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*
Departments of Pulmonary and Critical Care Medicine,
Cancer Biology, Lerner Research Institute, Cleveland Clinic Foundation, Cleveland, OH 44195;
Department of Medicine, Baylor College of Medicine, Houston, TX 77030; and
§
University of Pittsburgh, Pittsburgh, PA 15261
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Abstract |
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 Top Abstract IntroductionMaterials and MethodsResultsDiscussionReferences |
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Introduction |
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TopAbstractIntroductionMaterials and MethodsResultsDiscussionReferences |
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Materials and Methods |
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TopAbstractIntroductionMaterials and MethodsResultsDiscussionReferences |
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Healthy, nonsmoking control individuals (n = 23)
and asthmatic, nonsmoking individuals (n = 28) were
studied. To be enrolled, asthmatic individuals must have shown a 
14%
increase in absolute forced expiratory volume in 1 s
(FEV1), either spontaneously or after
bronchodilator within the year before enrollment, and have satisfied
the definition of asthma (10). Asthma severity and
temporal course in volunteers included mild intermittent and mild
persistent asthma (10). Asthmatic individuals had not
received oral or i.v. corticosteroids within the previous 6 mo. All
asthmatic individuals used short-acting inhaled
ß2-agonists on an as-needed basis, but did not
use ß2-agonist medication on the day of
bronchoscopic study. Seven asthmatic individuals were studied while
using inhaled corticosteroid (1000 µg/day flunisolide for at least 3
wk). Healthy control volunteers were taking no medication. Exclusion
criteria for both asthmatic and healthy control individuals included
age over 65 yr or under 18 yr, pregnancy, HIV infection, history of
respiratory infection in the previous 6 wk, tobacco use within the past
5 yr, and/or >10 pack yr of smoking. Additional exclusion criteria for
control individuals included history of allergies, history of rhinitis
and/or sinusitis, prolonged exposure to secondhand smoke at home or
work, exposure to dusty environments or known pulmonary
disease-producing agents, history of lung disease, or history of
recurrent episodes of breathlessness, chest tightness, cough, and/or
sputum production. Control volunteers were also excluded from
participating if physical examination demonstrated signs of wheezing on
forced expiration. Pulmonary function testing for control and asthmatic
individuals was performed on a spirometer (Spinnaker TL, Cybermedic,
Louisville, CO). The forced vital capacity (FVC),
FEV1, and ratio of FEV1 to
FVC (FEV1/FVC) were collected for each of three
efforts. The study was approved by the Cleveland Clinic Foundation
institutional review board, and written informed consent was obtained
from all individuals.
Bronchoscopic studies
Airway epithelial cells were obtained by bronchoscopic brushing of second- and third-order bronchi through a flexible fiberoptic bronchoscopy as previously described (11). Because many of the studies described required large numbers of cells, not all studies could be performed on all samples. The number of samples evaluated for each experiment is stated in the text. Bronchoalveolar lavage (BAL) was also performed to recover epithelial lining fluid and inflammatory cells, i.e., alveolar macrophages (12). Briefly, three 50-ml aliquots of warm (37°C) sterile saline solution were infused into a segmental or subsegmental bronchus and then aspirated back. NO levels in bronchiolar gases were also measured during bronchoscopy as previously described (13). The bronchoscope was advanced into the lung, and real-time NO measurements were obtained at a rate of 20 samplings/s using a Teflon tube inserted through the working channel of the bronchoscope and connected to a chemiluminescence analyzer for detection of NO (NOA 280, Sievers, Boulder, CO) while the subject was holding his breath (13).
Cytokine levels in the lung were evaluated using a segmental
bronchoprovocation with Ag in atopic asthmatics and nonatopic healthy
controls (14). Ags for bronchial challenge (ragweed,
grass, cat, or Dermatophagoides farinae) had no detectable
endotoxin (<0.006 ng/ml; Limulus Lysate, BioWhittaker,
Walkersville, MD). Ag sensitivity was determined by skin testing as
previously described (14). Ag equal to the dose producing
a 20% decrease in FEV1 with whole lung Ag
challenge was inserted into the right middle lobe subsegment during
bronchoscopy. BAL (two 60-ml aliquots of warm sterile saline) was
initially performed at baseline in the lingula and after Ag treatment
at 8, 24, and 48 h in the right middle lobe. A quantitative ELISA
for IFN-
detection was purchased from Endogen (Cambridge,
MA).
Cell culture
Airway epithelial cells obtained by bronchial brushing were
cultured in serum-free Lechner and LaVeck medium (LHC-8, Biofluids,
Rockville, MD) on plates pretreated with coating medium containing 29
µg/ml collagen (vitrogen from Collagen Corp., Palo Alto, CA), 10
µg/ml BSA (Biofluids), and 10 µg/ml fibronectin (Calbiochem, La
Jolla, CA) (12, 15). BET1A, a human bronchial epithelial
cell line transformed with the T-Ag-containing plasmid pRSV-T (a gift
from C. Harris, National Cancer Institute, Bethesda, MD)
(16), was cultured in serum-free Lechner and LaVeck medium
with additives 0.33 nM retinoic acid and 2.75 µM epinephrine on
plates precoated with coating medium as described above. A549 cells, an
epithelial cell line derived from lung adenocarcinoma (American Type
Culture Collection, Manassas, VA), were cultured in MEM (Life
Technologies, Grand Island, NY) with 10% heat-inactivated FBS
(15). The mouse macrophage cell line RAW264.7 was cultured
in DMEM (Life Technologies) with 5% heated-inactivated FBS.
Recombinant human IL-1ß and TNF-
were obtained from Genzyme
(Cambridge, MA).
RNA extraction and Northern analysis
Total RNA was extracted and evaluated by Northern analyses as
previously described or by slot-blot technique by application in
duplicate of 0.5 µg of total RNA to nylon membrane (Duralon,
Stratagene, La Jolla, CA) (11). The membranes were
hybridized with a 32P-labeled 1.9-kb NOSII cDNA
(pCCF21) (12) or, as a control, with -actin cDNA
(pHFA-1) (17). Quantitation of NOSII mRNA relative to
-actin was accomplished using a PhosphorImager (Molecular Dynamics,
Sunnyvale, CA).
NOSII mRNA transcription in airway epithelial cells
The NOSII gene transcription rate was measured by nuclear
transcription run-on analyses (18). Nuclei were isolated
from human airway epithelial cells freshly obtained or cultured for
8 h in LHC-8. Nuclei were incubated with
-32P-labeled UTP (Amersham, Arlington Heights,
IL; 40 µCi/µl) and ATP, CTP, GTP, and RNase inhibitor (Roche,
Indianapolis, IN) to label nascent RNA transcripts. The
32P-labeled RNA was purified on an RNase-free
Sephadex G-50 quick spin column (Roche). Quantitation of labeled
nascent RNA was accomplished by application of DNA targets to nylon
membrane (Duralon, Stratagene) using a slot-blot technique and
hybridization with 32P-labeled RNA. The membranes
were washed with buffer containing RNase A (5 µg/ml), RNase T1 (5
U/ml), and proteinase K (50 µg/ml), respectively. The DNA targets
included plasmids containing NOSII cDNA (pCCF21), a human -actin
cDNA (17), or, as a negative control, the plasmid pSK
Bluescript (Stratagene) containing no human DNA. The relative NOSII
gene transcription rate in freshly obtained or cultured human airway
epithelial cells was quantitated relative to -actin using a
PhosphorImager (Molecular Dynamics).
RT-PCR and segmental analysis of the NOSII gene
cDNA was reverse transcribed from total RNA extracted from freshly obtained airway epithelial cells using Moloney murine leukemia virus RNase H- reverse transcriptase, oligo(dT)12–18 primer, and random hexamers (Life Technologies). cDNA was amplified by PCR using human NOSII-specific primers as previously described (19) for segmental analysis of the NOSII gene. PCR products were separated by gel electrophoresis and evaluated by Southern analyses using 32P-labeled full-length human NOSII cDNA (19).
Electrophoretic mobility shift assays (EMSA)
Whole cell extract (WCE) from freshly obtained airway epithelial
cells and untreated or cytokine-treated cell lines was prepared as
previously described (15). The protein concentration was
measured by the Coomassie protein assay (Pierce, Rockford, IL). The
following oligonucleotides were used in this study: the IFN-
activation site oligonucleotide (GAS)
(5'-GCCTGATTTCCCCGAAATGACGGC-3') corresponding to human IFN
regulatory factor-1 (IRF-1) promoter from -130 to -106 bp
relative to the transcription start point (20), Stat
binding element
(SBE; 5'-GCTCTTCTCCCAGGAACTCAATG-3')
corresponding to secreted type IL-1R antagonist gene promoter from bp
-254 to -231 relative to the transcription starting point
(21), and 
B
site(5'-AACTCCGGGAATTTCCCTGGCCC-3') corresponding to human
GRO gene promoter from bp -82 to -60 relative to the
transcription start point (22). Underlined sequences
represent the consensus elements for GAS, SBE, and B, respectively.
These oligonucleotides were synthesized by Operon (Alameda, CA) and end
labeled with [-32P]ATP by polynucleotide
kinase.
Detection of IRF-1 GAS-Stat1, and SBE-Stat6 binding complexes was
performed as previously described (20, 21). For NFB
activation detection, 32P-labeled oligonucleotide
(0.2 ng) was incubated with 5 µg of WCE protein in a 25-µl final
reaction volume containing 20 mM HEPES (pH 7.9), 5% glycerol, 50 mM
NaCl, 1 mM DTT, 0.1 mM EDTA, 200 µg/ml BSA, and 4 µg of
polydeoxyinosinic:polydeoxcytidylic acid (Amersham). The binding
reaction mixture was incubated at room temperature for 15 min before
electrophoresis on 4% acrylamide gels in 0.25x TBE (22.3 mM Tris,
22.2 mM borate, and 0.5 mM EDTA). The gels were dried and analyzed by
autoradiography. To demonstrate specificity of binding, competition was
performed by adding unlabeled oligonucleotide at a 100-fold molar
excess of 32P-labeled oligonucleotide probe in
the binding reaction. To specifically identify DNA binding proteins, 2
µg of rabbit anti-p50 (NF-B), p65 (RelA) polyclonal Abs (Santa
Cruz Biotechnology, Santa Cruz, CA), Stat1 monoclonal or polyclonal Abs
(20, 21), or rabbit anti-Stat6 (Santa Cruz
Biotechnology) were added to the binding reaction mix and incubated for
20 min at 4°C before adding the 32P-labeled
oligonucleotide.
Western analyses
Airway epithelial cells freshly obtained by bronchoscopic
brushing from asthmatics and healthy controls were suspended in buffer
(3 mM DTT, 5 µg/ml aprotinin, 1 µg/ml leupeptin and pepstatin A,
0.1 mM PMSF, 1% Nonidet P-40, and 40 mM HEPES, pH 7.5), and cell
lysate was prepared by three cycles of freeze/thaw. Total protein was
measured using the Coomassie protein assay (Pierce). Lysate from A549
cells stimulated with 100 U/ml IFN-, 10 ng/ml TNF-, and 10 U/ml
IL-1ß for 72 h was used as a positive control (12).
Whole cell lysate protein was denatured and reduced by treatment with
buffer containing 0.05 M Tris (pH 6.8), 1% SDS, 10% glycerol,
0.00125% bromophenol blue, and 0.5% 2-ME for 3 min at 95°C. Total
protein (50 µg/lane) was separated by electrophoresis on an 8%
SDS-polyacrylamide gel and then electrophoretically transferred onto
nitrocellulose (NitroBind EP4HY315F5, Micron Separations,
Westboro, MA) for 2 h at 4°C. Membranes were incubated with 1%
BSA in TBS (20 mM Tris-HCl (pH 7.0) and 137 mM NaCl) with 0.1% Tween
for 1 h at room temperature to block nonspecific binding, then
with the primary anti-nitrotyrosine polyclonal Ab (1/2500)
overnight at 4°C. Following washing, a peroxidase-conjugated
secondary anti-rabbit IgG (1/5000 in 1% BSA/TBS-0.1% Tween,
NA934, Amersham) was incubated with the membrane for 1 h at room
temperature followed by washes with TBS-0.1% Tween. The enhanced
chemiluminescent system (Amersham) was used for detection of signals.
To confirm the specificity of nitrotyrosine Ab, free nitrotyrosine
(3.75 mM; Sigma, St. Louis, MO) was added to block staining with
anti-nitrotyrosine. As a control for protein loading, Western
analyses for ß-actin were performed using a primary monoclonal
anti-ß-actin Ab (clone AC-74 (A-5316), Sigma). Nitrotyrosine
quantitation was accomplished by the ratio of relative densitometric
units of the multiple bands positive for nitrotyrosine to the ß-actin
band on Western blots using a Sierra Scientific resolution CCD camera
(Sunnyvale, CA) and National Institutes of Health Image 1.6.
Western analysis of cell lysate for NOSII was performed using a rabbit polyclonal primary Ab against the carboxyl terminus of NOSII protein (Merck, Rahway, NJ) and a peroxidase-linked species-specific donkey anti-rabbit secondary Ab (Amersham). Quantitation of the NOSII relative to ß-actin was accomplished by the ratio of relative densitometric units of the single NOSII band to ß-actin band on Western blots using a Sierra Scientific resolution CCD camera and National Institutes of Health Image 1.6. Similarly, NOSI and NOSIII were evaluated by Western analyses using a polyclonal (rabbit) epitope purified anti-NOSIII Ab (PA1-037, Affinity BioReagents, Golden, CO) directed against human NOSIII peptide (aa 1179–1194) at a dilution of 1/1000 and a polyclonal (rabbit) anti-NOSI Ab (PA3-032, Affinity BioReagents) directed against the calmodulin binding domain (aa 724–739) of rat NOSI at a dilution of 1/5000. NOS Abs were tested for cross-reactivity to 500 ng each of purified NOSI, NOSII, or NOSIII. In addition, NOSII Ab specificity was ascertained by blocking the Ab using NO54 (1 µg/ml), a free synthetic peptide corresponding to the carboxyl terminus of human NOSII (YRASLEMSAL-COOH; Merck), as previously described (23).
Arginine and citrulline analyses by HPLC
Two separate chromatography programs were employed to detect
arginine or citrulline, but the same columns and fluorescence detector
were used in each (23, 24). HPLC/fluorescence detection
analysis was conducted with a Perkin-Elmer LC240 fluorescence detector
(Norwalk, CT) and a Beckman HPLC system (Palo Alto, CA) using an
excitation wavelength of 340 nm and an emission wavelength of 455 nm
for detection. Amino acids were purchased from Sigma. Amino acid
standards or lysate were mixed with a 4-fold volume of methanol, placed
on ice for 5–10 min, then centrifuged at 13,000 rpm for 2 min. The
supernatant (20 µl) was mixed with 80 µl of
o-phthalaldehyde (OPA) reagent, and 50 µl was injected by
an autosampler. Separation of amino acid derivatives was conducted on a
Hypersil 5, C18 column (125 x 4.0 mm; Phenomenex, Belmont, CA),
using a security guard column (C18 (ODS, Octadecyl); length, 4 mm;
inside diameter, 3.0 mm; Phenomenex). OPA reagent (6 mM) was prepared
fresh daily in 0.1 M sodium borate
(Na2B4O7,
Sigma) in H2O containing 1% 2-ME. Amino acids
were separated using gradients formed from two degassed solvent
mixtures consisting of solvent A and solvent B. For arginine detection,
solvent A consisted of 5 mM ammonium acetate, pH 6.0, and methanol
(4/1, v/v), and solvent B was 100% methanol. For citrulline, solvent A
was comprised of 12.5 mM sodium phosphate, pH 7.0, with 0.35%
tetrahydrafuran, 10.5% methanol, and 4.5% acetonitrile, and solvent B
was 100% methanol. For arginine, a flow rate of 0.5 ml/min was used
with a gradient consisting of a linear increase of solvent B from
0–50% over 13 min, followed by a linear increase to 100% over the
next 2 min, then 100% B for 3 min followed by decrease to 0% over 1
min. Cell lysate (volume equivalent to total protein, 2 µg) was
injected on the column, and peaks were compared with authentic
standards of arginine (20–80 pmol; correlation coefficient of standard
curves, 0.97). For citrulline, a volume equivalent to total protein
of 10 µg was injected on the column, and peaks were compared with
authentic standards of citrulline (0.31–10 pmol; correlation
coefficient of standard curves, 0.97).
Statistical analyses
Continuous variables were summarized by group as sample size, mean, and SEM unless otherwise indicated. Statistical comparisons were performed using ANOVA, Student’s t test, or Smith-Satterthwaite t test as appropriate.
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Results |
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TopAbstractIntroductionMaterials and MethodsResultsDiscussionReferences |
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Healthy control and asthmatic individuals were similar in terms of
age, sex, and race (Table I
). Healthy
control volunteers had no evidence of airflow limitation and asthmatics
had mild degrees of airflow limitation as determined by ratios of
FEV1 to FVC (Table I).
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We have previously determined lung tissue levels of NO in healthy controls by measures of NO in subsegmental airway (bronchiolar) gases by bronchoscopy during a breath-hold maneuver, i.e., headspace gas (13). Headspace NO accurately reflects the concentration of NO in liquids/tissues, since at atmospheric pressures over 97% of NO is rapidly distributed from the liquid to the gaseous phase (13, 25). In this study NO was measured in bronchiolar gases in the lower airway during bronchoscopy, while the individuals were instructed to breath-hold. Bronchiolar gas NO is significantly higher in asthmatics compared with controls (NO (ppb): asthma, 24 ± 2 (n = 6); control, 6.7 ± 0.3 (n = 5); p < 0.01).
Increased reactive nitrogen species in asthma
Reaction of NO and superoxide is rapid and produces peroxynitrite
(6, 26). Peroxynitrite or other RNI can lead to nitration
of tyrosine, allowing nitrotyrosine to be used as a collective marker
of reactions between NO and reactive oxygen species (ROS) (6, 26). We quantitated the extent of tyrosine nitration and
evaluated the range of proteins nitrated by Western analyses using
specific anti-nitrotyrosine Abs. Multiple bands representing
nitrated proteins are detected on Western analyses, which are blocked
by free nitrotyrosine. Increased nitrotyrosine is detected in asthmatic
airway epithelial cells compared with controls
(nitrotyrosine/ß-actin: asthma, 12 ± 1 (n =
5); controls, 5 ± 1 (n = 6);
p = 0.004; Fig. 1).
The most prominent band in both healthy control and asthmatic cell
lysates is at 44 kDa and is increased in asthmatic epithelial cell
lysates. Interestingly, nitrotyrosine is nearly undetectable in airway
epithelial cells from asthmatics using inhaled corticosteroids (Fig. 1). These studies show that NO is increasingly consumed by biochemical
reactions in the lungs of asthmatics. In the context of increased
consumption, increased NO in bronchiolar gases strongly suggests that
NO synthesis is increased in asthma.
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To investigate NO synthesis, NOS protein expression was evaluated
by Western analysis of airway epithelial cell lysates using specific
anti-NOS Abs. NOSI and NOSIII are not detectable in airway
epithelial cells by Western analyses (Figs. 2, A and C).
However, a protein (131 kDa) in the asthmatic and control airway
epithelial cell lysates is detected using anti-NOSII Ab, which is
similar in size to NOSII detected in positive control lysate from A549
cells stimulated with IFN- (100 U/ml), TNF- (10 ng/ml), and
IL-1ß (10 U/ml) for 72 h. Asthmatic airway NOSII expression is
significantly higher than control (NOSII/ß-actin: asthma, 0.60
± 0.08 (n = 6); control, 0.33 ± 0.06
(n = 5); p < 0.05; Fig. 2B).
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The availability of intracellular arginine may regulate NO
synthesis (27, 28, 29, 30, 31). Quantitation of arginine by HPLC
reveals that asthmatic airway epithelial cells contain over 3-fold
higher levels of arginine than healthy controls (arginine (mean ±
SD): control, 22 ± 3 pmol/µg total protein (n =
3); asthma, 77 ± 16 (n = 3); p =
0.02; Fig. 3). Arginine and citrulline in
BAL fluid and citrulline in airway epithelial cell lysates are not
detectable (<0.3 pmol). Thus, post-translational mechanisms that
support high output NO synthesis are induced in asthma.
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To evaluate whether increased NOS II protein in asthma was related
to increased NOSII mRNA expression, Northern analyses of total RNA from
airway epithelial cells freshly obtained by bronchoscopic brushing and
from alveolar macrophages obtained by BAL of asthmatics
(n = 7) and controls (n = 9) were
performed. NOSII mRNA is demonstrated in airway epithelial cells as a
prominent signal at 4.5 kb using a 32P-labeled
NOSII cDNA (pCCF21), with higher levels of NOSII mRNA in asthmatics
(NOSII/-actin mRNA: asthma, 0.62 ± 0.09 (n =
7); control, 0.27 ± 0.08 (n = 9);
p < 0.01; Fig. 4). In
murine systems, macrophages are a major source of NO (32).
In paired samples of airway epithelium from bronchial brushing and
human lung macrophages from bronchoalveolar lavage simultaneously
obtained at bronchoscopy, abundant levels of NOSII are present in
airway epithelium, but NOSII is not detected in macrophages by Northern
analyses (Fig. 4).
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Corticosteroids are able to inhibit the cytokine- and
endotoxin-induced expression of NOSII in vitro (33, 34, 35).
Interestingly, NOSII mRNA expression in asthmatics using inhaled
corticosteroid is less than that in asthmatics not using inhaled
corticosteroid and is similar to that in healthy control individuals in
this study (NOSII/-actin mRNA: asthma with corticosteroid, 0.26
± 0.07; Fig. 5). Three asthmatics,
evaluated in a pairwise fashion, have decreased NOSII mRNA expression
following 3 wk of inhaled corticosteroid use (Fig. 5). These results
suggest that the decreased NO and nitrotyrosine in asthmatics using
inhaled corticosteroids are due to decreased NOSII gene expression.
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mRNA regulation may be modulated at many points, including
transcription, processing, and stability. The human NOSII gene contains
26 exons encoding a peptide of 1153 aa (19, 36). Recently,
four sites of alternative splicing of the NOSII mRNA have been
identified that lead to deletion of exon 5, exons 8 and 9, exons 9–11,
or exons 15 and 16 (19). In tissue culture cells, NOSII
induction by cytokines and endotoxin results in an increase in
alternatively spliced mRNA transcripts (19). Importantly,
the regions encoded by exons 8 and 9 are highly conserved among NOSs
and are critical for NOS dimerization and subsequent synthetic activity
(36). We evaluated asthmatic and healthy control airway
epithelium for alternative splicing of NOSII mRNA. Total RNA extracted
from the asthmatic or control airway epithelial cells was transcribed
to cDNA, and segmental analysis of the NOSII gene was performed by PCR
using specific primers. Southern analysis of PCR products show that
alternatively spliced NOSII mRNAs are present, but are a minority of
the NOSII mRNA in asthmatic and control airway epithelial cells (Fig. 6). The majority of NOSII expressed in
the airway is processed normally, resulting in full-length NOSII that
is capable of NO synthesis.
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Airway epithelial cells in vitro require stimulation with
microbial products or cytokines to induce expression of NOSII
(15, 37, 38, 39). To investigate whether the high level of
NOSII mRNA in asthmatic airway epithelial cells was dependent upon the
airway milieu, airway epithelial cells from healthy or asthmatic
individuals were studied ex vivo. Each sample of airway epithelial
cells obtained by bronchial brushing was divided into two aliquots;
one-half of the sample was extracted for RNA immediately (0 h), and the
remaining one-half was placed in culture with specialized serum-free
medium (LHC8) and extracted for RNA after 24 h. Similar to
previous work (12), NOSII expression is lost in primary
airway epithelial cells of healthy controls in culture
(n = 4 paired samples; Fig. 7). Despite the high levels of NOSII mRNA
in the asthmatic airway epithelial cells, NOSII mRNA is not detectable
by Northern analysis following 24-h culture (n = 3
paired samples). These data provide strong support that NOSII mRNA
expression is dependent on factors and/or conditions related to the
airway environment.
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Evidence in the literature and our previous work point to
transcriptional regulation of NOSII mRNA (15, 37, 38, 39). In
this study the rate of NOSII transcription relative to -actin in
vivo was compared with rates in vitro by run-on experiments using
nuclei extracted from airway epithelial cells freshly obtained at
bronchoscopy or after 8-h culture. Active transcription of NOSII mRNA
is present in airway epithelial cells in vivo, but transcription of
NOSII in airway epithelial cells ex vivo decreases relative to in vivo
levels (NOSII mRNA transcription relative to -actin mRNA (mean
± SD): freshly obtained human airway epithelial cells, 15 ± 4%;
airway epithelial cells after 8-h culture, 2 ± 2%;
n = 2 paired samples; Fig. 8). The rapid decrease in NOSII
transcriptional rate ex vivo provides conclusive evidence that airway
epithelial cells are dependent upon an in vivo factor(s) for expression
and regulation of the NOSII gene.
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in BAL fluid
IFN- is essential for NOSII expression in human primary airway
epithelial cells in vitro (15). In this study asthmatics
have a trend toward higher IFN- in BAL fluid compared with healthy
controls (p = 0.06; Fig. 9). IFN- in BAL fluid of
asthmatics is significantly higher than that in healthy controls using
a segmental bronchoprovocation model to mimic asthma exacerbation (all
time points, p < 0.03; Fig. 9). These results support
that asthmatics have increased levels of IFN-, a cytokine crucial
for NOSII gene expression (15, 37, 38, 39).
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and IL-4 induce expression of
NOSII in airway epithelial cells in culture that is dependent upon new
protein synthesis and epithelial cell production of soluble mediators
(15). IFN- induces gene expression through the Janus
kinase (JAK)-Stat1 pathway, which involves a tyrosine phosphorylation
cascade (40, 41). In this context, pretreatment with
genistein, a tyrosine kinase inhibitor, prevents IFN-/IL-4 induction
of NOSII expression in airway epithelial cells (Fig. 10). Interestingly, genistein also
prevents NOSII induction by the soluble mediators present in
conditioned medium of airway epithelial cells exposed transiently to
IFN-/IL-4 (Fig. 10). These data support an essential role of
tyrosine phosphorylation signaling events in NOSII expression in human
airway epithelial cells.
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To investigate the involvement of tyrosine kinase signaling and
specifically JAK-Stat pathway activation in NOSII expression in asthma
in vivo, EMSA of WCE from freshly obtained airway epithelial cells of
asthmatics and controls was performed (Fig. 11). Several cytokines implicated in
the airway inflammatory reaction of asthma activate the JAK-Stat1
pathway (40, 41). While IFN- uses Stat1, IL-4 activates
Stat6 (40, 41). Binding complexes in airway epithelium are
detected using the GAS element from the human IRF-1 promoter. Stat1 is
confirmed in the complex by anti-human Stat1 Abs (Fig. 11A). Stat1 activation is increased in asthmatic airway
epithelial cells compared with control (densitometric units of binding
complex: asthma, 46 ± 2 (n = 5); control,
22.6 ± 0.6 (n = 6); p < 0.01). A low level
of Stat6 activation is also noted (Fig. 11A). Using a Stat
binding element (SBE) from the secreted-type IL-1R antagonist gene as a
probe to specifically detect Stat6 activation, EMSA confirms a very low
level of Stat6-containing complex in the cell lysates of the same
individuals used for detecting Stat1 activation (data not shown). These
data are compatible with our previous report that WCE from airway
epithelial cells stimulated with IL-4 (10 ng/ml) in culture for 15 min
induced a very faint binding complex containing Stat6
(15).
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B was also investigated
by EMSA using NF-B binding element from the human GRO gene
(22) (Fig. 11
B). Although cytokines that signal
through NF-B may be increased in asthma, asthmatics in this study
have low levels of NF-B activation in airway epithelial cells,
similar to control values (densitometric units: asthma, 126 ± 4,
(n = 5); control, 127 ± 4 (n =
6); p > 0.5). |
Discussion |
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TopAbstractIntroductionMaterials and MethodsResultsDiscussionReferences |
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-tubulin post-transitionally in
the lung epithelial cell line A549, which alters microtubule function,
leading to changes in cell morphology and epithelial barrier function
(46). Although the precise protein targets undergoing
tyrosine nitration in the airway epithelial cells in vivo are not
determined, these studies identify a specific pattern of nitrated
proteins in airway epithelium that is increased in asthmatic
airways. The concentration of NO in any biologic system is a consequence of its rate of enzymatic formation and consumption/scavenging by other biomolecules. In the context of increased scavenging of NO by ROS, increased enzymatic synthesis is a likely mechanism for increased NO levels in asthma. However, NO biosynthesis is regulated at multiple levels in cells, i.e., NOS gene transcription, mRNA processing, protein expression and dimerization, and enzyme reaction kinetics (7). Immunostaining of lung tissue has suggested that NOS protein is increased in the airway epithelium of the asthmatic lung (8, 9). In this study NOSII protein is present in control airway epithelial cells, but is clearly increased in asthmatic airways in vivo. However, NO synthesis is dependent upon post-translational modifications to generate active NOS. Specifically, NOSs are synthesized as monomers and must dimerize to generate NO (7). Recently, deletion of regions critical for NOS dimerization due to alternative splicing of the NOSII mRNA has been identified (36). In tissue culture cells, NOSII induction by cytokines and endotoxin results in an increase in both constitutively and alternatively spliced mRNA transcripts (19, 36). In contrast, we show that the majority of NOSII mRNA in airway epithelial cells in vivo are processed as full-length transcripts.
Enzyme-catalyzed NO synthesis involves hydroxylation of arginine to
generate N-hydroxyarginine, an enzyme-bound intermediate,
which is then converted to citrulline. The intracellular concentration
of arginine (several hundred micromolar concentrations) (27, 28, 30, 47) has been reported to far exceed the
Km of the NO synthases (5–10 µM)
(47). In this context, it would seem unlikely that
arginine is ever rate limiting to the enzyme. However, arginine
administration drives NO synthesis in vivo and in cell culture systems
(27, 30, 31, 49). Independent of substrate effects,
arginine may regulate enzyme reaction kinetics through effects on
enzyme dimerization or influences on the reduction potential of the
enzyme (7). In addition, sequestration of arginine to
regions in the cell that are poorly accessible to NOS may account for
situations in which increasing arginine drives enzyme activity, even
when arginine is available in apparent excess (50). In
support of these concepts, the kinetics of NO production by NOSII in
activated macrophages over a range of arginine concentrations reveal a
Km for arginine in intact cells of
73–150 µM (49, 51). Intracellular arginine can be
increased by de novo synthesis through regeneration from citrulline or
transport from extracellular sources (28, 29, 30, 47).
Arginine synthetic pathways and transporter systems are induced
coordinately with NOSII induction in cell cultures. Argininosuccinate
synthetase, the rate-limiting enzyme in the synthesis of arginine, is
induced by endotoxin and IFN-, suppressed by corticosteroids, and
generally mirrors NOS induction in smooth muscle cells in vitro
(29). In this study arginine is present in healthy control
airway epithelial cells (
110 µM), while citrulline is not
detectable. Importantly, arginine levels are increased >3-fold in
asthmatic epithelial cells, suggesting coordinate induction of the
arginine synthetic pathways and/or cationic amino acid transporters to
support a high rate of NO synthesis in asthma.
Although translational and post-translational mechanisms are important
in the regulation of NO synthesis, NOSII is substantially regulated at
the level of transcription (37, 38, 39). As we and others have
previously shown, healthy human airway epithelium in vivo expresses the
NOSII gene continuously at abundant mRNA levels (12, 52).
Here, we show that the NOSII gene is actively transcribed in airway
epithelial cells in vivo. Transcription of the NOSII gene is at 15%
the transcription rate of -actin, an abundantly expressed mRNA in
the airway epithelium (11). NOSII mRNA expression in
asthmatic airway epithelium is higher than that in controls in vivo,
but is not increased in asthmatics receiving inhaled corticosteroid.
Inhaled corticosteroids are the most effective therapies for reducing
inflammation in asthma. While the use of inhaled corticosteroids as a
first-line treatment in asthma has increased, little is known regarding
the cellular and molecular mechanisms that contribute to the efficacy
of inhaled corticosteroids in vivo. Several studies have shown that
inhaled or i.v. corticosteroids reduce exhaled NO (1, 2, 3).
In situ analysis of the asthmatic airway suggested that NOSII
expression is reduced by corticosteroids (9). In general,
mechanisms by which corticosteroids regulate NOSII gene expression in
vivo are not known. In vitro, glucocorticoids inhibit NOSII expression
at multiple levels, including inhibition of gene transcription,
reduction of mRNA translation, and increased degradation of NOSII
protein (33, 34, 35). Increased NOSII mRNA in asthma, which is
down-regulated by corticosteroid, supports an association between NOSII
expression and airway inflammation.
Loss of NOSII expression in control and asthmatic airway epithelial
cells ex vivo substantiates a critical link between airway conditions
and/or factors in vivo and NOSII expression. Induction of NOSII
expression varies in different cell types, but typically is increased
by cytokines (15, 32, 37, 38, 39). IFN- is crucial for
induction of NOSII expression in airway epithelial cells in vitro
(15). IFN- signaling to gene expression begins with a
specific receptor interaction and oligomerization of receptor chains,
causing a tyrosine kinase cascade. Stat1 phosphorylation, dimerization,
and translocation to the nucleus are followed by binding to regulatory
DNA elements to activate transcription of IFN-stimulated genes
(40, 41). We and others have shown that IFN- leads to
Stat1 activation in primary human airway epithelial cells in culture
(15, 53). In this study we show that tyrosine kinase
inhibitor abolishes induction of NOSII in airway epithelial cells.
Recently, Stat1 activation has been demonstrated in the asthmatic
airway by nuclear localization of Stat1 in airway epithelial cells and
demonstration of phosphorylation of Stat1 by Western analyses of
epithelial cell lysates (54). The Stat1 activation
correlated with the induction of IFN-/Stat1-stimulated genes,
including IRF-1, which has been identified as essential for NOSII
activation in murine macrophages (32). In this study Stat1
activation quantitated by EMSA is present in controls, but is increased
in asthmatic airway epithelial cell lysates. In contrast to increased
Stat1 activation in the asthmatic airway, other cell-signaling proteins
are not increasingly activated. We show that Stat6 and NF-B
activation are not increased in asthmatic airway compared with those in
healthy controls. Previous study has shown that Stat3 and AP-1
activation is not increased in asthma (54). Stat1 tyrosine
phosphorylation and translocation to the nucleus occur in response to
many growth factors and cytokines, including IFN-, IL-10,
IFN-/ß, epidermal growth factor, platelet-derived growth factor,
GM-CSF, IL-6, IL-11, leukemia inhibitory factor, ciliary neurotropic
factor, oncostatin M, growth hormone, prolactin, and CSF-1 (40, 41). IFN- has both anti- and proinflammatory effects in
the lung. In fact, IFN- mediates numerous anti-inflammatory
effects, including inhibition of Ag and Th2-cell induced pulmonary
eosinophilia and airway hyper-reactivity (55). However,
IFN- is also implicated in the pathobiology leading to airway
inflammation and hyper-reactivity in asthma (55, 56, 57, 58). For
example, OVA-sensitized mice develop airway hyper-responsiveness
dependent upon IFN- (57). Further, adoptive transfer of
Th1 lymphocytes, which characteristically produce IFN-, increases
airway inflammation in a murine model of allergic asthma
(58). In this study IFN- levels are higher in asthmatic
epithelial lining fluid than in controls following a segmental
bronchoprovocation with Ag. The large number of
IFN-/Stat1-stimulated genes, including IRF-1, ICAM-1, and NOSII, are
probably involved in the airway inflammatory events of asthma.
Collectively, these data provide strong support for Stat1 activation
mediating NOSII gene expression in human airway epithelial cells
in vivo.
NF-B activation and binding to B DNA elements in the 5'-flanking
region of the NOSII gene play a role in the cytokine induction of NOSII
in the human lung epithelial cell line A549 in vitro
(37, 38, 39). However, studies of NF-B activation in asthma
are conflicting, perhaps in part due to the types of samples analyzed
(48, 54). Expectorated sputum from asthmatics or pooled
biopsies of asthmatic airways have shown increased NF-B activation
compared with controls (48), while no increase in
activation was noted by nuclear localization of NF-B in biopsies and
bronchial brushings of asthmatic airway epithelium (54).
Here, NF-B activation in asthmatic airway epithelial cells obtained
by bronchial brushing is at levels similar to those in healthy
controls. Our results support that increased NF-B activation is not
involved in NOSII induction in asthmatic airways. On the other hand,
NF-B activation is present in control and asthmatic epithelia and
may contribute to the tonic expression of NOSII in the airway.
In conclusion, multiple mechanisms function coordinately to support
high level NO synthesis in the asthmatic airway. Human airway
epithelium has abundant expression of NOSII due to continuous
transcriptional activation of the gene in vivo. We propose that
increased NOSII gene expression in asthmatic airways is related to
increased Stat1 activation caused by increased cytokines, e.g.,
IFN-. High levels of intracellular arginine may enhance enzyme
reaction kinetics and drive NO synthesis. Thus, airway epithelial cells
have highly efficient NO synthetic machinery, which is amplified in
airway inflammation. These studies lay the groundwork for evaluating
therapeutic strategies to decrease NO and RNI formation through
inhibitors of arginine transport systems, specific inhibitors of NOSII,
or antioxidant augmentation.
|
Acknowledgments |
|---|
; D. J. Stuehr for
recombinant NOSIII and NOSII; J. L. Humes for anti-NOSII Ab;
Affinity Bioreagents Laboratories for anti-NOSI and anti-NOSIII
Abs; O. Uttenthal for anti-nitrotyrosine Ab; L. Kedes for
pHFA-1; J. Lang for artwork; J. Hammel for biostatistical testing;
and F. T. Kaneko and M. Numata for technical
support. |
Footnotes |
|---|
2 Address correspondence and reprint requests to Dr. Serpil C. Erzurum, Cleveland Clinic Foundation, 9500 Euclid Avenue/A90, Cleveland, OH 44195.
3 Abbreviations used in this paper: RNI, reactive nitrogen intermediates; NOS, NO synthase; FEV1, forced expiratory volume in 1 s; FVC, forced vital capacity; BAL, bronchoalveolar lavage; WCE, whole cell extract; GAS, IFN- activation site; IRF-1, IFN regulatory factor-1; SBE, Stat binding element; OPA, o-phthalaldehyde; ROS, reactive oxygen species; JAK, Janus kinase.
Received for publication November 24, 1999. Accepted for publication March 22, 2000.
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References |
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TopAbstractIntroductionMaterials and MethodsResultsDiscussionReferences |
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B activation in alveolar macrophages. Am. J. Respir. Cell Mol. Biol. 21:311. and interleukin 4 stimulate prolonged expression of inducible nitric oxide synthase in human airway epithelium through synthesis of soluble mediators. J. Clin. Invest. 100:829.[Medline]
-, ß-, and -actin mRNAs: skeletal but not cytoplasmic actins have an amino-terminal cysteine that is subsequently removed. Mol. Cell. Biol. 3:787.
