NCS-1 and CaM results in a higher activity than with CaM alone. Moreover, NCS-1 is coexpressed with calcineurin and nitric oxide synthase in several neuron populations. Finally, injections of NCS-1 into calmodulin-defective cam1 Paramecium partially restore wildtype behavioral responses. With this highly purified preparation of NCS-1, we have obtained crystals suitable for crystallographic structure studies. NCS-1, despite its very different structure, distribution, and Ca(2+)-binding affinity as compared with CaM, can substitute for or potentiate CaM functions. Therefore, NCS-1 represents a novel protein capable of mediating multiple Ca(2+)-signaling pathways in the nervous system.

Calmodulin: effects of cell stimuli and drugs on cellular activation

The activity, localization and cellular content of CaM can be regulated by drugs, hormones and neurotransmitters. Regulation of physiological responses of CaM can depend upon local Ca(2+)-entry domains in the cells and phosphorylation of CaM target proteins, which would either decrease responsiveness of CaM target enzymes or increase CaM availability for binding to other target proteins. Despite the abundance of CaM in many cells, persistent cellular activation by a variety of substances can lead to an increase in CaM, reflected both in the nucleus and other cellular compartments. Increases in CaM-binding proteins can accompany stimuli-induced increases in CaM. A role for CaM in vesicular or protein transport, cell morphology, secretion and other cytoskeletal processes is emerging through its binding to cytoskeletal proteins and myosins in addition to the more often investigated activation of target enzymes. More complete knowledge of the physiological regulation of CaM can lead to a greater understanding of its role in physiological processes and ways to alter its actions through pharmacology.

Dual calcium ion regulation of calcineurin by calmodulin and calcineurin B

The dependence of calcineurin on Ca2+ for activity is the result of the concerted action of calmodulin, which increases the turnover rate of the enzyme and modulates its response to Ca2+ transients, and of calcineurin B, which decreases the Km of the enzyme for its substrate. The calmodulin-stimulated protein phosphatase calcineurin is under the control of two functionally distinct, but structurally similar, Ca(2+)-regulated proteins, calmodulin and calcineurin B. The Ca(2+)-dependent activation of calcineurin by calmodulin is highly cooperative (Hill coefficient of 2.8-3), and the concentration of Ca2+ needed for half-maximum activation decreases from 1.3 to 0.6 microM when the concentration of calmodulin is increased from 0.03 to 20 microM. Conversely, the affinity of calmodulin for Ca2+ is increased by more than 2 orders of magnitude in the presence of a peptide corresponding to the calmodulin-binding domain of calcineurin A. Calmodulin increases the Vmax without changing the Km value of the enzyme. Unlike calmodulin, calcineurin B interacts with calcineurin A in the presence of EGTA, and Ca2+ binding to calcineurin B stimulates native calcineurin up to only 10% of the maximum activity achieved with calmodulin. The Ca(2+)-dependent activation of a proteolyzed derivative of calcineurin, calcineurin-45, which lacks the regulatory domain, was used to study the role of calcineurin B. Removal of the regulatory domain increases the Vmax of calcineurin, as does binding of calmodulin, but it also increases the affinity of calcineurin for Ca2+. Ca2+ binding to calcineurin B decreases the Km value of calcineurin without changing its Vmax.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of calmodulin-dependent cyclic nucleotide phosphodiesterase isoenzymes

Calmodulin-dependent phosphodiesterase (CaMPDE) is one of the key enzymes involved in the complex interactions which occur between the cyclic-nucleotide and Ca2+ second-messenger systems. Calmodulin-dependent phosphodiesterase exists in different isoenzymic forms, which exhibit distinct molecular and/or catalytic properties. The kinetic properties suggest that the 63 kDa brain isoenzyme is distinct from the brain 60 kDa and heart and lung CaMPDE isoenzymes. The CaMPDE isoenzymes of 60 kDa from brain, heart and lung are regulated by calmodulin, but the affinities for calmodulin are different. At identical concentrations of calmodulin, the bovine heart CaMPDE isoenzyme is stimulated at a much lower Ca2+ concentration than the bovine brain or lung isoenzymes. The bovine lung CaMPDE isoenzyme contains calmodulin as a tightly bound subunit, so that a change in calmodulin concentration had no effect on the [Ca2+]-dependence of activation of this isoenzyme. These observations are consistent with the notion that differential regulation by calmodulin and Ca2+ is an important function of these isoenzymes, which provide fine-tuning mechanisms for calmodulin action.

Calmodulin mediates melatonin cytoskeletal effects

In this article, we review the data concerning melatonin interactions with calmodulin. The kinetics of melatonin-calmodulin binding suggest that the hormone modulates cell activity through intracellular binding to the protein at physiological concentration ranges. Melatonin interaction with calmodulin may allow the hormone to modulate rhythmically many cellular functions. Melatonin's effect on tubulin polymerization, and cytoskeletal changes in MDCK and N1E-115 cells cultured with melatonin, suggest that at low concentrations (10(-9) M) cytoskeletal effects are mediated by its antagonism to Ca2+-calmodulin. At higher concentrations (10(-5)M) non-specific binding of melatonin to tubulin occurs thus overcoming the specific melatonin antagonism to Ca2+-calmodulin. Since the structures of melatonin and calmodulin are phylogenetically well preserved, calmodulin-melatonin interaction probably represents a major mechanism for regulation and synchronization of cell physiology.

Mechanisms of antagonistic action of internal Ca2+ on serotonin-induced potentiation of Ca2+ currents in Helix neurones

The influence of internal Ca2+ ions has been investigated during intracellular perfusion of isolated neurones from pedal ganglia of Helix pomatia in which serotonin (5-HT) induces a cyclic-adenosine-monophosphate-(cAMP)-dependent enhancement of high-threshold Ca2+ current (ICa). Internal free Ca2+ ([Ca2+]i) was varied between 0.01 and 10 microM by addition of Ca(2+)-EGTA [ethylenebis(oxonitrilo)tetraacetate] buffer. Elevation of [Ca2+]i depressed the 5-HT effect. The dose/effect curve for the Ca2+ blockade had a biphasic character and could be described by the sum of two Langmuir's isotherms for tetramolecular binding with dissociation constants Kd1 = 0.063 microM and Kd2 = 1 microM. Addition of calmodulin (CM) antagonists (50 microM trifluoperazine or 50 microM chlorpromazine), phosphodiesterase (PDE) antagonists [100 microM isobutylmethylxanthine (IBMX) or 5 mM theophylline] and protein phosphatase antagonists [2 microM okadaic acid (OA)] in the perfusion solution caused "anticalcium" action and modified the Ca2+ binding isotherm. Using the effect of OA and IBMX, two components of the total Ca2+ inhibition were separated and evaluated. In the presence of one of these blockers tetramolecular curves with Kd1 = 0.04 microM and Kd2 = 0.69 microM were obtained describing the activation of the retained unblocked enzyme--PDE or calcineurin (CN) correspondingly. The sum of these isotherms gave a biphasic curve similar to that in control. Leupeptin (100 microM), a blocker of Ca(2+)-dependent proteases did not influence the amplitude of 5-HT effect, indicating that channel proteolysis is not involved in the depression. Our findings show that the molecular mechanism of Ca(2+)-induced suppression of the cAMP-dependent upregulation of Ca2+ channels is due to involvement of two Ca(2+)-CM-dependent enzymes: PDE reducing the cAMP level, and CN causing channel dephosphorylation. No other processes are involved in the investigated phenomenon at a Ca2+ concentration of less than or equal to 10 microM.

Calcium influxes and calmodulin modulate the expression and physicochemical properties of acetylcholinesterase molecular forms during development in vivo

1. Acetylcholinesterase (AcChoE; EC 3.1.1.7) exists in several molecular forms that may be anchored to cell membranes or associated with extracellular matrix. AcChoE bound to lipidic membranes is detergent extractable (DE AcChoE), whereas the enzyme associated with extracellular matrix is high salt soluble (HSS AcChoE). The latter variant is accumulated in synaptic regions by an unknown mechanism. 2. We have suggested previously that depolarization-induced Ca2+ influx is a major factor that modulates AcChoE synthesis in vivo, as well as the conversion of some DE AcChoE to HSS variant. In the present study, we have examined (i) the effects of depolarization-induced skeletal muscle inactivity and ionophore-induced Ca2+ influxes on the expression of AcChoE molecular forms and (ii) the hypothesis that Ca(2+)-dependent calmodulin may be involved in the conversion of at least some forms of DE AcChoE to HSS variant in vivo. 3. Chick embryos were treated in ovo during the early period of nerve-muscle interactions with d-tubocurarine (dTC; a competitive neuromuscular blocking agent) or with decamethonium (dMET; a depolarizing agent). Both dTC and dMET equally and significantly reduced embryonic neuromuscular activity (motility). However, dTC significantly decreased AcChoE overall activity, whereas dMET had virtually no effect on AcChoE expression, compared to controls. 4. Treatment of embryos with the Ca2+ ionophore A23187 significantly increased the total AcChoE activity as well as the DE/HSS ratio of each AcChoE molecular form. However, treatment with N-(6-Aminohexyl)-5-chloro-1-naphthalenesulfonamide (also termed W-7), a calmodulin antagonist, did not alter the total AcChoE activity, but significantly increased the DE/HSS ratio of AcChoE forms. 5. These results support the idea that (i) depolarization and/or Ca2+ influxes, but not muscle contraction, may regulate AcChoE expression in skeletal muscle and (ii) Ca(2+)-dependent calmodulin activation may be involved in the conversion of some DE AcChoE to their HSS variant in vivo.

Fluorescence anisotropy imaging microscopy maps calmodulin binding during cellular contraction and locomotion

Calmodulin is a calcium transducer that activates key regulatory and structural proteins through calcium-induced binding to the target proteins. A fluorescent analog of calmodulin in conjunction with ratio imaging, relative to a volume indicator, has demonstrated that calmodulin is uniformly distributed in serum-deprived fibroblasts and there is no immediate change in the distribution upon stimulation with complete serum. The same fluorescent analog of calmodulin together with steady state fluorescence anisotropy imaging microscopy has been used to define the temporal and spatial changes in calmodulin binding to cellular targets during stimulation of serum-deprived fibroblasts and in polarized fibroblasts during wound healing. In serum-deprived fibroblasts, which exhibit a low free calcium ion concentration, a majority of the fluorescent analog of calmodulin remained unbound (fraction bound, fB < 10%). However, upon stimulation of the serum-deprived cells with complete serum, calmodulin binding (maximum fB approximately 95%) was directly correlated with the time course of the elevation and decline of the free calcium ion concentration, while the contraction of stress fibers continued for an hour or more. Calmodulin binding was also elevated in the leading lamellae of fibroblasts (maximum FB approximately 50%) during the lamellar contraction phase of wound healing and was spatially correlated with the contraction of transverse fibers containing myosin II. Highly polarized and motile fibroblasts exhibited the highest anisotropy (calmodulin binding) in the retracting tails and in association with contracting transverse fibers in the cortex of the cell. These results suggest that local activation of myosin II-based contractions involves the local binding of calmodulin to target proteins. The results also demonstrate a powerful yet simple mode of light microscopy that will be valuable for mapping molecular binding of suitably labeled macromolecules in living cells.

Purification and characterization of bovine brain calmodulin-dependent protein kinase. II. The significance of autophosphorylation in the regulation of 63 kDa calmodulin-dependent cyclic nucleotide phosphodiesterase isozyme

Bovine brain contains two calmodulin-dependent phosphodiesterase kinases which are separated on Sephacryl S-300 column. One of these kinases has been purified to homogeneity and shown to belong to the calmodulin-dependent protein kinase II family. Phosphorylation of the 63 kDa phosphodiesterase by this purified protein kinase results in the incorporation of 1.0 mol phosphate per mol subunit and an accompanying increase in Ca2+ concentrations required for the phosphodiesterase activation by calmodulin. The protein kinase undergoes autophosphorylation to incorporate 1.0 mol phosphate per mol of subunit of the enzyme and the autophosphorylated enzyme is active, independent of the presence of Ca2+. The autophosphorylation reaction as well as the protein kinase reaction are rendered Ca2+ independent in less than 15 seconds when approximately one mol phosphate per mol protein kinase is incorporated. The result suggests that activation of phosphodiesterase phosphorylation reaction may occur prior to the activation of phosphodiesterase and phosphatase during a cell Ca2+ flux via the protein kinase autophosphorylation mechanism.

A fluorescence temperature-jump study on Ca2(+)-induced conformational changes in calmodulin

Calmodulin has been shown to alter its conformation so as to interact with a number of target proteins upon Ca2+ binding. A Ca2(+)-binding study of calmodulin was performed by monitoring the fluorescence of intrinsic tyrosine residues and the probe 1-anilinonaphthalene-8-sulfonate (ANS). ANS fluorescence was shown to reflect Ca2+ binding to both high- and low-affinity sites. On the one hand, tyrosine fluorescence was sensitive only to the high-affinity Ca2+ binding. Temperature-jump investigation of the ternary complex of Ca2(+)-calmodulin-ANS in combination with monitoring of ANS fluorescence demonstrated the kinetic characteristics of the conformational change. The relaxation process was attributed to Ca2(+)-induced conformational change and the rate constants of this process were evaluated. On the basis of the rate constants of the conformational change, a rapid response of calmodulin in Ca2+ signaling is suggested.

Spontaneous and evoked quantal neurotransmitter release at the neuromuscular junction of the larval housefly, Musca domestica

The release of neurotransmitter was monitored at the neuromuscular junctions of larval housefly ventrolateral muscles 6a and 7a, using intracellular recording, and a loose patch clamp technique to isolate discrete release sites. Transmitter release occurred spontaneously and could also be evoked by neural stimuli. Spontaneous discharges consisted of events which were randomly distributed in time and of bursts of temporally ordered events. Evoked and spontaneous release occurred in a quantal manner. The quantal content of evoked excitatory postsynaptic currents (EPSCs) was dependent upon the extracellular calcium concentration, increasing with a 3.8 power dependency. The relationship between the quantal content of a response and extracellular calcium concentration was offset by the presence of magnesium in the bathing saline. The rates of decay of miniature EPSCs (mEPSCs) and EPSCs were also found to increase with extracellular calcium concentration, consistent with a non-diffusion limited block of the glutamate receptor-channel complex by calcium ions (KB 2.5 x 10(4) s-1 M-1, P less than 0.01). The frequency of random mEPSCs (0.26 +/- 0.32 Hz, n = 24 cells) was independent of the extracellular calcium concentration. Random mEPSCs were not inhibited by 1 microM tetrodotoxin which blocked mEPSC bursts and neurally evoked responses. EPSCs evoked during mEPSC bursts had a significantly lower quantal content than those EPSCs recorded from the same nerve terminal between bursting, indicating that both of these forms of release recruited quanta from a common pool of transmitter. Following a neurally evoked EPSC the mEPSC frequency was potentiated severalfold, this delayed release was influenced by EPSCs with large quantal contents evoked in saline containing elevated calcium concentrations.(ABSTRACT TRUNCATED AT 250 WORDS)

Computational and site-specific mutagenesis analyses of the asymmetric charge distribution on calmodulin

Calmodulin's calculated electrostatic potential surface is asymmetrically distributed about the molecule. Concentrations of uncompensated negative charge are localized near certain alpha-helices and calcium-binding loops. Further calculations suggest that these charge features of calmodulin can be selectively perturbed by changing clusters of phylogenetically conserved acidic amino acids in helices to lysines. When these cluster charge reversals are actually produced by using cassette-based site-specific mutagenesis of residues 82-84 or 118-120, the resulting proteins differ in their interaction with two distinct calmodulin-dependent protein kinases, myosin light chain kinase and calmodulin-dependent protein kinase II. Each calmodulin mutant can be purified to apparent chemical homogeneity by an identical purification protocol that is based on conservation of its overall properties, including calcium binding. Although cluster charge reversals result in localized perturbations of the computed negative surface, single amino acid changes would not be expected to alter significantly the distribution of the negative surface because of the relatively high density of uncompensated negative charge in the region around residues 82-84 and 118-120. However, this does not preclude the possibility of single amino acid charge perturbations having a functional effect on the more intimate, catalytically active complex. The electrostatic surface of calmodulin described in this report may be a feature that would be altered only by cluster charge reversal mutations. Overall, the results suggest that the charge properties of calmodulin are one of several properties that are important for the efficient assembly of calmodulin-protein kinase signal transduction complexes in eukaryotic cells.

TRH and BAY K 8644 synergistically stimulate prolactin release but not 45Ca2+ uptake

Thyrotropin-releasing hormone (TRH) (1 microM) and the Ca2+-channel agonist BAY K 8644 (1 microM) each induced transient increases in prolactin secretion from primary cultures of rat anterior pituitary cells in perifusion. When BAY K 8644 was added after a TRH-induced secretory peak, the additional effect of BAY K 8644 on prolactin release was approximately twofold greater over a 30-min period than the effect of BAY K 8644 on previously untreated cells. TRH and BAY K 8644 were also synergistic when added in the opposite order or simultaneously. Substitution of other agents for BAY K 8644 revealed that only high K+ (40 mM) was at least additive with TRH in stimulating prolactin secretion; treatment with TRH inhibited, rather than facilitated, subsequent stimulation of prolactin secretion by angiotensin II (100 nM) or the ionophore A23187 (20 microM). The cooperative effect was not specific for TRH because BAY K 8644 also acted synergistically with angiotensin II or 40 mM K+. In GH4C1 cells, in which TRH and BAY K 8644 were also synergistic in releasing prolactin, measurements with the fluorescent indicator indo-1 showed that TRH and BAY K 8644 could each elevate cytosolic Ca2+ above the level stimulated by the other. Unexpectedly, TRH was found to inhibit BAY K 8644-stimulated 45Ca2+ uptake in both GH4C1 and primary cultured cells. These results indicate that BAY K 8644 and TRH synergistically stimulate prolactin secretion by a mechanism other than a cooperative effect on the activity of dihydropyridine-sensitive Ca2+ channels.

Feasibility of long-term storage of graded information by the Ca2+/calmodulin-dependent protein kinase molecules of the postsynaptic density

The feasibility of long-term information storage by brain type II Ca2+/calmodulin-dependent protein kinase molecules is explored. Recent evidence indicates that this protein has switch-like properties. Equations are derived showing that a single kinase holoenzyme could form a bistable switch having the stability necessary to encode long-term memory, and that a group of kinase molecules, such as that contained within the postsynaptic density, could form a device capable of storing graded information.

Calcium release from calmodulin and its C-terminal or N-terminal halves in the presence of the calmodulin antagonists phenoxybenzamine and melittin measured by stopped-flow fluorescence with Quin 2 and intrinsic tyrosine. Inhibition of calmodulin-dependent protein kinase of cardiac sarcoplasmic reticulum

Calcium dissociation from the C-terminal and N-terminal halves of calmodulin, intact bovine brain calmodulin and the respective phenoxybenzamine complexes or melittin complexes was measured directly by stopped-flow fluorescence with the calcium chelator Quin 2 and, when possible, also by protein fluorescence using endogenous tyrosine fluorescence by mixing with EGTA. Calcium dissociation from the C-terminal half of calmodulin, which contains only the two high-affinity calcium-binding sites, and from intact calmodulin was monophasic, with good correlation of the rates of calcium dissociation obtained by the two methods. The apparent rates with Quin 2 and endogenous tyrosine fluorescence were 13.4 s-1 and 12.8 s-1, respectively, in the C-terminal half and 10.5 s-1 and 10.8 s-1, respectively, in intact calmodulin (pH 7.0, 25 degrees C, 100 mM KCl). Alkylation of the C-terminal half resulted in a biphasic calcium dissociation (Quin 2: kobs 1.90 s-1 and 0.73 s-1 respectively; tyrosine: kobs 1.65 s-1 and 0.61 s-1 respectively). Alkylation of intact calmodulin resulted in a four-phase calcium dissociation measured with Quin 2 (kobs 85.3 s-1, 11.1 s-1, 1.92 s-1 and 0.59 s-1); the latter two phases are assumed to represent calcium release from high-affinity sites since they correspond to the biphasic tyrosine fluorescence change in intact alkylated calmodulin (kobs 2.04 s-1 and 0.53 s-1 respectively) and the rate parameters determined in the C-terminal half. Evidently perturbation of the calcium-binding sites by alkylation reduces the rate of calcium dissociation and allows a distinction to be made between dissociation from each of the two high-affinity sites as well as the distinct conformational change on dissociation of each calcium. Alkylation of the N-terminal half resulted in biphasic calcium release with rates (kobs 153 s-1 and 10.9 s-1 respectively) similar to those observed in intact alkylated calmodulin. The rates of calcium dissociation from calmodulin-melittin or fragment-melittin complexes, measured with Quin 2, were slower and monophasic in the C-terminal half (kobs 1.12 s-1), biphasic in the N-terminal half (kobs 140 s-1 and 26.8 s-1 respectively) and triphasic in intact calmodulin (kobs 126 s-1, 12.1 s-1 and 1.38 s-1). Calmodulin antagonists thus increase the apparent calcium affinity of high and low-affinity sites mainly due to a reduced calcium 'off rate', presumably because of conformation restrictions.(ABSTRACT TRUNCATED AT 400 WORDS)

Binding of calmodulin to the neuronal cytoskeletal protein kinase type II cooperatively stimulates autophosphorylation

The kinetics of autophosphorylation of the cytoskeletal form of the neuronal calmodulin-dependent protein kinase type II were studied as a function of calmodulin binding under the same conditions. Whereas calmodulin binding was noncooperative with respect to calmodulin concentration (Hill coefficient = 1), the activation of autophosphorylation and the phosphorylation of exogenous substrates showed marked positive cooperativity (Hill coefficient greater than or equal to 1.6). Reduction of the active calmodulin concentration by the addition of the calmodulin antagonist trifluoperazine confirmed the cooperative nature of enzyme activation, because autophosphorylation was more sensitive to the drug than was binding at high concentrations of calmodulin. At intracellular levels of calmodulin the binding and activation of autophosphorylation were cooperative functions of magnesium and calcium concentration. The calmodulin-dependent cooperative activation seems to be a unique feature of the cytoskeletal, but not the soluble, form of the protein kinase and may result from the supramolecular organization of the cytoskeletal enzyme. These observations suggest that interactions among the subunits of the oligomeric cytoskeletal calmodulin-dependent protein kinase regulate enzyme activation, enhancing the sensitivity of the enzyme to small changes in the intracellular calcium levels that may be particularly relevant to signaling at the synapse.

Direct comparison of Ca2+ requirements for calmodulin interaction with and activation of protein phosphatase

The mechanism of Ca2+-dependent protein-protein interaction and enzyme activation by calmodulin was investigated with the phosphoprotein phosphatase, calcineurin. Dimethylaminonaphthalene (dansyl)-calmodulin, a fluorescent derivative used to monitor complex formation, produced similar maximal activation (10- to 12-fold) with a Ca2+ dependence (Ka = 17 microM) identical to that of native calmodulin. The Ca2+-dependent increase in fluorescence intensity of dansyl-calmodulin was enhanced 100-150% by calcineurin, indicating complex formation; the concentration of Ca2+ required for a half-maximal increase in fluorescence was the same (K1/2 approximately equal to 7 microM) with and without calcineurin. Since the Ca2+ concentration required for activation appeared to differ from that necessary for protein-protein interaction, a method was devised to measure both the formation of complexes between dansyl-calmodulin and calcineurin and enzyme activity in the same samples. Direct comparison of interaction (measured by polarization of fluorescence) and enzyme activity demonstrated different Ca2+ requirements for the two events. Whereas dansyl-calmodulin-calcineurin interaction, measured in the presence of phosphoprotein substrate, exhibited very little cooperativity (Hill coefficient = 1.2, Ca2+ concentration required for the half-maximal increase in fluorescence, K1/2, approximately equal to 6 microM), phosphatase activation was highly cooperative (Hill coefficient = 3.5) and required 3 times higher Ca2+ concentration for half-maximal stimulation. Equivalent results were obtained with p-nitrophenyl phosphate as substrate. These data are consistent with a sequential mechanism for interaction and activation wherein filling of perhaps two Ca2+ sites permits calmodulin interaction with the phosphatase; this complex is inactive, requiring further binding of Ca2+ for activation. Such a scheme would provide a sensitive switch for control of enzyme activity within a narrow range of free Ca2+ concentration.