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The influence of cystic fibrosis serum and calcium on secretion in the rabbit tracheal mucociliary apparatus
Vol. 83, No. 4, 1978
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages
August 29,1978
1595-1601
THE INFLUENCEOF CYSTICFIBROSIS SERUM ANDCALCIUM ON SECRETIONIN THE RABBIT TRACHEAL MUCOCILIARY APPARATUS
J.H. Conover and E.J. Conod Denartment of Pediatrics St. Vincent's Hospital and Medical Center of New York and New York University Medical School New York, New York Received
July
25,1978
SUMM4RY: Cystic Fibrosis serum or its isolated component IgG fraction and calcium ionophore A23187 all produced a quantitatively greater increase of mucus glyconrotein secretion in the rabbit tracheal epithelium than did control serum or its isolated component IgG fraction. These values were determined by dry weight secretion per gram of tissue and on subsequent sialic acid content of secretions. This demonstrable increase in mucus production represents a measurable difference in the functioning of the cultured mucociliarv apparatus due to the influence of cystic fibrosis serum. Cystic fibrosis the ciliary cultured
(CF) sera has been shown to adversely affect
and mucous components of the microscopically rabbit
tracheal
ciliated
epithelium
(1,2).
both
observed
Hhile the dual
nature of this CF serum-induced response is well known, much of the attention
has previously
hence the term ciliary
been focused on the prominent ciliary dyskinesia factor
shown that both secretory
and ciliarv
(CDF) (3,4).
asnects of
the
vector--
He have recently mucociliary
res-
ponse are induced by CF sera and are mediated by calcium ions (1,5,(i). In these instances, specific the total
chelation of calcium in CF sera eliminated
CDF response and control
cium ionophore A23187 generated of which was distinctly Both light
identified
typical
CDF resoonse--each
complete
by electronmicroscopy
and electron microscopic cellular
gested that mucoussecretion lium after
a
sera supplemented bv 2 X 1W4M cal-
observations have sug-
is increased in the rabbit
exposure to CF affected
and carrier
(6).
tracheal epithe-
sera or their
purified
IgG
0006-291X/78/0834-1595$01.00/0 1595
Copyright 0 1978 by Academic Press, Inc. All rights of reproduction in any form reserved.
Vol. 83, No. 4, 1978
fractions tions,
as compared together
clinically sera
with
with
the
control
led
mucous
mucous
substances.
production
do control
or in
This
and heterozygotes
report
stimulate sera.
purified
serum-derived
sociated
substance
in viscositv
could
whether
that
production were
IgG fractions,
further
in the pathophysiology
mucus seen
in the
rate
of one or more specific
demonstrate
Such increases
ohserva-
CF and CF carrier
an increase
the production
greater
These
of nulmonarv
potentiate
will
RESEARCH COMMJNKATIONS
or IgG fractions.
us to investigate
IgC fractions,
of total
AND BIOPHYSICAL
sera
increase
in CF subjects
or their
than
BIOCHEMICAL
sera
of r&hit similarly
CF patients
tracheal
extended
imolicating
of this
from
mucus
to individual
TgG and/or
some as-
disorder.
Rabbit tracheal tissue was prepared according to our orevious renort separated luminal epithelial mucosa (4), except that the mechanically (tracheal sheath) was used as a whole intact unft without mincing into smaller pieces. These tracheal sheaths are composed of both submucosa and mucosa as defined bv electronmicroscopy (6) and in general contain a large abundance of mucous-producing epithelial gohlet cells, and a variable degree of the predominantlv mucous-producjng tubule-alveolar glands. Four intact tracheal sheaths nrepared in this fashion were immediately placed in a common Petri dish (35 X 10 mm) containing 2.5 ml of either CF, CF obligate heterozygote CF-H or normal control sera. Replicate Petri dishes for each test sera were incubated at 37OC for different intervals (1,2,4,6,8 and 24 hours). At the end of each incubation period, the test serum of each dish was collected and the respective tracheal sheaths removed and gently agitated with forceps in another Petri dish containing 5 ml of Hanks' Ralanced Salt Solution without phenol red indicator at pi! 7.0. In each instance, the wash, containing apparent mucus-like insoluble material, was combined with its respective test serum and centrifuged at 2fWO mm for lo minutes to isolate the insoluble mucus-like material. Tn every instance, the re suiting pellet was washed twice with 5 ml distilled water and resuspended reisolated bv centrifugation and finally in 0.5 ml of distilled water, placed in a pre-weighed glass ampule where it was lyophilized for 24 hours. Each of the washed intact tracheal sheaths was blotted once on filter paper and also ulaced in pre-weighed glass amnules for lyophilization. The resulting lyophilized secretions and tissues were then weighed on a ?fettler H 20 T balance and secretions expressed as dry sialic acid (measured as weight per gram tissue. Subsequently, N-acetylneuraminic acid) by the thiobarbituric acid method of Warren (7) and DNA measured by the method of Schneider (8) were performed on each test sample secretion. Figure as control evidenced: It
1 demonstrates sera
in this
dry weight
can be seen that
DNA content
a typical
of this
test
system.
of secretion, after system
time-response
2 hours rises
All
three
sialic
acid
of incubation sharply.
1596
This
curve test
parameters
(NANA) with
for
CF as well are
and DNA.
any sera,
that
mav be due to a noted
the
BIOCHEMICAL
Vol. 83, No. 4, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
180 170 160 I!%l1
.-g. -I c m140
l
2 mz IlO-. i=
l
Em F goz 2, 00t; 70-
’ is E"
l
0 l
0. ‘W! :. 0
60-
50403020-
‘,’
INCUBATION
igure
1.
Time-resvonse curve sera. Open circles represent CF sera.
Figure
2.
Tracheal secretory response heterozygotes and controls.
microscopic
appearance
which
serves
earlier
than
the
NANA and mucous appreciably Figure
lower
2 depicts
tracheal
tissue,
The vertical grout:
CF=76.6+5.4
control=30.4+2.6 between
line
one-hour
production, than
the
2 hour
Vhile
also
(S.E.Y.)
used
of the wejehts
mr:
me secretion. and control
1597
for
substances for
this
and 15 normal
was
study. aer
gram
control
the mean value
subjects. for
each
CF-F-69.73.6
mp: secretion;
t-test,
the mean difference
Ry Student's subject
intervals
of secretion
indicates
secretion;
wash solution,
seemed effective
interval
each column
CF patients,
time
of these
13 CF, 21 V-1'
emnloying across
value
from
fn the hanks'
damage.
the quantity
the results
CF homozygotes
to sera
cells
of tissue
listed
CONTROL
of tracheal explants to CF and control represent control sera; closed circles
of epithelial
as an index
CF
02
AT 37” c (SCOURS)
is
significant
(p<.WN35)
as is
Vol. 83, No. 4, 1978
BIOCHEMICAL
l.6-
0
1.7-
0
AND 8lOPHYSlCAL
RESEARCH COMMUNICATIONS
1.6-
8 Swetbn , 8 NANA ,
g
0.9
2
08
3z
0.7
m W 0’
0.6 0.5
=
0.4
1.32
l l
0.3 O
l .e
0.2 0.1
0
CF-IGG DONORSOF SERUM-IgG
Control-IgG
-I-
CF-t-l
CF
3
CONTROL
Figure
3.
Tracheal secretory resnonse heterozygotes and controls.
Figure
4.
Secretory response to serum-ICC. Each of four CF and four control patients is represented by a har granh that connects both the weight of secretion and the corresponding NANA values for each sample.
that
between
not
significantly
secretion
CF-I! and controls different
produced Dowever,
contrast
to the broad
samples.
In addition,
normal
range.
control
line
each column
moles
NANA.
rather
of values
from
It
indicates
NANA: CF-11=.62+.nQ can he seen that
CF and CF-H means are is
the mean value
hoth
of
hv control in
and carrier the
Figure
entire 3 is
a
The vertical for
each group:
NANA; Control
CF and carrier
1598
amount
distributed
overlan
same secretions.
moles
than
CF affected
values
micro
a greater
narrowly
in any sample.
of these
CF patients,
individuals
are
No DNA was detected
moles
There
the heterozvgous
of XANA values
.05 micro
values
from
l!owever,
CF and carrier
scatter
scattergram across
(p<.OOO5). (.25<0<.30).
by hoth
subjects.
to sera
groups
CF=.74+ -
.28+.02 have higher
micro levels
of
BIOCHEMICAL
Vol. 83, No. 4, 1978
sialic
acid
ference is
than
comparable
between
Again,
4.15).
(.lO
Also,
both
reflect
are
controls
CF-H values
failed
to delineate
the
CF serum bioassay
testing
In these
each of four do the
four
were
all
adjusted
the
line
marked
phosphate
buffer
Figure
sera
from
each of five
fore
testing.
Serum-derived
a much greater from
control
described
(9)
from
response
subjects.
than
IgG fractions
phosphate
buffer
those
here
(ll),
values
from
for
IgG fractions
secretory
represents
in
IgG was separated
4 shows that
secretion"
the
to normal
control
donors
iononhore
to a level
that in
control
and
obtained
when
induced could
from
increase a measureable
the
secretion easily
any sample
2 X 10W4Y calcium sera.
was divided
was added
was determined
The demonstrable
of adding
Co.)
To one portion
represents
that
as a narticioant
as previously
the effect
(Lilly
No DNA was detected
report
favorahlv
was used alone.
A23187
of iononhore
those
tested.
results
implicated
1.5 mg protein/ml
"spontaneous
5 demonstrates
be seen that
lo).
Figure
promotes
to about
group
bioassay
has been
(9,
fractions
ionophore
parameters
(IgG)
investigations.
comparable
while
(4).
on DFAE cellulose
CF subjects
range.
CF and CF-H values
previous
response
CF, CF-H and controls
significant
NANA values
each respective between
not
scattered,
these
as
(.Cn25
overlau
are widely
for
groups
CF serum gamma globulin
(p <.0005)
the normal
differences
these
significant
completely
Also
supports
the mean dif-
is
values
of secretion
NANA and secretions,
t--test,
CF and CF-H groups
distrihuted.
of significant
is
RESEARCH COMMUNICATIONS
and CF-H subjects
between
narrowly
the weights
The lack
NANA values
CF and CF-H sample
of controls
for
between
the mean difference
Again,
By Student's
controls.
CF and control
the difference
AND BIOPHYSICAL
at this
by both
ionoohore
a dose resoonse
in mucous
nroduction
difference
in the
1599
into
calcium
represent
In this
instance
two nortions
he-
iononhore.
It
weight
and NANA
a typical
can
CF serum response.
concentration. curve,
This
seen in Figure
presented functioning
in this of
the
dose 6.
Vol. 83, No. 4, 1978
AND BIOPHYSICAL
RESEARCH COMWNICATIONS
NANA
.O
160 82 I e
BIOCHEMICAL
-
140-
“: 0-J cn 2
120-
2
80-
100
-
F 60-l 4O20
1 t
’
I 2
I 3
1 I
05
INDIVIDUAL
5
CONTROL
SERA
Concentration
06
CALCIUM
(x2)
IONOPHORE
A23187
Figure
5.
Calcium ionophore A23187 and secretion. Each control is represented by two bar graphs. In every instance, responding NANA and secretory weights are connected. depicts the secretory caoacitv of the untreated serum, the other shows the effect of added ionophore to the
Figure
6.
Dose-resnonse curve of tracheal explants to calcium ionophore All values were determined at 37'C during the specified A23187. Ionophore was prepared for testing 2 hour incubation period. in Basal Yedium Eagle as previously described (1).
rabbit
mucociliary
apparatus
participation
of calcium
glycoproteins
to determine
under
these This
Foundation
test work March
James Conover, Cystic
influence
of CF sera
We are presently
ions. if
a predominant
separating
moiety
is
being
and the these
mucous
secreted
conditions. was supported
in part
of Dimes and from Ph.D.
Fibrosis
due to the
sample corOne while same sample.
is
a recipient
by grants the Cystic of a
from
the National
Fibrosis
Research
Foundation.
Scholar
Award
of the
Pediat.
Res.,
11, 131-
Foundation. --REFERENCES
1.
Bogart, 134.
B.,
Conod,
E.,
and Conover,
1600
J.
(1977)
Vol. 83, No. 4, 1978
BIOCHEMICAL
AND BIOPHYSICAL
2.
RESEARCH COMMUNICATIONS
\s!ilson, G., Xonsher, ?I., and Fudenherg, 17. (1977) Pediat. PCS., 11, 143-146. 3. Speck, A., Peick, H., Cress, II., and Logan, 1.'. (1967) Pediat. lies. 1, 173-178. J., Ronforte, R., Hathaway, P., Pacius, S., Conod, E., 4. Conover, liirschhorn, K., and Kopel, F. (1973) Pedfat. Res. 7, 220-223. 5. Conover, J., Conod, E., Gaerlan, P., and Bogart, B. (1976) Lancet 2, 1362-1363. 6. Bogart, B., Conod, E., Gaerlan, P., and Conover, J. (1978) Pediat. Res. 12, 15-24. 7. Warren, L. (1959) J. Biol. Chem. 234, 1971-1975. 8. Schneider, IT., (1957) Hethods in Enzymology, 3, pn. 680-683, Academic Press, New York. 9. Conod, E., Gaerlan, P., and Conover, J. (1977) Pediat. Res. 11, 45-47. 10. Bowman, B., Lankford, B., Fuller, G., Carson, S., Kurosky, A., and Barnett, K. (1975) Biochem. Bionhys. Res. Commun. 64, 1319-1315. 11. Lowrv, O., Rosebrough, N., Farr, A., and Qandall. R. (1951) J. Bfol. Chem. 193, 265-277.
1601
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS Pages
August 29,1978
1595-1601
THE INFLUENCEOF CYSTICFIBROSIS SERUM ANDCALCIUM ON SECRETIONIN THE RABBIT TRACHEAL MUCOCILIARY APPARATUS
J.H. Conover and E.J. Conod Denartment of Pediatrics St. Vincent's Hospital and Medical Center of New York and New York University Medical School New York, New York Received
July
25,1978
SUMM4RY: Cystic Fibrosis serum or its isolated component IgG fraction and calcium ionophore A23187 all produced a quantitatively greater increase of mucus glyconrotein secretion in the rabbit tracheal epithelium than did control serum or its isolated component IgG fraction. These values were determined by dry weight secretion per gram of tissue and on subsequent sialic acid content of secretions. This demonstrable increase in mucus production represents a measurable difference in the functioning of the cultured mucociliarv apparatus due to the influence of cystic fibrosis serum. Cystic fibrosis the ciliary cultured
(CF) sera has been shown to adversely affect
and mucous components of the microscopically rabbit
tracheal
ciliated
epithelium
(1,2).
both
observed
Hhile the dual
nature of this CF serum-induced response is well known, much of the attention
has previously
hence the term ciliary
been focused on the prominent ciliary dyskinesia factor
shown that both secretory
and ciliarv
(CDF) (3,4).
asnects of
the
vector--
He have recently mucociliary
res-
ponse are induced by CF sera and are mediated by calcium ions (1,5,(i). In these instances, specific the total
chelation of calcium in CF sera eliminated
CDF response and control
cium ionophore A23187 generated of which was distinctly Both light
identified
typical
CDF resoonse--each
complete
by electronmicroscopy
and electron microscopic cellular
gested that mucoussecretion lium after
a
sera supplemented bv 2 X 1W4M cal-
observations have sug-
is increased in the rabbit
exposure to CF affected
and carrier
(6).
tracheal epithe-
sera or their
purified
IgG
0006-291X/78/0834-1595$01.00/0 1595
Copyright 0 1978 by Academic Press, Inc. All rights of reproduction in any form reserved.
Vol. 83, No. 4, 1978
fractions tions,
as compared together
clinically sera
with
with
the
control
led
mucous
mucous
substances.
production
do control
or in
This
and heterozygotes
report
stimulate sera.
purified
serum-derived
sociated
substance
in viscositv
could
whether
that
production were
IgG fractions,
further
in the pathophysiology
mucus seen
in the
rate
of one or more specific
demonstrate
Such increases
ohserva-
CF and CF carrier
an increase
the production
greater
These
of nulmonarv
potentiate
will
RESEARCH COMMJNKATIONS
or IgG fractions.
us to investigate
IgC fractions,
of total
AND BIOPHYSICAL
sera
increase
in CF subjects
or their
than
BIOCHEMICAL
sera
of r&hit similarly
CF patients
tracheal
extended
imolicating
of this
from
mucus
to individual
TgG and/or
some as-
disorder.
Rabbit tracheal tissue was prepared according to our orevious renort separated luminal epithelial mucosa (4), except that the mechanically (tracheal sheath) was used as a whole intact unft without mincing into smaller pieces. These tracheal sheaths are composed of both submucosa and mucosa as defined bv electronmicroscopy (6) and in general contain a large abundance of mucous-producing epithelial gohlet cells, and a variable degree of the predominantlv mucous-producjng tubule-alveolar glands. Four intact tracheal sheaths nrepared in this fashion were immediately placed in a common Petri dish (35 X 10 mm) containing 2.5 ml of either CF, CF obligate heterozygote CF-H or normal control sera. Replicate Petri dishes for each test sera were incubated at 37OC for different intervals (1,2,4,6,8 and 24 hours). At the end of each incubation period, the test serum of each dish was collected and the respective tracheal sheaths removed and gently agitated with forceps in another Petri dish containing 5 ml of Hanks' Ralanced Salt Solution without phenol red indicator at pi! 7.0. In each instance, the wash, containing apparent mucus-like insoluble material, was combined with its respective test serum and centrifuged at 2fWO mm for lo minutes to isolate the insoluble mucus-like material. Tn every instance, the re suiting pellet was washed twice with 5 ml distilled water and resuspended reisolated bv centrifugation and finally in 0.5 ml of distilled water, placed in a pre-weighed glass ampule where it was lyophilized for 24 hours. Each of the washed intact tracheal sheaths was blotted once on filter paper and also ulaced in pre-weighed glass amnules for lyophilization. The resulting lyophilized secretions and tissues were then weighed on a ?fettler H 20 T balance and secretions expressed as dry sialic acid (measured as weight per gram tissue. Subsequently, N-acetylneuraminic acid) by the thiobarbituric acid method of Warren (7) and DNA measured by the method of Schneider (8) were performed on each test sample secretion. Figure as control evidenced: It
1 demonstrates sera
in this
dry weight
can be seen that
DNA content
a typical
of this
test
system.
of secretion, after system
time-response
2 hours rises
All
three
sialic
acid
of incubation sharply.
1596
This
curve test
parameters
(NANA) with
for
CF as well are
and DNA.
any sera,
that
mav be due to a noted
the
BIOCHEMICAL
Vol. 83, No. 4, 1978
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
180 170 160 I!%l1
.-g. -I c m140
l
2 mz IlO-. i=
l
Em F goz 2, 00t; 70-
’ is E"
l
0 l
0. ‘W! :. 0
60-
50403020-
‘,’
INCUBATION
igure
1.
Time-resvonse curve sera. Open circles represent CF sera.
Figure
2.
Tracheal secretory response heterozygotes and controls.
microscopic
appearance
which
serves
earlier
than
the
NANA and mucous appreciably Figure
lower
2 depicts
tracheal
tissue,
The vertical grout:
CF=76.6+5.4
control=30.4+2.6 between
line
one-hour
production, than
the
2 hour
Vhile
also
(S.E.Y.)
used
of the wejehts
mr:
me secretion. and control
1597
for
substances for
this
and 15 normal
was
study. aer
gram
control
the mean value
subjects. for
each
CF-F-69.73.6
mp: secretion;
t-test,
the mean difference
Ry Student's subject
intervals
of secretion
indicates
secretion;
wash solution,
seemed effective
interval
each column
CF patients,
time
of these
13 CF, 21 V-1'
emnloying across
value
from
fn the hanks'
damage.
the quantity
the results
CF homozygotes
to sera
cells
of tissue
listed
CONTROL
of tracheal explants to CF and control represent control sera; closed circles
of epithelial
as an index
CF
02
AT 37” c (SCOURS)
is
significant
(p<.WN35)
as is
Vol. 83, No. 4, 1978
BIOCHEMICAL
l.6-
0
1.7-
0
AND 8lOPHYSlCAL
RESEARCH COMMUNICATIONS
1.6-
8 Swetbn , 8 NANA ,
g
0.9
2
08
3z
0.7
m W 0’
0.6 0.5
=
0.4
1.32
l l
0.3 O
l .e
0.2 0.1
0
CF-IGG DONORSOF SERUM-IgG
Control-IgG
-I-
CF-t-l
CF
3
CONTROL
Figure
3.
Tracheal secretory resnonse heterozygotes and controls.
Figure
4.
Secretory response to serum-ICC. Each of four CF and four control patients is represented by a har granh that connects both the weight of secretion and the corresponding NANA values for each sample.
that
between
not
significantly
secretion
CF-I! and controls different
produced Dowever,
contrast
to the broad
samples.
In addition,
normal
range.
control
line
each column
moles
NANA.
rather
of values
from
It
indicates
NANA: CF-11=.62+.nQ can he seen that
CF and CF-H means are is
the mean value
hoth
of
hv control in
and carrier the
Figure
entire 3 is
a
The vertical for
each group:
NANA; Control
CF and carrier
1598
amount
distributed
overlan
same secretions.
moles
than
CF affected
values
micro
a greater
narrowly
in any sample.
of these
CF patients,
individuals
are
No DNA was detected
moles
There
the heterozvgous
of XANA values
.05 micro
values
from
l!owever,
CF and carrier
scatter
scattergram across
(p<.OOO5). (.25<0<.30).
by hoth
subjects.
to sera
groups
CF=.74+ -
.28+.02 have higher
micro levels
of
BIOCHEMICAL
Vol. 83, No. 4, 1978
sialic
acid
ference is
than
comparable
between
Again,
4.15).
(.lO
Also,
both
reflect
are
controls
CF-H values
failed
to delineate
the
CF serum bioassay
testing
In these
each of four do the
four
were
all
adjusted
the
line
marked
phosphate
buffer
Figure
sera
from
each of five
fore
testing.
Serum-derived
a much greater from
control
described
(9)
from
response
subjects.
than
IgG fractions
phosphate
buffer
those
here
(ll),
values
from
for
IgG fractions
secretory
represents
in
IgG was separated
4 shows that
secretion"
the
to normal
control
donors
iononhore
to a level
that in
control
and
obtained
when
induced could
from
increase a measureable
the
secretion easily
any sample
2 X 10W4Y calcium sera.
was divided
was added
was determined
The demonstrable
of adding
Co.)
To one portion
represents
that
as a narticioant
as previously
the effect
(Lilly
No DNA was detected
report
favorahlv
was used alone.
A23187
of iononhore
those
tested.
results
implicated
1.5 mg protein/ml
"spontaneous
5 demonstrates
be seen that
lo).
Figure
promotes
to about
group
bioassay
has been
(9,
fractions
ionophore
parameters
(IgG)
investigations.
comparable
while
(4).
on DFAE cellulose
CF subjects
range.
CF and CF-H values
previous
response
CF, CF-H and controls
significant
NANA values
each respective between
not
scattered,
these
as
(.Cn25
overlau
are widely
for
groups
CF serum gamma globulin
(p <.0005)
the normal
differences
these
significant
completely
Also
supports
the mean dif-
is
values
of secretion
NANA and secretions,
t--test,
CF and CF-H groups
distrihuted.
of significant
is
RESEARCH COMMUNICATIONS
and CF-H subjects
between
narrowly
the weights
The lack
NANA values
CF and CF-H sample
of controls
for
between
the mean difference
Again,
By Student's
controls.
CF and control
the difference
AND BIOPHYSICAL
at this
by both
ionoohore
a dose resoonse
in mucous
nroduction
difference
in the
1599
into
calcium
represent
In this
instance
two nortions
he-
iononhore.
It
weight
and NANA
a typical
can
CF serum response.
concentration. curve,
This
seen in Figure
presented functioning
in this of
the
dose 6.
Vol. 83, No. 4, 1978
AND BIOPHYSICAL
RESEARCH COMWNICATIONS
NANA
.O
160 82 I e
BIOCHEMICAL
-
140-
“: 0-J cn 2
120-
2
80-
100
-
F 60-l 4O20
1 t
’
I 2
I 3
1 I
05
INDIVIDUAL
5
CONTROL
SERA
Concentration
06
CALCIUM
(x2)
IONOPHORE
A23187
Figure
5.
Calcium ionophore A23187 and secretion. Each control is represented by two bar graphs. In every instance, responding NANA and secretory weights are connected. depicts the secretory caoacitv of the untreated serum, the other shows the effect of added ionophore to the
Figure
6.
Dose-resnonse curve of tracheal explants to calcium ionophore All values were determined at 37'C during the specified A23187. Ionophore was prepared for testing 2 hour incubation period. in Basal Yedium Eagle as previously described (1).
rabbit
mucociliary
apparatus
participation
of calcium
glycoproteins
to determine
under
these This
Foundation
test work March
James Conover, Cystic
influence
of CF sera
We are presently
ions. if
a predominant
separating
moiety
is
being
and the these
mucous
secreted
conditions. was supported
in part
of Dimes and from Ph.D.
Fibrosis
due to the
sample corOne while same sample.
is
a recipient
by grants the Cystic of a
from
the National
Fibrosis
Research
Foundation.
Scholar
Award
of the
Pediat.
Res.,
11, 131-
Foundation. --REFERENCES
1.
Bogart, 134.
B.,
Conod,
E.,
and Conover,
1600
J.
(1977)
Vol. 83, No. 4, 1978
BIOCHEMICAL
AND BIOPHYSICAL
2.
RESEARCH COMMUNICATIONS
\s!ilson, G., Xonsher, ?I., and Fudenherg, 17. (1977) Pediat. PCS., 11, 143-146. 3. Speck, A., Peick, H., Cress, II., and Logan, 1.'. (1967) Pediat. lies. 1, 173-178. J., Ronforte, R., Hathaway, P., Pacius, S., Conod, E., 4. Conover, liirschhorn, K., and Kopel, F. (1973) Pedfat. Res. 7, 220-223. 5. Conover, J., Conod, E., Gaerlan, P., and Bogart, B. (1976) Lancet 2, 1362-1363. 6. Bogart, B., Conod, E., Gaerlan, P., and Conover, J. (1978) Pediat. Res. 12, 15-24. 7. Warren, L. (1959) J. Biol. Chem. 234, 1971-1975. 8. Schneider, IT., (1957) Hethods in Enzymology, 3, pn. 680-683, Academic Press, New York. 9. Conod, E., Gaerlan, P., and Conover, J. (1977) Pediat. Res. 11, 45-47. 10. Bowman, B., Lankford, B., Fuller, G., Carson, S., Kurosky, A., and Barnett, K. (1975) Biochem. Bionhys. Res. Commun. 64, 1319-1315. 11. Lowrv, O., Rosebrough, N., Farr, A., and Qandall. R. (1951) J. Bfol. Chem. 193, 265-277.
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