Characterization of Vanadyl Sulfate Effect on Vascular Contraction: Roles of Calcium and Tyrosine Phosphorylation

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

This Article

	Abstract
	Full Text (PDF)
	Submit a response
	Alert me when this article is cited
	Alert me when eLetters are posted
	Alert me if a correction is posted
	Citation Map

Services

	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager

Citing Articles

	Citing Articles via Google Scholar

Google Scholar

	Articles by Cadène, A.
	Articles by Cros, G.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Cadène, A.
	Articles by Cros, G.

Vol. 281, Issue 1, 491-498, 1997

Characterization of Vanadyl Sulfate Effect on Vascular Contraction: Roles of Calcium and Tyrosine Phosphorylation¹

Anne Cadène, Florin Grigorescu, Jean-Jacques Serrano and Gérard Cros

Laboratoire de Pharmacologie (A.C., J.J.S., G.C.), Faculté de Pharmacie, Montpellier, France and Institut Universitaire de Recherche Clinique (F.G.), Molecular Endocrinology, Montpellier, France

	Abstract

Top Abstract Introduction Materials & Methods Results Discussion References

In order to explore the mechanism of action of vanadyl sulfate (VOSO₄), previously described as an antidiabetic and antihypertensiveagent, we have investigated the role of calcium and tyrosine phosphorylationin the contractile responses of rat aorta or skinned rabbit mesentericartery rings. VOSO₄ induced a concentration-dependent contractionof aorta (pD₂ = 3.2), which was potentiated by endothelium removal(pD₂ = 4.2). After a first exposure to VOSO₄, no change in responsivenesswas observed even though high vanadium concentrations had accumulatedin the aortic tissue ( $approx$ 4 × 10³ M). VOSO₄ induced, in calcium-free medium, a significant responsethat, relative to contractions measured in Krebs-Henseleit buffer,was higher (36%) than norepinephrine (16%)-, arginine-vasopressin(8%)- or KCl (5%)-induced responses. 8-(N,N-diethylamino)octyl3,4,5-trimethoxybenzoate hydrochloride (TMB-8), an intracellularcalcium release inhibitor, did not modify VOSO₄-induced responseeither in the presence or in the absence of ambient calcium. Onskinned preparations, VOSO₄ antagonized Ca⁺⁺-induced contraction. The tyrosine kinase inhibitors tyrphostin23 (T₂₃) and tyrphostin 47 (T₄₇) potentiated by 4- and 14-fold,respectively, the activity of VOSO₄, in contrast to the lack ofeffect of T₄₇ on pervanadate-induced contraction. When phosphotyrosinecontent was revealed by Western blotting, VOSO₄ had no effectalone, but in the presence of T₄₇, it dramatically increased thephosphotyrosine content. This result contrasts again with PV-inducedtyrosine phosphorylation, which was blocked by T₄₇. These datasuggest that the signaling events involved in vascular effectsof VOSO₄, although they depend little on calcium mobilization,are related to tyrosine phosphorylation, likewise through a pathwaydifferent from that of pervanadate.

	Introduction

Top Abstract Introduction Materials & Methods Results Discussion References

The pharmacology of vanadium, a Group Vb transition metal, has been extensively investigated in the last decade, particularlyin terms of its insulinomimetic properties (Brichard and Henquin,1995; Cros et al., 1992), and their possible therapeutic applicationin diabetes mellitus (Cam et al., 1993; Goldfine et al., 1995;Cohen et al., 1995).

Compelling evidence had accumulated, showing differences in the cellular mechanism of action of the various vanadium species.Vanadate (V⁵⁺) and vanadyl (V⁴⁺) derivatives have in vivo antidiabetic properties correlatedwith an increase in insulin sensitivity, whereas their cellularmechanism, though it remains controversial, is thought to be independentof insulin receptor activation (Goldfine et al., 1995). More recentlydeveloped peroxovanadium (pervanadate) derivatives were shownto be able to lower blood glucose in the insulin-dependent diabeticBB rat in vivo (Yale et al., 1995), and their cellular mechanismseems to be directly linked to insulin receptor activation (Bevanet al., 1995). The vanadate (V⁵⁺) and vanadyl (V⁴⁺) oxidation states also differ markedly in biochemical (Cantleyand Aisen, 1979; Elberg et al., 1994), pharmacological (Bhanotand McNeill, 1994; Boscolo et al., 1994; Nakai et al., 1995) andtoxicologic (Llobet and Domingo, 1984) properties. In particular,vanadate derivatives were shown to have prohypertensive properties(Boscolo et al., 1994), whereas vanadyl derivatives were shownto be antihypertensive agents (Bhanot and McNeill, 1994; Bhanotet al., 1994).

Since 1980 (Ozaki and Urakawa, 1980) it has been known that vanadium salts are able to induce contraction of a variety ofsmooth muscles tissues, including vascular smooth muscle. Vanadatesalts have been studied most, and their mechanism of action remainsuncertain despite extensive investigations. The structural similaritybetween vanadate $---$ but not vanadyl $---$ and phosphate groups, as wellas the inhibitory effect of vanadate on sarcoplasmic and endoplasmiccalcium-ATPase (SERCA) (Raeymakers et al., 1983), suggested themobilization of intracellular calcium stores (Sanchez-Ferrer etal., 1988). Since the description of various isoforms of SERCA,however, it has recently been shown that vanadate has no effecton muscular isoforms (Lytton et al., 1992). The increased levelof tyrosine phosphorylation, typically described in the mechanismof the insulinomimetic effects of vanadium derivatives (Tamuraet al., 1984; Shechter et al., 1995), was also found to be associatedwith the smooth muscle contractile activities of vanadate andPV (DiSalvo et al., 1993; Laniyonu et al., 1994), which are stillunknown in the case of vanadyl.

The aim of the present study was to use isolated vascular preparations to characterize further the vascular properties ofVOSO₄ and to study its mechanism of action. In particular, weexamined the relative contributions of calcium and tyrosine phosphorylationto its activity. We describe the concentration-dependent VOSO₄-inducedcontraction in aortic tissue that is regulated by, but not dependenton, the presence of endothelium and that occurs in the absenceof extracellular calcium or the presence of blockers for extracellularcalcium entry and intracellular calcium mobilization. Surprisingly,the activity of VOSO₄, but not that of the potent tyrosine phosphataseinhibitor PV, was amplified by the tyrosine kinase inhibitorstyrphostins, concomitantly with elevated levels of tyrosine phosphorylation.

	Materials and Methods

Top Abstract Introduction Materials & Methods Results Discussion References

Contractile effect of VOSO₄ on rat isolated aorta. Thoracic aorta rings 3 mm long were was obtained from male Wistar rats (300-350 g) and suspended at 37°C in aerated (95% O₂,5% CO₂) Krebs-Henseleit buffer (mM): NaCl, 119; KCl, 4.7; CaCl₂,2.5; MgSO₄, 1.0; KH2PO₄, 1.2; NaHCO₃, 25; glucose, 11.1; pH 7.4.Isometric tension recording was performed in tissues equilibratedfor 60 min under 1 g tension, washed with buffer every 15 minand then exposed to 40 mM KCl to test the viability and "sensitize"preparations for subsequent exposure to contractile agents. Whenindicated, a second KCl (40 mM)-induced response was recordedas "internal standard." VOSO₄ was used either as single concentrations(10⁴ or 5 × 10⁴ M) or as cumulative concentrations (1 to 1000 µM). Vanadium levelswere determined by atomic absorption spectrophotometry (Mongoldet al., 1990).

Endothelium was removed by gentle rubbing of the internal lumina of aortic rings. The effect of endothelium removal was confirmedby the inability of ACh (10⁵ M) to induce vasodilation after NEPI (6 × 10⁷ M)-induced contraction.

Role of calcium in contractile activity of VOSO₄. The role of calcium was first assessed on rat thoracic aorta. KCl (40 mM), AVP (3 × 10⁸ M) and NEPI (6 × 10⁷ M) were used for comparison purposes. The amplitude of responsesof these agonists was comparable to that of VOSO₄ (5 × 10⁴ M). Consecutive exposures to the same agent yielded similar responses(not illustrated).

The effect of the calcium entry blocker N (0.01-1 µM) and that of the intracellular calcium liberation inhibitor TMB-8 (30µM) (Chiou and Malagodi, 1975

) were assessed as follows: The preparationwas first exposed to the contractile agent (designated as controlcontraction) and was then washed and exposed to N or TMB-8 for20 or 30 min, respectively. Finally, the tissue preparation wasexposed to the contractile agent in the presence of antagonist.

To investigate the role of calcium-free buffer, contraction was measured after subsequent incubations of arterial rings for45 min in calcium-free buffer and then for 15 min in the presenceof 1 mM EDTA, followed by extensive washing in calcium-free bufferwithout EDTA.

The role of calcium was also assessed by using skinned rabbit mesenteric arteries prepared with saponin according to the methodof Sunano et al. (1988)

. Briefly, mesenteric arteries were removedand cleaned of fat and fibrous tissue. Arterial vessel was cutinto rings and placed in aerated (95% O₂, 5% CO₂) relaxing mediumcontaining 130 mM KCl, 20 mM Tris-maleate, 5 mM Na₂ATP and 4 mMEGTA, pH 6.8, at 25°C. Preparations were equilibrated under 1g tension, treated for 20 min with 50 µg/ml saponin and then washedfor another 20 min. Thereafter, mesenteric arteries were submittedto cumulative concentrations of free Ca⁺⁺ (obtained by adding CaCl₂ to the medium containing 4 mM EGTA)in the absence or presence of VOSO₄. Free Ca⁺⁺ concentrations were calculated according to the method describedby Fabiato and Fabiato (1979)

Role of tyrosine phosphorylation. The role of tyrosine phosphorylation in the contractile activity of Ca⁺⁺ was assessed by using the tyrosine kinase inhibitors genistein,T₄₇ (RG 50864) and T₂₃ (RG 50810), as well as inactive tyrphostinderivatives (T₁ and T₆₃). The tyrosine kinase inhibitors weredissolved in dimethylsulfoxide (DMSO) and used at a concentrationof 0.2 mM. DMSO alone had no contractile activity at the maximalconcentration used (0.1%).

The tyrosine kinase inhibitors were added 10 min before the following contractile agents: VOSO₄ (10⁴ M), KCl (40 mM), AVP (3 × 10⁸ M), NEPI (5 × 10⁷ M) and PV (10⁴ M). PV had previously been described as a potent inhibitor oftyrosine phosphatases and thus an inducer of tyrosine phosphorylation(Shisheva and Shechter, 1993a

). In addition, the effects of T₄₇were examined in preparations without endothelium and in calcium-freemedium. Responses were expressed as percent of KCl-induced contraction,described above as the "internal standard" in the absence of inhibitors.

Investigations of phosphotyrosine content were conducted by Western blotting on 8-mg segments of rat aorta prepared for isometrictension recording after removal of endothelium. Aortic segmentswere exposed to VOSO₄ (10⁴ or 5 × 10⁴ M), PV (10⁴ M) or the associations of T₄₇ plus VOSO₄ (10⁴ M) or PV (10⁴ M) and frozen at maximal contraction. For control, aortic preparationswere frozen under basal tension (1 g) in the presence or absenceof T₄₇. Tissues were kept at $-$ 80°C until processed for Westernblotting.

Pieces of aortic tissue were thawed, homogenized at 4°C in a Thomas tissue grinder with a Teflon pestle, directly solubilizedin Laemmli buffer and boiled for 3 min. Insoluble material wasdiscarded after microfuge centrifugation (18 000 × g), solubilizedproteins were resolved by SDS-PAGE (7.5% acrylamide) under reducingconditions (100 mM dithiothreitol) and transferred to nitrocellulosepaper. Nitrocellulose strips were incubated for 8 h at 4°C inblocking solution containing 20 mM, 150 mM NaCl, 0.01% (v/v) Tween20 and 3% bovine serum albumin. The antiphosphotyrosine recombinantantibody RC20, coupled with horseradish peroxidase (HRPO), wasincubated in the blocking buffer at 1:250 dilution for 2 h at22°C, and further steps were followed for ECL detection as recommendedby the manufacturer (Amersham). For the detection of phosphotyrosine,lysates of A431 cells stimulated by EGF were used as standardsas recommended by Affinity Research Products Ltd. (Exeter, UK).

Materials. VOSO₄ · 5H₂O and other reagents of analytical or sequence grade were from Prolabo (Paris, France). The PV solution was preparedaccording to Pumiglia et al. (1992) by incubating one part of500 mM H₂O₂ with five parts of 10 mM sodium orthovanadate for10 min at 37°C immediately before use. This procedure inducedthe formation of a mixture of peroxovanadium complexes (Campbellet al., 1989) and has been widely used in pharmacological studiesshowing differences between the properties of PV and those ofvanadate (Bevan et al., 1995). AVP, NEPI, N, saponin, phenylmethyl-sulphonylfluoride (PMSF), aprotinin and leupeptin were from the Sigma ChemicalCo. (St Louis, MO). TMB-8, genistein and the tyrphostins werefrom Biomol (Plymouth Meeting, PA).

The RC20 linked to HRPO was from Affinity Research Products Ltd. Bradford protein assay, molecular weight standards and allcompounds for electrophoresis were from Bio-Rad Chemical Division(Richmond, CA). Nitrocellulose paper (BA85, 0.2 mm) was from Schleicher& Schuell (Keene, NH).

Data analysis and statistics. Results of vascular contraction were expressed as mean ± S.E.M. Half-maximal effective concentrations (EC₅₀) were calculatedusing a computer program for multiple iterations on the Hill equation.pD₂ values were determined as log 1/EC₅₀. Statistical comparisonswere done using Newman-Keuls' test or Student's t test for pairedor unpaired data, as appropriate. A probability value of lessthan 5% was considered significant.

	Results

Top Abstract Introduction Materials & Methods Results Discussion References

VOSO₄-induced contraction in rat aorta. Typical isolated aorta responses after the addition of a single concentration of VOSO₄ are shown in figure 1, panel A. VOSO₄induced maximal vasoconstriction after 5 to 10 min. In most cases,a slowly developing contraction was followed by a steep increasein tension.

View larger version (20K):
[in this window]
[in a new window]

Fig. 1. VOSO₄-induced contraction on rat aorta. A) Typical tracing of aorta isometric contraction obtained at 5 × 10⁴ M VOSO₄ in standard Krebs-Henseleit buffer as described in "Materialsand Methods." B) Cumulative concentration-response curves of rataorta contraction obtained with endothelium or after removal ofendothelium. Contraction is expressed as percent of KCl (40 mM)-inducedcontraction (control). Points represent the mean (n = 6) and barsthe S.E.M. Statistically significant differences are indicatedby * (P $<=$ .05).

The role of the endothelium in the contractile properties of VOSO₄ was assessed by comparing VOSO₄ cumulative concentration-responsecurves in the presence or absence of endothelium (fig. 1, panelB). pD₂ was significantly higher in the absence of endothelium(4.06 ± 0.19) than in its presence (3.19 ± 0.12).

VOSO₄-induced contraction was readily reversible on washing and was reproducible in the same preparation for two consecutivecumulative concentration curves or two single-concentration (5× 10⁴ M) responses (data not shown). Vanadium tissue concentrationafter completion of one concentration-response curve averaged576 ± 132 µg/g (n = 4). After extensive washing (six times) andreturn to baseline, it was still 190 ± 20 µg/g. These data indicatethat vanadium accumulates in aortic segments at concentrations10 times higher than in the buffer and that significant amountsof vanadium ( $approx$ 4 × 10³ M) remain stored in tissues after washing without significantlyaffecting further VOSO₄-induced responses.

Role of calcium. The influence of various concentrations of the calcium entry blocker N (0.01 to 1 µM) on VOSO₄-, AVP-, NEPI- and KCl-inducedcontractions is shown in figure 2. The inhibitory activity ofN was concentration-dependent. The order of potency of N to inhibitcontractile agents was AVP $>=$ KCl >> VOSO₄ > NEPI.

View larger version (26K):
[in this window]
[in a new window]

Fig. 2. Effect of nicardipine on the contractile responses of isolated rat aorta to various contractile agents. Isometric tensionmeasurement of isolated segments of rat aorta was performed instandard Krebs-Henseleit buffer as described in "Materials andMethods." The effect of various concentrations of nicardipineon the contractile responses to VOSO₄ (5 × 10⁴ M), KCl (40 mM), AVP (3 × 10⁸ M) and NEPI (6 × 10⁷ M) is expressed as percent of the control responses measuredon the same preparations in the absence of nicardipine. Pointsrepresent the mean ± S.E.M. (n = 8). Statistically significantdifferences as compared with the effect of VOSO₄ are indicatedby * (P < .05).

In the absence of extracellular calcium, VOSO₄ at 5 × 10⁴ M induced a slowly developing contraction with a maximum, after 20to 30 min, reaching ~36% of the control contraction in standardbuffer (not illustrated). This value was significantly higherthan those obtained with KCl, AVP or NEPI (fig. 3).

View larger version (50K):
[in this window]
[in a new window]

Fig. 3. Effects of calcium-free buffer and TMB-8 on the contractile responses of isolated aorta induced by various agents. Isometrictension responses of isolated rat aortic segments to VOSO₄ (5× 10⁴ M), KCl (40 mM), AVP (3 × 10⁸ M) and NEPI (6 × 10⁷ M) were measured in standard and in calcium-free buffer as describedin "Materials and Methods," in the absence or presence of TMB-8(30 µM). Results are expressed as percent of the control responsesobtained in standard buffer on the same preparations. Values aremeans ± S.E.M. of 6 to 12 experiments. Results obtained with VOSO₄are significantly different (P $<=$ .05) from those obtained withthe other contractile agents in all cases.

The effect of the intracellular calcium liberation inhibitor TMB-8 on the activity of various contractile agents was measuredin standard or calcium-free buffer (fig. 3). In standard buffer,responses to KCl, AVP and NEPI were significantly inhibited byTMB-8. In calcium-free buffer, the remaining fraction of NEPI-inducedresponse was further reduced by TMB-8. By contrast, the effectof VOSO₄-induced contraction measured in standard or calcium-freebuffer remained unchanged in the presence of TMB-8.

The possible relationship between calcium and VOSO₄ was studied on skinned vessels under conditions where intracellular Ca⁺⁺ concentrations could be experimentally controlled. No contractileresponse to VOSO₄ could be obtained in the absence of calcium(data not shown). Figure 4 illustrates the effect of cumulatedfree Ca⁺⁺ concentrations on the contraction measured in the absence orpresence of three concentrations of VOSO₄. At 10⁴ M and 10³ M VOSO₄, Ca⁺⁺-induced responses were dramatically reduced. The same concentration-dependentinhibitory effect of VOSO₄ on Ca⁺⁺-induced contraction was also observed when VOSO₄ was added afterthe vessel had been maximally contracted with 10⁵ M Ca⁺⁺ (not illustrated).

View larger version (23K):
[in this window]
[in a new window]

Fig. 4. Effect of Ca⁺⁺ on rabbit skinned mesenteric arteries measured in the absence or presence of various concentrations of VOSO₄.Segments of rabbit mesenteric arteries were mounted for isometrictension measurement and skinned with saponin as described in "Materialsand Methods." Free Ca⁺⁺ concentrations were obtained by adding known amounts of CaCl₂in the presence of 4 mM EGTA. Results are expressed as grams ofdeveloped tension. Values are means ± S.E.M. of 5 to 10 experiments.* indicates a significant difference (P $<=$ .05) compared with thecontraction measured in the absence of VOSO₄.

Role of tyrosine phosphorylation. The influence of the tyrosine kinase inhibitors tyrphostins and genistein on the contractile activity of VOSO₄ is shown infigure 5. Genistein inhibited VOSO₄-induced contraction, but theeffects of the tyrphostins varied according to the compound used(Gazit et al., 1989). According to Gazit et al. (1989), tyrphostinsT₁ and T₆₃, with IC₅₀ > 1200 µM in the ability to inhibit EGFreceptor tyrosine kinase, were designated as "inactive." Whereasthe "inactive" tyrphostins T₁ and T₆₃ had no significant effecton contraction, T₄₇ (IC₅₀ = 2.4 µM) dramatically (14-fold) potentiatedthe activity of VOSO₄. T₂₃ (IC₅₀ = 35 µM), a milder tyrosine kinaseinhibitor than T₄₇, moderately (4-fold) potentiated the activityof VOSO₄. In contrast to its amplification effect on VOSO₄-inducedcontraction, T₄₇ either had no effect on or inhibited the activityof KCl, NAD and AVP, whereas genistein was inhibitory in all cases(data not shown).

View larger version (40K):
[in this window]
[in a new window]

Fig. 5. Effect of various tyrosine kinase inhibitors on VOSO₄-induced contraction in rat aorta. Isometric tension measurement of isolatedsegments of rat aorta was performed in standard Krebs-Henseleitbuffer as described in "Materials and Methods." The effect ofvarious tyrosine kinase inhibitors (0.2 mM) on the contractileresponses to VOSO₄ (10⁴ M) is expressed as percent of the contraction induced by 40 mMKCl in the absence of tyrosine kinase inhibitor (control). Meansvalues of 6 to 9 experiments are shown; vertical lines indicateS.E.M. * indicates a significant difference compared with thecontraction obtained with VOSO₄ in the absence of inhibitors.

T₄₇-induced potentiation of VOSO₄ was still present after endothelium removal and in calcium-free buffer. Indeed, in the absenceof endothelium, responses to 0.1 mM VOSO₄ were 26 ± 4% and 151± 2% of the KCl-induced response, in the absence and presenceof T₄₇, respectively. In the absence of calcium, responses were4 ± 1% and 53.9 ± 10%, in the absence and presence of T₄₇, respectively.

For comparison purposes, we also measured the effect of PV in the presence and absence of T₄₇. PV is a more specific tyrosinephosphatase inhibitor than vanadate or vanadyl derivatives andhas previously been shown to induce high levels of tyrosine phosphorylationin smooth muscle preparations (Laniyonu et al., 1994

). The amplitudeof contraction induced by 0.1 mM PV (19.2 ± 1.2%, n = 6) was higherthan that induced with the same concentration of VOSO₄ (11.8 ±1.7%, n = 6). However, no significant change in PV-induced contractionwas observed in the presence of T₄₇ (18.4 ± 1.3% of KCl-inducedresponse, n = 6).

Tyrosine phosphorylation was determined by Western blotting (fig. 6) on endothelium-deprived aortic segments. Neither T₄₇nor VOSO₄ produced any apparent change in phosphotyrosine levels.However, the combination of T₄₇ and VOSO₄ not only enhanced theVOSO₄-induced contractile response (fig. 5) but also produceda major increase in phosphotyrosyl content. Unlike VOSO₄ alone,PV alone increased the level of tyrosine phosphorylation. AlthoughT₄₇ had no effect on pervanade-induced contractile response, itinhibited the PV-induced increase in tyrosine phosphorylation.

View larger version (57K):
[in this window]
[in a new window]

Fig. 6. Identification by Western blotting of phosphotyrosine content of aortic tissue under various conditions. Samples were preparedas described in "Materials and Methods" and resolved in SDS-PAGE.Immunoblotting was performed with RC20 antibodies and revealedby ECL detection buffers. First and second lanes correspond toA431 cell lysate and control aortic tissue without stimulation,respectively. The following lanes correspond to T₄₇ (0.2 mM) alone,VOSO₄ (0.1 mM) alone, VOSO₄ (0.5 mM) alone, T₄₇ (0.1 mM) and VOSO₄(0.1 mM), pervanadate alone (10⁴ M) and pervanadate (0.1 mM) and T₄₇ (0.2 mM), respectively.

Four major protein bands were intensively phosphorylated in the presence of PV or the association VOSO₄ and T₄₇, with apparentmolecular weights of 200, 90, 70 and 30 kDa. Interestingly, onlythe protein band of 90 kDa was intensively phosphorylated by PVbut not by the VOSO₄ and T₄₇ association.

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

Although the vasoconstricting properties of vanadium salts were known, the vascular properties of the vanadyl (V⁴⁺) form of vanadium (V), recently described as antihypertensive(Bhanot and McNeill, 1994; Bhanot et al., 1994), had not beenspecifically studied and characterized. In the present study,we showed that VOSO₄ produced a concentration-dependent vasoconstrictionthat was fully repeatable on the same preparation even in thepresence of high vanadium tissue levels. Vasoconstriction 1) wasnot endothelium-dependent, 2) was present, although reduced inamplitude, in the absence of extracellular calcium and the presenceof blockers of extracellular calcium entry or intracellular calciummobilization and 3) was absent in skinned preparations. Unlikethe response to the potent tyrosine phosphatase inhibitor PV,VOSO₄-induced vasoconstriction was amplified by tyrphostins. Theamplification was associated with high levels of tyrosine phosphorylation.

VOSO₄ provoked vasoconstriction at concentrations (10-1000 µM) similar to those previously described with vanadate using thesame experimental model (Shimada et al., 1986; Laniyonu et al.,1994; St-Louis et al., 1995). These concentrations appear highcompared with those used for known receptor-specific agonists,such as NEPI and AVP (1 pM-1 µM), but are lower than those usedfor KCl (10-100 mM), a known depolarizing agent. However, we recentlyshowed that VOSO₄ was able to contract isolated smooth musclecells at subnanomolar concentrations (Soulié et al., 1996), whileactive concentrations of KCl remained within the 10 mM range (G.Cros, personal communication). These data indicate that VOSO₄can contract smooth muscle cells at concentrations close to physiologicalvanadium levels. Considering the capacities of vanadium to bindto tissues, it is possible that accessibility to the reactivesite is a major factor determining the active concentration ofVOSO₄ in a given preparation.

In addition to yielding previously described vanadate effects, our studies also indicated that VOSO₄-induced vasoconstrictionwas fully repeatable on the same aortic segment, both at singleand multiple cumulative concentrations. A recent study indicatedthat after a first exposure to PV, the aorta became unresponsivefor more than 2 h not only to a second exposure to PV but alsoto other contractile agents (such as NEPI and KCl) (Laniyonu etal., 1994). These data suggest that VOSO₄ and PV have differentmechanisms of action.

VOSO₄-induced vasoconstriction was amplified by endothelium removal. In our study, the same amplification was also obtainedin the presence of methylene blue, a well-known inhibitor of guanylylcyclase (not illustrated), which clearly indicates that VOSO₄vascular activity was not dependent on the presence of endothelium.This effect is probably modulated by endothelium relaxing factorsrather than by liberation of vasoconstrictive mediators. AlthoughChung et al. (1992) described an endothelium-dependent relaxationfactor induced by vanadate when aorta was fully contracted withNEPI, no significant relaxing effect was obtained with VOSO₄ underthe same conditions (data not shown).

On the basis of in vitro experiments showing that vanadate (analogous to phosphate) was able to inhibit calcium ATPases (Raeymaekerset al., 1983; Aureliano and Madeira, 1994), it has been widelyaccepted that inhibition of Ca⁺⁺-ATPase and the consequent intracellular calcium release are responsiblefor vanadate-induced contraction of smooth muscle (Sanchez-Ferreret al., 1988; Ozaki and Urakawa, 1980).

Because compelling studies have noted differences in pharmacological properties between vanadyl and vanadate salts, the roleof calcium in the mechanism of action of VOSO₄ should be re-assessed.

Our results indicate that extracellular calcium influx plays a significant role in determining the amplitude of VOSO₄-inducedcontraction. Indeed, in the presence of the voltage-dependentslow Ca⁺⁺ channel blocker N and in the absence of extracellular calcium,the VOSO₄-induced response was reduced to 70% and 35% of control,respectively. Thus, as is true of vanadate, VOSO₄ contractileactivity in vascular tissue is not totally dependent on extracellularcalcium, which suggests that calcium influx is not the initiatingevent of contraction.

Intracellular calcium release is unlikely to play a role for the following reasons: 1) In calcium-free buffer, a higher proportionof the contraction was conserved for VOSO₄ (35%) than for anyother agent, including NEPI (17% of control). Because NEPI activityis dependent on calcium mobilization from intracellular storesfollowed by calcium entry from extracellular space (Kowarski etal., 1985), comparison of the inhibiting effects of N and calcium-freebuffer on NEPI-induced contraction (16% and 83% of control, respectively)indicates that a major proportion of intracellular mobilizablecalcium is absent in our "calcium-free" experimental conditions.2) TMB-8, a known intracellular calcium mobilization inhibitor,did not modify VOSO₄-induced contraction, either in the presenceor in the absence of extracellular calcium, whereas it did inhibitNEPI-induced contraction. 3) Recent data (Lytton et al., 1992)have shown that though all sarcoplasmic or endoplasmic Ca⁺⁺-ATPases (SERCA) isoforms are inhibited by the Ca⁺⁺-ATPase inhibitor thapsigargin, only the SERCA3 isoform is inhibitedby vanadate. However, SERCA3 is not expressed in muscle, and otherhypotheses must be considered.

It is also possible that the vanadyl ion directly activates the contractile machinery or sensitizes it to the effect of intracellularcalcium. Experiments using skinned rabbit mesenteric arteries $---$ theprocedure is unsuccessful in rat aorta $---$ showed that, much likevanadate (Nayler and Sparrow, 1983; Sunano et al., 1988), VOSO₄not only had no effect in the absence of calcium but also inhibitedcalcium-induced contractions at concentrations higher than 10µM. Therefore, direct activation or sensitizing is unlikely.

Another hypothesis compatible with our results is that VOSO₄ initiates at the cellular membrane level a cascade of eventsleading to sensitization to the effects of intracellular calciumand, secondarily, to the entry of extracellular calcium. Suchindirect sensitization would be impaired by saponin in our experimentalconditions in which agonist-induced contraction is abolished (Itohet al., 1983). In addition, although the aortic tissue accumulatedhigh amounts of vanadium ( $approx$ 4 mM) after a first exposure to VOSO₄,it was still able to respond to a low extracellular concentrationof VOSO₄ (0.1 mM), which further suggests that the "initiatingevent" of contraction is located at the membrane level. A possiblecandidate for that "initiating event" is phospholipase D (PLD)activation. Indeed, PLD can be activated by an increase in tyrosinephosphorylation (Bourgoin and Grinstein, 1992), and an increasein tyrosine phosphorylation is involved in the mechanism of theinsulinomimetic activity of vanadium salts (Brichard and Henquin,1995). Activation of PLD induces the formation of phosphatidicacid and diacylglycerol, which could sensitize the contractilemachinery to calcium without the elevation of intracellular calciumlevels. In our study, the response to VOSO₄ was partially blockedby the PLD inhibitor butanol in the presence or absence of calcium(not illustrated), which suggests the possible participation ofPLD in the VOSO₄-induced response.

Although the initiating event of contraction was not determined in the present study, the possible role of a tyrosine phosphorylationcascade in the regulation of VOSO₄-induced contraction was explored.Indeed, various studies have shown that tyrosine kinase inhibitorsare able to antagonize the smooth muscle contractile activitiesof vanadate (Di Salvo et al., 1994), PV (Laniyonu et al., 1994)and even various agonists such as angiotensin II (Marrero et al.,1994) and NEPI (Toma et al., 1995). These results indicate thattyrosine phosphorylation plays a major role in the regulationof smooth muscle contraction (Hollenberg, 1994). Although thenonspecific tyrosine kinase inhibitor genistein, which blocksATP binding to the enzyme, partially inhibited VOSO₄-, KCl-, AVP-and NEPI-induced contractions, the tyrphostins, which are analogousto phosphorylated tyrosine, dramatically amplified VOSO₄-inducedvasoconstriction. Their potency was correlated with the abilityto antagonize EGF (or PDGF)-induced tyrosine phosphorylation (Gazitet al., 1989). These events occurred both in the presence andin the absence of extracellular calcium and were not dependenton the presence of endothelium. Furthermore, though no changein the degree of tyrosine phosphorylation was apparent with VOSO₄or T₄₇, a major phosphorylation occurred in the presence of bothof them. Unlike VOSO₄, PV, a potent tyrosine phosphatase inhibitor,induced an increase in tyrosine phosphorylation that was preventedby T₄₇, whereas T₄₇ had no influence on PV-induced contraction,as previously shown by Laniyonu et al. (1994).

These data indicate that the correlation between the contractile process and the degree of tyrosine phosphorylation is stillunclear, even with compounds known to act on the level of tyrosinephosphorylation, such as PV. It is surprising that a tyrosinekinase inhibitor, which was able to inhibit the increase of tyrosinephosphorylation induced by PV in our experimental conditions,amplifies both VOSO₄-induced contraction and tyrosine phosphorylation.These data indicate either some additional unknown effect of tyrphostinsor a complex regulatory process in the tyrosine phosphorylationcascade.

In addition, our data confirmed the differences previously noted among vanadium salts in their cellular mechanisms of action.Indeed, the insulinomimetic activity of PV has been related tothe phosphosphorylation of insulin receptor (IR) by inhibitionof the IR tyrosine phosphatase (Shisheva and Shechter, 1993a),whereas vanadyl and vanadate are thought to act on the postreceptorcascade (Shisheva and Shechter, 1993b). Contrary to what was recentlyshown in stretched or pharmacologically stimulated coronary arteries(Adam et al., 1995), the activity of mitogen-activated proteinkinase does not seem to be associated with VOSO₄-induced contraction,because no protein band was detected at 45 kDa. It is interestingto note, however, that among the three substrates (205, 116 and86 kDa) shown by Di Salvo et al. (1993) to be tyrosine-phosphorylatedduring guinea pig taenia coli exposure to vanadate, two of themwere also detected in our experimental conditions after exposureto PV (90 and 200 kDa) or to VOSO₄ and T₄₇ (200 kDa). Furthercharacterization and identification of these bands may yield newinsights into the role of tyrosine phosphorylation in the regulationof smooth muscle contraction.

It was recently shown in rat adipocytes that vanadate was able to stimulate in vitro a staurosporine-sensitive cytosolic tyrosinekinase that might be involved in its insulinomimetic activity(Shisheva and Shechter 1993b; Shechter et al., 1995). Preliminaryresults obtained in our laboratory on vascular tissue indicatedthat staurosporine had no effect on VOSO₄ in the absence of calcium,while blocking the amplification by T₄₇ (data not shown). Furtherstudies are necessary to establish whether such a tyrosine kinaseis involved in the regulation of vascular smooth muscle contractility.

Finally, the question of why a vasoconstricting compound has antihypertensive properties should be asked. When used in vitro,vanadium may have different properties or even properties apparentlyopposite to those it exhibits during chronic in vivo studies,as we recently showed for insulin secretion (Cadène et al., 1996).Another possibility is that although VOSO₄ induces vasoconstrictionin vitro, chronic VOSO₄ treatment lowers insulin resistance $---$ aknown prohypertensive factor $---$ and subsequently corrects hypertension(Bhanot et al., 1995).

In summary, our results indicate that the vascular activity of VOSO₄, 1) is regulated by, but not dependent on, the presenceof endothelium, 2) occurs in the absence of extracellular calciumand in the presence of an intracellular calcium mobilization blockerand 3) is amplified by the tyrosine kinase inhibitors tyrphostins(amplification is associated with high levels of tyrosine phosphorylation).As is true of its insulinomimetic activity, the cellular mechanismof the vascular activity of vanadyl appears different from thatof PV. Further studies will determine the initiating event ofVOSO₄-induced contraction. The surprising amplification of bothVOSO₄-induced vascular response and tyrosine phosphorylation bya relatively specific growth factor tyrosine kinase inhibitormay be of interest for future studies on the regulation of tyrosinephosphorylation cascade and its role in the regulation of vascularcontractility.

	Acknowledgments

The expert technical assistance of Karine Portet and F. Gasc is gratefully acknowledged. The authors also wish to thank Dr.J. Azay for her constructive critique of the manuscript.

	Footnotes

Accepted for publication December 12, 1996.

Received for publication July 9, 1996.

¹ This work was supported by the French Minister of Education (EA 2035) and by grant 701016 of CNAMTS 1991-1994 to FG.

Send reprint requests to: Dr. Gérard Cros, Laboratoire de Pharmacologie, Faculté de Pharmacie, 34060 Montpellier Cedex 02, France.

	Abbreviations

AVP, [Arginine⁸]-vasopressin; EGTA, ethyleneglycol-bis-( $beta$ -aminoethyl ether) N,N $'$ -tetra-acetic acid; N, nicardipine; NEPI, norepinephrine; VOSO₄, vanadyl sulfate; TMB-8, 8-(N,N-diethylamino)octyl 3,4,5-trimethoxybenzoate hydrochloride; T_1,23,47,63, tyrphostins 1, 23, 47, 63; PV, pervanadate; SDS-PAGE, sodium dodecyl sulfate-polyacrylamide.

	References

Top Abstract Introduction Materials & Methods Results Discussion References

Adam, L. P., Franklin, M. T., Raff, G. J. and Hathaway, D. R.: Activation of mitogen-activated protein kinase in porcine carotid arteries. Circ. Res. 76: 183-190, 1995[Abstract/Free Full Text].
Aureliano, M. and Madeira, V. M. C.: Vanadate oligoanions interact with the proton ejection by the Ca²⁺ pump of sarcoplasmic reticulum. Biochem. Biophys. Res. Commun. 205: 161-167, 1994[Medline].
Bevan, A. P., Drake, P. G., Yale, J. F., Shaver, A. and Posner, B. I.: Peroxovanadium compounds: Biological actions and mechanisms of insulin-mimesis. Mol. Cell. Biochem. 153: 49-58, 1995[Medline].
Bhanot, S. and McNeill, J. H.: Vanadyl sulfate lowers plasma insulin and blood pressure in spontaneously hypertensive rats. Hypertension 24: 625-632, 1994[Abstract/Free Full Text].
Bhanot, S., McNeill, J. H. and Bryer-Ash, M.: Vanadyl sulfate prevents fructose-induced hyperinsulinemia and hypertension in rats. Hypertension 24: 625-632, 1994.
Bhanot, S., Michoulas, A. and McNeill, J. H.: Antihypertensive effects of vanadium compounds in hyperinsulinemic, hypertensive rats. Mol. Cell. Biochem. 153: 205-209, 1995[Medline].
Boscolo, P., Carmignani, M., Volpe, A. R., Felaco, M., Del Rosso, G., Porcelli, G. and Giuliano, G.: Renal toxicity and arterial hypertension in rats chronically exposed to vanadate. Occupat. Environ. Med. 51: 500-503, 1994[Abstract/Free Full Text].
Bourgoin, S. and Grinstein, S.: Peroxides of vanadate induce activation of phospholipase D in HL-60 cells. Role of tyrosine phosphorylation. J. Biol. Chem. 267: 11908-11916, 1992[Abstract/Free Full Text].
Brichard, S. M. and Henquin, J. C.: The role of vanadium in the management of diabetes. TIPS 16: 265-270, 1995.
Cadène, A., Gross, R., Poucheret, P., Mongold, J. J., Masiello, P., Roye, M., Ribes, G., Serrano, J. J. and Cros, G.: Vanadyl differently influences insulin response to glucose in isolated pancreas of normal rats after in vivo or in vitro exposure. Eur. J. Pharmacol. 318: 145-151, 1996[Medline].
Cam, M. C., Pederson, R. A., Brownsey, R. W. and McNeill, J. H.: Long-term effectiveness of oral vanadyl sulphate in streptozotocin-diabetic rats. Diabetologia 36: 218-224, 1993[Medline].
Campbell, N. J., Dengel, A. C. and Griffith, W. P.: Studies on transition metal peroxo complexes-X. The nature of peroxovanadates in aqueous solution. Polyheron 8: 1379-1386, 1989.
Cantley, L. C. and Aisen, P.: The fate of cytoplasmic vanadium. J. Biol. Chem. 254: 1781-1784, 1979[Abstract/Free Full Text].
Chiou, C. Y. and Malagodi, M. H.: Studies on the mechanism of action of a new Ca²⁺ antagonist, 8-(N,N-diethylamino)octyl 3,4,5-trimethoxybenzoate hydrochloride, in smooth and skeletal muscles. Br. J. Pharmacol. 53: 279-285, 1975[Medline].
Chung, S. M., Ahn, D. S., Seok, H. S., Jeong, Y. and Kang, B. S.: Effects of vanadate on vascular contractility and membrane potential in the rabbit aorta. Yonsei Med. J. 33: 14-22, 1992[Medline].
Cohen, N., Halberstam, M., Shlimovich, P., Chang, C. J., Shamoon, H. and Rossetti, L.: Oral vanadyl sulphate improves hepatic and peripheral insulin sensitivity in patients with non-insulin-dependent diabetes mellitus. J. Clin. Invest. 95: 2501-2509, 1995.
Cros, G., Mongold, J. J., Serrano, J. J., Ramanadham, S. and McNeill, J. H.: Effects of vanadyl derivatives on animal models of diabetes. Mol. Cell. Biochem. 109: 163-166, 1992[Medline].
Di Salvo, J., Semenchuk, L. A. and Lauer, J.: Vanadate-induced contraction of smooth muscle and enhanced protein tyrosine phosphorylation. Arch. of Biochem. Biophys. 304: 386-391, 1993.
Di Salvo, J., Pfitzer, G. and Semenchuk, L. A.: Protein tyrosine phosphorylation, cellular Ca²⁺, and Ca²⁺ sensitivity for contraction of smooth muscle. Can. J. Physiol. Pharmacol. 72: 1434-1439, 1994[Medline].
Elberg, G., Li, J. and Shechter, Y.: Vanadium activates or inhibits receptor and non-receptor protein tyrosine kinases in cell-free experiments, depending on its oxidation state. J. Biol. Chem. 269: 9521-9527, 1994[Abstract/Free Full Text].
Fabiato, A. and Fabiato, F.: Calculator programs for computing the composition of solution containing multiple metals and ligands used for experiments in skinned muscle cells. J. Physiol. 75: 463-505, 1979.
Gazit, A., Yaish, P., Gilon, C. and Levitzki, A.: Tyrphostin I: Synthesis and biological activity of protein tyrosine kinase inhibitors. J. Med. Chem. 32: 2344-2352, 1989[Medline].
Goldfine, A. B., Simonson, D. C., Folli, F., Patti, M.-E. and Kahn, C. R.: In vivo and in vitro studies of vanadate in human and rodent diabetes mellitus. Mol. Cell. Biochem. 153: 217-231, 1995[Medline].
Hollenberg, M. D.: Tyrosine kinase pathways and the regulation of smooth muscle contractility. TIPS 15: 109-114, 1994.
Itoh, T., Kuriyama, H. and Suzuki, H.: Differences and similarities in the noradrenaline- and caffeine-induced mechanical responses in the rabbit mesenteric artery. J. Physiol. 337: 609-629, 1983.[Abstract/Free Full Text]
Kowarski, D., Shuman, H., Somlyo, A. P. and Somlyo, A. V.: Calcium release by noradrenaline from central sarcoplasmic reticulum in rabbit main pulmonary artery smooth muscle. J. Physiol. 366: 153, 1985.[Abstract/Free Full Text]
Laniyonu, A., Saifeddine, M., Ahmad, S. and Hollenberg, M. D.: Regulation of vascular and gastric smooth muscle contractility by pervanadate. Br. J. Pharmacol. 113: 403-410, 1994[Medline].
Llobet, J. M. and Domingo, J. L.: Acute toxicity of vanadium compounds in rats and mice. Toxicol. Lett. 23: 227-231, 1984[Medline].
Lytton, J., Westlin, M., Burk, S. E., Shull, G. E. and Maclennan, D. H.: Functional comparisons between isoforms of the sarcoplasmic or endoplasmic reticulum family of calcium pumps. J. Biol. Chem. 267: 14483-14489, 1992[Abstract/Free Full Text].
Marrero, M. B., Paxton, W. G., Duff, J. L., Berk, B. C. and Berstein, K. E.: Angiotensin II stimulates tyrosine phosphorylation of phospholipase C-g1 in vascular smooth muscle cells. J. Biol. Chem. 269: 10935-10939, 1994[Abstract/Free Full Text].
Mongold, J. J., Cros, G. H., Vian, L., Tep, A., Ramanadham, S., Sio, G., Diaz, J., McNeill, J. H. and Serrano, J. J.: Toxicological aspects of vanadyl sulfate on diabetic rats: Effects on vanadium levels and pancreatic $beta$ cell morphology. Pharmacol. Toxicol. 67: 192-198, 1990[Medline].
Nakai, M., Watanabe, H., Fujiwara, C., Kakegawa, H., Satoh, T., Takada, J., Matsushita, R. and Sakurai, H.: Mechanism of insulin-like action of vanadyl sulfate: Studies on interaction between rat adipocytes and vanadium compounds. Biol. Pharm. Bull. 18: 719-725, 1995[Medline].
Nayler, R. A. and Sparrow, M. P.: Mechanism of vanadate-induced contraction of airways smooth muscle of the guinea-pig. Br. J. Pharmacol. 80: 163-172, 1983[Medline].
Ozaki, H. and Urakawa, N.: Effects of vanadate on mechanical responses and Na-K pump in vascular smooth muscle. Euro. J. Pharmacol. 68: 339-347, 1980[Medline].
Pumiglia, K. M., Lau, L. F., Huang, C. K., Burroughs, S. and Feinstein, M. B.: Activation of signal transduction in platelets by the tyrosine phosphatase inhibitor pervanadate (vanadyl hydroperoxide). Biochem. J. 286: 441-449, 1992.
Raeymaekers, L., Wuytack, F., Eggermont, J., De Schutter, G. and Casteels, R.: Isolation of plasma-membrane fraction from gastric smooth muscle. Biochem. J. 210: 315-322, 1983[Medline].
Sanchez-Ferrer, C. F., Marin, J., Lluch, M., Valverde, A. and Salaices, M.: Actions of vanadate on vascular tension and sodium pump activity in cat isolated cerebral and femoral arteries. Br. J. Pharmacol. 93: 53-60, 1988[Medline].
Shechter, Y., Li, J., Meyerovitch, J., Gefel, D., Bruck, R., Elberg, G., Miller, D. and Shisheva, A.: Insulin-like actions of vanadate are mediated in an insulin-receptor-independent manner via non-receptor protein tyrosine kinases and protein tyrosine phosphatases. Mol. Cell. Biochem. 153: 39-47, 1995[Medline].
Shimada, T., Shimamura, K. and Sunano, S.: Effects of sodium vanadate on various types of vascular smooth muscles. Blood Vessels 23: 113-124, 1986[Medline].
Shisheva, A. and Shechter, Y.: Mechanism of pervanadate stimulation and potentiation of insulin-activated glucose transport in rat adipocytes: Dissociation from vanadate effect. Endocrinology 133: 1562-1568, 1993a[Abstract].
Shisheva, A. and Shechter, Y.: Role of cytosolic tyrosine kinase in mediating insulin-like actions of vanadate in rat adipocytes. J. Biol. Chem. 268: 6463-6469, 1993b[Abstract/Free Full Text].
Soulié, M. L., Cadène, A., Magous, R., Serrano, J. J., Bali, J. P., Teissedre, P. L. and Cros, G.: Contractile effects of nanomolar concentrations of vanadyl sulphate on gastric smooth muscle cells isolated from normal or diabetic rats. Fund. Clin. Pharmacol. 10: 60-61, 1996[Medline].
St-Louis, J., Sicotte, B., Breton, E. and Srivastava, A. K.: Contractile effects of vanadate on artic rings from virgin and pregnant rats. Mol. Cell. Biochem. 153: 145-150, 1995[Medline].
Sunano, S., Shimada, T., Shimamura, K., Moriyama, K. and Ichida, S.: Extra- and intracellular calcium in vanadate-induced contraction of vascular smooth muscle. Heart Vessels 4: 6-13, 1988[Medline].
Tamura, S., Brown, T. A., Whipple, J. H., Fujita-Yamaguchi, Y., Dubler, R. E., Cheng, K. and Larner, J.: A novel mechanism for the insulin-like effect of vanadate on glycogen synthase in rat adipocytes. J. Biol. Chem. 259: 6650-6658, 1984[Abstract/Free Full Text].
Toma, C., Jensen, P. E., Prieto, D., Hughes, A., Mulvany, M. J. and Aalkjaer, C.: Effects of tyrosine kinase inhibitors on the contractility of rat mesenteric resistance arteries. Br. J. Pharmacol. 114: 1266-1272, 1995[Medline].
Yale, J. F., Lachance, D., Bevan, A. P., Vigeant, C., Shaver, A. and Posner, B. I.: Hypoglycemic effects of peroxovanadium compounds in Sprague-Dawley and diabetic BB rats. Diabetes 44: 1274-1279, 1995[Abstract].

This Article

	Abstract
	Full Text (PDF)
	Submit a response
	Alert me when this article is cited
	Alert me when eLetters are posted
	Alert me if a correction is posted
	Citation Map

Services

	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager

Citing Articles

	Citing Articles via Google Scholar

Google Scholar

	Articles by Cadène, A.
	Articles by Cros, G.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Cadène, A.
	Articles by Cros, G.

Characterization of Vanadyl Sulfate Effect on Vascular Contraction: Roles of Calcium and Tyrosine Phosphorylation1

Characterization of Vanadyl Sulfate Effect on Vascular Contraction: Roles of Calcium and Tyrosine Phosphorylation¹