Calcium activation of macrocilia in the ctenophoreBeroë

1. Macrocilia on the lips of the ctenophore Bero? are usually quiescent, but can be activated to beat rapidly and continuously by various stimuli. 2. During feeding, macrocilia beat actively and serve to spread the lips of Bero? over its prey. 3. Vigorous, repetitive mechanical stimulation of the lips evokes widespread activation of macrocilia via a pathway that is probably neural. 4. Extracellular electrical stimulation (DC or bipolar pulse-trains) elicits immediate activation of macrocilia on lip pieces, but not on dissociated cells. 5. Macrocilia on lip pieces are activated to beat by high KCl artificial sea water (ASW), but not by high KCl Ca-free ASW. Continuous beating for long periods is also elicited by high Ca ASW or Mg-free ASW, but not by Ca-Mg-free ASW. Addition of La, Cd, Co or Mn (10 mM) to high KCl ASW reversibly blocks activation. Verapamil, D-600, nifedipine, or BAY K 8644 (10 microM) has no effect on KC1-induced activation, but the anticalmodulin drug W-7 (10 microM) reversibly inhibits beating. 6. Mild heat treatment dissociates macrociliary cells from lip tissue. Such isolated macrociliary cells usually beat continuously in normal sea water, and swim in circular paths. Ca-free ASW, or addition of Co or Mn to ASW, inhibits beating of dissociated cells. High KCl ASW activates beating of quiescent, isolated macrociliary cells. 7. Ca-Mg-free ASW inhibits beating of dissociated macrociliary cells, and return to Mg-free ASW activates motility, allowing one to activate macrocilia on isolated cells simply by addition of Ca.(ABSTRACT TRUNCATED AT 250 WORDS)     

Optimization of α‐Amylase Immobilization in Calcium Alginate Beads

Abstract

α‐Amylase enzyme was produced by Aspergillus sclerotiorum under SSF conditions, and immobilized in calcium alginate beads. Effects of immobilization conditions, such as alginate concentration, CaCl₂ concentration, amount of loading enzyme, bead size, and amount of beads, on enzymatic activity were investigated. Optimum alginate and CaCl₂ concentration were found to be 3% (w/v). Using a loading enzyme concentration of 140 U mL^?1, and bead (diameter 3 mm) amount of 0.5 g, maximum enzyme activity was observed. Beads prepared at optimum immobilization conditions were suitable for up to 7 repeated uses, losing only 35% of their initial activity. Among the various starches tested, the highest enzyme activity (96.2%) was determined in soluble potato starch hydrolysis for 120 min at 40°C.     

Calcium: Just Another Regulator in the Machinery of Life?

*BACKGROUND: Current hypotheses imply that stimulus-response systems in plants are networks of signal transduction pathways. It is usually assumed that these pathways connect receptors with effectors via chains of molecular events. Diverse intermediate signalling components (transducers) participate in these processes. However, many cellular transducers respond to several stimuli. Hence, there are no discrete chains but rather pathways that interconnect network-modules of different command structure. In particular, the cytosolic free Ca2+ concentration ([Ca2+](cyt)) is thought to perform many different tasks in a wide range of cellular events. However, this range of putative functions is so wide that it is often questioned how Ca2+ can comply with the definition of a second messenger. *THE Ca2+ SIGNATURE HYPOTHESIS: Some authors have suggested the concept of a specific signature of the ([Ca2+](cyt)) response. This implies that characteristics of the time course of changes in ([Ca2+](cyt)) and their localized sites of appearance in cells are used by the plant to identify the type and intensity of the stimulus. This hypothesis has triggered many investigations, which have yielded contradictory results. * THE CURRENT PICTURE: Much evidence suggests that the functions of calcium can be grouped into three classes: Ca2+ as a protective agent, Ca2+ as a chemical switch and Ca2+ as a 'digital' information carrier. Examples of the first two classes are presented here. The third is more controversial; while some investigations seem to support this idea, others call the Ca2+ signature hypothesis into question. Further investigations are needed to shed more light on Ca(2+)-driven signalling cascades.     

Regulation of Glucokinase by Intracellular Calcium Levels in Pancreatic β Cells

Glucokinase (GCK) controls the rate of glucose metabolism in pancreatic β cells, and its activity is rate-limiting for insulin secretion. Posttranslational GCK activation can be stimulated through either G protein-coupled receptors or receptor tyrosine kinase signaling pathways, suggesting a common mechanism. Here we show that inhibiting Ca²⁺ release from the endoplasmic reticulum (ER) decouples GCK activation from receptor stimulation. Furthermore, pharmacological release of ER Ca²⁺ stimulates activation of a GCK optical biosensor and potentiates glucose metabolism, implicating rises in cytoplasmic Ca²⁺ as a critical regulatory mechanism. To explore the potential for glucose-stimulated GCK activation, the GCK biosensor was optimized using circularly permuted mCerulean3 proteins. This new sensor sensitively reports activation in response to insulin, glucagon-like peptide 1, and agents that raise cAMP levels. Transient, glucose-stimulated GCK activation was observed in βTC3 and MIN6 cells. An ER-localized channelrhodopsin was used to manipulate the cytoplasmic Ca²⁺ concentration in cells expressing the optimized FRET-GCK sensor. This permitted quantification of the relationship between cytoplasmic Ca²⁺ concentrations and GCK activation. Half-maximal activation of the FRET-GCK sensor was estimated to occur at ∼400 nm Ca²⁺. When expressed in islets, fluctuations in GCK activation were observed in response to glucose, and we estimated that posttranslational activation of GCK enhances glucose metabolism by ∼35%. These results suggest a mechanism for integrative control over GCK activation and, therefore, glucose metabolism and insulin secretion through regulation of cytoplasmic Ca²⁺ levels.     

Effects of Calcium Ion on the Catalytic Activity of α-Chymotrypsin in Organic Solvents

Addition of small amounts of calcium ion markedly accelerated the transesterification of N-acetyl-l-tyrosine methyl ester to its ethyl ester by the catalysis of α-chymotrypsin in organic solvents. Maximum increase of the reaction rate was about 12-fold in the presence of 25 μm of calcium ion in ethanol. The rate increase was strongly dependent on calcium ion concentration and nature of organic solvents. Esterification of N-acetyl-l-tyrosine and hydrolysis of N-acetyl-l-tyrosine ethyl ester by α-chymotrypsin in organic solvents were also accelerated by calcium ion. The reactions obeyed Michaelis–Menten kinetics, and the acceleration of the reactions was due to the increase in k_cat.     

Study on the Binding State of Calcium in Photosystem ⅡOxygen-Evolution Complex

Washing spinach PSII oxygen-evolution complex (OEC) with 2 mmol/L EGTA or extraction medium caused a 28.4% and 25.0% loss of oxygen evolution activities respectively, but the loss of polypeptide components of OEC did not take place, whereas washing with 1 mol/L NaCI caused both a 90.0% loss of oxygen evolution activity and loss of 17, 23kD polypeptides. Adding 5–10 mmol/L CaC12 could restore oxygen evolution activities of OEC by various washing to a great extent, but had no effect on control OEC, whereas adding 5–10 mmol/L EGTA had no effect on the OEC by various' washing, but caused the loss of oxygen evolution mixtures, which could induce the release of of 17, 23kD polypeptides from OEC, caused 54.3% loss of oxygen evolution activity, under this circumstance, adding 2 mmol/L of EGTA could only maintain a weak oxygen evolution activity of OEC, but adding 10 mmol/L of CaCl2 could restore oxygen evolution activity of OEC to the control level. These findings' suggest a two way loose binding of Ga2+ to PSⅡ OEC in one way Ca2+ is loose bound to the surface of PSⅡOEC and in other, the Ca2+-binding site is wrapped by 17, 23kD polypeptides. Both of them have effect on oxygen evolution activity of PSⅡ OEC. By way, Mn2+ can antagonize the restoration of oxygen evolution activity by Ca2+ to the NaCl-washing PSⅡ OEC.     

Characterization of Acetylcholine-induced Increases in Cytosolic Free Calcium Concentration in Individual Rat Pancreatic β-cells

The intracellular free Ca²⁺ ion concentration ([Ca²⁺]i) was measured using fura-2 microspec-trofluorimetry in individual rat pancreatic β-cells prepared by enzymatic digestion and fluorescence-activated cell sorting. The mean basal concentration of [Ca²⁺]i in β-cells in the presence of 4.4 mM glucose and 1.8 mM Ca²⁺ was 112±1.6 nM (n=207). The action of acetylcholine (ACh) was concentration-dependent, and raising the concentration resulted in [Ca²⁺]i spikes of increasing amplitude and duration in some, but not all of the β-cells. In addition, the β-cells demonstrated variable sensitivity to ACh. The increases in [Ca²⁺]i were rapid, transient and were blocked by atropine at 10^?6M. A brief exposure to 50 mM K⁺ resulted in a transient increase in [Ca²⁺]i similar to that induced by ACh, but resistant to atropine. A high concentration of ACh (100μL 10^?4M or 10^?3M) induced [Ca²⁺]i oscillations in 11 out of 57 β-cells in the presence of 4.4 mM glucose. Using calcium channel blockers and Ca²⁺ free medium, the source of the increase in [Ca²⁺]i was deduced to be from extracellular spaces. Changing the temperature from 22 to 37°C did not affect the action of ACh on [Ca²⁺]i. These data strongly suggest that ACh exerted a direct action on [Ca²⁺]i in normal rat pancreatic β-cells and support a role for Ca²⁺ as a second messenger in the action of ACh.     

β Subunits of Voltage-Gated Calcium Channels

Calcium channel beta subunits have marked effects on the trafficking and on several of the biophysical properties of all high voltage activated calcium channels. In this article I shall review information on the different genes, on the structure of the beta subunits, and on their differential expression and post-translational modification. Their role in trafficking and assembly of the calcium channel heteromultimer will be described, and I will then review their effects on voltage-dependent and kinetic properties, stressing the differences between palmitoylated beta2a and the other beta subunits. Evidence for effects on calcium channel pharmacology will also be examined. I shall discuss the hypothesis that beta subunits can bind reversibly to calcium channels, and examine their role in the G protein modulation of calcium channels. Finally, I shall describe the consequences of knock-out of different beta subunit genes, and describe evidence for the involvement of beta subunits in disease.     

Diversity and Developmental Expression of L-type Calcium Channel ��2 Proteins and Their Influence on Calcium Current in Murine Heart

By now, little is known on L-type calcium channel (LTCC) subunits expressed in mouse heart. We show that CaVβ2 proteins are the major CaVβ components of the LTCC in embryonic and adult mouse heart, but that in embryonic heart CaVβ3 proteins are also detectable. At least two CaVβ2 variants of ∼68 and ∼72 kDa are expressed. To identify the underlying CaVβ2 variants, cDNA libraries were constructed from poly(A)⁺ RNA isolated from hearts of 7-day-old and adult mice. Screening identified 60 independent CaVβ2 cDNA clones coding for four types of CaVβ2 proteins only differing in their 5′ sequences. CaVβ2-N1, -N4, and -N5 but not -N3 were identified in isolated cardiomyocytes by RT-PCR and were sufficient to reconstitute the CaVβ2 protein pattern in vitro. Significant L-type Ca²⁺ currents (I_Ca) were recorded in HEK293 cells after co-expression of CaV1.2 and CaVβ2. Current kinetics were determined by the type of CaVβ2 protein, with the ∼72-kDa CaVβ2a-N1 shifting the activation of I_Ca significantly to depolarizing potentials compared with the other CaVβ2 variants. Inactivation of I_Ca was accelerated by CaVβ2a-N1 and -N4, which also lead to slower activation compared with CaVβ2a-N3 and -N5. In summary, this study reveals the molecular LTCC composition in mouse heart and indicates that expression of various CaVβ2 proteins may be used to adapt the properties of LTCCs to changing myocardial requirements during development and that CaVβ2a-N1-induced changes of I_Ca kinetics might be essential in embryonic heart.Cardiac contractions require Ca²⁺ influx in cardiomyocytes from the extracellular fluid, which leads to Ca²⁺ release from the sarcoplasmic reticulum via ryanodine receptors (1).This Ca²⁺-induced Ca²⁺ release (CICR)⁴ causes a marked increase in intracellular Ca²⁺ concentration for short periods of time and underlies cardiac contraction (2, 3). The Ca²⁺ influx into cardiac myocytes is mediated by high voltage-activated L-type Ca²⁺ channels (LTCCs), which are heteromultimeric complexes comprised predominantly of the pore-forming CaVα₁ subunit and the auxiliary CaVβ subunit (4). In heart, the principal CaVα₁ subunit, CaVα₁c (CaV1.2), is encoded by the Cacna1C gene (5). Four genes (Cacnb1-4) encoding CaVβ subunits have been identified that are expressed in the heart of different species including human, rabbit, and rat (6, 7, 8).CaVβ proteins are ∼500 amino acid cytoplasmic proteins that bind to the CaVα₁ I-II intracellular loop (9) and affect channel gating properties (4), trafficking (10, 11), regulation by neurotransmitter receptors through G-protein βγ subunit activation (12), and sensitivity to drugs (13). The CaVβ primary sequence encodes five domains, arranged V1-C1-V2-C2-V3. V1, V2, and V3 are variable domains, whereas C1 and C2 are conserved (14). Structural studies reveal that C1 and C2 form a SH3 domain (Src homology 3 domain) and a NK domain (nucleotide kinase domain), respectively (15). Although C1-V2-C2 makes the CaVβ core, in heart the V1 region appears critical for the kinetics of I_Ca and heart function. Accordingly a mutation in the V1 region of the Cacnb2 gene was recently identified as an underlying cause of Brugada syndrome (16).In mice-targeted deletion of the Cacnb2 gene (17) but not of Cacnb1 (18), Cacnb3 (19, 20), or Cacnb4 (21) leads to a morphologically and functionally compromised heart, which causes severe defective remodeling of intra- and extra-embryonic blood vessels and death at early embryonic stages both when the Cacnb2 gene was targeted globally or in a cardiac myocyte-specific way (17). Although these results point to an essential role of CaVβ2 for I_Ca and cardiac function, the existence of various CaVβ2 splice variants and heterogeneity of the expressed CaVβ2 proteins require further studies on the subunit composition of LTCCs in the mouse heart. In addition and in view of the growing number of preclinical studies using mouse models carrying definite Ca²⁺ channel subunits as transgenes in heart tissue, the identification of the relevant gene products underlying the endogenous mouse cardiac L-type channel is essential. Recent mouse models (e.g. 22, 23, 24) carrying a rat CaVβ2 splice variant (“rat CaVβ2a”) (25) expressed in rat and rabbit brain (26), but not in rabbit heart (26), have only escalated this requirement, because it has never been shown that the mouse orthologue of this variant is endogenously expressed in the mouse heart.So far, five CaVβ2 variants varying only in the V1 domain have been identified from different species (25, 27, 28) and in human heart these variants have been obtained mainly by RT-PCR approaches (29, 30). In contrast, there is little information on the CaVβ proteins present in mouse heart, their respective splice variants, and expression ratios. We therefore started to study CaVβ expression in the murine heart using Western blots and cDNA cloning and to reveal their functional impact on LTCCs formed by the murine CaV1.2 protein.     

Calcium signaling in Parkinson’s disease

Calcium (Ca²⁺) is an almost universal second messenger that regulates important activities of all eukaryotic cells. It is of critical importance to neurons, which have developed extensive and intricate pathways to couple the Ca²⁺ signal to their biochemical machinery. In particular, Ca²⁺ participates in the transmission of the depolarizing signal and contributes to synaptic activity. During aging and in neurodegenerative disease processes, the ability of neurons to maintain an adequate energy level can be compromised, thus impacting on Ca²⁺ homeostasis. In Parkinson’s disease (PD), many signs of neurodegeneration result from compromised mitochondrial function attributable to specific effects of toxins on the mitochondrial respiratory chain and/or to genetic mutations. Despite these effects being present in almost all cell types, a distinguishing feature of PD is the extreme selectivity of cell loss, which is restricted to the dopaminergic neurons in the ventral portion of the substantia nigra pars compacta. Many hypotheses have been proposed to explain such selectivity, but only recently it has been convincingly shown that the innate autonomous activity of these neurons, which is sustained by their specific Cav1.3 L-type channel pore-forming subunit, is responsible for the generation of basal metabolic stress that, under physiological conditions, is compensated by mitochondrial buffering. However, when mitochondria function becomes even partially compromised (because of aging, exposure to environmental factors or genetic mutations), the metabolic stress overwhelms the protective mechanisms, and the process of neurodegeneration is engaged. The characteristics of Ca²⁺ handling in neurons of the substantia nigra pars compacta and the possible involvement of PD-related proteins in the control of Ca²⁺ homeostasis will be discussed in this review.     

Role of Calcium and Adenosine Cyclic 3′-5′ Phosphate in Action of Adrenocorticotropin

ALTHOUGH adenosine cyclic monophosphate (cyclic AMP) has been proposed as a mediator through which many hormones exert their physiological effects¹, it is also well established that calcium plays a crucial role in hormone release². Both calcium^3,4 and cyclic AMP^1,5 have been implicated in the action of adrenocorticotropin (ACTH) on the adrenal cortex and although various hypotheses have been advanced concerning their roles in steroid production and release, elucidation of their functions in the adrenal gland is hindered because most studies have been carried out on in vitro systems where the physiological release response cannot be studied. The isolated cat adrenal gland perfused in situ ⁶ approximates the situation in vivo, yet eliminates the influence of several factors, including the anterior pituitary. In the intact adrenal preparation one can also measure both steroid synthesis and release and can better evaluate the respective effects of cyclic AMP and calcium on these processes.     

Calcium Modulation of Ligand Affinity in the Cyclic GMP–gated Ion Channels of Cone Photoreceptors

To investigate modulation of the activation of cGMP-gated ion channels in cone photoreceptors, we measured currents in membrane patches detached from the outer segments of single cones isolated from striped bass retina. The sensitivity of these channels to activation by cGMP depends on the history of exposure to divalent cations of the membrane''s cytoplasmic surface. In patches maintained in 20 μM Ca⁺⁺ and 100 μM Mg⁺⁺ after excision, the current amplitude dependence on cGMP is well described by a Hill equation with average values of K _1/2, the concentration necessary to activate half the maximal current, of 86 μM and a cooperativity index, n, of 2.57. Exposing the patch to a solution free of divalent cations irreversibly increases the cGMP sensitivity; the average value of K _1/2 shifts to 58.8 μM and n shifts to 1.8. Changes in cGMP sensitivity do not affect other functional parameters of the ion channels, such as the interaction and permeation of mono- and divalent cations. Modulation of cGMP activation depends on the action of an endogenous factor that progressively dissociates from the channel as Ca⁺⁺ concentration is lowered below 1 μM. The activity of the endogenous modulator is not well mimicked by exogenously added calmodulin, although this protein competes with the endogenous modulator for a common binding site. Thus, the modulation of cGMP affinity in cones depends on the activity of an unidentified molecule that may not be calmodulin.     

Post-Translational Modifications of β Subunits of Voltage-Dependent Calcium Channels

Different post-translational modifications of Ca channel subunits have been identified. Recent studies have characterized the palmitoylation of the Ca channel _2a subunit, as well as one effect of this modification on channel function. The potential importance of palmitoylation on other channel properties is discussed. Other studies have addressed the role of phosphorylation of subunits in the regulation of voltage-dependent Ca channels. Phosphorylation of subunits by second messenger-activated protein kinases, as well as by unidentified protein kinases, may affect interactions between channel subunits and other aspects of channel function. The differential modification of Ca channel subunit isoforms by post-translational events likely results in diversely regulated channels with unique properties.     

Calcium Extrusion Pump PMCA4: A New Player in Renal Calcium Handling?

Calcium (Ca²⁺) is vital for multiple processes in the body, and maintenance of the electrolyte concentration is required for everyday physiological function. In the kidney, and more specifically, in the late distal convoluted tubule and connecting tubule, the fine-tuning of Ca²⁺ reabsorption from the pro-urine takes place. Here, Ca²⁺ enters the epithelial cell via the transient receptor potential vanilloid receptor type 5 (TRPV5) channel, diffuses to the basolateral side bound to calbindin-D_28k and is extruded to the blood compartment via the Na⁺/Ca²⁺ exchanger 1 (NCX1) and the plasma membrane Ca²⁺ ATPase (PMCA). Traditionally, PMCA1 was considered to be the primary Ca²⁺ pump in this process. However, in recent studies TRPV5-expressing tubules were shown to highly express PMCA4. Therefore, PMCA4 may have a predominant role in renal Ca²⁺ handling. This study aimed to elucidate the role of PMCA4 in Ca²⁺ homeostasis by characterizing the Ca²⁺ balance, and renal and duodenal Ca²⁺-related gene expression in PMCA4 knockout mice. The daily water intake of PMCA4 knockout mice was significantly lower compared to wild type littermates. There was no significant difference in serum Ca²⁺ level or urinary Ca²⁺ excretion between groups. In addition, renal and duodenal mRNA expression levels of Ca²⁺-related genes, including TRPV5, TRPV6, calbindin-D_28k, calbindin-D_9k, NCX1 and PMCA1 were similar in wild type and knockout mice. Serum FGF23 levels were significantly increased in PMCA4 knockout mice. In conclusion, PMCA4 has no discernible role in normal renal Ca²⁺ handling as no urinary Ca²⁺ wasting was observed. Further investigation of the exact role of PMCA4 in the distal convoluted tubule and connecting tubule is required.     

Increased Expression of the Cardiac L-type Calcium Channel in Estrogen Receptor–deficient Mice

Steroid hormones control the expression of many cellular regulators, and a role for estrogen in cardiovascular function and disease has been well documented. To address whether the activity of the L-type Ca²⁺ channel, a critical element in cardiac excitability and contractility, is altered by estrogen and its nuclear receptor, we examined cardiac myocytes from male mice in which the estrogen receptor gene had been disrupted (ERKO mice). Binding of dihydropyridine Ca²⁺ channel antagonist isradipine (PN200-110) was increased 45.6% in cardiac membranes from the ERKO mice compared to controls, suggesting that a lack of estrogen receptors in the heart increased the number of Ca²⁺ channels. Whole-cell patch clamp of acutely dissociated adult cardiac ventricular myocytes indicated that Ca²⁺ channel current was increased by 49% and action potential duration was increased by 75%. Examination of electrocardiogram parameters in ERKO mice showed a 70% increase in the QT interval without significant changes in PQ or QRS intervals. These results show that the membrane density of the cardiac L-type Ca²⁺ channel is regulated by the estrogen receptor and suggest that decreased estrogen may lead to an increase in the number of cardiac L-type Ca²⁺ channels, abnormalities in cardiac excitability, and increased risk of arrhythmia and cardiovascular disease.     

Calcium alginate entrapped preparation of α-galactosidase: its stability and application in hydrolysis of soymilk galactooligosaccharides

Thermostable α-galactosidase from Aspergillus terreus _GR was insolubilized using concanavalin A obtained from jack bean extract and in order to maintain the integrity of complex in the presence of its substrate or products, this complex was crosslinked with glutaraldehyde. Soluble α-galactosidase entrapped in calcium alginate retained 82% of enzyme activity whereas, Con A-α-galactosidase complex entrapped in calcium alginate and crosslinked Con A-α-galactosidase complex entrapped calcium alginate retained 74 and 61% activity, respectively. A fluidized bed reactor was constructed for continuous hydrolysis of galactooligosaccharides in soymilk using crosslinked Con A-α-galactosidase complex entrapped calcium alginate. Optimum conditions such as pH (5.0) and temperature (65°C) were the same for all immobilized enzyme preparations and soluble enzyme. Crosslinked Con A-α-galactosidase entrapped complex exhibited enhanced thermostability and showed 62% of activity (38%) after 360 min at 65°C. Entrapped crosslinked Con A-α-galactosidase complex preparation was superior in the continuous hydrolysis of oligosaccharides in soymilk by batch processes compared to the other entrapped preparations. The entrapped crosslinked concanavalin A-α-galactosidase complex retained 95% activity after eight cycles of use.     

“Calcium metabolism in intact isolated thymocytes”

Summary Isolated rat thymocytes incubated under proper metabolic conditions extrude Ca²⁴ previously taken up under metabolically unfavourable conditions.The extrusion can be supported by both respiratory and glycolytic energy but glycolysis seems to be more efficient for this purpose.La^3– (50–200 M) and the ionophore A 23187 inhibit cell Ca²⁺ extrusion.Ruthenium Red (1–100 M)) does not influence cell Ca²⁺ extrusion while it inhibits the in situ mitochondrial cation uptake.All the results are consistent with a cell regulation model of Ca ²⁺ content in which both plasma membrane and mitochondria co-operate, acting in opposite directions, in order to decrease cytosolic Ca ²⁺ concentration.The possibility of Na⁺-Ca²⁺ hetero-exchange participation to cell Ca²⁺ homeostasis regulation is also discussed.     

Effects of Intracellular Calcium Chelation and Pifithrin-α on Deoxynucleotide Metabolism in Human Lymphocytes

Previously, we have found that activation of deoxycytidine kinase elicited by various DNA-damaging chemical agents could be prevented by BAPTA-AM, a cell-permeable calcium chelator or by pifithrin-α, a pharmacological inhibitor of p53. Here, we show that stimulation of deoxycytidine kinase by UV-light also is calcium-dependent and pifithrin-α-sensitive in tonsillar lymphocytes, while thymidine kinase 1 activity is stabilised in the presence of BAPTA-AM. Importantly, both UV-irradiation and calcium chelation decreased the incorporation of labelled deoxycytidine and thymidine into DNA. Pifithrin-alpha dramatically reduced the labelling of both the nucleotide and DNA fractions, possibly due to inhibition of transmembrane nucleoside transport.