Division of Pulmonary and Critical Care Medicine and Institute of Genetic Medicine, Departments of Medicine and Pediatrics, Johns Hopkins School of Medicine, Baltimore, Maryland 21224
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ABSTRACT |
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Chronic hypoxia
depolarizes and reduces K+ current in pulmonary arterial
smooth muscle cells (PASMCs). Our laboratory previously demonstrated
that hypoxia-inducible factor-1 (HIF-1) contributed to the development
of hypoxic pulmonary hypertension. In this study, electrophysiological
parameters were measured in PASMCs isolated from intrapulmonary
arteries of mice with one null allele at the Hif1a locus
encoding HIF-1 [Hif1a(+/
)] and from their wild-type
[Hif1a(+/+)] littermates after 3 wk in air or 10%
O2. Hematocrit and right ventricular wall and left
ventricle plus septum weights were measured. Capacitance,
K+ current, and membrane potential were measured with whole
cell patch clamp. Similar to our laboratory's previous results,
hypoxia-induced right ventricular hypertrophy and polycythemia were
blunted in Hif1a(+/
) mice. Hypoxia increased PASMC
capacitance in Hif1a(+/+) mice but not in
Hif1a(+/
) mice. Chronic hypoxia depolarized and reduced
K+ current density in PASMCs from Hif1a(+/+)
mice. In PASMCs from hypoxic Hif1a(+/
) mice, no reduction
in K+ current density was observed, and depolarization was
significantly blunted. Thus partial deficiency of HIF-1
is
sufficient to impair hypoxia-induced depolarization, reduction of
K+ current density, and PASMC hypertrophy.
pulmonary hypertension; voltage-gated potassium current; membrane potential; hypoxia-inducible factor-1; pulmonary arterial smooth muscle cell
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INTRODUCTION |
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PROLONGED EXPOSURE TO DECREASED alveolar O2 tension, as occurs with many pulmonary diseases, leads to sustained pulmonary vasoconstriction, vascular remodeling, and pulmonary hypertension. Development of pulmonary hypertension is associated with eventual right heart failure and increased morbidity and mortality. Morphological changes associated with chronic hypoxia include pulmonary arterial smooth muscle cell (PASMC) hypertrophy and hyperplasia, muscularization of precapillary arterioles, and increased deposition of extracellular matrix components (11, 17, 18). Functional changes that occur in the pulmonary vasculature as a consequence of chronic hypoxia include membrane depolarization (23, 25) and altered vasoreactivity in response to numerous agonists (4, 5, 9, 10, 15, 19, 27).
Membrane potential plays a vital role in regulating vascular caliber and the proliferative state of PASMCs through control of cytosolic Ca2+ concentration ([Ca2+]i). In PASMCs, 4-aminopyridine (4-AP), but not charybdotoxin (ChTX), causes membrane depolarization and increased [Ca2+]i (2, 22, 31), indicating that resting membrane potential is regulated predominantly by a specific subtype of voltage-gated K+ (KV) channel that is 4-AP sensitive and ChTX insensitive. Furthermore, in vivo exposure to chronic hypoxia attenuates KV channel currents (23, 24), causes membrane depolarization (23, 25), and elevates basal [Ca2+]i (21) in PASMCs.
Hypoxia-inducible factor-1 (HIF-1) is a transcription factor composed
of HIF-1 and HIF-1
subunits. Although HIF-1
is constitutively expressed in the lung, expression of HIF-1
is tightly regulated by
O2 tension (29). HIF-1 has been shown to
activate the transcription of genes encoding several factors important
in the development of hypoxic pulmonary hypertension including
endothelin-1, erythropoietin, inducible nitric oxide synthase, and
vascular endothelial growth factor (7, 13, 20).
Mouse embryonic stem cells carrying a null allele at the
Hif1a locus encoding HIF-1 were generated, and mice with
complete [Hif1a(
/
)] or partial
[Hif1a(+/
)] HIF-1
deficiency were analyzed (8). Hif1a(
/
) embryos died by gestational
day 10.5, whereas Hif1a(+/
) mice were viable
and indistinguishable from their wild-type [Hif1a(+/+)]
littermates (8). Hif1a(+/+) mice exposed to
10% O2 for 3 wk exhibited right heart hypertrophy,
elevated pulmonary arterial pressure, polycythemia, and extension of
muscle into previously nonmuscular pulmonary arterioles
(30). Development of pulmonary hypertension, polycythemia,
and vascular remodeling was blunted in Hif1a(+/
) mice
exposed to chronic hypoxia (30), indicating that HIF-1
plays an important role in the development of hypoxic pulmonary
hypertension. The mechanisms underlying contraction and proliferation
of pulmonary vascular smooth muscle during the development of pulmonary
hypertension are complex and poorly understood, however, and much is
yet to be determined regarding the role of HIF-1 in mediating the
pathogenesis of hypoxic pulmonary hypertension. Moreover, although
partial deficiency for HIF-1
was associated with impaired
hypoxia-induced pulmonary vascular remodeling (30), it was
unclear whether this was due to altered PASMC electrophysiology, hyperplasia, and/or hypertrophy.
Given that the development of vasoconstriction and vascular remodeling
in response to chronic hypoxia are likely to be influenced by membrane
potential, we hypothesized that partial deficiency for HIF-1 would
limit the changes in PASMC electrophysiology induced by chronic
hypoxia. To test this hypothesis, we used whole cell patch-clamp
techniques to determine the effect of chronic hypoxia on cell
capacitance, membrane potential, and K+ currents in PASMCs
isolated from Hif1a(+/+) and Hif1a(+/
) mice.
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METHODS |
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All procedures were approved by the Animal Care and Use
Committee of the Johns Hopkins University School of Medicine. Mice were
generated on a C57B6 × 129 genetic background as previously described (8). Hif1a(+/+) and mice with one
null allele at the Hif1a locus [Hif1a(+/)]
mice were mated, and offspring genotype was determined by PCR
(8). Male Hif1a(+/+) and Hif1a(+/
)
mice (8 wk old) were placed in a hypoxic chamber and exposed to either normoxia or normobaric hypoxia for 21 days. The chamber was
continuously flushed with either room air or a mixture of room air and
N2 (10 ± 0.5% O2) to maintain low
CO2 concentrations (<0.5%). Chamber O2 and
CO2 concentrations were continuously monitored (OM-11
O2 analyzer and LB-2 CO2 analyzer,
Sensormedics, Anaheim, CA). The mice were exposed to room air for 10 min twice a week to clean the cages and replenish food and water
supplies. At the end of the hypoxic exposure, mice were injected with
heparin and anesthetized with pentobarbital sodium (43 mg/kg ip). The
chest was opened, and measurements of hematocrit were made on blood
from the heart that was collected in capillary tubes. The heart and
lungs were removed en bloc and transferred to a petri dish of
physiological salt solution (PSS) containing (in mM) 130 NaCl, 5 KCl,
1.2 MgCl2, 1.5 CaCl2, 10 HEPES, and 10 glucose,
with the pH adjusted to 7.2 with 5 M NaOH. The right ventricle (RV) of
the heart was separated from the left ventricle and septum (LV+S) after
removal of the atria, and the two portions were blotted dry and weighed.
The method for obtaining single PASMCs has been described previously (22). Briefly, intrapulmonary arteries (200- to 500-µm OD) were isolated and cleaned of connective tissue. After the endothelium was disrupted by gently rubbing the luminal surface with a cotton swab, the arteries were allowed to recover for 30 min in cold (4°C) PSS followed by 20 min in reduced-Ca2+ PSS (20 µM CaCl2) at room temperature. The tissue was digested in reduced-Ca2+ PSS containing collagenase (type I; 1,750 U/ml), papain (9.5 U/ml), bovine serum albumin (2 mg/ml), and dithiothreitol (1 mM) at 37°C for 10 min. After digestion, single smooth muscle cells were dispersed by gentle trituration with a wide-bore transfer pipette in Ca2+-free PSS, and the cell suspension was transferred to the cell chamber for study.
Electrophysiological Measurements
Myocytes were continuously superfused with PSS containing (in mM) 130 NaCl, 5 KCl, 1.2 MgCl2, 2 CaCl2, 10 HEPES, and 10 glucose, with the pH adjusted to 7.4 with 5 M NaOH. Patch pipettes (tip resistance 3-5 MEffect of chronic hypoxia on whole cell
K+ currents.
To identify the K+ currents present in mouse PASMCs,
membrane currents were activated by depolarizing pulses of 800 ms from a holding potential of 60 mV to test potentials ranging from
50 to
+40 mV in +10-mV step increments. Current measurements were made under
control conditions 3-4 min after the cells were treated with 100 nM ChTX to inhibit Ca2+-activated K+
(KCa) channels and 3-4 min after the subsequent
addition of 10 mM 4-AP to inhibit KV channels. In
subsequent experiments, KV currents were isolated by
pretreating cells with ChTX (100 nM) and with
[Ca2+]i buffered to eliminate effects on
KV current that were secondary to the hypoxia-induced
elevation in [Ca2+]i. The effect of chronic
hypoxia on KV currents was determined by comparison of
current-voltage (I-V) relationships of peak KV current density measured in cells from normoxic and hypoxic
Hif1a(+/+) and Hif1a(+/
) animals.
Effect of chronic hypoxia on membrane potential. Membrane potential was measured in current-clamp mode with I = 0. Membrane potential was measured for 2 min, and cells with unstable membrane potentials were discarded. Membrane potential for each cell was determined by calculating the average membrane potential for the 2-min recording period.
Drugs and Chemicals
ChTX was obtained from American Peptides (Sunnyvale, CA). All other chemicals were obtained from Sigma (St. Louis, MO). A stock solution of ChTX (10Data Analysis
Amplitudes of currents are expressed as current density obtained by normalizing peak current with cell capacitance. To examine the inactivation kinetics of KV currents, current was separated into inactivating and noninactivating components. The time course of inactivation of KV current at +30 mV was fit with the exponential equation (22) I(t) = Ao + A1e(Statistical significance was determined with Student's t-test (paired or unpaired as applicable). A value of P < 0.05 was accepted as significant. Data are expressed as means ± SE; n is the number of cells tested.
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RESULTS |
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Effect of Chronic Hypoxia on Right Ventricular Hypertrophy and Hematocrit
The development of pulmonary hypertension was assessed by measuring RV hypertrophy in hypoxic mice. RV free wall and LV+S weights were similar in normoxic Hif1a(+/+) and Hif1a(+/
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Effect of Chronic Hypoxia on Cell Capacitance
Cell capacitance was measured in single freshly isolated PASMCs under conditions of whole cell patch clamp. Average cell capacitance in PASMCs from normoxic Hif1a(+/+) and Hif1a(+/
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Identification of K+ Currents in Mouse PASMCS
Application of step depolarizations from a holding potential of
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Effect of Chronic Hypoxia on KV Current
In the presence of ChTX, peak KV current was measured and normalized to cell capacitance. Consistent with the known voltage dependence of this channel, KV current density increased with increasing voltage, reaching 4.81 ± 0.87 pA/pF at +30 mV in cells from Hif1a(+/+) mice (n = 8) and 5.03 ± 1.6 pA/pF at +30 mV in cells from Hif1a(+/
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Effect of Chronic Hypoxia on Membrane Potential
Resting membrane potential was measured in PASMCs with whole cell patch clamp in current-clamp mode. In PASMCs from normoxic mice, the average resting membrane potential was
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DISCUSSION |
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Development of pulmonary hypertension during chronic hypoxia
results from a reduction in vascular caliber due to both sustained contraction and remodeling. Pulmonary vasoconstriction and smooth muscle cell hypertrophy and hyperplasia are associated with elevated resting [Ca2+]i levels, a consequence of
reduced KV channel activity and depolarization. Using a
murine model of hypoxic pulmonary hypertension, we found that partial
deficiency for HIF-1 results in a significant attenuation of RV
hypertrophy and polycythemia, results consistent with previous observations by our laboratory (30). We also found
that hypoxia induced PASMC hypertrophy, reduction of KV
current, and depolarization in Hif1a(+/+) mice, effects that
were reduced or absent in Hif1a(+/
) mice. These results
delineate a critical role for HIF-1
in the pathophysiological
response of PASMCs to hypoxia.
A large body of data indicates that alterations in PASMC structure and
function occur during the development of pulmonary hypertension. We
demonstrated that PASMC size, as reflected in the measurement of cell
capacitance, was increased in cells from chronically hypoxic
Hif1a(+/+) mice, a response that was completely absent in
Hif1a(+/) mice. Although the molecular mechanisms
underlying PASMC hypertrophy and proliferation are not clear, our data
indicate that normal levels of HIF-1
are required for
hypoxia-induced hypertrophy of pulmonary vascular smooth muscle. The
absence of PASMC hypertrophy in hypoxic Hif1a(+/
) mice
provides a basis for the attenuation of vascular remodeling that
has been reported previously (30).
Exposure to chronic hypoxia resulted in a reduction in whole cell
KV current density in PASMCs from Hif1a(+/+)
mice, similar to results previously described in rat models (23,
24). Reduction of KV current density is also a
feature of human pulmonary hypertension (32). Because
KV current was normalized to cell capacitance, the
reduction in KV current density in these cells could be due to the fact that PASMC size is increased in chronically hypoxic Hif1a(+/+) mice. For the observed reduction in
KV current density (54% at +30 mV), PASMC capacitance
would have to increase by >100%. However, PASMC capacitance increased
63% in response to chronic hypoxia, suggesting that PASMC hypertrophy
alone cannot account for the entire decrease in KV current.
Moreover, the KV current inactivation kinetics are markedly
different in PASMCs from chronically hypoxic Hif1a(+/+) and
Hif1a(+/) mice, providing further evidence that the
reduction in KV current density is not simply due to an
increase in cell size. These data suggest that at least a portion of
the decrease in current density is attributable to a reduction in
KV channel activity. The effect of chronic hypoxia on
KV current density observed in Hif1a(+/+) mice
was absent in Hif1a(+/
) mice. Although one reason for the
lack of reduction in KV current density may be the
prevention of PASMC hypertrophy in hypoxic Hif1a(+/
) mice,
maintenance of normal KV channel activity is also likely to
contribute to the preservation of KV current density, as
supported by the fact that KV current inactivation kinetics
were not altered in these cells. These findings indicate that full
expression of HIF-1
is required for the hypoxia-induced decrease in
KV current.
It is unclear whether reduced KV channel activity in
response to chronic hypoxia is due to a change in PASMC phenotype,
altered regulation of the channels, decreased KV channel
expression, or a combination of these factors. Regulatory pathways
involved in the inhibition of K+ channels include
association with -subunits or phosphorylation by protein kinase C
(PKC) (1, 3, 12, 14). Hypoxia alters PKC isozyme
expression and subcellular distribution (6, 28). Exposure
of cultured PASMCs to hypoxia decreases mRNA and protein expression of
KV
-subunits, whereas KV
-subunit
expression is unaffected (26). If these changes in protein
expression occur in vivo, then the hypoxia-induced reduction in
KV current density could be explained by a decrease in
KV channel number in concert with increased association
with inhibitory
-subunits.
Under normal conditions, the major regulator of resting membrane
potential in PASMCs appears to be the KV channel because inhibition of these channels causes membrane depolarization, activation of voltage-gated Ca2+ channels, and increased
[Ca2+]i (22, 31). The observed
reduction in KV current density in PASMCs from
Hif1a(+/+) mice after exposure to chronic hypoxia is
consistent with the observed hypoxia-induced depolarization in
these animals. The magnitude of depolarization in Hif1a(+/+) mice is similar to that previously reported in the rat and in humans
(23, 24). Depolarization was significantly attenuated, although not completely prevented, in PASMCs from chronically hypoxic
Hif1a(+/) mice. This finding, coupled with the
demonstration that the hypoxia-induced reduction in KV
current was completely eliminated in these mice, suggests that
depolarization in response to chronic hypoxia is due to more than
simply a change in K+ channel conductance. Other ion
channels can participate in the regulation of resting membrane
potential, and a decrease in Cl
conductance and/or an
increase in Na+ or Ca2+ conductance could also
result in depolarization. Nonetheless, our data provide compelling
evidence that partial deficiency of HIF-1
blunts hypoxia-induced
changes in PASMC electrophysiology.
In summary, we have demonstrated that exposure to chronic hypoxia
increased cell capacitance, reduced KV current density, and
depolarized PASMCs and that these effects were reduced or absent in
PASMCs from mice partially deficient for HIF-1. No other gene
product has been shown to have such a profound effect on pulmonary
vascular and, specifically, PASMC responses to chronic hypoxia. These
striking results indicate that hypoxic induction of HIF-1
is
required for both PASMC depolarization and hypertrophy, although
whether these represent primary or secondary responses to chronic
hypoxia is not clear. PASMC hypertrophy contributes to vascular
remodeling through medial thickening of arterioles, whereas reduction
of KV current and depolarization may play a causal role in
the regulation of cell function through control of
[Ca2+]i, which is associated with cell
contraction, proliferation, and gene expression. Our data indicate that
HIF-1
plays a pivotal role in mediating both the vasoconstriction
and vascular remodeling observed during the pathogenesis of hypoxic
pulmonary hypertension, which contributes significantly to morbidity
and mortality in patients with chronic lung disease.
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ACKNOWLEDGEMENTS |
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This work was supported by National Institutes of Health Grants HL-51912 (to J. T. Sylvester), HL-55338 and DK-39869 (both to G. L. Semenza) and American Heart Association Grant AHA-9930255N (to L. A. Shimoda). L. A. Shimoda is the recipient of a Scientist Develop Grant from the American Heart Association.
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FOOTNOTES |
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J. S. K. Sham is an Established Investigator of the American Heart Association. D. J. Manalo was supported by a postdoctoral fellowship from the Pulmonary Hypertension Association and by Johns Hopkins University Multidisciplinary Training Program in Lung Diseases Grant T32-HL-07534.
Address for reprint requests and other correspondence: L. A. Shimoda, Div. of Pulmonary and Critical Care Medicine, Johns Hopkins Univ., 5501 Hopkins Bayview Cir., JHAAC 4A.52, Baltimore, MD 21224 (E-mail: shimodal{at}welch.jhu.edu).
The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Received 6 November 2000; accepted in final form 1 February 2001.
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