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Redox changes in the respiratory chain related to acid secretion by the intact gastric mucosa
Vol. 36, No. 2, 1969
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
REDOX CHANGES IN THE RESPIRATORYCHAIN RELATED TO ACID SECRETION BY THE INTACT GASTRIC MUCOSA S. J. Hersey and F. F. Jbbsis Dept. of Physiology, Duke Univ., Durham, N. C.
27706
Received June 2, 1969 SUMMARY Spectrophotometric studies were carried out on the intact isolated gastric mucosa of bullfrog. The anoxic vs oxygenated difference spectrum revealed absorbtion maxima typical of respiratory chain components with some noteworthy special features. Large reductions of all the components occured upon stimulation of acid secretion by histamine while inhibition by thiocyanate was accompanied by oxidation of all components. The reductions accompanying histamine addition do not appear to be due to hypoxia.
Active secretion of hydrochloric upon oxidative
acid by the gastric mucosa is dependent
metabolism (1,2,3) and in turn exerts a controlling
respiration in this tissue (4,s). the concentration
effect on
This control is thought to arise from changes in
of ADP which supposedly depends upon the hydrolysis
during the secretory process (3,6).
According to this theory the mitochondria
within the tissue would be close to the resting metabolic state,
state 4 (7), when
hydrogen ion secretion is inhibited and approach state 3, the actively state, upon stimulation the steady-state
of secretion.
oxidation-reduction
(SCN).
metabolizing
To test this hypothesis we have examined levels of respiratory
intact gastric mucosa during stimulation by thiocyanate
of ATP
chain components in the
by histamine and inhibition
of secretion
The results have been such that we find it impossible to
describe them in terms of transitions
between states 4 and 3.
This work was supported by grants from U.S.P.H.S, Smith, Kline and French. 243
GM00929,
and Tom
Vol. 36, No. 2, 1969
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
METHODS The stomachs of Bullfrogs (Rana catesbiana) were perfused with Ringer The mucosa was then separated from the
solution via the descending aorta. -
muscularis by sharp dissection and mounted as a diaphragm between two lucite half chambers with clear optical windows which served as cuvette system.
The
chambers served to separate two adjacent pieces of the same mucosa as well as to separate the mucosal and serosal surfaces.
The tissues were bathed in a
bicarbonate buffered amphibian Ringer solution and aereated with 95% 02 5% C02. For the measurement of hydrogen ion secretion the mucosal solution was replaced with an unbuffered solution having identical Acid secretion was measured by titrating a fixed end -point. pre-incubated
salt content and aereated with 100% 02.
samples of the mucosal bathing media to
In order to reduce their spontaneous secretion tissues were
for 12 to 18 hours in the cuvette system at 12’C (8).
solutions both during the pre-incubation with 10 mM pyuvate. wavelength-scanning,
Difference differential
Serosal
and during experiments were fortified
spectra were obtained using a “split-beam”, spectrophotometer
(9).
RESULTS Fig. 1 shows an anoxic difference obtained at 12’C.
spectrum of the intact gastric mucosa
The absorption maxima are identified
on the figure,
spectrum appears to be rather typical
of the respiratory
in mitochondria and in other tissues,
with two exceptions.
355 mu has not been completely identified.
in the 350 to 360 murange.
chain components found
In all probability
component of NADH (340 mu peak) and an additional The other peculiarity
This
First,
the peak at
it contains a
component with a maximum
is an apparent shift of the
cytochrome b-u band to 560 m!, from the usual peak at 564 mu . The differences noted go unexplained for the present. 244
Vol. 36, No. 2, 1969
BIOCHEMICAL
AND BlOPHYSlCAL RESEARCH COMMUNICATIONS
Figure 1. Anoxic difference spectrum of bullfrog gastric mucosa . Sample tissue was made anoxic by bubbing chambers with N2 , sealing the chamber with mineral oil and allowing the tissue to consume the residual 02 for 30 minutes. Reference tissue (baseline) was oxygenated. Temperature 120C. Note separate optical density scales for right and left parts of curve.
Further experiments were carried out to determine what changes, if any, occurred upon stimulating
or inhibiting
acid secretion.
These experiments were
performed at 18OC. Fig. 2A shows the change in optical density produced by the addition of histamine (lO+M) secreting base line.
as compared to the non-stimulated
but spontaneously
It can be clearly seen that the stimulation of acid secretion
is accompanied by large reductions of all of the respiratory
chain components.
Fig. 2B shows the effect of a subsequent addition of SCN (10 mM) to the same tissue. Since Fig. 2A and 2B represents experiments on the identical
sample, the magnitude
of the oxidation-reduction
Fig. 28 shows that
changes are directly
comparable.
SCN not only reverses the reductions produced by histamine but causes a further oxidation. beyond the level which is found in the spontaneously secreting condition.
It should be noted that in these experiments the peak absorption wave245
Vol. 36, No. 2, 1969
BIOCHEMKAL
AND BlOPh’YSlCAL RESEARCH COMMUNICATIONS
c7 n
A
niti*mlne c(*c,)a SW 1
P
e (*a.)
a
604 b ba
*
-a02
o.a-
-0.04
0.02o.o?L
-0.06
F
B
SCN
P :
\
\? -0.02
/
\ \
‘1
:
::
\
.
.
1
340 NADN T
I / !
‘\-
/
:
441 o,~*a)r
r l400
T
I
1
, 460
-
\
/’
‘1,
\
.I
1
-0.00
/ ‘\
/ ‘41
-0.04
t
’
IT . 1 Iwo Cl
‘J
I o.a-
\-I t 602 e(*eJ
ba
aOt0
t bso ebc,)a
0.03-
I
I
,
I
I
I
I
600
A (mp)
Figure 2. Spectral changes induced by histamine and thiocyanate. Curve A, optical density changes at 40 minutes after addition of histamine (10m4M) as compared with spontaneously secreting condition (baseline). Curve B, optical density changes at 20 minutes after addition of SCN(lO-2M); for this spectrum the histamine stimulated condition (Curve A) was used as baseline. Temperature, 18OC.
length in the NADH region of the difference
spectra occurs at approximately
not 355 mu as seen in the anoxic spectra.
It should also be noted that the
cytochrome bo peak still occurs at 560 mP rather than the usual 564 mu . In the experiment depicted in Fig. 2 histamine stimulation produced 246
340 mu
Vol. 36, No. 2, 1969
approximately
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
a 200% increase in hydrogen ion secretion as compared to the
spontaneously secreting condition.
SCN in turn reduced the rate essentially
to zero.
For 8 similar experiments the mean increase in hydrogen ion secretion produced by histamine was 240% and in each case SCN reduced the secretory rate to zero. all of these experiments oxidation-reduction
changes in the respiratory
components accompanied the changes in acid secretion. at 10°C, no significant
chain
In experiments carried out
changes in acid secretion resulted from the addition of
histamine or SCN, nor were there any changes in the oxidation-reduction respiratory
In
state of the
chain components.
The massive reduction of all members of the respiratory
chain upon stimulation
by histamine is similar to the effects expected for hypoxia or local anoxic. to test this possibility
two types of experiments were performed.
In order
In the first,
acid
secretion and O2 consumption were increased by raising the temperature from 14’C to 29’C.
The observed percentage of cytochromes a3, c and b in the oxidized
plotted in Fig. 3 as a function of the temperature.
00 1 14
I I8
I
22
form is
If hypoxia occurred a continuous
I
26
I
30
OC
Effect of temperature on steady-state oxidation level of cytochromes. Figure 3. Tissues were in the spontaneously secreting condition. 60 minutes equilibration period was allowed after each temperature change. Total cytochrome compliment was determined as the difference between the anoxic and oxygenated conditions at 1ooc. 247
Vol. 36, No. 2, 1969
BlOCHMCAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
decline should be evident.
This is clearly not the case, from 14-23’C a relatively
stable level is maintained.
The further decreases at temperatures beyond 23’C
probably signal the first occurrence of hypoxia.
In the second type of experiment,
the stomachs were not cleared of blood and hemoglobin was used as an indicater of the PO2 in the tissue.
At 18OC the reduction of cyt.
a3 accompanied histamine
stimulation without a change of the spectrum from Hb02 to Hb. intracapillary
Thus the
O2 pressure must remain above 100 mm Hg, a level that should be
fully adequate to provide O2 to the cells by diffusion in identical
fashion to the
normal occurrence in vivo.
DISCUSSION The difference normal respiratory
spectra of the intact gastric mucosa reveal the presence of the
chain components with some notable,
special features.
The
unexpected peak at 355 mu is probably composed of two separate components, NADH, and an unidentified The unidentified
compound which absorbs in the, 350-360 mu region.
component does not appear to be directly
linked with the respiratory
chain in as much as it does not undergo oxidation-reduction of the tissue with histamine or SCN.
Only the normal NADH peak at 340 mu seems
to be affected by changes in the rate of acid secretion. might similarly approximately
be caused by an additional 550-560 mV.
oxidation-reduction
changes upon treatment
The shift in the cyt bo peak
peak with a wavelength maximum of
Such an additional
component, however,
changes upon treatment with histamine and SCN.
experiments indicate that this component is not cytochrome b5.
must undergo Preliminary
Further identification
of the component would be of considerable interest owing to its possible involvement in acid secretion. The oxidation-reduction
changes produced by histamine and SCN are very
diffe.rent born those that would be expected if the mitochondria within the gastric 248
BIOCHEMICAL
Vol. 36, No. 2, 1969
AND EUOPHYSICAL RESEARCH COMMUNICATIONS
mucosa were undergoing simple transitions
between state 4 and state 3.
Stimulation
of acid secretion by histamine results in an increased oxygen consumption (4,5) suggesting that the tissue ought to approach state 3. NADH, flavoprotein
In this case an oxidation of
and cyt b should be observed easily and perhaps a slight
reduction of cyt c and cyt a3 could be measured (7). all of the respiratory
The results actually
show that
chain components attain a more reduced steady-state.
Furthermore, the reduction seen in cyt a3 is a very large amount, often involving 20% or greater change of the total.
Inhibition
a
of acid secretion might be expected to
produce a transition towards state 4 and this would involve a reduction of most of the respiratory
chain components.
opposite changes actually inhibition
The results with SCN show that essentially
the
occur : all the components become more oxidized.
Since
of acid secretion by SCN does not affect the rate of 02 uptake (4,10,11,12,13),
the effect appears to be one of “uncoupling” presence of SCN the steady-state
the two tissue functions.
In fact in the
do resemble those of maximally respiring
mitochondria much more closely than when the tissue is secreting acid. The very large oxidation-reduction
changes of cyt a3 are remarkable since in
mitochondria changes of at most a few percent are observed in any transitions the exception The possibility
of a transition
with
between state 5 (anoxia) and one of the other states.
that reductions seen upon stimulation with histamine result from a local
hypoxia produced by the increased oxygen consumption seems unlikely three observations.
First SCN re-oxidizes
in view of
cyt a3 while it is known that a concomitant
decrease in oxygen consumption does not occur, at least not within the time span of these experiments (4,10,11,12,13). increase continuously finally
with increases in the rate of O2 consumption (Fig. 3).
the lack of a disoxygenation
existence of a critically
Secondly the degree of reduction of cyt a3 does not
of hemoglobin in the capillaries
low oxygen tension in the tissue.
249
And
denies the
Vol. 36, No. 2, 1969
BlOCHEMlCAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
In summary, the results do not appear to be explainable of mitochondria within the tissue reflecting concentrations. and oxidative
changes in phosphate acceptor
A more detailed theory as to the relationship metabolism must therefore be advanced.
involve a much more direct relationship
simply on the basis
between acid secretion
Such a new theory may well
between respiration and secretion than is
found in the adenosinephosphate cycling mechanism.
REFERENCES 1. Davenport, H. W., In “Metabolic Aspects of Transport Across Cell Membranes” ed. Q. R. Murphy. Madison University Wisconsin Press. p. 295 (1957). 2, Rehm, W. S. and W. H. Dennis, Ibid. p. 303 (1957). 3. Forte, J. G., P. H. Adams, and R. E. Davies, Biochem. Biophys. Acta la: 25 (1965) 4. Forte, J. G. and R. E. Davies, Amer. 1. Physiol. 22: 218 (1964).5. Villgeas, L. and R. P. Durbin, Biochem., Biophys., Acta 44: 612 (1960). Acta 105 : 472 (1965). 6. Kasbekar, D. K., and R. P. Durbin, Biochem. , Biophys . , -7. Chance, B. and G. R. Williams, 1. Biol. Chem. 217 : 409 (1955). 8. Kasbekar, D. K., -Proc. Sot. Exptl.%l--A,-* Med 125 * 263 (1967). 9. Jl)bsis, F. F., I. Gen. Physiol. 46: 905 (1963). 10. Davies, R. E. andC.Terner, Biochem. L 44: 377 (1949). 11. Alonso, D., R. Rynes and J. B. Harris, G I. Physiol. 208: 1183 (1965). 12. Bannister, W. H., -w Nature 203 : 978 (1964). 13. Moody, F. G., Amer. 1. Physiol. 2&: 127 (1968).
250
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
REDOX CHANGES IN THE RESPIRATORYCHAIN RELATED TO ACID SECRETION BY THE INTACT GASTRIC MUCOSA S. J. Hersey and F. F. Jbbsis Dept. of Physiology, Duke Univ., Durham, N. C.
27706
Received June 2, 1969 SUMMARY Spectrophotometric studies were carried out on the intact isolated gastric mucosa of bullfrog. The anoxic vs oxygenated difference spectrum revealed absorbtion maxima typical of respiratory chain components with some noteworthy special features. Large reductions of all the components occured upon stimulation of acid secretion by histamine while inhibition by thiocyanate was accompanied by oxidation of all components. The reductions accompanying histamine addition do not appear to be due to hypoxia.
Active secretion of hydrochloric upon oxidative
acid by the gastric mucosa is dependent
metabolism (1,2,3) and in turn exerts a controlling
respiration in this tissue (4,s). the concentration
effect on
This control is thought to arise from changes in
of ADP which supposedly depends upon the hydrolysis
during the secretory process (3,6).
According to this theory the mitochondria
within the tissue would be close to the resting metabolic state,
state 4 (7), when
hydrogen ion secretion is inhibited and approach state 3, the actively state, upon stimulation the steady-state
of secretion.
oxidation-reduction
(SCN).
metabolizing
To test this hypothesis we have examined levels of respiratory
intact gastric mucosa during stimulation by thiocyanate
of ATP
chain components in the
by histamine and inhibition
of secretion
The results have been such that we find it impossible to
describe them in terms of transitions
between states 4 and 3.
This work was supported by grants from U.S.P.H.S, Smith, Kline and French. 243
GM00929,
and Tom
Vol. 36, No. 2, 1969
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
METHODS The stomachs of Bullfrogs (Rana catesbiana) were perfused with Ringer The mucosa was then separated from the
solution via the descending aorta. -
muscularis by sharp dissection and mounted as a diaphragm between two lucite half chambers with clear optical windows which served as cuvette system.
The
chambers served to separate two adjacent pieces of the same mucosa as well as to separate the mucosal and serosal surfaces.
The tissues were bathed in a
bicarbonate buffered amphibian Ringer solution and aereated with 95% 02 5% C02. For the measurement of hydrogen ion secretion the mucosal solution was replaced with an unbuffered solution having identical Acid secretion was measured by titrating a fixed end -point. pre-incubated
salt content and aereated with 100% 02.
samples of the mucosal bathing media to
In order to reduce their spontaneous secretion tissues were
for 12 to 18 hours in the cuvette system at 12’C (8).
solutions both during the pre-incubation with 10 mM pyuvate. wavelength-scanning,
Difference differential
Serosal
and during experiments were fortified
spectra were obtained using a “split-beam”, spectrophotometer
(9).
RESULTS Fig. 1 shows an anoxic difference obtained at 12’C.
spectrum of the intact gastric mucosa
The absorption maxima are identified
on the figure,
spectrum appears to be rather typical
of the respiratory
in mitochondria and in other tissues,
with two exceptions.
355 mu has not been completely identified.
in the 350 to 360 murange.
chain components found
In all probability
component of NADH (340 mu peak) and an additional The other peculiarity
This
First,
the peak at
it contains a
component with a maximum
is an apparent shift of the
cytochrome b-u band to 560 m!, from the usual peak at 564 mu . The differences noted go unexplained for the present. 244
Vol. 36, No. 2, 1969
BIOCHEMICAL
AND BlOPHYSlCAL RESEARCH COMMUNICATIONS
Figure 1. Anoxic difference spectrum of bullfrog gastric mucosa . Sample tissue was made anoxic by bubbing chambers with N2 , sealing the chamber with mineral oil and allowing the tissue to consume the residual 02 for 30 minutes. Reference tissue (baseline) was oxygenated. Temperature 120C. Note separate optical density scales for right and left parts of curve.
Further experiments were carried out to determine what changes, if any, occurred upon stimulating
or inhibiting
acid secretion.
These experiments were
performed at 18OC. Fig. 2A shows the change in optical density produced by the addition of histamine (lO+M) secreting base line.
as compared to the non-stimulated
but spontaneously
It can be clearly seen that the stimulation of acid secretion
is accompanied by large reductions of all of the respiratory
chain components.
Fig. 2B shows the effect of a subsequent addition of SCN (10 mM) to the same tissue. Since Fig. 2A and 2B represents experiments on the identical
sample, the magnitude
of the oxidation-reduction
Fig. 28 shows that
changes are directly
comparable.
SCN not only reverses the reductions produced by histamine but causes a further oxidation. beyond the level which is found in the spontaneously secreting condition.
It should be noted that in these experiments the peak absorption wave245
Vol. 36, No. 2, 1969
BIOCHEMKAL
AND BlOPh’YSlCAL RESEARCH COMMUNICATIONS
c7 n
A
niti*mlne c(*c,)a SW 1
P
e (*a.)
a
604 b ba
*
-a02
o.a-
-0.04
0.02o.o?L
-0.06
F
B
SCN
P :
\
\? -0.02
/
\ \
‘1
:
::
\
.
.
1
340 NADN T
I / !
‘\-
/
:
441 o,~*a)r
r l400
T
I
1
, 460
-
\
/’
‘1,
\
.I
1
-0.00
/ ‘\
/ ‘41
-0.04
t
’
IT . 1 Iwo Cl
‘J
I o.a-
\-I t 602 e(*eJ
ba
aOt0
t bso ebc,)a
0.03-
I
I
,
I
I
I
I
600
A (mp)
Figure 2. Spectral changes induced by histamine and thiocyanate. Curve A, optical density changes at 40 minutes after addition of histamine (10m4M) as compared with spontaneously secreting condition (baseline). Curve B, optical density changes at 20 minutes after addition of SCN(lO-2M); for this spectrum the histamine stimulated condition (Curve A) was used as baseline. Temperature, 18OC.
length in the NADH region of the difference
spectra occurs at approximately
not 355 mu as seen in the anoxic spectra.
It should also be noted that the
cytochrome bo peak still occurs at 560 mP rather than the usual 564 mu . In the experiment depicted in Fig. 2 histamine stimulation produced 246
340 mu
Vol. 36, No. 2, 1969
approximately
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
a 200% increase in hydrogen ion secretion as compared to the
spontaneously secreting condition.
SCN in turn reduced the rate essentially
to zero.
For 8 similar experiments the mean increase in hydrogen ion secretion produced by histamine was 240% and in each case SCN reduced the secretory rate to zero. all of these experiments oxidation-reduction
changes in the respiratory
components accompanied the changes in acid secretion. at 10°C, no significant
chain
In experiments carried out
changes in acid secretion resulted from the addition of
histamine or SCN, nor were there any changes in the oxidation-reduction respiratory
In
state of the
chain components.
The massive reduction of all members of the respiratory
chain upon stimulation
by histamine is similar to the effects expected for hypoxia or local anoxic. to test this possibility
two types of experiments were performed.
In order
In the first,
acid
secretion and O2 consumption were increased by raising the temperature from 14’C to 29’C.
The observed percentage of cytochromes a3, c and b in the oxidized
plotted in Fig. 3 as a function of the temperature.
00 1 14
I I8
I
22
form is
If hypoxia occurred a continuous
I
26
I
30
OC
Effect of temperature on steady-state oxidation level of cytochromes. Figure 3. Tissues were in the spontaneously secreting condition. 60 minutes equilibration period was allowed after each temperature change. Total cytochrome compliment was determined as the difference between the anoxic and oxygenated conditions at 1ooc. 247
Vol. 36, No. 2, 1969
BlOCHMCAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
decline should be evident.
This is clearly not the case, from 14-23’C a relatively
stable level is maintained.
The further decreases at temperatures beyond 23’C
probably signal the first occurrence of hypoxia.
In the second type of experiment,
the stomachs were not cleared of blood and hemoglobin was used as an indicater of the PO2 in the tissue.
At 18OC the reduction of cyt.
a3 accompanied histamine
stimulation without a change of the spectrum from Hb02 to Hb. intracapillary
Thus the
O2 pressure must remain above 100 mm Hg, a level that should be
fully adequate to provide O2 to the cells by diffusion in identical
fashion to the
normal occurrence in vivo.
DISCUSSION The difference normal respiratory
spectra of the intact gastric mucosa reveal the presence of the
chain components with some notable,
special features.
The
unexpected peak at 355 mu is probably composed of two separate components, NADH, and an unidentified The unidentified
compound which absorbs in the, 350-360 mu region.
component does not appear to be directly
linked with the respiratory
chain in as much as it does not undergo oxidation-reduction of the tissue with histamine or SCN.
Only the normal NADH peak at 340 mu seems
to be affected by changes in the rate of acid secretion. might similarly approximately
be caused by an additional 550-560 mV.
oxidation-reduction
changes upon treatment
The shift in the cyt bo peak
peak with a wavelength maximum of
Such an additional
component, however,
changes upon treatment with histamine and SCN.
experiments indicate that this component is not cytochrome b5.
must undergo Preliminary
Further identification
of the component would be of considerable interest owing to its possible involvement in acid secretion. The oxidation-reduction
changes produced by histamine and SCN are very
diffe.rent born those that would be expected if the mitochondria within the gastric 248
BIOCHEMICAL
Vol. 36, No. 2, 1969
AND EUOPHYSICAL RESEARCH COMMUNICATIONS
mucosa were undergoing simple transitions
between state 4 and state 3.
Stimulation
of acid secretion by histamine results in an increased oxygen consumption (4,5) suggesting that the tissue ought to approach state 3. NADH, flavoprotein
In this case an oxidation of
and cyt b should be observed easily and perhaps a slight
reduction of cyt c and cyt a3 could be measured (7). all of the respiratory
The results actually
show that
chain components attain a more reduced steady-state.
Furthermore, the reduction seen in cyt a3 is a very large amount, often involving 20% or greater change of the total.
Inhibition
a
of acid secretion might be expected to
produce a transition towards state 4 and this would involve a reduction of most of the respiratory
chain components.
opposite changes actually inhibition
The results with SCN show that essentially
the
occur : all the components become more oxidized.
Since
of acid secretion by SCN does not affect the rate of 02 uptake (4,10,11,12,13),
the effect appears to be one of “uncoupling” presence of SCN the steady-state
the two tissue functions.
In fact in the
do resemble those of maximally respiring
mitochondria much more closely than when the tissue is secreting acid. The very large oxidation-reduction
changes of cyt a3 are remarkable since in
mitochondria changes of at most a few percent are observed in any transitions the exception The possibility
of a transition
with
between state 5 (anoxia) and one of the other states.
that reductions seen upon stimulation with histamine result from a local
hypoxia produced by the increased oxygen consumption seems unlikely three observations.
First SCN re-oxidizes
in view of
cyt a3 while it is known that a concomitant
decrease in oxygen consumption does not occur, at least not within the time span of these experiments (4,10,11,12,13). increase continuously finally
with increases in the rate of O2 consumption (Fig. 3).
the lack of a disoxygenation
existence of a critically
Secondly the degree of reduction of cyt a3 does not
of hemoglobin in the capillaries
low oxygen tension in the tissue.
249
And
denies the
Vol. 36, No. 2, 1969
BlOCHEMlCAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
In summary, the results do not appear to be explainable of mitochondria within the tissue reflecting concentrations. and oxidative
changes in phosphate acceptor
A more detailed theory as to the relationship metabolism must therefore be advanced.
involve a much more direct relationship
simply on the basis
between acid secretion
Such a new theory may well
between respiration and secretion than is
found in the adenosinephosphate cycling mechanism.
REFERENCES 1. Davenport, H. W., In “Metabolic Aspects of Transport Across Cell Membranes” ed. Q. R. Murphy. Madison University Wisconsin Press. p. 295 (1957). 2, Rehm, W. S. and W. H. Dennis, Ibid. p. 303 (1957). 3. Forte, J. G., P. H. Adams, and R. E. Davies, Biochem. Biophys. Acta la: 25 (1965) 4. Forte, J. G. and R. E. Davies, Amer. 1. Physiol. 22: 218 (1964).5. Villgeas, L. and R. P. Durbin, Biochem., Biophys., Acta 44: 612 (1960). Acta 105 : 472 (1965). 6. Kasbekar, D. K., and R. P. Durbin, Biochem. , Biophys . , -7. Chance, B. and G. R. Williams, 1. Biol. Chem. 217 : 409 (1955). 8. Kasbekar, D. K., -Proc. Sot. Exptl.%l--A,-* Med 125 * 263 (1967). 9. Jl)bsis, F. F., I. Gen. Physiol. 46: 905 (1963). 10. Davies, R. E. andC.Terner, Biochem. L 44: 377 (1949). 11. Alonso, D., R. Rynes and J. B. Harris, G I. Physiol. 208: 1183 (1965). 12. Bannister, W. H., -w Nature 203 : 978 (1964). 13. Moody, F. G., Amer. 1. Physiol. 2&: 127 (1968).
250