Vol. 281, Issue 3, 1186-1190, 1997
Stimulation of Airway Mucociliary Transport and Epithelial
Ciliary Motility by the Triazolopyridazin Derivative
TAK-2251
J.
Tamaoki,
A.
Chiyotani,
H.
Takemura,
K.
Konno,
T.
Matsumoto and
Y.
Ashida
First Department of Medicine, Tokyo Women's Medical College (J.T.,
A.C., H.T., K.K.),
Tokyo and Pharmaceutical Research Laboratories,
Takeda Chemical Industries (T.M., Y.A.), Osaka, Japan
 |
Abstract |
To elucidate whether a newly developed antiallergic drug, the
triazolopyridazin derivative TAK-225, alters airway mucociliary clearance and, if so, what the mechanism of action is, we measured mucociliary transport in the rabbit tracheal mucosa ex vivo
and ciliary motility of the tracheal epithelium in vitro.
Mucociliary transport function was determined by the transport rate of
Evans blue dye that had been placed on the mucosal surface above the carina. Oral administration of TAK-225 (0.3-30 mg/kg) increased Evans
blue transport toward the larynx in a dose-dependent manner. Addition
of TAK-225 caused a rapid and sustained increase in the ciliary beat
frequency of tracheal epithelium, as assessed by photoelectric method;
the maximal increase from the base-line value was 25.1 ± 4.6%
(P < .01), and the concentration required to produce a
half-maximal effect (EC50) was 3.1 ± 0.8 × 10
7 M. This effect was greatly attenuated by pretreatment
with the cAMP antagonist adenosine 3
,5-cyclic monophosphorothioate,
but not by Ca++-free medium containing ethylene glycol-bis
[
-aminoethyl ether] N,N,N,N-tetraacetic acid
and [1,2-bis(2)aminophenoxy]ethane N,N,N,N-tetraacetic
acid-acetomethoxy ester. Incubation of tracheal epithelium with TAK-225
increased intracellular cAMP contents in a concentration-dependent
manner. These results suggest that TAK-225 enhances airway mucociliary
clearance probably through cAMP-mediated stimulation of ciliary
motility of airway epithelium.
| |
Introduction |
Mucociliary clearance plays a
principal role in the nonspecific host defense mechanism in the lungs,
whereby locally produced biological debris and trapped inhaled
particles and bacteria are removed from the conducting airways of the
respiratory tract (Wanner, 1977
). It has been believed that the rate of
mucus transport toward the oropharynx depends on the beat frequency and
coordination of epithelial cilia, on the physicochemical properties of
periciliary fluid and on mucus secretion (Silberberg, 1983; Satir and
Sleigh, 1990). Because the mucociliary transport is impaired in various airway diseases, such as chronic bronchitis, bronchiectasis, cystic fibrosis and asthma (Maurer et al., 1982; O'Riordan
et al., 1992; Smaldone et al., 1993), stimulation
of ciliary activity seems desirable in the treatment of these
conditions.
We have recently synthesized the triazolopyridazin derivative TAK-225
(2-ethyl-2-[(7-methyl-[1,2,4] tiazolo [1,5-b]
pyridazin-6-yl)-oxymethyl] butanesulfonamide) (fig. 1)
and found that p.o. administration of this compound to sensitized
guinea pigs potently inhibits allergen-induced bronchoconstriction and
recruitment of eosinophils into the airway (Ashida et al.,
1995). TAK-225 could thus possess antiasthmatic properties, but its
effect on airway mucociliary clearance is unknown. Therefore, in the
present study, to determine whether TAK-225 affects mucociliary
transport and, if so, whether the alteration of epithelial ciliary
function is involved, we measured mucociliary transport in the rabbit
tracheal mucosa by the Evans blue method ex vivo and by CBF
of the tracheal epithelium in vitro.
| |
Materials and Methods |
Measurement of mucociliary transport.
Japanese white rabbits
weighing between 2.5 and 3.0 kg were obtained from SLC Japan Co.
(Hamamatsu, Japan) and housed in a conventional animal facility at our
laboratory. The rabbits received TAK-225 (Takeda Chemical Industries,
Osaka, Japan) at a dose of 0.3, 3 or 30 mg/kg. Freshly prepared TAK-225
dissolved in 5% DMSO was administered in 1.0-ml volumes by oral gavage
with a 17-gauge feeding tube fitted to a 2.5-ml syringe. In the control
experiment, animals received in a similar manner an equal volume of the
vehicle (5% DMSO) alone. Our separate study showed that 5% DMSO
itself had no effect on tracheal mucociliary transport. After 1 h
of TAK-225 administration, the rabbits were anesthetized with i.m. ketamine (50 mg/kg) and exsanguinated by sectioning the abdominal aorta
and inferior vena cava. The trachea was then removed, dissected free
from the underlying connective tissues and mounted horizontally onto a
filter paper soaked with Hanks' balanced salt solution in a moist
chamber warmed to 37°C.
The cartilage rings of the whole trachea were incised transaxially, and
the surface of the membranous portion was exposed. On this surface, 1 µl of 0.5% Evans blue dye (Sigma Chemical Co., St. Louis, MO) in
sterile saline was gently placed by a microsyringe 1.5 cm above the
carina. After the incubation of tissues in a moist chamber for 2, 5, 10 or 20 min, four 1.0-cm-long transverse sections of the trachea were
sequentially obtained from the carina toward the larynx (section 1 to section 4) (fig. 2). Because Evans blue dye placed on
section 2 can be transported toward section 3 and then section 4, higher levels of Evans blue contents in sections 3 and 4 in
TAK-225-treated rabbits compared with controls were assumed to
represent increased tracheal mucociliary clearance. In our preliminary
experiment, during a 20-min observation, the Evans blue that was
transported to a more cephalad section than section 4 was less than 5%
of the total, even in the animals treated with 30 mg/kg TAK-225. For
all sections, Evans blue dye was extracted in 2 ml of formamide, kept
in water at 40°C for 24 h and measured in a spectrophotometer
(Nihon Bunko Co., V-550, Tokyo, Japan) at 620 nm. The Evans blue level
in each tracheal section was expressed as percentage of the total
amount of the dye in sections 1 to 4.
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Fig. 2.
Time-dependent changes in Evans blue (EB) dye
contents in the rabbit tracheal sections after application of the dye
to the mucosal surface 1.5 cm above the carina. The EB level in each tracheal section was expressed as percentage of the total amount of the
dye in sections 1 to 4. Values are means ± S.E.;
n = 8 for each point. * P < .05, ** P < .01, significantly different from corresponding values at time 0.
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Measurement of CBF.
The method we used to measure CBF of
rabbit tracheal epithelium has been described in detail previously
(Tamaoki et al., 1995). Briefly, the mucosa of excised
rabbit trachea was cut into small pieces (1-2 mm2) and
rinsed several times with Hanks' balanced salt solution. Then the
tissues were placed on a cover glass (18 × 24 mm) coated with
human placental collagen (5.8 µg/cm2, Sigma) in a petri
dish and incubated in Ham's nutrient F12 medium containing 10 µg/ml
insulin, 5 µg/ml transferrin, 25 ng/ml epidermal growth factor, 7.5 µg/ml endothelial cell growth supplement, 50 U/ml penicillin, 50 µg/ml streptomycin and 50 µg/ml gentamicin at 37°C in a
CO2 incubator (95% air-5% CO2). On the
seventh day of incubation, the cover glass on which the cultured
explant was adhered was mounted in a Rose chamber, which was then
placed on the stage of a microscope equipped with a phase-contrast
condenser and an on-base type of halogen illuminator (Nikon,
Optiphoto-XF, Tokyo, Japan). The photometer (Hamamatsu Photonics,
NFX-II, Hamamatsu, Japan) with built-in periplanatic eyepiece, a
limiting aperture and a lateral focusing telescope were attached to the
head of the microscope. Because of the beating action of cilia, light from the illuminator passed through the preparation in varying intensities. These variations in light intensity were detected by the
photometer and transduced to voltage impulses, which were recorded by a
pen recorder (Panasonic, VP-6213A, Osaka, Japan). Measurements of CBF
were averaged from clumps of two or more cells with free borders devoid
of debris. Our preliminary experiments showed that the variation in CBF
among preparations was less than 0.8 Hz (<7%) and that there were no
significant differences in variation between experimental groups. In
addition to CBF, we assessed ciliary coordination by the image of the
beating pattern recorded on a video camera (Sony, VO-5800, Tokyo,
Japan) with a videocassette recorder capable of freeze-frame replay.
Ciliary discoordination was defined as the loss of metachronal wave on the free border of the cell clump (Sanderson and Sleigh, 1981; Tamaoki
et al., 1989).
Before the measurement of CBF, the preparation was allowed to stabilize
for 30 min in KH solution of the following composition (in mM): NaCl,
118; KCl, 5.9; CaCl2, 2.5; MgSO4, 1.2;
NaH2PO4, 1.2; NaHCO3, 25.5;
D-glucose, 5.6 adjusted pH to 7.4 and warmed at 37°C.
After determination of the base-line CBF, medium was drained off the
chamber and replaced with KH solution containing 5% DMSO or 5% DMSO
plus TAK-225 (105 M), and CBF was continuously recorded
for 30 min. To study a dose-response relationship, we applied TAK-225
(108 to 104 M) to the chamber and
determined the highest recorded value in response to each
concentration. In this experiment, only one dose of TAK-225 was given
per preparation.
Because both intracellular cAMP and Ca++ play a major role
in the regulation of airway epithelial ciliary motility (Dirksen and
Sanderson, 1990; Lansley et al., 1992; Benedetto et
al., 1994), we assessed their contributions to the action of
TAK-225. Tissues were treated for 15 min with the cAMP antagonist
Rp-cAMPS (104 M, BIOLOG Life Science Institute, Bremen,
Germany) or with Ca++-free KH solution containing both EGTA
(5 × 103 M, Sigma) and the intracellular
Ca++-chelating agent BAPTA-AM (5 × 105
M, Dojin Lab Inc., Kumamoto, Japan), and the maximal response of CBF to
the subsequent application of TAK-225 (105 M) was
determined. In our separate experiment, Rp-cAMPS itself had no effect
on the base-line value of CBF, but Ca++-free medium
containing EGTA and BAPTA-AM decreased CBF by 8.1 ± 1.0% (P < .05, n = 10).
Measurement of intracellular cAMP.
To confirm whether the
effect of TAK-225 on ciliary motility was associated with cAMP
production, we measured intracellular levels of cAMP (Brooker et
al., 1979). The epithelial cells were incubated with various
concentrations of TAK-225 (107 to 104 M)
for 10 min in the presence of 3-isobutyl-1-methylxanthine (103 M, Sigma) to inhibit cAMP phosphodiesterase
activity. The cells were quickly removed from the chamber and placed in
ice-cold 10% trichloroacetic acid with ether; the residue was
dissolved in acetate buffer. Then cAMP levels were determined in
triplicate by [3H]-cAMP (Amershan Life Science Japan,
Tokyo, Japan), corrected for ether extraction of 88% recovery and
normalized for protein content of the cells as determined by the method
of Lowry et al. (1951), with bovine serum albumin as a
standard.
Statistics.
All values were expressed as means ± S.E.
Statistical analysis was performed by ANOVA using Scheffé's
F test, and a P value of less than .05 was considered
statistically significant.
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Results |
Mucociliary transport.
Mucociliary transport in the tracheal
mucosa of the rabbits that received the vehicle of TAK-225 alone (5%
DMSO) is shown in figure 2. The contents of Evans blue dye in section
2, where the dye had been placed at time 0 on the mucosal surface,
gradually decreased and reached a plateau after 10 min (98.1 ± 2.4 
42.3 ± 7.4% of the total, P < .01, n = 8). The decrease in Evans blue content in section 2 was accompanied by a corresponding increase in the dye content in
section 3 and subsequently in section 4, which indicates that Evans
blue was transported from the lower trachea toward the larynx.
As shown in fig. 3, administration of TAK-225 enhanced
tracheal mucociliary transport in a dose-dependent manner. After 10 min
of the dye application, TAK-225 at doses of 3 mg/kg and 30 mg/kg
decreased Evans blue content in section 2 to 35.2 ± 4.4% and
26.0 ± 3.5%, respectively (n = 16), values that
were significantly less than the value for the vehicle (5% DMSO) alone
(51.2 ± 5.4%, n = 16; P < .05 and P < .01, respectively). Similarly, Evans blue content in section 4 was
dose-dependently increased by TAK-225.
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Fig. 3.
Dose-dependent effect of TAK-225 on mucociliary
transport in the rabbit trachea. Evans blue (EB) contents in the
tracheal sections were determined 10 min after application of the dye
to the mucosal surface. The EB level in each tracheal section was expressed as percentage of the total amount of the dye in sections 1 to
4. Values are means ± S.E.; n = 16 for each
column. * P < .05, ** P < .01, significantly different
from corresponding values for vehicle (5% DMSO) alone.
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Ciliary motility.
Addition of TAK-225 (105 M) to
the chamber elicited a rapid increase in CBF of rabbit tracheal
epithelium from the base-line value of 12.3 ± 0.4 to 16.6 ± 0.7 Hz (P < .001, n = 9) within 30 s; this
effect was followed by the decline and the subsequent stable response
(fig. 4). The CBF value in the presence of TAK-225 was
still significantly greater than the base-line CBF (P < .001). In
contrast, addition of the vehicle alone had no effect. As shown in
figure 5, TAK-225 increased the initial peak response of
CBF in a concentration-dependent fashion: the maximal increase from the
base-line value was 25.1 ± 4.6% (P < .01, n = 8), and the concentration of the drug required to
produce a half-maximal effect (EC50) was 3.1 ± 0.8 × 107 M (n = 8).
Discoordination of ciliary beating was not observed in the video
recording throughout the experiments.
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Fig. 4.
Time course of the effect of TAK-225 on CBF of rabbit
cultured tracheal epithelium. Either TAK-225 (105 M,  )
or its vehicle (5% DMSO,  ) was added to the chamber at time 0 (). Values are means ± S.E.; n = 9 for each
point. ** P < .01, *** P < .001, significantly different
from corresponding values for vehicle.
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Fig. 5.
Concentration-dependent effect of TAK-225 on CBF of
rabbit cultured tracheal epithelium. Various concentrations of TAK-225 were added to the chamber, and the initial peak response of CBF to each
concentration was determined. Responses are expressed as percent
increase in CBF from base-line values determined before addition of the
drug. Data are means ± S.E.; n = 8. * P < .05, ** P < .01, significantly different from base-line
values.
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|
Pretreatment of tissues with the cAMP antagonist Rp-cAMPS
(104 M) greatly attenuated the TAK-225 (105
M)-induced increase in CBF (P < .001, n = 10),
but Ca++-free medium containing EGTA (5 × 103 M) and BAPTA-AM (5 × 105 M) did
not alter the effect of TAK-225 (fig. 6).
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Fig. 6.
Effects of Rp-cAMPS (104 M) and
Ca++-free medium containing BAPTA-AM (5 × 105 M) on CBF of rabbit cultured tracheal epithelium in
response to TAK-225. The cells were incubated for 15 min with each
blocker, and then TAK-225 (105 M) was added to the
chamber. Responses are expressed as percent increase in CBF from
base-line values determined before the addition of TAK-225. Data are
means ± S.E.; n = 10. *** P < .001, significantly different from the response to TAK-225 alone.
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Intracellular cAMP levels.
Addition of TAK-225 caused a
concentration-dependent increase in intracellular cAMP levels of rabbit
tracheal epithelium, the maximal increase being from 33.2 ± 3.6 to 96.0 ± 7.6 pmol/mg protein (P < .01, n = 8; fig. 7), but the vehicle (5% DMSO) alone had no
effect.
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Fig. 7.
Concentration-dependent effect of TAK-225 on
intracellular cAMP contents in rabbit cultured tracheal epithelium. The
cells were incubated with various concentrations of TAK-225 (closed columns) or its vehicle (5% DMSO) alone (shaded column) for 10 min,
and cAMP contents were determined by radioimmunoassay. In the control
experiment, no drug was added (open column). Data are means ± S.E.; n = 8 for each column. * P < .05, ** P < .01, significantly different from control values.
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| |
Discussion |
Our studies demonstrate that the triazolopyridazin derivative
TAK-225 enhances mucociliary clearance in the rabbit trachea, by a
mechanism that probably involves stimulation of the ciliary motility of
airway epithelium. In the present experiment, we developed an ex
vivo method to evaluate airway mucociliary clearance by determining the transport rate of Evans blue dye that had been placed
on the tracheal mucosal surface above the carina. We found that the
rate of propulsion of the dye toward the larynx was increased in a
dose-dependent fashion by pretreatment of animals with TAK-225, a
result that indicates an accelerated tracheal mucociliary clearance.
The antiallergic drug TAK-225 has recently been synthesized in our
laboratory and found to reduce various airway reactions associated with
IgE-dependent asthma. For example, p.o. administration of TAK-225 to
sensitized guinea pigs inhibits allergen-induced infiltration of
eosinophils into the airway and the immediate and late phases of
bronchoconstriction (Ashida et al., 1995). On the other
hand, impairment of tracheobronchial mucociliary clearance has long
been suspected of playing a significant role in asthma (Wanner, 1977;
O'Riordan et al., 1992). Mezey and co-workers (1978) showed
decreased base-line tracheal mucus velocity in ragweed-sensitized asthmatics, which became further impaired after acute bronchospasm had
been induced by inhalation of specific antigen. Moreover, Bateman and
co-workers (1983) and Pavia and colleagues (1985) reported that
mucociliary clearance is impaired in asthmatics with mild, stable
disease and in asthmatics in remission, respectively, relative to
normal volunteers. Therefore, the TAK-225-induced stimulation of
tracheal mucociliary transport observed in the present study suggests
that, in addition to its antiallergic activities, this drug might be
beneficial in the treatment of asthma.
It has been generally accepted that mucociliary transport is governed
by ciliary activity and by the depth and rheologic properties of
periciliary fluid (Silberberg, 1983; Satir and Sleigh, 1990). We thus
hypothesized that stimulation of ciliary activity could account for the
effect of TAK-225 on the transport of Evans blue dye. Consequently,
addition of TAK-225 rapidly increased the CBF of rabbit tracheal
epithelium in a concentration-dependent manner. However, the
effectiveness of ciliary action depends on several characteristics of
ciliary beating, of which the CBF is but one. Coordination of the
beating pattern, for instance, also plays a role in ciliary performance
(Satir and Sleigh, 1990). In the present study, no ciliary
discoordination was noted among adjacent cilia on the same cell or
several bordering cells in association with the increased CBF in
response to TAK-225. Thus it seems reasonable to speculate that the
observed increase in CBF can be translated into the enhanced
mucociliary transport, as predicted by theoretical models of
mucociliary pumping (Ross and Corrsin, 1974), but further studies on
the effect of this drug on airway secretion are required.
Ciliary motility of airway epithelium is regulated mainly by cAMP and
Ca++ (Dirksen and Sanderson, 1990; Lansley et
al., 1992; Benedetto et al., 1994). Intracellular cAMP
activates glycogenolysis and subsequently stimulates the production of
ATP, an energy source of ciliary beating (Satir, 1982), via
the Krebs cycle (Tamaoki et al., 1989), and the mobilization
of intracellular Ca++ apparently acts on the ciliary
axoneme via the formation of Ca++-calmodulin
complexes (Verdugo et al., 1983). In our experiment, the
increase in CBF produced by TAK-225 was not altered by pretreatment of
cells with Ca++-free solution in the presence of the
intracellular Ca++-chelating agent BAPTA-AM to inhibit both
Ca++ influx and Ca++ release from intracellular
stores, but it was greatly attenuated by the cAMP antagonist Rp-cAMPS.
This result suggests that the ciliary stimulatory action of TAK-225 is
mediated by cAMP. This notion was further supported by the finding that
incubation of the tracheal epithelium with TAK-225 increased
intracellular cAMP contents in a concentration-dependent manner, but
the mechanism by which this triazolopyridazin derivative stimulated
cAMP synthesis remains unknown.
In conclusion, the triazolopyridazin derivative TAK-225, a newly
developed, orally active antiallergic drug, enhances airway mucociliary
transport presumably through cAMP-mediated stimulation of the ciliary
motility of airway epithelium. Therefore, TAK-225 could be of value in
the treatment of impaired mucociliary clearance, such as occurs in
asthma.
| |
Acknowledgments |
The authors thank Yoshimi Sugimura and Masayuki Shino for their
technical assistance. We also thank Dr. Kiyoshi Takeyama for his
important suggestions.
| |
Footnotes |
Accepted for publication February 14, 1997.
Received for publication October 24, 1996.
1
This work was supported in part by Grant-in-Aid No.
06670632 from the Ministry of Education, Science and Culture, Japan.
Send reprint requests to: Jun Tamaoki, M.D., First
Department of Medicine, Tokyo Women's Medical College, 8-1 Kawada-Cho,
Shinjuku, Tokyo 162, Japan.
| |
Abbreviations |
DMSO, dimethylsulfoxide;
CBF, ciliary beat
frequency;
KH, Krebs-Henseleit;
Rp-cAMPS, adenosine 3,5-cyclic
monophosphorothioate;
EGTA, ethylene glycol-bis [-aminoethyl
ether]
N,N,N,N-tetraacetic acid;
BAPTA-AM, [1,2-bis (2) aminophenoxy] ethane
N,N,N,N-tetraacetic
acid-acetomethoxy ester.
| |
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Abstract
Introduction
