点击显示 收起
【摘要】
Objective- We investigated the effects of angiotensin II (Ang II) on inward rectifier K + (Kir) channels in small-diameter coronary arterial smooth muscle cells (SCASMCs) of control and isoproterenol (Iso)-induced hypertrophied rabbits.
Methods and Results- Kir current amplitude and Kir channel protein expression were definitely lower in the Iso-induced hypertrophied model than in the control. In a pressurized arterial experiment, 15 mmol/L K + -induced vasodilation was greater in the control arteries than in the arteries of Iso-induced hypertrophied model. Ang II reduced the Kir current in a concentration-dependent manner, and this inhibition was greater in SCASMCs from Iso-induced hypertrophied model than from control. Although, there was no difference in the expression of Ang II type 2 (AT 2 ) receptor between SCASMCs of control and Iso-induced hypertrophied model, the expression of Ang II type 1 (AT 1 ) receptor and phosphorylated PKC were greater in SCASMCs of Iso-induced hypertrophied model than of control.
Conclusion- Ang II inhibits Kir channels more prominently in SCASMCs of Iso-induced hypertrophied model owing to increases in the expression of AT 1 receptor and the activation of PKC. Our findings about the differential expression of Kir channels and different modulation of Kir channels by a vasoconstrictor (Ang II) in a hypertrophy model are important for better understanding the responsiveness of small-diameter arteries during hypertrophy.
Kir current amplitude was definitely lower in the coronary arterial smooth muscle cells of Iso-induced hypertrophied model than in the control. Ang II inhibits Kir current, which is more prominent in Iso-induced hypertrophied model owing to increases in the expression of AT 1 receptor and the activation of PKC. The results help for better understanding the responsiveness of small-diameter arteries during hypertrophy.
【关键词】 inward rectifier K + channel hypertrophy angiotensin II PKC microcirculation
Introduction
A reduced coronary reserve in response to various factors is a recognized feature of cardiac hypertrophy and is often accompanied by a high incidence of sudden cardiac death. 1,2 Most of the studies on reduced coronary reserve have demonstrated endothelial dysfunction, increased arteriolar tone, increased perivascular fibrosis, increased extracellular forces, abnormal angiogenesis, and structural alterations to the arterioles. 3-6 Furthermore, ion channels of the coronary arteries are also altered in cardiac hypertrophy. For example, Ca 2+ -activated K + channels of the coronary arteries are significantly reduced in left ventricular hypertrophy (LVH), 7 and voltage-dependent K + current is also decreased without changes in the channel kinetics in LVH. 8
Inward rectifier K + (Kir) channels have been identified in small-diameter (microvessel, not conduit) coronary and cerebral arteries; they may play an important role in the regulation of resting membrane potential and therefore arterial tone. 9-11 Although little is known about the modulation of Kir channels in smooth muscle, the activation of Kir channels induces vasodilation of small-diameter arteries, which can cause the extracellular K + concentration to rise to as high as 15 mmol/L 9, and exposure to hypoxic condition. 11 During pathological conditions such as hypertrophy and hypertension, 120 mm Hg), changes in the properties of the Kir channels have not been fully studied. Considering the fact that small-diameter arteries play a major role in the control of systemic blood pressure and local blood flow, it is essential to identify and characterize the changes in Kir channels under pathological conditions.
Angiotensin II (Ang II) modulates various types of ion channels. For example, Ang II activates a nonselective cation channel 12 and Ca 2+ channels in vascular smooth muscle cells. 13,14 Ang II also inhibits the voltage-dependent K + (Kv) channel and ATP-sensitive K + (K ATP ) channel by activating Ca 2+ -independent PKC in vascular smooth muscle cells 15-18 and inhibits the Ca 2+ -activated K + (BK Ca ) channel independently of PKC in vascular smooth muscle cells. 19,20 Our recent report suggested that Ang II inhibits the Kir channel through the activation of Ca 2+ -dependent PKC by acting at the AT 1 receptor. 21 However, the Ang II effect on the Kir channel in pathological states has not been studied. Thus, in the present study, we demonstrate (1) changes in the properties of the Kir channels in small-diameter coronary arterial smooth muscle cells (SCASMCs) during LVH and (2) changes of inhibition of Kir channel by Ang II, and their mechanisms in LVH using a patch clamp technique, Western blots, and arterial dilation experiments.
Materials and Methods
Induction of Cardiac Hypertrophy in an Animal Model
Male New Zealand White rabbits (2.0 to 2.6 kg) were used as an animal model in this study. Rabbits were purchased from the Samtako Bio Korea Inc (Osan, Korea). Cardiac hypertrophy was induced in the test group by daily isoproterenol administration (300 µg/kg body weight i.v.) for 7 days. The control group was treated similarly with 0.9% saline (1 mL/kg body weight). The degree of hypertrophy was estimated by measuring the heart weight to body weight ratio, cardiac infarction size, blood pressure, and cell capacitances (supplemental Table I, available online at http://atvb.ahajournals.org). Only those test animals proven to exhibit cardiac hypertrophy (onset of hypertrophy=93%, n=78) were used for further study.
Cell Preparation
Enzymatic isolation of single coronary arterial smooth muscle cells was performed as previously described. 11,21 Briefly, the left anterior descending coronary arteries (<100 µm) were dissected out and cleaned of blood and connective tissue. The arteries were then transferred to 1 mL of Ca 2+ -free normal Tyrode solution that contained papain (1.0 mg/mL), bovine serum albumin (BSA, 1.5 mg/mL), and dithiothreitol (DTT, 1.0 mg/mL). After incubation for 25 minutes at 37°C, the arteries were transferred to 1 mL of Ca 2+ -free normal Tyrode solution containing collagenase (2.8 mg/mL), BSA, and DTT then incubated for 20 minutes at 37°C. After the aforementioned enzyme treatment, the cells were isolated by gentle agitation with a fire-polished Pasture pipette in Kraft-Brühe (KB) medium.
Vessel Preparation and Measurement
The endothelium-denuded coronary arteries (from control rabbits and Iso-induced hypertrophied rabbits) with the diameter of <100 µm and 2 to 3 mm in length were isolated from branches of the left anterior descending coronary artery and cleaned of connective tissue in the physiological salt solution under a stereomicroscope. The artery was cannulated at one end with glass capillary, secured with nylon monofilament suture, and placed in chamber incubated at 35°C. The arteries were maintained in flow state and held at a constant intraluminal pressure of 60 mm Hg. The diameter of the artery was measured with the video programs (Crescent Electronics).
Solution
Normal Tyrode solution contained (in mmol/L): NaCl, 135; KCl, 5.4; NaH 2 PO 4, 0.33; CaCl 2, 1.8; MgCl 2, 0.5; HEPES, 5; glucose, 16.6; adjusted to pH 7.4 with NaOH. 20, 60, and 140 mmol/L K + external solutions were made by substituted NaCl for KCl in the normal Tyrode solution. KB solution contained (in mmol/L): KOH, 70; L-glutamate, 50; KH 2 PO 4, 20; KCl, 55; taurine, 20; MgCl 2, 3; glucose, 20; HEPES, 10; EGTA, 0.5; adjusted to pH 7.3 with KOH. The pipette-filling solution contained (in mmol/L): K-aspartate, 115; KCl, 25; NaCl, 5; MgCl 2, 1; Mg-ATP, 4; EGTA, 0.1; HEPES, 10; adjusted to pH 7.2 with KOH. To minimize the activity of K ATP channels, a high concentration of ATP (4 mmol/L) was used. The physiological salt solution contained (in mmol/L): NaCl, 119; KCl, 4.7; NaHCO 3, 24; KH 2 PO 4, 1.2; CaCl 2, 1.8; MgSO 4, 1.2; EDTA, 0.023; glucose, 11. The solution aerated with 95% O 2 /5% CO 2 to keep the pH at 7.4.
TTC Staining
Six rabbits from control and Iso-induced hypertrophied model were used to calculate the infarction ratio. The hearts were sliced into 6 sections parallel to the atrioventricular groove. The slices were incubated in a TTC solution prepared in phosphate buffer pH 7.4 for 30 minutes at 37°C. The TTC in viable myocardium was converted by lactate dehydrogenase isoenzymes (LDH, Sigma) to form a red formazan pigment that stains tissue with dark red. 22 The infarct area that did not take the TTC stain remained pale in color.
Electrophysiology
Whole-cell patch-clamp recordings were made using an Axon interface and Axopatch 1C amplifier (Axon instruments) as described previously. 11,21 To measure the resting membrane potential, we applied the perforated-patch technique using nystatin. Nystatin was added to a fresh aliquot of the above pipette solution every 2 hours to give a final concentration of 200 µg/mL.
Western Blot
Western blot of endothelium-denuded small-diameter coronary arteries was performed according to published methods. 11,21 Briefly, protein samples (15 µg from 8 rabbits) were obtained from the strips of endothelium-denuded small-diameter coronary arteries, which were homogenized in a hand-held Micro-tissue Grinder (PYREX). Membranes were probed with the ß-tubulin antiserum (Sigma) at a dilution of 1:1000, antiserum for phosphorylated PKC (Upstate Biotechnology) at a dilution of 1:1500, antiserum for total PKC (Santa Cruz) at a dilution of 1:1000, and antiserum for AT 1 (Abcam) and AT 2 (Santa Cruz) receptors at a dilution of 1:1000 for 1 hour at room temperature. Then, membranes were incubated with secondary antibodies at a dilation of 1:1000 to 1:3000, a goat anti-mouse IgG for ß-tubulin (Santa Cruz), a goat anti-rabbit IgG for PKC (Sigma), a goat anti-mouse IgG for AT 1 receptor (Sigma), and a mouse anti-goat IgG for AT 2 receptor (Santa Cruz). Western blot for Kir2.1 also has been described previously. 11 Briefly, membranes were probed with the GAPDH antiserum at a dilution of 1:1000 and antiserum for Kir2.1 (Santa Cruz) at a dilution of 1:500. Membranes were incubated with secondary antibodies, a goat anti-mouse IgG for GAPDH (Santa Cruz), a mouse anti-goat IgG for Kir2.1 (Santa Cruz).
Statistics
Origin 6.0 software (Microcal Software, Inc) was used for data analysis. Interaction kinetics between drugs and channels was described on the basis of a first-order blocking scheme. 21
Data are presented as the means±SEM. Statistical analyses were performed by using unpaired Student t test. P <0.05 was defined as statistically significant.
Results
Characteristics of the Experimental Model
The effects of isoproterenol (Iso) infusion are shown in supplemental Table I. The body-weight gain was not significantly different between the Iso-infused and control animals. However, the heart weight and heart to body weight ratio of Iso-infused animals were significantly increased. Left ventricular weight, infarction size, and blood pressure (systolic and diastolic) were also increased in Iso-infused animals. The patch clamp experiment revealed that the cell volume (mean cell capacitance) of SCASMCs isolated from Iso-infused animals was 13% greater than that of control SCASMCs; the membrane potential became more positive in SCASMCs from Iso-infused animals. No serious cavity effusion or increases in lung or liver weights were observed (data not shown). From these data, this model can be considered to demonstrate hypertrophy. 23
Comparison of Ba 2+ -Sensitive Kir Channels
Figure 1 illustrates the Kir currents recorded from the SCASMCs of control (<100 µm) and Iso-induced hypertrophied animals. Kir currents were recorded in response to a voltage step from -60 to -140 mV for 50 ms, followed by a depolarizing voltage ramp from -140 to +40 mV at a rate of 0.5 V/s. The contribution of K ATP channels to the measured current was minimized by the inclusion of ATP (4 mmol/L) in the pipette solution, and our previous reports clearly showed that K ATP currents were not involved in this condition. 11 To prove the Kir currents, we examined various concentrations of extracellular K +, 5.4, 20, 60, and 140 mmol/L with fixed intracellular K + concentration, 140 mmol/L. As shown in Figure 1A and 1 B, Ba 2+ -sensitive Kir currents were detected in both SCASMCs from control and Iso-induced hypertrophied model. However, the amplitude of the Kir current was greater in control than in Iso-induced hypertrophied (15.55±0.52 pA/pF in control and 11.13±0.63 pA/pF in Iso-induced hypertrophied model at -140 mV under extracellular 140 mmol/L K +, Figure 1 C). To further identify the reduction of Kir channel density, we tested the amplitudes of the Ba 2+ -induced vasoconstriction and the 15 mmol/L K + -induced vasodilation in small-diameter coronary arteries of control and those of Iso-induced hypertrophied model. Although most systemic arteries constrict in response to an increase in the extracellular K + concentration, moderate increases in extracellular K + ( 15 mmol/L) in small-diameter coronary and cerebral arteries lead to vasodilation and increased blood flow by the activation of Kir channels. 9,24,25 Consistent with the patch clamp data, the 50 µmol/L Ba 2+ -induced vasoconstriction was greater in control than in Iso-induced hypertrophied model ( Figure 2A and 2 B, Control: 21.14±1.02%, hypertrophy: 14.13±0.79% vasoconstriction, respectively). Also, the 15 mmol/L K + -induced vasodilation was greater in small-diameter coronary arteries of control than those of Iso-induced hypertrophied model ( Figure 2C and 2 D, Control: 48.89±3.45%, hypertrophy: 36.77±4.37% dilation, respectively). We also performed a Western blot experiment with an antibody specific for Kir2.1 to identify the reduction of Kir channel density. Our previous report suggested that only Kir2.1, not Kir2.2 or Kir2.3, was detected in SCASMCs. 11,25 As shown in Figure 3 A, the expression level of Kir2.1 was decreased in the Iso-induced hypertrophied animals (Densitometric ration. 1.31±0.20 for control; 0.72±0.15 for hypertrophy, Figure 3 B). Therefore, we concluded that the expression of Kir channels in small-diameter coronary arteries was decreased in Iso-induced hypertrophied animals.
Figure 1. Inward rectifier K + currents in SCASMCs of control (<100 µm) and Iso-induced hypertrophied model. Current-voltage relationship of 50 µmol/L Ba 2+ -sensitive currents in 5.4, 20, 60, 140 mmol/L K + in control (A) and Iso-induced hypertrophy (B). The fraction of the current that was Ba 2+ -sensitive was determined by subtracting the current in the presence of 50 µmol/L Ba 2+ from that in the control condition. C, Currents were normalized to cell capacitance and are 50 µmol/L Ba 2+ -sensitive currents measured at -140 mV under extracellular 140 mmol/L K +. All n=6. * P <0.01.
Figure 2. Change of the vascular tone in small-diameter coronary arteries from control and Iso-induced hypertrophied model by a moderate increase of K + (15 mmol/L K + ). Representative tracings show the effect of 50 µmol/L Ba 2+ on vascular tone in the small-diameter coronary arteries of control (A) and Iso-induced hypertrophy (B). Typical experimental tracings show the effect of 15 mmol/L K + on vascular tone in the small-diameter coronary arteries from control (C) and Iso-induced hypertrophied model (D). All n=4.
Figure 3. Kir2.1 expression level as determined by Western blot in small-diameter coronary arteries of control and Iso-induced hypertrophied model. A, Representative data showing the distribution of Kir2.1 in small-diameter coronary arteries from control and Iso-induced hypertrophied animal. B, Summary of relative intensity as shown in A. n=3. * P <0.05. The relative intensity was determined using Multi Gauge V2.2.
Inhibition of Kir Current by Ang II
We investigated the effect of Ang II on Kir currents in SCASMCs from control and Iso-induced hypertrophied animal. To increase the magnitude of the Kir currents, both the extracellular and intracellular K + concentrations were maintained at 140 mmol/L. Ang II caused a significant reduction in the magnitude of the Kir currents ( Figure 4A and 4 B). Increasing the concentration of Ang II increased the level of inhibition of the Kir current in both SCASMCs from control and Iso-induced hypertrophied model. The dose-response curve indicated that the SCASMCs from Iso-induced hypertrophied model were more sensitive to the Ang II-induced inhibition of Kir currents compared with the control SCASMCs. A nonlinear least-squares fit of the Hill equation to the concentration-dependence data yielded an apparent K d value of 253.81±7.42 nmol/L and 74.62±5.04 nmol/L in control and in Iso-induced hypertrophy, respectively, and a Hill coefficient of 1.24±0.11 and 1.69±0.17 in control and in Iso-induced hypertrophy, respectively ( Figure 4 C).
Figure 4. Ang II inhibited Kir current in SCASMCs of control and Iso-induced hypertrophy. Whole-cell current recording showing the response to 100 nmol/L Ang II of the SCASMCs from control (A) and Iso-induced hypertrophied model (B), respectively. C, Concentration-dependence of the Ang II-induced blockage of Kir currents in the SCASMCs of control (white circle, all n=5) and Iso-induced hypertrophy (black circle, all n=5). The reduction in current at -140 mV was used as an index of blockage. The smooth line represents the best fit with the Hill equation. * P <0.05, # P <0.01.
Comparison of the Expression Levels of AT 1 and AT 2 Receptor
We sought to understand why the inhibition of Kir currents by Ang II was greater in the SCASMCs from Iso-induced hypertrophied animal. Therefore, we performed Western blots on homogenized endothelium-denuded small-diameter arterial tissues to evaluate the expression of Ang II type 1 (AT 1 ) and Ang II type 2 (AT 2 ) receptor proteins in native small-diameter coronary arteries from control and Iso-induced hypertrophied animals. As shown in Figure 5 B, the expression level of AT 2 receptor did not differ between the control and Iso-induced hypertrophied model (Densitometric ration. 0.42±0.04 for control; 0.39±0.05 for hypertrophy). By contrast, marked increases in the protein level of AT 1 were observed in small-diameter coronary arteries from the Iso-induced hypertrophied model (Densitometric ration. 0.36±0.06 for control; 0.59±0.07 for hypertrophy, Figure 5 A).
Figure 5. Representative Western blot results for AT 1, AT 2, and Ca 2+ -dependent PKC isoforms ( and ß) in endothelium-denuded small-diameter coronary arteries from control and Iso-induced hypertrophied model. Western blotting was performed using anti-AT 1 (A) and anti-AT 2 (B) receptor antibodies. All n=3. C, Western blot analysis of the expression of phosphorylated PKC (pPKC ), PKCß (pPKCß), and ß-tubulin (n=4). D, Western blot analysis of the expression of total PKC and ß-tubulin (n=3).
Comparison of the Expression Levels of PKC
Our previous study clearly showed that Ang II inhibits Kir channels through AT 1 receptors by the activation of Ca 2+ -dependent PKC, not Ca 2+ -independent PKC. 21 Thus, to test whether the expression level of PKC was changed in the Iso-induced hypertrophied model, we conducted a Western blot analysis on homogenized endothelium-denuded small-diameter arterial tissues, using antibodies specific for phosphorylated PKC (pPKC ) and PKCß (pPKCß). Although we could not detect the expression of pPKCß in small-diameter coronary arteries from control and Iso-induced hypertrophied animal, the expression level of pPKC was greater in small-diameter coronary arteries from Iso-induced hypertrophy (2.1-fold, Figure 5 C). Furthermore, the expression level of total PKC was not different from control and Iso-induced hypertrophied animals ( Figure 5 D). We also tested a PKC activator, phorbol 12,13-dibutyrate (PDBu), on Kir currents in SCASMCs of control and Iso-induced hypertrophy. Application of PDBu, in the presence of an inhibitor of Ca 2+ -dependent PKC (PKC and PKCß), Gö 6979 (1 µmol/L), showed no significant decrease of Kir currents in both SCASMCs of control and Iso-induced hypertrophied model (supplemental Figure IA through IC). These findings confirm that the effect of Ang II occurs through the activation of Ca 2+ -dependent PKC isoform ( ) in both SCASMCs of control and Iso-induced hypertrophied animal. Thus, to specifically activate PKC, we included a specific inhibitor of Ca 2+ -independent PKC, PKC translocation inhibitory peptide (PKC TIP, 40 µmol/L). 26 The application of 100 nmol/L PDBu inhibited the Kir current by 32.15±3.56% in control and by 49.63±4.12% in Iso-induced hypertrophied model (Supplemental Figure ID and IE). Supplemental Figure IF summarizes the effect on the Kir current of PDBu alone and PDBu together with PKC TIP at a concentration of 100 nmol/L. These results suggest that Kir channels in SCASMCs of Iso-induced hypertrophied animals are more strongly regulated by PKC than those in the control SCASMCs.
Discussion
The major findings of this study were that (1) the density of the Kir current is significantly reduced in a model of Iso-induced hypertrophied small-diameter coronary arteries and (2) the sensitivity to Ang II is more prominent in Iso-induced hypertrophied small-diameter coronary arteries owing to the increased expression of AT 1 receptor and the activation of PKC.
Several models of ventricular hypertrophy have been used in physiological studies, including catecholamine-induced hypertrophy, 7,27-29 hypertrophy occurring in spontaneously hypertensive rat strains, 30,31 and hypertrophy induced by right ventricle 32 or left ventricular pressure overload. 33,34 Among these models, catecholamine (Iso)-induced cardiac hypertrophy is a simple well-established model and provides useful information that may have a relevant application to clinically observed disease. 35 In our study, cardiac hypertrophy was induced in rabbits by daily injections of 300 µg/kg Iso for 7 days. In this model, although the ratio of heart weight to body weight was increased by 18%, no change in the liver-to-body weight or lung-to-body weight ratio was detected (data not shown), which suggested that heart failure did not occur. Thus, this model can be classified as mild hypertrophy. 23
Ang II can bind to at least 2 high-affinity receptors, designated AT 1 and AT 2 receptors. 36 Ang II receptors have been reported to couple to several cellular signaling pathways. For example, Ang II binds to AT 1 receptor, which induced vasoconstriction via activation of PLC and consequently PKC. 37 However, Ang II relaxes microvessel via stimulation of the AT 2 receptor with subsequent opening of BKCa channels, leading to membrane repolarization and vasodilation. 38 In our experiment, the expression level of AT 2 receptor did not differ between the control and Iso-induced hypertrophied model. Contrastingly, a marked increase in the expression level of AT 1 in small-diameter coronary arteries was observed in the Iso-induced hypertrophied model ( Figure 5 ). Despite many previous reports insisting the absolute requirement of AT 1 receptors for the development of hypertension and cardiac hypertrophy, 39,40 most studies have focused on the reduction in left ventricular mass with AT 1 receptor blocker or angiotensin-converting enzyme inhibitor. 41,42 Therefore, this study discloses, for the first time, the role of Ang II receptors level of expression as a possible function correlated with Iso-induced hypertrophied model. The data suggest that the increased expression of AT 1 receptor, rather than AT 2 receptor, can augment the Ang II-induced Kir channel inhibition in Iso-induced hypertrophied model.
Ang II has been shown to affect several different types of ion channels in vascular smooth muscle, and various signaling pathways have been implicated in these effects. Studies have revealed that Ang II inhibits K ATP current through the activation of PKC, which is a Ca 2+ -independent PKC isoform, and the inhibition of PKA. 16,18 Similarly, Ang II reduces the Kv current by the activation of PKC and inhibition of PKA. 15,17 Although the mechanism of BK Ca channel inhibition by Ang II is not known clearly, Ang II inhibits BK Ca channels by a PKC-independent mechanism in cells cultured from pig coronary arteries. 19,20 We recently demonstrated that Ang II inhibited Kir channels by activating Ca 2+ -dependent PKC isoform through the AT 1 receptor, 21 and we clearly showed that pretreatment with PLC and PKC inhibitors prevented the Ang II-induced inhibition of Kir current. Although an inhibitor of Ca 2+ -dependent PKC isoforms clearly reduced the Ang II effect on Kir channels, the inhibitory effect of Ang II on the Kir current was not affected by the inhibition of the PKC isoform. In the current study, we confirmed that the PKC isoform is abundant in SCASMCs, whereas PKCß was not detectable. Moreover, there was comparatively higher level of expression of phosphorylated PKC in SCASMCs in Iso-induced hypertrophied model than that in control. Furthermore, the inhibitory effect of Ang II in Kir channel was more prominent in SCASMCs of Iso-induced hypertrophied model. Consistent with our findings, previous reports suggested that a conduit artery contained relatively large amounts of PKC, relatively little PKC, and hence, showing a Ca 2+ -independent PKC-dependent contraction, whereas the microvessels have a relative high amount of PKC and little PKC and hence show a Ca 2+ -dependent PKC-dependent contraction. 43,44 Previous data also showed that PKC is the major contributor among PKC isoforms involved in hypertrophic signaling in cardiomyocytes via ERK1/2-dependent signaling pathway. 45,46 Although our data might, at least partly, explain the active response of small-diameter coronary arteries as a function of the changes of Kir channel density as well as the sensitivity to vasoconstrictor (Ang II) in pathological condition, further study is needed to disclose the cellular benefit behind such adaptation in small-diameter coronary artery.
It has been suggested that Kir channels, which have been detected only in small-diameter cerebral and coronary arterial smooth muscle cells, contribute to the resting tone in coronary and middle cerebral artery, as increase of moderate extracellular K + concentration leads to vasodilation, and Ba 2+ cause constriction of the vascular artery at resting tone. 9-11,47 Therefore, Kir channels that are open during the resting condition maintain coronary vessels in a relatively hyperpolarized state and, consequently, maintain the arteries in a partially dilated state. The significant decrease in Kir channel density in this model could be partly explained by the possibility that the membrane potential became more positive and exceeded the range for the open probability of Kir channels. The net result induced inactivation or reduced function of Kir channels during hypertrophy. Although K + channel function has been reported for multiple pathological conditions, pathology-associated changes in Kir channel function have received little attention in the literature. To our knowledge, only a few studies have been published. The authors reported that cerebral arteries isolated from hypertensive rats no longer dilated in response to extracellular K + concentrations that activated the Kir channels. 48 Furthermore, the response of Kir channels to extracellular K + was significantly attenuated after 2 hours of ischemia and 24 hours of reperfusion in the rat middle cerebral arteries. 49
Although ion channels of vascular smooth muscle could be altered during hypertrophy, most studies and clinical approaches have been focused on the cardiac function that related to ion channels or receptors or even their signal transduction mechanisms. Many anti-left ventricular hypertrophy drugs eg, ß-blockers, nitrates, and modulators of the rennin-angiotensin-aldosterone system have been developed to counteract ventricular remodeling. 50 In this study, however, we clearly demonstrated that the function of Kir channels in small-diameter coronary arteries was proved to be significantly altered in hypertrophy. The recorded dysfunction of Kir channel in vascular smooth muscle consequently reduces the vascular contractile response and coronary reserve, which could accelerate vascular remodeling. Therefore, the data afford new insight about possible future contribution of Kir channels in the development of therapeutic intervention especially against vascular microcirculation related cardiac hypertrophy.
In summary, we suggest for the first time that the alteration of Kir channel density limits vasodilating responses to moderate increase of extracellular K + in small-diameter coronary arteries of hypertrophied rabbit heart. Considering that small-diameter coronary arteries respond actively to changes in luminal flow, intravascular pressure, and the concentration of local metabolites, 25 information about the differential expression of Kir channels and different modulation of Kir channels by a vasoconstrictor (Ang II) in a hypertrophy model is important for understanding the responsiveness of small-diameter arteries during hypertrophy.
Acknowledgments
Sources of Funding
This work was supported by Grants R05-2003-000-00413-0, R05-2004-000-00905-0, and R01-2004-000-10045-0 of the Korea Science and Engineering Foundation, and the Korea Research Foundation Grant funded by the Korean Government (MOEHRD) (KRF-2005-210-E00003, KRF-2005-211-E00006, KRF-2005-037-E00002, KRF-2006-351-E00002, and KRF-2006-351-E00003).
Disclosures
None.
【参考文献】
Kohya T, Kimura S, Myerburg RJ, Bassett AL. Susceptibility of hypertrophied rat hearts to ventricular fibrillation during acute ischemia. J Mol Cell Cardiol. 1988; 20: 159-168.
Pye MP, Cobbe SM. Mechanisms of ventricular arrhythmias in cardiac failure and hypertrophy. Cardiovasc Res. 1992; 26: 740-750.
Schwartzkopff B, Motz W, Frenzel H, Vogt M, Knauer S, Strauer BE. Structural and functional alterations of the intramyocardial coronary arterioles in patients with arterial hypertension. Circulation. 1993; 88: 993-1003.
Hittinger L, Mirsky I, Shen YT, Patrick TA, Bishop SP, Vatner SF. Hemodynamic mechanisms responsible for reduced subendocardial coronary reserve in dogs with severe left ventricular hypertrophy. Circulation. 1995; 92: 978-986.
Burke AP, Farb A, Liang YH, Smialek J, Virmani R. Effect of hypertension and cardiac hypertrophy on coronary artery morphology in sudden cardiac death. Circulation. 1996; 94: 3138-3145.
Kaufmann P, Vassalli G, Lupi-Wagner S, Jenni R, Hess OM. Coronary artery dimensions in primary and secondary left ventricular hypertrophy. J Am Coll Cardiol. 1996; 28: 745-750.
Kim NR, Chung J, Kim E, Han J. Changes in the Ca 2+ -activated K + channels of the coronary artery during left ventricular hypertrophy. Circ Res. 2003; 93: 541-547.
Kim NR, Han J, Kim E. Altered delayed rectifier K + current of rabbit coronary arterial myocytes in isoproterenol-induced hypertrophy. Korean J Physiol Pharmacol. 2001; 5: 33-40.
Knot HJ, Zimmermann PA, Nelson MT. Extracellular K + -induced hyperpolarizations and dilatations of rat coronary and cerebral arteries involve inward rectifier K + channels. J Physiol. 1996; 492: 419-430.
Quayle JM, Dart C, Standen NB. The properties and distribution of inward rectifier potassium currents in pig coronary arterial smooth muscle. J Physiol. 1996; 494: 715-726.
Park WS, Han J, Kim NR, Ko JH, Kim SJ, Earm YE. Activation of inward rectifier K + channels by hypoxia in rabbit coronary arterial smooth muscle cells. Am J Physiol. 2005a; 289: H2461-H2467.
Hughes AD, Bolton TB. Action of angiotensin II, 5-hydroxytryptamine and adenosine triphosphate on ionic currents in single ear artery cells of rabbit. Br J Pharmacol. 1995; 116: 2148-2154.
Ohya Y, Sperelakis N. Involvement of a GTP-binding protein in stimulating action of angiotensin II on calcium channels in vascular smooth muscle cells. Circ Res. 1991; 68: 763-771.
Seki T, Yokoshiki H, Sunagawa H, Nakamura M, Sperelakis N. Angiotensin II stimulation of Ca 2+ channel current in vascular smooth muscle cells is inhibited by lavendustin-A and LY-294002. Pflügers Arch. 1999; 437: 317-323.
Clément-Chomienne O, Walsh MP, Cole WC. Angiotensin II activation of protein kinase C decreases delayed rectifier K + current in rabbit vascular myocytes. J Physiol. 1996; 495: 689-700.
Hayabuchi Y, Davies NW, Standen NB. Angiotensin II inhibits rat arterial K ATP channels by inhibiting steady-state protein kinase A activity and activating protein kinase C. J Physiol. 2001a; 530: 193-205.
Hayabuchi Y, Standen NB, Davies NW. Angiotensin II inhibits and alters kinetics of voltage-gated K + channels of rat arterial smooth muscle. Am J Physiol. 2001b; 281: H2480-H2489.
Kubo M, Quayle JM, Standen NB. Angiotensin II inhibition of ATP-sensitive K + currents in rat arterial smooth muscle cells through protein kinase C. J Physiol. 1997; 503: 489-496.
Toro L, Amador M, Stefani E. ANG II inhibits calcium activated potassium channels from coronary smooth muscle in lipid bilayers. Am J Physiol. 1990; 258: H912-H915.
Minami K, Hirata Y, Tokumura A, Nakaya Y, Fukuzawa K. Protein kinase C-independent inhibition of the Ca 2+ -activated K + channel by angiotensin II and endothelin-1. Biochem Pharmacol. 1995; 49: 1051-1056.
Park WS, Kim N, Youm JB, Warda M, Ko JH, Kim SJ, Earm YE, Han J. Angiotensin II inhibits inward rectifier K + channels in rabbit coronary arterial smooth muscle cells through protein kinase C. Biochem Biophys Res Commun. 2006a; 341: 728-735.
Kim NR, Lee YS, Kim HK, Joo H, Youm JB, Park WS, Warda M, Cuong DV, Han J. Potential biomarkers for ischemic heart damage identified in mitochondrial proteins by comparative proteomics. Proteomics. 2006; 6: 1237-1249.
Hart G. Cellular electrophysiology in cardiac hypertrophy and failure. Cardiovasc Res. 1994; 28: 933-946.
Chrissobolis S, Ziogas J, Chu Y, Faraci FM, Sobey CG. Role of inwardly rectifying K + channels in K + -induced cerebral vasodilatation in vivo. Am J Physiol. 2000; 279: H2704-H2712.
Park WS, Ko EA, Han J, Kim NR, Earm YE. Endothelin-1 inhibits inward rectifier K + channels in rabbit coronary arterial smooth muscle cells through protein kinase C. J Cardiovasc Pharmacol. 2005b; 46: 681-689.
Johnson JA, Gray MO, Chen CH, Mochly-Rosen D. A protein kinase C translocation inhibitor as an isozyme-selective antagonist of cardiac function. J Biol Chem. 1996; 271: 24962-24966.
Benjamin JJ, Jabil JE, Tan LB, Cho K, Weber KT, Clark WA. Isoproterenol-induced myocardial fibrosis in relation to myocyte necrosis. Circ Res. 1989; 65: 657-670.
Teerlink JR, Pfeffer JM, Pfeffer MA. Progressive ventricular remodeling in response to diffuse isoproterenol-induced myocardial necrosis in rats. Circ Res. 1994; 75: 105-113.
Gillis AM, Mathison HJ, Patel C, Lester WM. Quinidine pharmacodynamics in normal and isoproterenol-induced hypertrophied blood-perfused working rabbit hearts. J Cardiovasc Pharmacol. 1996; 27: 916-926.
Ji Y, Huang Y, Han Y, Xu Y, Ferro A. Cardiac effects of amiloride and of enalapril in the spontaneously hypertensive rats. J Hypertens. 2003; 21: 1583-1589.
Zwadlo C, Borlak J. Disease-associated changes in the expression of ion channels, ion receptors, ion exchangers and Ca 2+ -handling proteins in heart hypertrophy. Toxicol Appl Pharmacol. 2005; 207: 244-256.
Kleiman RB, Houser SR. Calcium currents in normal and hypertrophied isolated feline ventricular myocytes. Am J Physiol. 1988; 255: H1434-H1442.
Nordin C, Siri F, Aronson SR. Electrophysiologic characteristics of single myocytes isolated from hypertrophied guinea-pig hearts. J Mol Cell Cardiol. 1989; 21: 729-739.
Furukawa T, Myerberg RJ, Furukawa N, Kimura S, Bassett AL. Metabolic inhibition of I Ca,L and I K differs in feline left ventricular hypertrophy. Am J Physiol. 1994; 266: H1121-H1131.
Meszaros J, Ryder KO, Hart G. Transient outward current in catecholamine-induced cardiac hypertrophy in the rat. Am J Physiol. 1996; 271: H2360-H2367.
Unger T, Chung O, Csikos T, Culman J, Gallinat S, Gohlke P, Hohle S, Meffert S, Stoll M, Stroth U, Zhu YZ. Angiotensin receptors. J Hypertens. 1996; 14: S95-S103.
Timmermans PB, Wong PC, Chiu AT, Herblin WF, Benfield P, Carini DJ, Lee RJ, Wexler RR, Saye JA, Smith RD. Angiotensin II receptors and angiotensin II receptor antagonists. Pharmacol Rev. 1993; 45: 205-251.
Dimitropoulou C, White RE, Fuchs L, Zhang H, Catravas JD, Carrier GO. Angiotensin II relaxes microvessels via the AT 2 receptor and Ca 2+ -activated K + (BK Ca ) channels. Hypertension. 2001; 37: 301-307.
Hunyady L, Turu G. The role of the AT 1 angiotensin receptor in cardiac hypertrophy: angiotensin II receptor or stretch sensor?. Trends Endocrinol Metab. 2004; 15: 405-408.
Crowley SD, Gurley SB, Herrera MJ, Ruiz P, Griffiths R, Kumar AP, Kim HS, Smithies O, Le TH, Coffman TM. Angiotensin II causes hypertension and cardiac hypertrophy through its receptors in the kidney. Proc Natl Acad Sci. 2006; 103: 17985-17990.
Matsusaka H, Kinugawa S, Ide T, Matushima S, Shiomi T, Kubota T, Sunagawa K, Tsutsui H. Angiotensin II type 1 receptor blocker attenuates exacerbated left ventricular remodeling and failure in diabetes-associated myocardial infarction. J Cardiovasc Pharmacol. 2006; 48: 95-102.
Zhang C, Yasuno S, Kuwahara K, Zankov DP, Kobori A, Makiyama T, Horie M. Blockade of angiotensin II type 1 receptor improves the arrhythmia morbidity in mice with left ventricular hypertrophy. Circ J. 2006; 70: 335-341.
Ohanian V, Ohanian J, Shaw L, Scarth S, Parker PJ, Heagerty AM. Identification of protein kinase C isoforms in rat mesenteric small arteries and their possible role in agonist-induced contraction. Circ Res. 1996; 78: 806-812.
Dessy C, Matsuda N, Hulvershorn J, Sougnez CL, Sellke FW, Morgan KG. Evidence for involvement of the PKC-alpha isoform in myogenic contractions of the coronary microcirculation. Am J Physiol. 2000; 279: H916-H923.
Braz JC, Bueno OF, De Windt LJ, Molkentin JD. PKC alpha regulates the hypertrophic growth of cardiomyocytes through extracellular signaling regulated kinase1/2 (ERK1/2). J Cell Biol. 2002; 156: 905-919.
Kerkela R, Ilves M, Pikkarainen S, Tokola H, Ronkainen J, Vuolteenaho O, Leppaluoto J, Ruskoaho H. Identification of PKCalpha isoform-specific effects in cardiac myocytes using antisense phosphorothioate oligonucleotides. Mol Pharmacol. 2002; 62: 1482-1491.
Park WS, Son YK, Kim NR, Youm JB, Joo H, Warda M, Ko JH, Earm YE, Han J. The protein kinase A inhibitor, H-89, directly inhibits K ATP and Kir channels in rabbit coronary arterial smooth muscle cells. Biochem Biophys Res Commun. 2006b; 340: 1104-1110.
McCarron JG, Halpern W. Impaired potassium-induced dilation in hypertensive rat cerebral arteries does not reflect altered Na +, K + -ATPase dilation. Circ Res. 1990; 67: 1035-1039.
Marrelli SP, Johnson TD, Khorovets A, Childres WF, Bryan RM Jr. Altered function of inward rectifier potassium channels in cerebrovascular smooth muscle after ischemia/reperfusion. Stroke. 1998; 29: 1469-1474.
Tiyyagura SR, Pinney SP. Left ventricular remodeling after myocardial infarction: past, present, and future. Mt Sinai J Med. 2006; 73: 840-851.
作者单位:Mitochondrial Signaling Laboratory (W.S.P., J.-H.K., N.K., Y.K.S., S.H.K., M.W., J.H.), Mitochondria Research Group, Department of Physiology and Biophysics, College of Medicine, Biohealth Products Research Center, Cardiovascular and Metabolic Disease Research Center, Inje University, Busan, Korea;