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The incorporation of l-[Me-14C]methionine and [Me-3H]choline into lung phosphatides
BIOCHIMICA
552
ET BIOPHYSICA
ACTA
*BA 55431
THE INCORPORATION
OF
L-
iJfe-‘JC]METHIONINE
AND [Me-3H]CHOLINE
INTO LUNG PHOSPHATIDES
H.
L.
SPITZER,
k;. MORRISON
AND
J. R. NOR&&W
Department of Medicine, Pulmonavy and Gastvoentevology Divisions, The University of Alabama rMedica1 Center, Birmingham, Ala. (U.S.A (Received October z6th, 1967) (Revised manuscript received December
Iqth,
.)
1967)
SUMMARY
A comparison has been made of r.-[Me-Wlmethionine and [Me-3H]chohne incorporation in viva into lung and liver lecithin. The data suggest that the liver is not the source of lung lecithin and that synthesis in S&V occurs via the CDP-choline pathway. The synthesis in Z&JOof lecithin via methylation of phosphatidyl ethanolamine appears to be of only minor importance in lung and probably results from a slow turnover of methionine methyl in this tissue. Using L-[Me-Wlmethionine it has been shown that the phospholipid tentatively identified as phosphatid~~l-~,Ndimethylethanolamine in lung is probably an intermediate in the stepwise methylation of phosphatidylethanolamine. The finding of significant [Me-3H]choline activity in lung and liver phosphatidyl-N,N-dimethylethanolamine reconfirms the original observation that betaine is an important source of a methyl group in the methylation of phosphatidylethanolamine.
INTRODUCTION
A number of investigators have reported that up to 594 of the phospholipids of lung tissue and pulmonary surfactant lipoprotein is phosphatidyl-N,N-dimethylethanolaminel~z. MORGAN, PINLEY AND FIALKOW’ found that the phosphatidyl-N,~~dimethylethanolamine of dog lung tissue and the lecithin associated with pulmonary surfactant lipoprotein had similar fatty acid patterns suggesting a product : precursor relationship. GLUCK AND SRIBNEY~ using homogenates of lung from rabbit fetuses found that incorporation of radioactive choline into lecithin declined and that the methyl group of [Me-W]S-adenosylmethionine increased shortly prior to term. The conclusion drawn from these data by others” has been that perhaps the major pathway of surfactant lecithin synthesis occurs via methylation of phosphatidylethanolamine in the granular pneumoncytes. The present study was undertaken to elucidate some of the aspects of the biosynthesis in vizroof lung lecithin. Biockim. Biopk~~s. Acta, 152 (1968) 552-558
LUNG LECITHIN SYNTHESIS in. ViWJ
553
MATERIAL AND METHODS Female Sprague-Dawley rats (weighing 200-250 g) maintained on standard lab chow were used in all experiments. From the time of isotope administration until sacrifice by cervical dislocation the animals were allowed free access to food and water. At time of sacrifice lungs and liver were quickly removed, washed in cold 0.99;; NaCl, homogenized, lipids extracted and the phospholipids characterized by methods reported elsewhere 6t6. Briefly, after separation of phospholipids by silicic acid column chromatography, all compounds were checked for purity by the thin-layer chromatographic
method
of SKIPSKI et al.? using IO O/ 1’0 H,SO,
detection of organic material. [Jle-3H]Choline (IOO mC/mmole)
spray followed by charring
and L-[hfeJ4C]methionine
for
(10.4 mC/mmole)
were purchased from New England Nuclear Corp. [r,s-‘%,]Choline (20 mC/mmole) was purchased from Schwarz BioResearch, Inc. Appropriate mixtures of radioactive material
were made up in sterile 0.97~ NaCl, and I ml injected
attempt
was made to determine
the amount
of activity
ilia the tail vein. No
remaining
in the syringe
or
lost by bleeding. Radioactivity was determined in a Nuclear-Chicago Mk. I liquid scintillation spectrometer as described in detail by BALINT et al.@. Fatty acids were determined
using an F & M Model 402 gas chromatograph
describeda.
All reagents
were of analytical
by methods
previously
grade.
RESULTS AND DISCUSSION In separation the
of lung phosphatides
phosphatidylethanolamine
chromatography
peak
of this fraction
spot corresponded
to standard
significant
eluted
revealed
radioactivity
off a silicic
acid
was detected
column.
two spots with iodine vapor.
phosphatidylethanolamine
in
Thin-layer
and contained
The larger only trace
radioactivity. A smaller second spot ran just behind the phosphatidylethanolamine, was ninhydrin negative and contained 957, of the radioactivity detected in the phosphatidylethanolamine
peak eluted off the silicic acid column.
FIALKOW’ have identified Radioactivity
this material
was also detected
in the phosphatidylethanolamine
eluted off a silicic acid column. Thin-layer spot, phosphatidylethanolamine, having thin-layer
plate just behind
MORGAN, FINLEY AND
as phosphatidyl-N,N-dimethylethanolamine. fraction
from liver
chromatography however revealed a single a trace of radioactivity. The area on the
phosphatidylethanolamine
and corresponding
to phos-
phatidyl-N,N-dimethylethanolamine contained 955(, of the radioactivity detected in the phosphatidylethanolamine peak eluted off the silicic acid column. Table I gives the distribution of L-(Me-lK]methionine and [ICfe-3H]choline incorporation between the choline phosphatides and phosphatidyl-N,N-dimethylethanolamine in lung and liver. The amount of [MQH]choline activity in phosphatidyl-N,N-dimethylethanolamine was unexpected. To determine whether the radioactivity detected in this spot might be due to an unusual lecithin species eluted from the silicic acid column along with phosphatidyl-N,N-dimethylethanolamine, double label choline studies were performed using [r,z-14C,]choline and [Me-3H]choline (see Table II). [Me-3H]Choline incorporation into phosphatidyl-N,N-dimethylethanolamine was similar to that in Table I. [r,z-14C]Choline was detected at twice background (14C background 16 counts/min) and was not considered significant. RioChim.
Bioph_Vs.
.4Cfa,
152
(196s)
552-558
H. L. SPITZER, K. MORRISON, J. R. NORMAN
554 The finding of [MGH]choline amine could be expected according GREENBERG'~ direct
activity in phosphatidyl-N,N-dimethylethanolto the scheme proposed by BREMER, FIGARD AND
in which the loss of the first methyl
transmethylation
between
betaine
group in choline
and homocysteine
catabolism
to form
is a
methionine.
Similar data regarding choline-methyl group reutilization in methylation of phosphatidylethanolamine have been reported by GROTH, BAIN AND PFEIFFER". Betaine TABLE
1
DISTRIBUTIONOF L-[M&%]METHIONINE LIVER
AND [Me-~H]CHOLINE RADIOACTIVITY IN
LUNG
AND
PHOSPHATIDES
Values are expressed in disint./min applied to a silicic acid column. Phosphatide Phosphatidyl-N,Ndimethylethanolamine* Choline Choline phosphatides**
of isolated
material from I mg of phospholipid
phosphorus
Liver
Time (h)
LLl?‘lg Choline
Methionine
Ckoline
Methionine __-
2 4 2 4
5445 3935 4099280 4266542
851 1050 18080 27802
14974 25078 1398348 1573830
424” 3 445 542 180 534672
* Phosphatidyl-N,N-dimethylethanolamine is a tentative identification based on comparison of our thin-fayer chromatographic data with that obtained by MORGAN, FINLEY AND FIALKOW~. This phosphohpid has been designated Px by other investigators.*,9 MORGAN, FINLEY AND FIALKOW~ identified Px as phosphatidyl-N,N-dimethylethanolamine by gas-chromatographic analysis of the base. ** Choline phosphatides: lecithin, lvsolecithin and sphingomyelin. Female rats were given simultaneously an intravenous injection-of 25 PC L-[Me-Ylmethionine and IOO ,uC [IUe-3Hjcholine. Results are from pooled tissue from 3 animals.
has been shown to be as effective of phosphatidylethanolamine12. (Table
a methyl
donor as methionine
The inability
to detect
II) in phosphatidyl-N,N-dimethylethanolamine
MUNTZ~~that phosphatidylcholine ethanolamine. Lecithin (a) methylation
synthesis
in mammalian
of phosphatidyl
confirms
is not catabolized
in the methylation
[~,a-lJC,]choline
radioactivity
the original work of
to phosphatidyl-N,N-dimethyl-
species takes place via two major pathways*;
ethanolamine
with methionine
being the donor of
of choline via cytidine diphosphate all three methyl groups10y15 or (b) incorporation compare choline (CDP-choline) 16. The present study was designed to simultaneously these pathways in lung and liver using L-[A1G4C]methionine and [I11e3H]choline. By calculating the ratio of [AlGH]choline to L-[,lle-l”C]methionine incorporation into lecithin one is able to approximate the relative activity of these two pathways in one tissue and compare it to another tissue. Table III gives the specific activity (disint./ min per patom lipid P) of L- [dle-l%]methionine and [&Is-3Hlcholine incorporation into lung and liver lecithin. The ratio of [AWe-3Hlcholine to L-[Ale-Klmethionine incorporation into lecithin isolated from liver is 2.5 at z h and 2.9 at 4 h, while in lung the ratios are 250 and 160. The values obtained for liver are in good agreement to Lwith those reported in the literature6917. Since the ratio of [A$e-JH]choline [Ale-lJC]methionine is IOO times greater in lung than in liver lecithin it would appear * A third pathway has been described I4 direct incorporation of free choline into lecithin. This pathway would give identical results as those assigned to the CDP-choline pathway in the present study. Biochiw.
BzopJr~~s. .Icta,
152 (1968) 552-558
LUNG
LECITHIN
TABLE
SYNTHESIS
i!ZViVO
555
II
DISTRIBUTION Values
are
applied
to
OF [&I&3H]CHOLINE expressed a silicic _
in acid
AND
disint./min
of
[I,~-*4C,]~~~~~~~ isolated
Animal
Phosphatidylethanolamine
3H ‘4C
Phosphatidyl-N,NCholine phosphatides** See
Table
***
Radioactivity
rats
were
and
12.5 &
that
given
IN LUNG
PHOSPHATIDES
phospholipid
phosphorus
***
3H
7538987
*** II
150532
3
I423 5838
13172
1%
A4xiwal
3083
71’54
***
16.355
274248
9889591
23S711
199493
definition.
was
detected
simultaneously
[I,z-K,]choline
methylation
pathway
of
***
II71
14C
I for
I mg
A4i2imzl 2
1
7954
3H
dimethylethanolamine*
*. **
from
column.
Phosfihatide
Choline
RADIOACTIVITY
material
at twice
background
an intravenous (20
injection
was
of IOO$
not
considered
significant.
[Me+H]choline
(IOO
Female
mC/mmole)
mC/mmole).
of phosphatidylethanolamine
of lecithin
and
synthesis
may not be the major
biosynthetic
in lung.
There are several possible explanations
for the differences
observed
in lecithin
synthesis in lung and liver: (a) Lung tissue receives lecithin intact from the liver via plasma. (b) There is a selective dilution or uptake of choline or methionine by lung or liver tissue. (c) The major pathway of lecithin synthesis in lung tissue is via the CDPcholine pathway and not via methylztion of phosphatidylethanolamine. (d) Lung lecithin
is a mixture
of molecular
over of lung tissue methionine principle in lung.
donor of the methyl
speci 2s synthesized via different pathways. (e) Turnmethyl is relatively slow. (f) Methionine is not the
group in the methylation
of phosphatidylethanolamine
In a study of lecithin synthesis using similar methodsBy17, it was found that equilibration of liver and plasma lecithin takes place at about 2 h. If the choline of lung tissue lecithin is derived from plasma lecithin the [Me-3H]choline to L- [Ale-Xlmethionine ratio should be ,similar to that found in liver. Since the ratio is always greater
than IOO in lung over the time period studies and less than 3 in the liver it is
difficult to believe that there is a relationship data tend to exclude the first possibility from the liver via plasma.
between
lung and liver lecithin.
(a) that lung tissue receives
There is 3 times more [,WGH]choline phatides (Table I) of lung than liver. Specific
lecithin
These intact
incorporation into the choline phosactivity (Table III) is greater in lung
lecithin than in liver lecithin. BJDRNSTAD AND BREMER'? using intraperitoneal injection of [I,z-14Cz]choline found incorporation into choline phosphatides greater in liver than lung. This difference is thought to be due to the mode of tracer administration. In parallel experiments the same investigators gave paired animals [I,z-14C,]choline plus unlabeled
choline.
Liver
and lung incorporation
was reduced
7596,
suggesting
similar dilution in both tissues. At present, there is no detailed evidence regarding selective dilution or uptake of choline or methionine by either lung or liver. This possibility (b) cannot be excluded. The incorporation of L- [Me-Xlmethionine into choline phosphatides was 20 times greater in liver than lung (Table I). Unlike choline incorporation, this difference Liver microsomes incubated with is present in animals injected intraperitoneally17. Riochinz.
Biophvs.
.-lcta,
152
(1968)
552-558
H. L. SPITZER, K. MORRISON, J. R. NORMAN
556 TABLE
III
SPECIFICACTIVITIESOF LUNGAPZD ~IETHIONINE Specific in
AND
activity
Table
LIVER
LECITHIN
.4FTER
INTRAVENOUS
INJECTION
OF L-[fife-‘%-
~M~~HJCHOLINE =
diSint./min
per
@om
lipid
P.
Experimental
conditions
are
the
Same
as stated
I.
Lung Cholirze
Time (11) 2
207 151
4
240218
Methioniv~r 828
-
I498
(,41e-14C]S-adenosylmethionine choline
phosphatides
LkW Choline
Methionirle
69487 82 520
2773.3 28319
incorporate
methylation of phosphatidylethanolamine reported that the ability of lung tissue ethanolamine
65 times
than lung microsomesls.
increases
markedly
more
methionine
methyl
into
Such data in vitro tend to show that
is greater in liver than lung. It has been homogenates to methylate phosphatidyl-
during gestation
with a concomitant
decline in the
activity of the CDP-choline pathway3. Since no data on net synthesis was given in this study one cannot determine the contribution of each pathway to lecithin synthesis. These data support the possibility (c) that the major pathway of lecithin synthesis ipt Go in lung tissue is via the CDP-choline pathway and not via methylation of phosphatidylethanolamine. The lecithin fatty
of lung tissue is composed
acids esterified
are palmitate
of a variety
to the glpcerylphosphorylcholine
43:/a, stearate
189;,
palmitoleate
of molecular
backbone
6y6, oleate
species.
The
in rat lung lecithin
1776, linoleate
694 and
arachidonate II:,;. These values are very similar to those reported by MORGAN, FINLEY AND FIALKOW’ for the lecithin of dog lung tissue. 75;$ of the fatty acids esterified to the surfactant lecithin are saturatedly19 indicating that it is probably a single molecular [Il1GH]choline tionated
species. Fig. I shows the pattern of phospholipid and L-I,Ue-“Clmethionine incorporation into
on a silicic acid column.
The fact that
the specific
phosphorus elution, lung lecithin frac-
activities
of LAVe+H]-
disint./min per @ml P
Fig. I. Silicic acid column elution of 4 h lung lecithin from Table I. 10 ml fractions were collected; 0.5 ml was taken from every other fraction for phosphorus determination. At the points indicated 5.ml aliquots were dried down and radioactivity determined. Phosphorus (O----O); specific activities (disint./min per ,ugatom lipid P) of [MeQH]choline (x---x ), L-[MG4C]methionine (A-A). (Sphingomyelin, [MGH]choline roe I 73 disint./min per /“atom lipid P, L- [Me-W]methionine 1008 disint./min per ,uatom lipid P.)
Biochim. Biophvs. .dcta. I j2 (1968)
552-558
LUNG LECITHIN
SYNTHESIS
in ViVO
choline
and L-[Me-14C]methionine
elution
argues very strongly
557 do not parallel
that
lung lecithin
each
other
nor the phosphorus
is a heterogeneous
mixture.
Similar
of liver lecithin. Also, have been reported by othersZ0q2r in fractionation studie+ of lecithin elution from a silicic acid column have shown that containing the most unsaturated fatty acids are eluted first and lecithins
findings detailed lecithins containing
mostly
saturated
fatty
acids are eluted
last.
Thus
it appears
that
the
lecithin of lung tissue is a heterogeneous mixture (possibility (d) above) and the highly unsaturated lecithins are synthesized viu methylation of phosphatidylethanolamine while the highly
saturated
No final conclusions,
lecithins
however,
are synthesized
concerning
via the CDP-choline
the lecithin of surfactant
pathway.
can be made until
it and the appropriate molecular species in lung tissue are compared. The finding of L-[Me-14C]methionine radioactivity in phosphatidyl-N,N-dimethylethanolamine
isolated
from
lung suggests
that
this compound
mediate in the stepwise methylation of phosphatidylethanolamine. L-[Me-laC]nlethionine incorporation (Table I) into this compound gests that the turnover these time periods mediate.
of methionine
one would expect
BALDESSARINI~~ has assayed
onine. Liver contains
methyl
is an inter-
The increase in from z to 4 h sug-
in the lung may be relatively
to see maximum a number
incorporation
slow. At
into an inter-
of rat tissues for S-adenosylmethi-
26 pg/g wet weight while lung contains
II pug/gwet weight. This
would tend to exclude the lack of immediate precursor for slow methionine methyl turnover but might imply less methyltransferase enzyme in lung tissue (possibility (e) above). Using tidylethanolamine of ethanolamine to exclude
[r,z-r4C,]ethanolamine there is much less conversion of phosphato lecithin in lung as compared to liver”. The similar incorporation and the methyl
the possibility
in methylation
group of methionine
of a methyl
of phosphatidylethanolamine
Lung lecithin
is a heterogeneous
into lung lecithin”
donor other than methionine in lung (possibility
mixture
of molecular
would tend
being involved
(f) above).
species synthesized
by
both the methylation of phosphatidylethanolamine and the CDP-choline pathway. It appears under the conditions of the present experiment ilz z&lo that methylation of phosphatidylethanolamine lecithin. synthesis
The data further
is of minor importance
in the synthesis
of lung tissue
show that liver is not the source of lung lecithin
occurs in situ mainly
Z&Zthe CDP-choline
and that
pathway.
ACKNOWLEDGEMENTS
The authors gratefully acknowledge the encouragement and guidance of Dr. J. M. MCKIBBIN throughout this investigation as well as the editorial criticisms of Dr. G. SACHS. This study was supported by a grant from the National Science Foundation GB-4765, U.S. Public Health Service Training Grant in Gastroenterology ~A-5286 and U.S. Public Health Service General Support Grant FR 05349. A portion of this work was conducted in the Clinical Research Center Laboratory of the University of Alabama Medical Center supported by the National Institutes of Health Grant ZMOI-FR-3207.
Biochim.
Riopl~ys.
Acta,
151 (1968)
552-558
H. I.. SPITZER,
55s
I<. MORRISON,
J. R. NORMAN
REFERENCES I z 3 4 5 6 7 8 g IO II IZ 13
14 15 16 17 18 Ig 20 21 PL
T. E. MORGAN, T. N. FINLEY AND H. FIALKOX~T, Biochirn. Bioph>~s. .4&a, 106 (1965) 403. A. NAIMARK AND D. KLASS, Car!. J. Phvsiol. Phawxacol., 45 (1967) 597. L. GLUCK .~ND M. SRIBNEY, Physiologist, 8 (1965) 174. J. X. CLERIENTS, Develop~nent of the Lang, Churchill, London, 1967, p. 202. J. A. BALINT, W. L. NYHAN, P. LIETMAN AND D. A. TURNER, J. Lab. Clin. Med., 58 (1961) 5-18 J. A. BALINT, D. A. BEELER, D. H. TREBLE AKD H. L. SPITZER, J. Lipid Res., 8 (1967) 486. V. P. SKIPSKI, R. F. PETERSON, J. SUNDERS AND M. BARCLAY, J. Lipid Res., 4 (1963) 227. P A. WEINHOLD AND C. A. VILLEE, Biochim. Bioplrys. Acta, 106 (1965) 540. J. R. NORMAN, S. D. BRIGGS AND R. A. .~VENT, Clin. Res., I.+ (1967) 105. J. BREI\IER, P. H. FIGARD AND D. RI. GREENBERG, B&him. Biophys. Acta, 43 (1960) 477. D. P. GROTH, J. A. BAIN AND C. C. PFEIFFER, J. Phawnacol. Exptl. Thevap., 124 (1958) zgo. J. A. STEKOL, S. WEISS, P. S~IITH AND K. \VEISS, ,I. Biol. Ckern., 201 (1953) 299. J. A. &IUNTZ, J. Biol. Chem., 182 (1950) 489. 11. 11. DILS AND H. HUBSCHER, Biochin~. BiopBys. Acta, 46 (1961) 505. J. D. WILSON, I-C. D. GIBSON AND S. UDENFRIEND, J. Biol. C&n., 235 (1960) 3213. E. P. KENNEDY AND S. B. WEISS, J. Biol. Chew., 22~ (1956) 193. P. BJG~RNSTAD AND J. BREMER, ,I. Lipid Res., 7 (1966) 38. J. BREMER AND D. M. GREENBERG, Biochim. Biophys. Acta, 46 (1961) 205. M. E. ABRAMS, J. A$#. Physiol., LI (1966) 718. M. ISOZAKI, A. YA~XAIXOTO, T. AMAKO, Y. SAKAI AND H. OKITA, Med. J. Osaka l_rm,,., IL (1962) 285. J. L. GLENN, E. OPALKA AND Ii. J. TISCHER, J. Biol. Ckewz., 238 (1963) 12.+9. R. J. BALDESSARINI, Biochewt. Phavnzacol., 15 (1966) 741.
Biochim.
Bioph_v~. .4cfa, 152 (1968) 552-558
552
ET BIOPHYSICA
ACTA
*BA 55431
THE INCORPORATION
OF
L-
iJfe-‘JC]METHIONINE
AND [Me-3H]CHOLINE
INTO LUNG PHOSPHATIDES
H.
L.
SPITZER,
k;. MORRISON
AND
J. R. NOR&&W
Department of Medicine, Pulmonavy and Gastvoentevology Divisions, The University of Alabama rMedica1 Center, Birmingham, Ala. (U.S.A (Received October z6th, 1967) (Revised manuscript received December
Iqth,
.)
1967)
SUMMARY
A comparison has been made of r.-[Me-Wlmethionine and [Me-3H]chohne incorporation in viva into lung and liver lecithin. The data suggest that the liver is not the source of lung lecithin and that synthesis in S&V occurs via the CDP-choline pathway. The synthesis in Z&JOof lecithin via methylation of phosphatidyl ethanolamine appears to be of only minor importance in lung and probably results from a slow turnover of methionine methyl in this tissue. Using L-[Me-Wlmethionine it has been shown that the phospholipid tentatively identified as phosphatid~~l-~,Ndimethylethanolamine in lung is probably an intermediate in the stepwise methylation of phosphatidylethanolamine. The finding of significant [Me-3H]choline activity in lung and liver phosphatidyl-N,N-dimethylethanolamine reconfirms the original observation that betaine is an important source of a methyl group in the methylation of phosphatidylethanolamine.
INTRODUCTION
A number of investigators have reported that up to 594 of the phospholipids of lung tissue and pulmonary surfactant lipoprotein is phosphatidyl-N,N-dimethylethanolaminel~z. MORGAN, PINLEY AND FIALKOW’ found that the phosphatidyl-N,~~dimethylethanolamine of dog lung tissue and the lecithin associated with pulmonary surfactant lipoprotein had similar fatty acid patterns suggesting a product : precursor relationship. GLUCK AND SRIBNEY~ using homogenates of lung from rabbit fetuses found that incorporation of radioactive choline into lecithin declined and that the methyl group of [Me-W]S-adenosylmethionine increased shortly prior to term. The conclusion drawn from these data by others” has been that perhaps the major pathway of surfactant lecithin synthesis occurs via methylation of phosphatidylethanolamine in the granular pneumoncytes. The present study was undertaken to elucidate some of the aspects of the biosynthesis in vizroof lung lecithin. Biockim. Biopk~~s. Acta, 152 (1968) 552-558
LUNG LECITHIN SYNTHESIS in. ViWJ
553
MATERIAL AND METHODS Female Sprague-Dawley rats (weighing 200-250 g) maintained on standard lab chow were used in all experiments. From the time of isotope administration until sacrifice by cervical dislocation the animals were allowed free access to food and water. At time of sacrifice lungs and liver were quickly removed, washed in cold 0.99;; NaCl, homogenized, lipids extracted and the phospholipids characterized by methods reported elsewhere 6t6. Briefly, after separation of phospholipids by silicic acid column chromatography, all compounds were checked for purity by the thin-layer chromatographic
method
of SKIPSKI et al.? using IO O/ 1’0 H,SO,
detection of organic material. [Jle-3H]Choline (IOO mC/mmole)
spray followed by charring
and L-[hfeJ4C]methionine
for
(10.4 mC/mmole)
were purchased from New England Nuclear Corp. [r,s-‘%,]Choline (20 mC/mmole) was purchased from Schwarz BioResearch, Inc. Appropriate mixtures of radioactive material
were made up in sterile 0.97~ NaCl, and I ml injected
attempt
was made to determine
the amount
of activity
ilia the tail vein. No
remaining
in the syringe
or
lost by bleeding. Radioactivity was determined in a Nuclear-Chicago Mk. I liquid scintillation spectrometer as described in detail by BALINT et al.@. Fatty acids were determined
using an F & M Model 402 gas chromatograph
describeda.
All reagents
were of analytical
by methods
previously
grade.
RESULTS AND DISCUSSION In separation the
of lung phosphatides
phosphatidylethanolamine
chromatography
peak
of this fraction
spot corresponded
to standard
significant
eluted
revealed
radioactivity
off a silicic
acid
was detected
column.
two spots with iodine vapor.
phosphatidylethanolamine
in
Thin-layer
and contained
The larger only trace
radioactivity. A smaller second spot ran just behind the phosphatidylethanolamine, was ninhydrin negative and contained 957, of the radioactivity detected in the phosphatidylethanolamine
peak eluted off the silicic acid column.
FIALKOW’ have identified Radioactivity
this material
was also detected
in the phosphatidylethanolamine
eluted off a silicic acid column. Thin-layer spot, phosphatidylethanolamine, having thin-layer
plate just behind
MORGAN, FINLEY AND
as phosphatidyl-N,N-dimethylethanolamine. fraction
from liver
chromatography however revealed a single a trace of radioactivity. The area on the
phosphatidylethanolamine
and corresponding
to phos-
phatidyl-N,N-dimethylethanolamine contained 955(, of the radioactivity detected in the phosphatidylethanolamine peak eluted off the silicic acid column. Table I gives the distribution of L-(Me-lK]methionine and [ICfe-3H]choline incorporation between the choline phosphatides and phosphatidyl-N,N-dimethylethanolamine in lung and liver. The amount of [MQH]choline activity in phosphatidyl-N,N-dimethylethanolamine was unexpected. To determine whether the radioactivity detected in this spot might be due to an unusual lecithin species eluted from the silicic acid column along with phosphatidyl-N,N-dimethylethanolamine, double label choline studies were performed using [r,z-14C,]choline and [Me-3H]choline (see Table II). [Me-3H]Choline incorporation into phosphatidyl-N,N-dimethylethanolamine was similar to that in Table I. [r,z-14C]Choline was detected at twice background (14C background 16 counts/min) and was not considered significant. RioChim.
Bioph_Vs.
.4Cfa,
152
(196s)
552-558
H. L. SPITZER, K. MORRISON, J. R. NORMAN
554 The finding of [MGH]choline amine could be expected according GREENBERG'~ direct
activity in phosphatidyl-N,N-dimethylethanolto the scheme proposed by BREMER, FIGARD AND
in which the loss of the first methyl
transmethylation
between
betaine
group in choline
and homocysteine
catabolism
to form
is a
methionine.
Similar data regarding choline-methyl group reutilization in methylation of phosphatidylethanolamine have been reported by GROTH, BAIN AND PFEIFFER". Betaine TABLE
1
DISTRIBUTIONOF L-[M&%]METHIONINE LIVER
AND [Me-~H]CHOLINE RADIOACTIVITY IN
LUNG
AND
PHOSPHATIDES
Values are expressed in disint./min applied to a silicic acid column. Phosphatide Phosphatidyl-N,Ndimethylethanolamine* Choline Choline phosphatides**
of isolated
material from I mg of phospholipid
phosphorus
Liver
Time (h)
LLl?‘lg Choline
Methionine
Ckoline
Methionine __-
2 4 2 4
5445 3935 4099280 4266542
851 1050 18080 27802
14974 25078 1398348 1573830
424” 3 445 542 180 534672
* Phosphatidyl-N,N-dimethylethanolamine is a tentative identification based on comparison of our thin-fayer chromatographic data with that obtained by MORGAN, FINLEY AND FIALKOW~. This phosphohpid has been designated Px by other investigators.*,9 MORGAN, FINLEY AND FIALKOW~ identified Px as phosphatidyl-N,N-dimethylethanolamine by gas-chromatographic analysis of the base. ** Choline phosphatides: lecithin, lvsolecithin and sphingomyelin. Female rats were given simultaneously an intravenous injection-of 25 PC L-[Me-Ylmethionine and IOO ,uC [IUe-3Hjcholine. Results are from pooled tissue from 3 animals.
has been shown to be as effective of phosphatidylethanolamine12. (Table
a methyl
donor as methionine
The inability
to detect
II) in phosphatidyl-N,N-dimethylethanolamine
MUNTZ~~that phosphatidylcholine ethanolamine. Lecithin (a) methylation
synthesis
in mammalian
of phosphatidyl
confirms
is not catabolized
in the methylation
[~,a-lJC,]choline
radioactivity
the original work of
to phosphatidyl-N,N-dimethyl-
species takes place via two major pathways*;
ethanolamine
with methionine
being the donor of
of choline via cytidine diphosphate all three methyl groups10y15 or (b) incorporation compare choline (CDP-choline) 16. The present study was designed to simultaneously these pathways in lung and liver using L-[A1G4C]methionine and [I11e3H]choline. By calculating the ratio of [AlGH]choline to L-[,lle-l”C]methionine incorporation into lecithin one is able to approximate the relative activity of these two pathways in one tissue and compare it to another tissue. Table III gives the specific activity (disint./ min per patom lipid P) of L- [dle-l%]methionine and [&Is-3Hlcholine incorporation into lung and liver lecithin. The ratio of [AWe-3Hlcholine to L-[Ale-Klmethionine incorporation into lecithin isolated from liver is 2.5 at z h and 2.9 at 4 h, while in lung the ratios are 250 and 160. The values obtained for liver are in good agreement to Lwith those reported in the literature6917. Since the ratio of [A$e-JH]choline [Ale-lJC]methionine is IOO times greater in lung than in liver lecithin it would appear * A third pathway has been described I4 direct incorporation of free choline into lecithin. This pathway would give identical results as those assigned to the CDP-choline pathway in the present study. Biochiw.
BzopJr~~s. .Icta,
152 (1968) 552-558
LUNG
LECITHIN
TABLE
SYNTHESIS
i!ZViVO
555
II
DISTRIBUTION Values
are
applied
to
OF [&I&3H]CHOLINE expressed a silicic _
in acid
AND
disint./min
of
[I,~-*4C,]~~~~~~~ isolated
Animal
Phosphatidylethanolamine
3H ‘4C
Phosphatidyl-N,NCholine phosphatides** See
Table
***
Radioactivity
rats
were
and
12.5 &
that
given
IN LUNG
PHOSPHATIDES
phospholipid
phosphorus
***
3H
7538987
*** II
150532
3
I423 5838
13172
1%
A4xiwal
3083
71’54
***
16.355
274248
9889591
23S711
199493
definition.
was
detected
simultaneously
[I,z-K,]choline
methylation
pathway
of
***
II71
14C
I for
I mg
A4i2imzl 2
1
7954
3H
dimethylethanolamine*
*. **
from
column.
Phosfihatide
Choline
RADIOACTIVITY
material
at twice
background
an intravenous (20
injection
was
of IOO$
not
considered
significant.
[Me+H]choline
(IOO
Female
mC/mmole)
mC/mmole).
of phosphatidylethanolamine
of lecithin
and
synthesis
may not be the major
biosynthetic
in lung.
There are several possible explanations
for the differences
observed
in lecithin
synthesis in lung and liver: (a) Lung tissue receives lecithin intact from the liver via plasma. (b) There is a selective dilution or uptake of choline or methionine by lung or liver tissue. (c) The major pathway of lecithin synthesis in lung tissue is via the CDPcholine pathway and not via methylztion of phosphatidylethanolamine. (d) Lung lecithin
is a mixture
of molecular
over of lung tissue methionine principle in lung.
donor of the methyl
speci 2s synthesized via different pathways. (e) Turnmethyl is relatively slow. (f) Methionine is not the
group in the methylation
of phosphatidylethanolamine
In a study of lecithin synthesis using similar methodsBy17, it was found that equilibration of liver and plasma lecithin takes place at about 2 h. If the choline of lung tissue lecithin is derived from plasma lecithin the [Me-3H]choline to L- [Ale-Xlmethionine ratio should be ,similar to that found in liver. Since the ratio is always greater
than IOO in lung over the time period studies and less than 3 in the liver it is
difficult to believe that there is a relationship data tend to exclude the first possibility from the liver via plasma.
between
lung and liver lecithin.
(a) that lung tissue receives
There is 3 times more [,WGH]choline phatides (Table I) of lung than liver. Specific
lecithin
These intact
incorporation into the choline phosactivity (Table III) is greater in lung
lecithin than in liver lecithin. BJDRNSTAD AND BREMER'? using intraperitoneal injection of [I,z-14Cz]choline found incorporation into choline phosphatides greater in liver than lung. This difference is thought to be due to the mode of tracer administration. In parallel experiments the same investigators gave paired animals [I,z-14C,]choline plus unlabeled
choline.
Liver
and lung incorporation
was reduced
7596,
suggesting
similar dilution in both tissues. At present, there is no detailed evidence regarding selective dilution or uptake of choline or methionine by either lung or liver. This possibility (b) cannot be excluded. The incorporation of L- [Me-Xlmethionine into choline phosphatides was 20 times greater in liver than lung (Table I). Unlike choline incorporation, this difference Liver microsomes incubated with is present in animals injected intraperitoneally17. Riochinz.
Biophvs.
.-lcta,
152
(1968)
552-558
H. L. SPITZER, K. MORRISON, J. R. NORMAN
556 TABLE
III
SPECIFICACTIVITIESOF LUNGAPZD ~IETHIONINE Specific in
AND
activity
Table
LIVER
LECITHIN
.4FTER
INTRAVENOUS
INJECTION
OF L-[fife-‘%-
~M~~HJCHOLINE =
diSint./min
per
@om
lipid
P.
Experimental
conditions
are
the
Same
as stated
I.
Lung Cholirze
Time (11) 2
207 151
4
240218
Methioniv~r 828
-
I498
(,41e-14C]S-adenosylmethionine choline
phosphatides
LkW Choline
Methionirle
69487 82 520
2773.3 28319
incorporate
methylation of phosphatidylethanolamine reported that the ability of lung tissue ethanolamine
65 times
than lung microsomesls.
increases
markedly
more
methionine
methyl
into
Such data in vitro tend to show that
is greater in liver than lung. It has been homogenates to methylate phosphatidyl-
during gestation
with a concomitant
decline in the
activity of the CDP-choline pathway3. Since no data on net synthesis was given in this study one cannot determine the contribution of each pathway to lecithin synthesis. These data support the possibility (c) that the major pathway of lecithin synthesis ipt Go in lung tissue is via the CDP-choline pathway and not via methylation of phosphatidylethanolamine. The lecithin fatty
of lung tissue is composed
acids esterified
are palmitate
of a variety
to the glpcerylphosphorylcholine
43:/a, stearate
189;,
palmitoleate
of molecular
backbone
6y6, oleate
species.
The
in rat lung lecithin
1776, linoleate
694 and
arachidonate II:,;. These values are very similar to those reported by MORGAN, FINLEY AND FIALKOW’ for the lecithin of dog lung tissue. 75;$ of the fatty acids esterified to the surfactant lecithin are saturatedly19 indicating that it is probably a single molecular [Il1GH]choline tionated
species. Fig. I shows the pattern of phospholipid and L-I,Ue-“Clmethionine incorporation into
on a silicic acid column.
The fact that
the specific
phosphorus elution, lung lecithin frac-
activities
of LAVe+H]-
disint./min per @ml P
Fig. I. Silicic acid column elution of 4 h lung lecithin from Table I. 10 ml fractions were collected; 0.5 ml was taken from every other fraction for phosphorus determination. At the points indicated 5.ml aliquots were dried down and radioactivity determined. Phosphorus (O----O); specific activities (disint./min per ,ugatom lipid P) of [MeQH]choline (x---x ), L-[MG4C]methionine (A-A). (Sphingomyelin, [MGH]choline roe I 73 disint./min per /“atom lipid P, L- [Me-W]methionine 1008 disint./min per ,uatom lipid P.)
Biochim. Biophvs. .dcta. I j2 (1968)
552-558
LUNG LECITHIN
SYNTHESIS
in ViVO
choline
and L-[Me-14C]methionine
elution
argues very strongly
557 do not parallel
that
lung lecithin
each
other
nor the phosphorus
is a heterogeneous
mixture.
Similar
of liver lecithin. Also, have been reported by othersZ0q2r in fractionation studie+ of lecithin elution from a silicic acid column have shown that containing the most unsaturated fatty acids are eluted first and lecithins
findings detailed lecithins containing
mostly
saturated
fatty
acids are eluted
last.
Thus
it appears
that
the
lecithin of lung tissue is a heterogeneous mixture (possibility (d) above) and the highly unsaturated lecithins are synthesized viu methylation of phosphatidylethanolamine while the highly
saturated
No final conclusions,
lecithins
however,
are synthesized
concerning
via the CDP-choline
the lecithin of surfactant
pathway.
can be made until
it and the appropriate molecular species in lung tissue are compared. The finding of L-[Me-14C]methionine radioactivity in phosphatidyl-N,N-dimethylethanolamine
isolated
from
lung suggests
that
this compound
mediate in the stepwise methylation of phosphatidylethanolamine. L-[Me-laC]nlethionine incorporation (Table I) into this compound gests that the turnover these time periods mediate.
of methionine
one would expect
BALDESSARINI~~ has assayed
onine. Liver contains
methyl
is an inter-
The increase in from z to 4 h sug-
in the lung may be relatively
to see maximum a number
incorporation
slow. At
into an inter-
of rat tissues for S-adenosylmethi-
26 pg/g wet weight while lung contains
II pug/gwet weight. This
would tend to exclude the lack of immediate precursor for slow methionine methyl turnover but might imply less methyltransferase enzyme in lung tissue (possibility (e) above). Using tidylethanolamine of ethanolamine to exclude
[r,z-r4C,]ethanolamine there is much less conversion of phosphato lecithin in lung as compared to liver”. The similar incorporation and the methyl
the possibility
in methylation
group of methionine
of a methyl
of phosphatidylethanolamine
Lung lecithin
is a heterogeneous
into lung lecithin”
donor other than methionine in lung (possibility
mixture
of molecular
would tend
being involved
(f) above).
species synthesized
by
both the methylation of phosphatidylethanolamine and the CDP-choline pathway. It appears under the conditions of the present experiment ilz z&lo that methylation of phosphatidylethanolamine lecithin. synthesis
The data further
is of minor importance
in the synthesis
of lung tissue
show that liver is not the source of lung lecithin
occurs in situ mainly
Z&Zthe CDP-choline
and that
pathway.
ACKNOWLEDGEMENTS
The authors gratefully acknowledge the encouragement and guidance of Dr. J. M. MCKIBBIN throughout this investigation as well as the editorial criticisms of Dr. G. SACHS. This study was supported by a grant from the National Science Foundation GB-4765, U.S. Public Health Service Training Grant in Gastroenterology ~A-5286 and U.S. Public Health Service General Support Grant FR 05349. A portion of this work was conducted in the Clinical Research Center Laboratory of the University of Alabama Medical Center supported by the National Institutes of Health Grant ZMOI-FR-3207.
Biochim.
Riopl~ys.
Acta,
151 (1968)
552-558
H. I.. SPITZER,
55s
I<. MORRISON,
J. R. NORMAN
REFERENCES I z 3 4 5 6 7 8 g IO II IZ 13
14 15 16 17 18 Ig 20 21 PL
T. E. MORGAN, T. N. FINLEY AND H. FIALKOX~T, Biochirn. Bioph>~s. .4&a, 106 (1965) 403. A. NAIMARK AND D. KLASS, Car!. J. Phvsiol. Phawxacol., 45 (1967) 597. L. GLUCK .~ND M. SRIBNEY, Physiologist, 8 (1965) 174. J. X. CLERIENTS, Develop~nent of the Lang, Churchill, London, 1967, p. 202. J. A. BALINT, W. L. NYHAN, P. LIETMAN AND D. A. TURNER, J. Lab. Clin. Med., 58 (1961) 5-18 J. A. BALINT, D. A. BEELER, D. H. TREBLE AKD H. L. SPITZER, J. Lipid Res., 8 (1967) 486. V. P. SKIPSKI, R. F. PETERSON, J. SUNDERS AND M. BARCLAY, J. Lipid Res., 4 (1963) 227. P A. WEINHOLD AND C. A. VILLEE, Biochim. Bioplrys. Acta, 106 (1965) 540. J. R. NORMAN, S. D. BRIGGS AND R. A. .~VENT, Clin. Res., I.+ (1967) 105. J. BREI\IER, P. H. FIGARD AND D. RI. GREENBERG, B&him. Biophys. Acta, 43 (1960) 477. D. P. GROTH, J. A. BAIN AND C. C. PFEIFFER, J. Phawnacol. Exptl. Thevap., 124 (1958) zgo. J. A. STEKOL, S. WEISS, P. S~IITH AND K. \VEISS, ,I. Biol. Ckern., 201 (1953) 299. J. A. &IUNTZ, J. Biol. Chem., 182 (1950) 489. 11. 11. DILS AND H. HUBSCHER, Biochin~. BiopBys. Acta, 46 (1961) 505. J. D. WILSON, I-C. D. GIBSON AND S. UDENFRIEND, J. Biol. C&n., 235 (1960) 3213. E. P. KENNEDY AND S. B. WEISS, J. Biol. Chew., 22~ (1956) 193. P. BJG~RNSTAD AND J. BREMER, ,I. Lipid Res., 7 (1966) 38. J. BREMER AND D. M. GREENBERG, Biochim. Biophys. Acta, 46 (1961) 205. M. E. ABRAMS, J. A$#. Physiol., LI (1966) 718. M. ISOZAKI, A. YA~XAIXOTO, T. AMAKO, Y. SAKAI AND H. OKITA, Med. J. Osaka l_rm,,., IL (1962) 285. J. L. GLENN, E. OPALKA AND Ii. J. TISCHER, J. Biol. Ckewz., 238 (1963) 12.+9. R. J. BALDESSARINI, Biochewt. Phavnzacol., 15 (1966) 741.
Biochim.
Bioph_v~. .4cfa, 152 (1968) 552-558