Intracellular and extracellular calcium utilization during hypoxic vasoconstriction of cyclostome aortas

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Intracellular and extracellular calcium utilization during hypoxic vasoconstriction of cyclostome aortas

Michael J. Russell¹, Nancy J. Pelaez², C. Subah Packer², Malcom E. Forster³, and Kenneth R. Olson¹

¹ Indiana University School of Medicine, South Bend Center for Medical Education, University of Notre Dame, Notre Dame 46556; ² Department of Cellular and Integrative Physiology, Indiana University School of Medicine, Indianapolis, Indiana 46202; and ³ Department of Zoology, University of Canterbury, Private Bag 4800, Christchurch, New Zealand

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Hypoxic vasoconstriction (HV) is an intrinsic response of mammalian pulmonary and cyclostome aortic vascular smooth muscle.The present study examined the utilization of calcium during HVin dorsal aortas (DA) from sea lamprey and New Zealand hagfish.HV was temporally correlated with increased free cytosolic calcium(Ca) in lamprey DA. Extracellularcalcium (Ca) did not contribute significantlyto HV in lamprey DA, but it accounted for 38.1 ± 5.3% of HV inhagfish DA. Treatment of lamprey DA with ionomycin, ryanodine,or caffeine added to thapsigargin-reduced HV, whereas HV was augmentedby BAY K 8644. Methoxyverapamil (D600) in zero Cadid not affect HV in lamprey DA, nor did it prevent further constrictionwhen Ca was restored during hypoxiain hagfish DA. Removal of extracellular sodium (Na)caused a constriction in both species. Lamprey DA relaxed to prehypoxictension following return to normoxia in zero Na,whereas relaxation was inhibited in hagfish DA. Relaxation followingHV was inhibited in lamprey DA when Naand Ca were removed. These resultsshow that HV is correlated with [Ca²⁺]_c in lamprey DA and that Na⁺/Ca²⁺ exchange is used during HV in hagfish but not lamprey DA. Multiplereceptor types appear to mediate stored intracellular calciumrelease in lamprey DA, and L-type calcium channels do not contributesignificantly to constriction in eithercyclostome.

vascular smooth muscle; hagfish; lamprey

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

HYPOXIC PULMONARY VASOCONSTRICTION (HPV) in mammalian pulmonary vascular smooth muscle is mediated by both endothelial anddirect smooth muscle effects (4, 5, 11, 33), and itmatches ventilation to perfusion by decreasing blood flow to underventilatedalveoli. The calcium dependence of HPV in mammals has been welldocumented (15, 24). During HPV, a rise in free cytosoliccalcium (Ca) accompanies a seriesof plasma membrane channel events that lead to full depolarizationand vasoconstriction, although the order and relative importanceof these events remain controversial (15, 23, 32, 34,35).

Vasoconstriction appears to be prevalent in the respiratory circuits of most nonmammalian vertebrates during hypoxia (10,12); however, the role of calcium and the intracellular mechanismsmediating these responses have not been examined. We have recentlydescribed for the first time a profound hypoxic vasoconstriction(HV) in postgill, but not pregill, systemic vessels from the NewZealand hagfish, the Pacific hagfish, and the sea lamprey (22).Although the physiological significance of this response in theseanimals is not presently known, we previously hypothesized thatcyclostomes may be a useful model with which to study the intrinsicmechanisms underlying HPV (22).

The purpose of the present study was to characterize the role of calcium during HV in the primitive cyclostome model. We examinedthe utilization of stored intracellular calcium (Ca)and extracellular calcium (Ca) duringthe hypoxic response in postgill systemic arteries [dorsal aortas(DA)] from sea lamprey and New Zealand hagfish. Results indicatethat in lamprey DA, 1) Ca is mobilizedduring HV and the rise in [Ca²⁺]_c during HV is temporally correlated with contractile force,2) Ca is not required for HV, 3) L-typecalcium channels are not activated for Cainflux during HV, 4) Ca²⁺ stores are used differently during HV than during adrenergicstimulation and are not easily depleted using standard pharmacologicalagents, and 5) Na⁺/Ca²⁺ exchange is present, but extracellular sodium (Na)is not required for relaxation following HV. The hypoxic responsein hagfish DA is somewhat different in that Cainflux contributes significantly to the overall magnitude of HV,and Na is requisite for relaxationfollowingHV.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Animals. Sea lamprey (Petromyzon marinus, 130-450 g) were captured by the U. S. Geological Survey, Biological Resources Division, inMichigan during the spring-summer spawning migration and airliftedto Notre Dame. At Notre Dame, they were housed in 500-liter rectangulartanks in aerated, flowing well water (15°C) and exposed to a 12:12-hlight-dark photoperiod. They were not fed. Lamprey were anesthetizedwith benzocaine (ethyl-p-aminobenzoate; 1:5,000 wt:vol), and thevessels were dissected out and placed in lamprey HEPES-bufferedsaline (LHBS) at 4°C.

New Zealand hagfish (Eptatretus cirrhatus, 800-2,100 g) were collected off Motunau Beach, New Zealand, and were transferredto Christchurch where they were held in aquariums containing runningseawater (16°C). They were held at least 1 wk before experimentationand were not fed during this period. Hagfish were anesthetizedwith benzocaine (1:5,000 wt:vol), and vessel segments were dissectedout, rinsed with a modified hagfish HEPES-buffered saline (HHBS),and stored in fresh HHBS at 4°C untiluse.

Vascular smooth muscle. DA from lamprey and hagfish were cut transaxially into 3- to 4-mm rings. Rings were hung on 280-µm stainless steel hooks andsuspended in 20-ml water-jacketed (15°C) smooth muscle chambers(21) containing the appropriate saline. In experiments withlamprey, stainless steel hooks attached vascular rings to plasticdiffusers inside the smooth muscle chambers. The diffusers weredesigned and fabricated in our lab to allow rapid mixing of chemicalsand gasses while protecting the rings from direct gas contact,thereby reducing turbulence. The diffusers were attached to lidsto minimize surface gas exchange with the atmosphere and facilitatedthe addition of drugs and bath changes. Hypoxia was administeredby aerating the muscle chambers with 100% nitrogen gas (N₂), andnormoxia was restored by aeration with room air. Tension was measuredwith Grass FTO3C force-displacement transducers and recorded oneither a computer-interfaced Gould 8000 series or Grass model8TC polygraph. Data were collected electronically using LabtechNotebook data-collection software (Laboratory Technologies, Andover,MA).

In experiments with New Zealand hagfish DA, tension was measured with Ugo Basile (Comerio, Italy) isometric force transducers(model 7004), and the signals were amplified with Gould (ValleyView, OH) transducer preamplifiers (model 1350). Signals weredisplayed on a Yokogawa LR4100E recorder (Yokogawa Electric, Tokyo,Japan) and recorded electronically with Labtech Notebook as describedabove. Diffusers were not available for these experiments. Inall instances, polygraph sensitivities were set to detect changesas small as 5mg.

Optimal resting tension for each of the different types of vessels used in this study was determined in preliminary experimentsby measuring the magnitude of 80 mM KCl contractions over a rangeof resting tensions from 0 to 1.5 g. Optimal resting tension (500-750mg) was subsequently applied to lamprey vessels for at least 30min before experimentation. Hagfish aortas were equilibrated for1 h before experimentation due to their slower response characteristics(22). Vessels were precontracted with either KCl (80-90 mM),the acetylcholine analog carbamylcholine chloride (carbachol,10⁵ M), or epinephrine (10⁵ M) and washed three times or aerated with 100% N₂ for 15-20 minand returned to room air. Baseline tension was then reestablishedfor at least 30 min before furtherexperimentation.

The effects of hypoxia on vessels pretreated with various agonists or drugs that have been shown to affect [Ca²⁺]_c were tested in baths of the appropriate buffered saline, containingeither 2 mM Ca²⁺ (lamprey), 5 mM Ca²⁺ (hagfish), or without Ca²⁺ but in the presence of the calcium-chelating agent EGTA (200µM). Agonists and drugs were applied to lamprey vessels 15 minbefore hypoxia. The slower responding hagfish vessels (22) weretreated for 1 h before hypoxia. In another series of experiments,helical strips were cut from lamprey DA and suspended in a tissuefluorometer system (see Fura 2-AM below) to simultaneously measurechanges in intracellular [Ca²⁺] andforce.

Fura 2-AM. The experimental apparatus for measuring [Ca²⁺]_c was similar to that described previously by Chen and Rembold (7). HelicalDA strips from lamprey were stretched to optimal length and loadedwith 5 µM fura 2-AM and 0.3 mM neostigmine in cold LHBS for 90min. Fura 2 fluorescence is bright enough following this loadingprotocol to permit measurements at intracellular dye concentrationsdetermined in rats to have no effect on calcium buffering or dampingof calcium transients that might interfere with excitation-contractioncoupling (7). Fluorophore leakage does not significantly contributeto the fluorescence measurements, because 1) bath perfusion ratesof 1 ml/min diluted any leaking indicator, and 2) the illuminatedarea includes only a small volume of bath solution. The tissuewas then mounted isometrically to a capacitive force transducerand bathed in a 3-ml water-jacketed tissue bath perfused withroom temperature LHBS bubbled with room air. A bifurcated lightguide was placed 0.5-1.0 mm from the lumenal surface of a 1.25-to 1.75-mm-wide smooth muscle strip. Excitation light was passedthrough one arm of the bifurcated light guide to illuminate a1.5-mm diameter spot near the center of a smooth muscle stripthat covered 75-100% of the light beam. Emitted light was passedretrograde through the other arm of the bifurcated light guideand then through a 525 ± 30-nm filter to a Throm EMI 9828 photomultipliertube. The demodulated fluorescence outputs (University of PennsylvaniaBiomedical Instrumentation Group) and the raw force signals wereconverted to digital signals by a Metrabyte Dash 16 AD board andstored on a personal computer. Cawas measured according to the method of Bruschi et al. (6).Briefly, changing calcium concentrations can be correlated withthe fluorescence ratio at 340/380 nm excitation after subtractingbackground fluorescence at each excitation wavelength. Backgroundfluorescence was determined at the end of each experiment by lysingcells with 0.2 mM MnCl₂ solution, followed by 5 mM MnCl₂ solutionto quench fura 2 fluorescence, then measuring autofluorescenceat pertinent wavelengths (340- and 380-nm excitation, 525-nm emission).Data were used from experiments where fluorescence at 380 nm wasat least 2.5 times as great as the background signal, and the340- and 380-nm fluorescence signals changed in opposite directionin response to the agonist. Simultaneous changes in isometricforce and 340/380 nm fluorescence ratios were recorded in responseto 90 mM KCl (maximum response) and in response to hypoxia. Changesin both tension and fluorescence ratio at 340/380 nm to hypoxiawere expressed as a percentage of the maximumresponse.

Chemicals. The composition of LHBS was as follows (in g/l): 8.74 NaCl, 0.22 KCl, 0.29 CaCl₂ · 2 H₂O, 0.14 MgSO· 7 H₂O, 0.72 HEPES acid form, 1.8 HEPES sodium salt, and 0.9glucose, pH 7.8. The composition of HHBS was as follows (in g/l):27.70 NaCl, 0.60 KCl, 0.75 CaCl₂ · 2 H₂O, 0.75 MgSO· 7 H₂O, 0.72 HEPES acid form, 1.82 HEPES sodium salt, and 1.00glucose, pH 7.8. All chemicals were purchased from Sigma Chemical(St. Louis,MO).

Calculations. At the end of an experiment, the vessel was blotted on paper toweling, weighed, and vessel tension was normalized to wet weight,i.e., milligrams of tension per grams wet weight. Because thehypoxic responses of individual vessels were reproducible (22),a vessel served as its own control and treatment effects werestatistically examined by paired t-test or repeated-measures tests.Results are presented as means ± SE. Student's t-test and ANOVAwere used for comparisons between vessels. The fiducial limitof significance was set at P $<=$ 0.05.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Sea lamprey. Contractile force and [Ca²⁺]_c increased simultaneously when DA were exposed to either 90 mM KCl or hypoxia (Fig. 1A). A temporalcorrelation between the active force generated by HV in lampreyDA and a rise in [Ca²⁺]_c was noted in all vessels treated. The active force, normalizedas the ratio of the force generated by HV to the force generatedby depolarization with 90 mM KCl, was linearly related to thechange in intracellular calcium, normalized as the ratio of thecalcium signal produced by HV to the calcium signal produced during90 mM KCl (Fig. 1B).

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Fig. 1. A: representative traces showing simultaneous measurement of fura 2 signal [cytosolic calcium concentration ([Ca²⁺]_c); top trace] and force (bottom trace) during stimulation with 90 mM KCl or hypoxia (N₂). B: correlation between active force (in g) and [Ca²⁺]_c in lamprey dorsal aortas (DA). The hypoxia tension (N₂) and Ca responses are expressed relative to a maximal KCl (80 mM) response; n = number of fish.

The magnitude of HV was not significantly affected by either prior removal of Ca (105.4 ± 12.4%of control) or the restoration of Ca(2 mM) during hypoxia (118.2 ± 12.0% of control, n = 4 fish; Fig.2A). Substitution of Na with sucrose(290 mM; Fig. 2B) produced a constriction in lamprey DA that wassignificantly stronger than the magnitude of the initial HV (n= 8 fish), and tension was further enhanced by subsequent exposureto hypoxia. The magnitude of this HV in zero [Na⁺]_o was not significantly different from the previous control HV,and vessels relaxed to prehypoxia levels when aerated with roomair. Removal of Na in the absence ofCa did not produce a significant contraction;however, subsequent application of hypoxia produced a significantlystronger HV (n = 8 fish) than a control HV in normal [Na⁺]_o, and vessel tension remained at 39.9 ± 2.2% of the HV whenvessels were returned to normoxia (Fig. 2C). All vessels in Fig.2, B and C, relaxed to baseline when [Na⁺]_o was restored.

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Fig. 2. Effects of extracellular calcium (Ca) and extracellular sodium (Na) on hypoxic vasoconstriction (HV) in lamprey DA. A: HV in zero [Ca²⁺]_o is not different from control HV in normal (2 mM) [Ca²⁺]_o. Restoration of [Ca²⁺]_o produces a slight but insignificant increase in tension. B: removal of Na significantly increases tension compared with a control HV (N₂). HV in the absence of Na is unaffected. Return to normoxia (Air) relaxes vessel to prehypoxic level; however, full relaxation is not achieved until [Na⁺]_o is restored. C: in the absence of Ca, removal of Na produces a transient contraction that is weakly sustained. Under these conditions, HV is augmented, prehypoxic tension is not restored on return to air, and full relaxation is achieved only when [Na⁺]_o is restored.

Pretreatment of lamprey DA with the L-type Ca²⁺ channel antagonist methoxyverapamil (D600; 10⁴ M) did not affect total tension during HV (Fig. 3), but additionof the L-type Ca²⁺ channel agonist BAY K 8644 (1 µM) to the baths significantlyenhanced HV to 122.6 ± 6.9% of control. Addition of the sarco/endoplasmicreticulum Ca²⁺ ATPase (SERCA) inhibitor cyclopiazonic acid (CPA; 5 µM) beforehypoxic exposure also increased HV significantly in D600-treatedvessels (177.0 ± 26.7% of control; Fig. 3). However, no differencewas noted in the hypoxic response of CPA-treated lamprey DA inzero Ca compared with HV of untreatedvessels in zero Ca (Fig. 4). In calcium-repleteLHBS but without D600, treatment with CPA increased baseline tensionin four of six vessels treated. HV was augmented an average of20%, and these vessels also did not relax completely on returnto normoxia (Fig. 3, inset).

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Fig. 3. Effects of L-type Ca²⁺ channel antagonist methoxyverapamil (D600) and agonist BAY K 8644 (BAY) on HV in lamprey DA and the effect of the sarco/endoplasmic reticulum Ca²⁺ ATPase pump inhibitor cyclopiazonic acid (CPA) on HV in D600-treated vessels. Values expressed as a percentage of an initial control (dashed line) hypoxia (N₂) response ± SE; (n) = number of fish. *Significantly different from control response (P $<=$ 0.05). Inset: effect of CPA on HV in untreated DA from 1 fish.

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Fig. 4. Effects of Ca²⁺-specific pharmacological agents on lamprey HV in zero [Ca²⁺]_o; CPA, ionomycin (IO), ryanodine (RY), thapsigargin (TH), and caffeine added to TH-treated vessels. Values are means ± SE and are given as a percentage of control. *Significant difference from an initial HV (P $<=$ 0.05); (n) = number of fish.

The Ca²⁺ ionophore ionomycin (IO; 50 µM) and the ryanodine-sensitive receptor agonist ryanodine (RY; 50 µM) significantly reducedHV to 36.2 ± 7.5 and 60.3 ± 8.2% of their respective control responsesin zero Ca (Fig. 4). The SERCA pumpinhibitor thapsigargin (TH; 5 µM) did not affect the magnitudeof HV (Fig. 4). Addition of 5 mM caffeine in the absence of Cadid not reduce HV in DA from two fish; however, caffeine addedto vessels pretreated with TH (Fig. 4) significantly reduced HVto 27.4 ± 5.9% ofcontrol.

Ca required for HV in lamprey DA was depleted more effectively by adrenergic stimulation thanby repeated hypoxic exposure (Fig. 5). Vessels were repeatedly(8 times) exposed to 20-min bouts of hypoxia in Ca²⁺-free baths before a significant reduction in HV was noted (Fig.5A). Applying hypoxia to vessels stimulated with 10⁵ M norepinephrine (NE) after 13 consecutive hypoxic exposuresin the absence of Ca produced a hypoxicconstriction as strong as the initial HV in normal Ca,and a final hypoxic exposure following this NE stimulation produceda constriction as strong as the first HV in zero Ca²⁺ (Fig. 5A). Repeated NE treatment (12 times) in zero Careduced HV to near baseline, yet hypoxic exposure during the 12thNE stimulation of vessels in zero Caproduced contractions as strong as the HV that followed the firstNE treatment (Fig. 5B). HV was significantly reduced in unstimulatedvessels when hypoxia followed a single NE treatment in Ca,and HV following the final NE washout in vessels exposed to 11NE treatments remained significantly lower than the first HV inzero Ca²⁺ (Fig. 5B).

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Fig. 5. Effect of repeated hypoxia (A) and norepinephrine (NE) treatment (B) on lamprey DA in zero [Ca²⁺]_o. Values are expressed as a percentage of an initial HV in 2 mM Ca (means ± SE). Black bars are NE responses, dotted bars are hypoxia (N₂), and striped bars represent N₂ response in NE-stimulated vessels. Dashed horizontal lines indicate 50 and 100% of control HV. *, $Dagger$ Significant difference from like control. *Significant difference from control HV in 2 mM [Ca²⁺]_o; $Dagger$ significant difference from control NE response in 2 mM [Ca²⁺]_o. P $<=$ 0.05; n = number of fish. Experiments were conducted over 2 consecutive days.

New Zealand hagfish. HV in hagfish was significantly reduced by 38.1 ± 4.8% of the previous control HV (n = 6 fish) in the absence of Ca.Subsequent restoration of [Ca²⁺]_o to normal (5 mM) increased HV to 156.8 ± 15.6% of control (Fig.6A).

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Fig. 6. A: myography of the typical contractile response of isolated hagfish DA to hypoxia in 5 mM [Ca²⁺]_o. B: effect of restoring 5 mM [Ca²⁺]_o to the bath during hypoxia. C: response of hagfish DA to [Na⁺]_o replacement with sucrose and to hypoxia (N₂) in the absence of Na. The vessel does not relax on restoration of normoxia, but it fully relaxes when [Na⁺]_o is restored.

The effect of replacing HHBS Na⁺ with an osmotically equivalent amount of sucrose (800 mM) is shown in Fig. 6B. Naremoval produced a significant constriction that was further enhancedby hypoxic exposure (n = 4 fish). These vessels did not relaxon return to normoxia but rapidly relaxed when [Na⁺]_o was restored during normoxicexposure.

HV in DA pretreated with D600 in zero Ca was reduced by 44.9 ± 3.0% (n = 6 fish). Tension wasrestored to 149.2 ± 15.7% of a previous HV by addition of Ca²⁺ while still in the presence of D600. The presence of D600 didnot significantly affect either the reduction of HV in zero Caor the augmented HV observed with [Ca²⁺]_orestoration.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The present experiments showed that HV in systemic arteries from two cyclostomes, the sea lamprey and the New Zealand hagfish,is a calcium-dependent response that uses intracellular (lamprey)or intracellular and extracellular calcium stores (hagfish). Theactive force generated during HV was temporally correlated withchanges in [Ca²⁺]_c in lamprey DA, indicative of the direct involvement of Ca²⁺ in the stimulus-response coupling of hypoxia to the activationof this vascular smooth muscle. To our knowledge, this is thefirst time active force and Ca measurementshave been taken simultaneously in any fish vessel. Lamprey HVwas reproducible over multiple hypoxic exposures in the absenceof Ca. Pretreatment of tissues withan L-type Ca²⁺ channel antagonist had no effect on Caentry during hypoxic episodes in either species, yet HV was significantlyincreased in lamprey DA treated with an L-type Ca²⁺ channel agonist. The magnitude of HV in lamprey DA was significantlyreduced in zero Ca by treatment withionomycin or RY, or by the addition of caffeine to TH-treatedvessels. NE more effectively depleted HV-used Cathan repeated hypoxia, and prestimulation with NE augmented HVafter separate NE and hypoxia responses were nearly abolished.Removal of sodium from the extracellular milieu inhibited relaxationof hypoxia-stimulated vessels. However, these responses variedbetween the two cyclostomes. Results clearly show that, althoughthe specifics of Ca²⁺ use may be different in cyclostomes and mammals, an increasein [Ca²⁺]_c is a requisite for HV in cyclostomes as it is forHPV.

Ca²+ dependence. The calmodulin-dependent cross- bridge cycling between actin and myosin filaments that produces contraction in mammalian smoothmuscle is mediated by an increase in [Ca²⁺]_c (1, 14), and an increase in [Ca²⁺]_c is, for the most part, temporally coupled with active tensionduring HPV (24). The present study shows for the first timethat HV in lamprey is also a calcium-mediatedprocess.

Contraction of lamprey DA was temporally coupled with [Ca²⁺]_c during stimulation with either 90 mM potassium chloride or hypoxia(Fig. 1). A similar rise in [Ca²⁺]_c accompanied HPV in rat pulmonary arteries, except that therat response included a transient [Ca²⁺]_c-independent relaxation that separated the initial and sustainedcontractions (24). This difference between the lamprey and ratresponses is likely due to additional factors modulating rat HPVthat are not present in lampreyHV.

The attenuating effect of the Ca²⁺ ionophore IO on the magnitude of HV in lamprey DA (Fig. 4) provides additional evidence thatan increase in [Ca²⁺]_c was required for HV. Ionomycin caused a transient contractionin lamprey DA in zero Ca that wasgreater than a control HV. Presumably, this was due to releaseof Ca from the sarcoplasmic reticulum(SR), which has also been shown to occur in mammalian vascularsmooth muscle (6). After the initial ionomycin spike, tensionreturned to near baseline within 10 min, suggesting that ionomycinalso increased Ca efflux from theDA. Similar responses have also been reported in mammalian vascularsmooth muscle where, in the absence of Ca,ionomycin promotes Ca efflux fromthe cell, partly by the action of IO as an ionophore and partlythrough IO activation of Na⁺/Ca²⁺ exchange (28).

Due to the limited availability of animals, the force-[Ca²⁺]_c relationship during HV in the hagfish was not examined in thepresent study. However, given the shared characteristics of lampreyand hagfish HV such as the strength, duration, endothelium independence,and reproducibility of HV (22), it seems reasonable to assumethat an increase in [Ca²⁺]_c is likely involved during HV in hagfish DA aswell.

Contributions of Ca and Ca during HV. Ca is required for HPV in most mammalian tissues (8, 9, 13, 16, 25, 34); however,the relative contributions of Ca andCa vary among species. Rat (25)and fetal lamb pulmonary vascular smooth muscles (8) have beenshown to be completely dependent on Ca,and HPV was markedly decreased by removal of Cain perfused ferret lungs (13). In isolated pulmonary arteriesfrom the cat, Harder et al. (16) found that raising or lowering[Ca²⁺]_o produced concomitant changes in the magnitude of HPV, whichcould be abolished by Ca blockade.Ca release was shown to be an initialstep in HPV of isolated rat pulmonary arteries (15) and of culturedpulmonary arterial smooth muscle cells (26). These studies alsoshowed HPV to be ultimately dependent on Ca.Experimental conditions during the present lamprey and hagfishDA studies were nearly identical, excluding differences in salinecomposition. However, the Ca and Carequirements between these species during HV were quitedifferent.

Results of the current study show that Ca is not requisite for HV in lamprey DA and that HV inthese tissues is mediated primarily by Ca.The magnitude of HV in lamprey DA was not significantly affectedby the removal (105% of control) or restoration (118% of control)of Ca (Fig. 2A). These results aresimilar to those obtained by Jabr et al. (17), who concludedthat HPV in small isolated canine pulmonary arteries is mediatedmainly by the release of Ca.

Removal of Ca from hagfish DA reduced HV to only 62% of a control response. Thus it appears thatHV in hagfish is more like HPV than is the lamprey HV in thatit is at least partly dependent on the influx of Ca.

Ca²+ channels. Large-conductance (L-type) Ca²⁺ channels appeared to be present in lamprey DA, because HV was augmented by pretreatment withthe L-type channel agonist BAY K 8644 (Fig. 3). However, L-typechannels were either inactive or insignificant during HV in thesevessels, because HV was independent of Caand was unaffected by D600 in the presence of 2 mM Ca(Fig. 3). Treatment with the SERCA pump inhibitor CPA augmentedHV in normal [Ca²⁺]_o (Fig. 3, inset), and this augmentation was not affected bythe presence of D600 (Fig. 3). Additionally, CPA had no effecton HV in zero Ca (Fig. 4). These resultssuggest that either the entry of Caindependent of L-type channels was responsible, in part, for theaugmented HV or that CPA blocked the export of Ca.

Hagfish DA used Ca during HV (Fig. 6B). However, the inability of D600 to affect HV suggests thatL-type Ca²⁺ channels are either not present or inactive and that an alternatepathway for Ca influx is used in thesefish. The full recovery of tension following restoration of Caeven in the presence of D600 supports the latter conclusion. Twopathways of Ca influx have been proposedto mediate the strength and duration of HPV. The first pathwaywas described in pulmonary vessels from adult sheep and involvesvoltage-dependent Ca influx throughL-type Ca²⁺ channels (34). L-type channels are sensitive to D600 blockade,which attenuates HPV (20). The second pathway, described byRobertson et al. (25) in rat pulmonary arteries, involves thevoltage-independent capacitative Caentry (CCE) during HPV. A pathway that is independent of L-typechannels and perhaps via a mechanism similar to CCE seems themost likely method for Ca influx duringHV in hagfishDA.

SR Ca²+ receptors. Two specific receptors mediate Ca release from the SR in mammalian vascular smooth muscle; thosesensitive to the plant alkaloid RY and those sensitive to inositol1,4,5-trisphosphate (IP₃). RY-sensitive receptors are opened byRY, Ca²⁺, or caffeine (19). IP₃-sensitive receptors on the SR may beopened directly by Ca²⁺ (19). Both receptor types can occur in the same vascular smoothmuscle (17). Calcium stores sensitive to IP₃ and RY appear tobe organized into spatially distinct compartments in pulmonaryarteries but are conjoined in renal arteries, allowing differential,agonist-dependent release of calcium in the former but not inthe latter (18). SR receptors in lamprey DA have not been previouslycharacterized. Our experiments indicate that these vessels alsopossess more than one type and that they may be spatially or functionallydistinct.

HV in lamprey DA appears to be at least partly dependent on an RY-sensitive receptor, because treatment with RY reduced theresponse by 40%. Neither of the SERCA pump inhibitors (TH andCPA) nor caffeine alone reduced HV in the absence of Ca.However, in the presence of TH, caffeine reduced HV by 80% (Fig.4). This suggests that at least 20% of the RY-like receptors wereactivated by caffeine. Of the three RY receptor (RYR) isoformsthat have been described, the RYR₂ type is the most caffeine sensitive(19). Thus a RYR₂-like receptor may be one of the caffeine-sensitivereceptor types present in lampreyDA.

An IP₃-sensitive receptor appears to be present in lamprey DA, based on the assumption that an NE contraction is mediatedby IP₃ in these vessels as it is in mammalian vascular smoothmuscle (19). The apparent rise in [Ca²⁺]_c that accompanies the NE response and the fact that in zeroCa the NE effect is rapidly diminished(Fig. 5B) support this conclusion. HV in lamprey DA may also beat least partly dependent on IP₃-sensitive Carelease because repeated NE treatments in zero Caeffectively reduced HV (Fig. 5B).

Ca²+ cycling during HV. Ca²⁺ cycling during hypoxia in lamprey DA may involve the release and/or reuptake of Ca²⁺ by intracellular stores (hypoxia-dependent stores) that are spatiallyor functionally different from the Ca²⁺ stores used by other contractile agonists. Caappeared to be more efficiently recycled during HV than duringadrenergic stimulation in these fish, because in zero Ca,repeated hypoxic exposures (8 times) were required compared withone NE treatment before a significant drop in HV was registered(Fig. 5, A and B). These results suggest that lamprey DA possessefficient mechanisms for uptake of Cainto these hypoxia-dependent stores. Inhibition of Na⁺/Ca²⁺ exchange during hypoxia may enhance Cauptake into the hypoxia-dependent stores by reducing Caefflux.

Hypoxia does not affect [Ca²⁺]_c in mammalian pulmonary vascular smooth muscle unless a prior preconditioning stimulus is applied(3). This has been proposed to be due to increased Ca²⁺ sequestration during hypoxia, which effectively isolates Ca²⁺ from contractile elements (28). Preconditioning with anotheragonist is thought to increase [Ca²⁺]_c sufficiently to overcome sequestration, thus effecting a hypoxicresponse (30). No prestimulation of lamprey DA was requiredfor HV. However, as we have described previously (22), HV wasaugmented in NE-pretreated lamprey vessels, implying that thereis a conditioning effect in lamprey DA as well. In the presentstudy, prestimulation with NE appeared to provide additional Cafor HV in zero Ca, because HV wasaugmented in NE-treated vessels that appeared to be Ca²⁺ deplete, i.e., no longer responsive to NE or hypoxia (Fig. 5,A and B). This augmentation may be due to uptake of Careleased from NE-activated stores into hypoxia-dependent stores.A similar Ca²⁺ transfer between distinct stores has been noted in cultured ratfetal aorta cells (29).

Na+/Ca²⁺ exchange during HV. The present study suggests that lamprey DA possess an active Na⁺/Ca²⁺ antiporter and that this exchange mechanism may be inhibitedduring HV. However, our results indicate that neither Cainflux nor Na⁺/Ca²⁺ exchange is important during HV or recovery from HV in thesevessels.

The presence of a functional Na⁺/Ca²⁺ antiporter in lamprey DA was suggested in the present study, because removal of Nain normal [Ca²⁺]_o produced a significant contraction (Fig. 2B), whereas removalof Na in the absence of Cafailed to increase tension (Fig. 2C). In mammalian vascular smoothmuscle with a functional Na⁺/Ca²⁺ antiporter, elimination of Na in thepresence of normal [Ca²⁺]_o removes the gradient for Na entryinto the cell. Ca extrusion from thecell is decreased, and the cell constricts (2). The lampreyresults imply that an influx of Camediates the contraction caused by Naremoval and that, under resting conditions, tension remains stablethrough continual Na⁺/Ca²⁺ antiporter activity. Removal of Caalone did not significantly lower tension in lamprey DA (Fig.2C), which suggests that maintenance of basal tone in these vesselsdoes not require Ca.

The Na⁺/Ca²⁺ antiporter appears to have been inhibited in lamprey DA during hypoxia. This is indicated by the ability of lampreyDA to endure multiple hypoxic bouts in zero Cabefore HV is diminished (Fig. 5A) and may explain, in part, theapparent Ca sparing during hypoxiacompared with stimulation with NE in zero Ca(Fig. 5, A and B). These results agree favorably with those obtainedin mammals. Restoration of [Ca²⁺]_c following the activation of mammalian vascular smooth musclehas been attributed, in part, to a Na⁺/Ca²⁺ antiporter on the plasmalemmal membrane (36). Inhibition ofthis Na⁺/Ca²⁺ exchange mechanism during hypoxia has been described in mammalianpulmonary arteries (31).

Neither Ca influx nor Na⁺/Ca²⁺ exchange was important during HV in lamprey DA, because HV in theabsence of Ca or Nawas not significantly different from a control HV (Fig. 2, A andB) and vessels relaxed to prehypoxia levels on return to normoxia.However, full relaxation was not achieved until [Na⁺]_o was restored (Fig. 2B). These data imply that an increase infree [Ca²⁺]_c resulted from inhibition of the Na⁺/Ca²⁺ antiporter and that this Ca was responsiblefor activating contractile elements distinct from those used duringHV. Removal of Na in the absence ofCa did not significantly increasetension, yet it increased HV and inhibited relaxation on returnto normoxia (Fig. 2C). Therefore, Careleased during HV under these conditions may also have reachedcontractile elements not normally activated during HV, perhapsdue to the absence of both Ca effluxand Caentry.

The presence of an Na⁺/Ca²⁺ exchange mechanism was also indicated in hagfish DA in the present study. Removal of Nafrom [Ca²⁺]_o-replete solutions constricted hagfish DA (Fig. 6B). Althoughlamprey and hagfish DA both constricted further to hypoxia, hagfishDA did not relax on return to normoxia until bath [Na⁺]_o was restored. The failure of these vessels to relax shows thatan Na⁺/Ca²⁺ exchange mechanism is clearly a requisite for Caextrusion during HV in hagfishDA.

Perspectives

We have previously described HV in cyclostomes as the possible antecedent for HPV. The present study examined the utilizationof Ca²⁺ during HV in two species of cyclostomes, and the results suggestthat Ca²⁺ handling during HV in lamprey DA relies on many of the same intrinsicmechanisms that are used during HPV. Ca²⁺ handling during HV indicated by this study offers a mechanisticcorollary for HPV in the simplest vertebrates and further supportsour assumption that HPV has a long lineage in vascular smoothmuscle.

	ACKNOWLEDGEMENTS

The authors thank B. Swink, U. S. Geological Survey, Biological Resources Division, Millersberg, MI, and D. Tattle, Universityof Canterbury, Christchurch, New Zealand, for help with animalcollection, and C. Komanecki for excellent technicalassistance.

	FOOTNOTES

This research was supported in part by National Science Foundation Predoctoral Fellowship No. 51750926573 (M. J. Russell),a University of Canterbury research grant (M. E. Forster), anAmerican Lung Association Career Investigator Award (C. S. Packer),and National Science Foundation Grant No. IBN 9923306 (K. R. Olson).K. R. Olson was a recipient of an Erskine Fellowship from theUniversity of Canterbury. N. J. Pelaez was the recipient of aHoward Hughes Medical Institute PredoctoralFellowship.

Address for reprint requests and other correspondence: K. R. Olson, SBCME, B-19 Haggar Hall, Univ. of Notre Dame, Notre Dame,IN 46556 (E-mail: olson.1{at}nd.edu).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

Received 8 February 2001; accepted in final form 10 July 2001.

	REFERENCES

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

1. Allen, BG, and Walsh MP. The biochemical basis of the regulation of smooth muscle contraction. Trends Biochem Sci 19: 362-368, 1994[ISI][Medline].

2. Ashida, T, and Blaustein MP. Regulation of cell calcium and contractility in mammalian arterial smooth muscle: the role of sodium-calcium exchange. J Physiol (Lond) 392: 617-635, 1987[Abstract/Free Full Text].

3. Bakhramov, A, Evans AM, and Kozlowski RZ. Differential effects of hypoxia on the intracellular Ca²⁺ concentration of myocytes isolated from different regions of the rat pulmonary arterial tree. Exp Physiol 83: 337-347, 1998[Abstract].

4. Bennie, RE, Packer CS, Powell DR, Jin N, and Rhoades RA. Biphasic contractile response of pulmonary artery to hypoxia. Am J Physiol Lung Cell Mol Physiol 261: L156-L163, 1991[Abstract/Free Full Text].

5. Brij, SO, and Peacock AJ. Cellular responses to hypoxia in the pulmonary circulation. Thorax 53: 1075-1079, 1998[Free Full Text].

6. Bruschi, G, Bruschi ME, Regolisti G, and Borghetti A. Myoplasmic Ca²⁺ force relationship studied with fura-2 during stimulation of rat aortic smooth muscle. Am J Physiol Heart Circ Physiol 254: H840-H854, 1988[Abstract/Free Full Text].

7. Chen, XL, and Rembold CM. Phenylephrine contracts tail artery by one electromechanical and three pharmacomechanical mechanisms. Am J Physiol Heart Circ Physiol 268: H74-H81, 1995[Abstract/Free Full Text].

8. Cornfield, DN, Stevens T, McMurtry IF, Abman SH, and Rodman DM. Acute hypoxia increases cytosolic calcium in fetal pulmonary artery smooth muscle cells. Am J Physiol Lung Cell Mol Physiol 265: L53-L56, 1993[Abstract/Free Full Text].

9. Cornfield, DN, Stevens T, McMurtry IF, Abman SH, and Rodman DM. Acute hypoxia causes membrane depolarization and calcium influx in fetal pulmonary artery smooth muscle cells. Am J Physiol Lung Cell Mol Physiol 266: L469-L475, 1994[Abstract/Free Full Text].

10. Crossley, D, Altimiras J, and Wang T. Hypoxia elicits an increase in pulmonary vasculature resistance in anaesthetised turtles (Trachemys scripta). J Exp Biol 201: 3367-3375, 1998[Abstract].

11. Dumas, JP, Bardou M, Goirand F, and Dumas M. Hypoxic pulmonary vasoconstriction. Gen Pharmacol 33: 289-297, 1999[ISI][Medline].

12. Faraci, FM, Kilgore DL, Jr, and Fedde MR. Attenuated pulmonary pressor response to hypoxia in bar-headed geese. Am J Physiol Regulatory Integrative Comp Physiol 247: R402-R403, 1984.

13. Farrukh, IS, and Michael JR. Cellular mechanisms that control pulmonary vascular tone during hypoxia and normoxia. Possible role of Ca²⁺ ATPases. Am Rev Respir Dis 145: 1389-1397, 1992[ISI][Medline].

14. Geeves, MA, and Holmes KC. Structural mechanism of smooth muscle contraction. Annu Rev Biochem 68: 687-728, 1999[ISI][Medline].

15. Gelband, CH, and Gelband H. Ca²⁺ release from intracellular stores is an initial step in hypoxic pulmonary vasoconstriction of rat pulmonary artery resistance vessels. Circulation 96: 3647-3654, 1997[Abstract/Free Full Text].

16. Harder, DR, Madden JA, and Dawson C. Hypoxic induction of Ca²⁺-dependent action potentials in small pulmonary arteries of the cat. J Appl Physiol 59: 1389-1393, 1985[Abstract/Free Full Text].

17. Jabr, RI, Toland H, Gelband CH, Wang XX, and Hume JR. Prominent role of intracellular Ca²⁺ release in hypoxic vasoconstriction of canine pulmonary artery. Br J Pharmacol 122: 21-30, 1997[ISI][Medline].

18. Janiak, R, Wilson SM, Montague S, and Hume JR. Heterogeneity of calcium stores and elementary release events in canine pulmonary arterial smooth muscle cells. Am J Physiol Cell Physiol 280: C22-C33, 2001[Abstract/Free Full Text].

19. Marín, J, Encabo A, Briones A, García-Cohen EC, and Alonso MJ. Mechanisms involved in the cellular calcium homeostasis in vascular smooth muscle: calcium pumps. Life Sci 64: 279-303, 1999[ISI][Medline].

20. McMurtry, IF, Davidson AB, Reeves JT, and Grover RF. Inhibition of hypoxic pulmonary vasoconstriction by calcium antagonists in isolated rat lungs. Circ Res 38: 99-104, 1999.

21. Olson, KR, and Meisheri KD. Effects of atrial natriuretic factor on isolated arteries and perfused organs in trout. Am J Physiol Regulatory Integrative Comp Physiol 256: R10-R18, 1989[Abstract/Free Full Text].

22. Olson, KR, Russell MJ, and Forster ME. Hypoxic vasoconstriction of cyclostome systemic vessels: the antecedent of hypoxic pulmonary vasoconstriction? Am J Physiol Regulatory Integrative Comp Physiol 280: R198-R206, 2001[Abstract/Free Full Text].

23. Post, JM, Gelband CH, and Hume JR. Ca²⁺_i inhibition of K⁺ channels in canine pulmonary artery: novel mechanism for hypoxia-induced membrane depolarization. Circ Res 77: 131-139, 1995[Abstract/Free Full Text].

24. Robertson, TP, Aaronson PI, and Ward JPT Hypoxic vasoconstriction and intracellular Ca²⁺ in pulmonary arteries: evidence for PKC-independent Ca²⁺ sensitization. Am J Physiol Heart Circ Physiol 268: H301-H307, 1995[Abstract/Free Full Text].

25. Robertson, TP, Hague D, Aaronson PI, and Ward JPT Voltage-independent calcium entry in hypoxic pulmonary vasoconstriction of intrapulmonary arteries of the rat. J Physiol (Lond) 525: 669-680, 2000[Abstract/Free Full Text].

26. Salvaterra, CG, and Goldman WF. Acute hypoxia increases cytosolic calcium in cultured pulmonary arterial myocytes. Am J Physiol Lung Cell Mol Physiol 264: L323-L328, 1993[Abstract/Free Full Text].

27. Salvaterra, CG, Rubin LJ, Schaeffer J, and Blaustein MP. The influence of the transmembrane sodium gradient on the responses of pulmonary arteries to decreases in oxygen tension. Am Rev Respir Dis 139: 933-939, 1989[ISI][Medline].

28. Smith, JB, Zheng T, and Lyu RM. Ionomycin releases calcium from the sarcoplasmic reticulum and activates Na⁺/Ca²⁺ exchange in vascular smooth muscle cells. Cell Calcium 10: 125-134, 1989[ISI][Medline].

29. Tribe, RM, Borin ML, and Blaustein MP. Functionally and spatially distinct Ca²⁺ stores are revealed in cultured vascular smooth muscle cells. Proc Natl Acad Sci USA 91: 5908-5912, 1994[Abstract/Free Full Text].

30. Vandier, C, Delpech M, Rebocho M, and Bonnet P. Hypoxia enhances agonist-induced pulmonary arterial contraction by increasing calcium sequestration. Am J Physiol Heart Circ Physiol 273: H1075-H1081, 1997[Abstract/Free Full Text].

31. Wang, YX, Dhulipala PK, and Kotlikoff MI. Hypoxia inhibits the Na⁺/Ca²⁺ exchanger in pulmonary artery smooth muscle cells. FASEB J 14: 1731-1740, 2000[Abstract/Free Full Text].

32. Ward, JPT, and Aaronson PI. Mechanisms of hypoxic pulmonary vasoconstriction: can anyone be right? Respir Physiol 115: 261-271, 1999[ISI][Medline].

33. Ward, JPT, and Robertson TP. The role of the endothelium in hypoxic pulmonary vasoconstriction. Exp Physiol 80: 793-801, 1995[Abstract].

34. Weir, EK, and Archer SL. The mechanism of acute hypoxic pulmonary vasoconstriction: the tale of two channels. FASEB J 9: 183-189, 1995[Abstract].

35. Weir, EK, Reeve HL, Peterson DA, Michelakis E, Nelson DP, and Archer SL. Pulmonary vasoconstriction, oxygen sensing, and the role of ion channels: Thomas A. Neff lecture. Chest 114: 17S-22S, 1998[ISI][Medline].

36. Zhu, Z, Tepel M, Neusser M, and Zidek W. Role of Na/Ca²⁺ exchange in agonist-induced changes in cytosolic Ca²⁺ in vascular smooth muscle cells. Am J Physiol Cell Physiol 266: C794-C799, 1994[Abstract/Free Full Text].

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