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Lipid molecular species composition of thylakoid membranes
12
Biochimica et Biophysics @ Elsevier/North-Holland
Acta, 617 (1980) Biomedical Press
12-19
BBA 57492
LIPID MOLECULAR MEMBRANES
MASATERU Research
NISHIHARA,
Institute
(Received
SPECIES
KAZUSHIGE
for Food Science,
June 18th,
COMPOSITION
OF THYLAKOID
YOKOTA
Kyoto
and MAKOTO
University,
Uji, Kyoto
KIT0 611 (Japan)
1978)
Key words: Lipid composition; (Chloroplast membrane)
Molecular
species; Galactosyl
acylglycerol;
Phospholipid;
Summary Lipid molecular species compositions of chloroplast thylakoid membranes of mesophyll cells from Spinacia oleracea, Glycine max, Oryza sativa and Zea mays and of bundle sheath cells from Zea mays have been quantitatively determined. No significant difference in the lipid molecular species composition was found among the five membrane sources. The predominant molecular species of monogalactosyldiacylglycerol was the l-linolenoyl1.2linolenoyl species. The l-linolenoyl12-linolenoyl and l-palmitoylQ2-linolenoyl species were the major molecular species of digalactosyldiacylglycerol. 6-Sulfoquinovosyldiacylglycerol was mainly composed of the palmitoyl//linolenoyl and palmitoyl// linoleoyl species. Almost all of the C-2 position of phosphatidylglycerol were esterified with the palmitoyl or A3-trans-hexadecenoyl residue. The molecular species compositions of phosphatidylcholine and phosphatidylinositol were basically similar to those of membranes in non-photosynthetic tissues.
Introduction Lipid composition of chloroplasts is extremely different from those of other intracellular organelles. Glycolipid is the major lipid class, and phospholipid is a minor component. Chloroplasts are composed of thylakoid and envelope membranes. Although monogalactosyldiacylglycerol and digalactosyldiacylglycerol
.4bbreviations: 16
:
3,
a-linolenic
14
: 0.
myristic
7,10,13-hexadecatrienoic acid.
acid; acid;
16 18
: 0, : 0.
palmitic stearic
acid; acid;
A3-trans-16 18
: 1, oleic
:
1,
acid;
A3-trans-hexadecenoic 18
: 2.
linoleic
acid;
acid; 18
: 3,
13
are the major components of these membranes [ 1,2], 6-sulfoquinovosyldiacylglycerol and phosphatidylglycerol are localized in the thylakoid membranes [l-3]. It is interesting to compare the lipid molecular species composition of the thylakoid membranes from several plant species for an understanding of the function of the membranes in photosynthesis. In this paper, we describe the lipid molecular species compositions of the thylakoid membranes prepared from Spinacia oleracea, Glycine max, Oryza sativa and Zea mays. Materials and Methods Chemicals. Phospholipase C (Bacillus cereus) was purchased from Calbiothem. Phospholipase AZ (Crotalus admanteus) was from Boehringer Mannheim. Heptadecanoic acid was the product of Applied Science. Thin-layer plates (Art. 5721, 5724 and 11845) were purchased from Merck. Plant material. Spinach (S. oleracea L. var. Viroflay, 42 days old), soybean (G. max L. merr. var. Tsurunoko, 42 days old), rice plant (0. sativa L. var. Nipponbare, 40 days old) and maize (2. mays L. var. Honey Buntum, 45 days old) were used for experiments. These plants were grown in the experimental farm of the Research Institute for Food Science, Kyoto University. Preparation of thylakoid membranes and lipid extraction. The leaves of S. oleracea, G. max and 0. satiua and 2. mays leaves were homogenized at 3°C according to Jensen and Bassham [ 41 and Woo et al. [ 51, respectively, just after the leaves were picked off the plants. Intact chloroplasts were prepared from mesophyll cells [4] and bundle sheath cells [ 51. The envelope membranes were removed by osmotic shock [6] and the thylakoid membranes were purified by differential centrifugation [2]. Lipids were extracted by the method of Bligh and Dyer [ 71. Lipid extract was washed twice with 2 M KCl. Separation and purification of lipid classes. Lipid classes were purified by using DEAE-cellulose column chromatography [ 81 followed by thin-layer chromatography. The solvent systems used for the purification of each lipid by thin-layer chromatography were as follows: monogalactosyldiacylglycerol by CHC1&H30H/CH3COCH3/H,0/CH$OOH (200 : 50 : 60 : 5 : 2, v/v), digalactosyldiacylglycerol, phosphatidylcholine, phosphatidylinositol and phosphatidic acid by CHC1&H30H/CH3COOH (65 : 25 : 8, v/v), 6-sulfoquinovosyldiacylglycerol and phosphatidylglycerol by CHC13/CH30H/28% NH,OH (200 : 120 : 15, v/v). Phospholipase reaction. Phospholipids were hydrolyzed by phospholipase C [ 91 or phospholipase AZ [lo]. Analysis of molecular species. Analysis of phospholipid molecular species composition was carried out as previously [9,11]. Further resolution of the phosphatidylglycerol molecular species composition was performed by using phospholipase AZ [lo]. The molecular species of monogalactosyldiacylglycerol and digalactosyldiacylglycerol were separated on AgNO,-plates [9] by using CHC1&H30H/Hz0 (120 : 47 : 8, v / v ) as a developing solvent. Separation of the 6sulfoquinovosyldiacylglycerol molecular species on AgN03-plate was performed by using a solvent system CHC1&H30H (250 : 100, v/v) after the lipid had been acetylated by acetic anhydride and pyridine [9]. The visualiza-
14
tion of the subfractions on the plates was performed as previously [9]. Lipid was extracted from each subfraction by using CHC13/CH30H (2 : 1, v/v) after the subfraction had been scraped off from the plate. Fatty acid methyl esters were prepared from the lipid extract and analyzed by gas-liquid chromatography [ 111. For the quantitative analysis, a known amount of heptadecanoic acid had been added to each subfraction before it was scraped off from the plate. Positional distribution of fatty acids in the molecular species was determined by gas-liquid chromatography/mass spectrometry analysis of monoacetyldiacylglycerol [ 91. The monoacetyldiacylglycerol was prepared from 1,2diacylglycerol [9] which was the product of 2% H,S04-hydrolysis of galactolipids [ 121. For the determination of the 6-sulfoquinovosyldiacylglycerol molecular species, fatty acid composition of each subfraction was analyzed. Determination of lipid composition. An appropriate amount of lipid extract was applied on a thin-layer plate and separated by two-dimensional chromatography [ 111. Sugar [ 131, phosphorus [ 141 and sulfur [15] were determined in separated subfractions. Results Lipid composition
Thylakoid membranes in mesophyll cells of S. oleracea, G. max, 0. sativa and 2. mays are composed of stroma and grana lamellae, but the membranes of 2. mays bundle-sheath cells lack grana lamellae. These thylakoid membranes had similar lipid compositions except for those from the bundle-sheath cells (Table I). Major lipids were monogalactosyldiacylglycerol (38-44%), digalactosyldiacylglycerol (24-30%), 6-sulfoquinovosyldiacylglycerol (14-18s) and phospholipids (15-19s). Phosphatidylglycerol was the major class of phospholipids. The lipid composition of bundle-sheath cells is different from those of mesophyll cells. The most remarkable difference is the high content of phosphatidic acid. It is unlikely that phosphatidic acid was produced by hydrolysis of phospholipids by phospholipase D in leaves during preparation of lipids as we will describe afterwards. Although unidentified glycolipid subfractions were TABLE LIPID ND,
I COMPOSITION
not
detected;
OF T. trace.
Lipids
THYLAKOID AU values
MEMBRANES are mol%.
s. oleracea
G. max
0.
satiua
z. mays Mesophyll
Bundle
Monogalactosyldiacylglycerol
38
39
44
40
30
Digalactosyldiacylglycerol
29
28
24
30
23
14
17
14
10
11
11
8
10
10
Phosphatidylcholine
3
3
3
1
6
Phosphatidylinositol
1
2
1
1
T
Phosphatidylethanolamine
ND
ND
Phosphatidic
T
6-Sulfosuinovosyldiacylglycerol lB Phosphatidylglycerol
acid
3
T
ND 3
4
2 19
sheath
15
TABLE
II
MOLECULAR
SPECIES
Molecular 2-18 ND,
species
: 1,
: O//2-18
1-16
not
detected;
Molecular
species
C-l 16 18 18
less
COMPOSITION than
5%
: 2,
1-18
T. trace.
All
s.
OF
were
: O//2-18 values
MONOGALACTOSYLDIACYLGLYCEROL
omitted
from
: 2.
the
Table.
: O//2-18
1-18
: 3,
These 1-18
molecular
: l//2-18
and
oleracea
G. nwx
1-16
: O//
:
2//2-18
: 3.
z. moys
sotiua
0.
MesophyU
:3 :3 :3
were
1-18
are mol%.
c-2
: O//18 : 3//18 : 3//16
species
:3
Bundle
2
6
55
82
89
92
83
36
ND
ND
ND
ND
1
4
sheath
I
detected on a thin-layer plate, the sum of sugar content of the subfractions was less than 5% of that of the known glycolipids. Phosphorus could not be detected in any unidentified subfractions. Sulfur was only detected in the subfraction of 6-sulfoquinovosyldiacylglycerol. Galactolipid molecular species composition The galactolipid molecular species compositions are shown in Tables II and III. The predominant molecular species of monogalactosyldiglyceride of the five thylakoid membranes was the 1-18 : 312-18 : 3 species. The lipid from 5’. olerucea contained the molecular species of which C-2 position was esterified with 16 : 3, a lower homologue of 18 : 3 [16]. Thus, the molecular species of monogalactosyldiacylglycerol was basically composed of the 1-18 : 312-18 : 3 species except that of S. oleracea. The 1-18 : 312-18 : 3 and 1-16 : 012-18 : 3 species were the most abundant species in digalactosyldiacylglycerol. However, the amount of the 1-18 : 31216 : 3 species in digalactosyldiglyceride of S. olerucea was much smaller than that in monogalactosyldiglyceride. 6-Sulfoquinovosyldiacylglycerol molecular species composition It was impossible to convert 6-sulfoquinovosyldiacylglycerol to monoacetyldiacylglycerol, since diacylglycerol was not formed from this lipid by 2% TABLE
III
MOLECULAR
SPECIES
Molecular 18
: 1.
species l-18
less
: O//2-18
COMPOSITION than : 2,
5%
1-18
were
:
l//2-18
OF
DIGALACTOSYLDIACYLGLYCEROL
omitted
from
:3
and
1-18
the
Table.
:
2112-18
These
: 3.
molecular ND.
not
species
detected;
were
: O//2-
1-16
T. trace.
All
values
are mol%. Molecular C-l 16 16 18 18 18
species
s.
oleraceo
G. max
satiua
0.
c-2
: O//18 : O//18 : O//18 : 31118 : 3//16
z. mays Mesophyl
:2 :3 :3 :3 :3
6 13 1 64 6
T 24 7
11 13 4
1 24 2
Bundle 8 19 T
64
66
69
64
ND
ND
ND
ND
sheath
16
TABLE
IV
MOLECULAR Molecular 18
SPECIES species
less
:3
18
: l//18
Molecular
and
COMPOSITION than
:
2//18
5%
:
were
OF
3. T, trace.
from
All
the
values
Table,
These
molecular
species
were
0.
sativa
16 16 16 18
: O//16 : O//l8 : O//18 : O//18 : O//18
: 0
T
T
:1 :2 :3 :3
7
3
15
10
75
71
T
: O//18
:
2,
%. mays Mesophyll
16
18
are mol%.
G. max
s. oleracea
species
6-SULFOQUINOVOSYLDIACYLGLYCEROL
omitted
29 T 8 63
14
T
Bundle
T
T
T
T
33
33
62
67
T
sheath
T
H,S04-hydrolysis. Therefore, we could not determine the positional distribution of fatty acids in the molecular species subfractions obtained by thin-layer chromatography (Table IV). No similarity was detected between the molecular species compositions of 6-sulfoquinovosyldiacylglycerol and galactolipids. The 18 : 3118 : 3 species was not detected. Major molecular species were the 16 : 0118 : 3 and 16 : 0118 : 2. The 16 : 0116 : 0 species was one of the major molecular species of 6*ulfoquinovosyldiacylglycerol from 0. sutiua. Phosphatidylglycerol molecular species composition Table V shows the molecular species composition of phosphatidylglycerol. The molecular species composition was different from those of other phospholipids in the thylakoid membranes. The species of which C-2 position was esterified with 16 : 0 and A3-trans-16 : 1 were the major molecular species. Generally, saturated and unsaturated fatty acids are distributed in phospholipid molecules in such a way that a saturated fatty acid is esterified to C-l position and unsaturated fatty acid to C-2 position [9,11,17-191. However, TABLE
V
MOLECULAR
SPECIES
Molecular 16 1-18
: 0.
species 1-18
: l//2-18
Molecular
16
: O//16 : 0 : O/lA3-trans-16 : O//A3-trans-16 : l//16 : 0 : l//A3-trans-16 : 21116 : 0 : 2//63-trans-16 : 31116 : 0 : 3/lA3-trans-16 : 21118 : 3
18 18 18 18 18 18 18
5%
s.
species c-2
18
COMPOSITION than
were
OF
oleracea
PHOSPHATIDYLGLYCEROL
omitted
: O//2-18 : 1, 1-18 : O//2-18 : 3, 1-18 : 2112-18 : 2 and
C-l
16
less
from
:
2,
1-18
the
Table.
These
: l//2-18 : 1, : 3112-18 : 3 T, trace. l-18
G. l?mY
0. satiua
molecular
l-18 All
z.
values
4
: :
1 1
:1
10
T 43
18 19
T
15
T
3
3
5
1
28
5
T 39 13 7 14
: 3,
Bundle 34 22 1 T 1
1
17
5
1
5
6
2
8
3
2
T
2
4
10 T
4
1
T
3
10 T
l-18 : O//2: l//2-18 : 2,
are mol%.
5
16
were l-18
mays
Mesophyll
:1 :1
species
: O//2-18
4 21
sheath
17 TABLE
VI
MOLECULAR Molecular 18
: 1,
:
1-18
Molecular C-l
SPECIES COMPOSITION
species
less than
l//2-18
species
:
l,l-18
s.
OF PHOSPHATIDYLCHOLINE
5% were omitted
:
l//2-18
:2
from
and 1-18
G. max
oleracea
the Table.
: l//2-18
These molecular
: 3.
0. satiua
z.
C-2
16 : O//18 16 : O//18 18 : O//l8 16 : O//18 18 : O//18 18 : 21118 18 : 21118 18 : 3//18
:1 :2 :2 :3 :3 :2 :3 :3
10 18 2 21 3 1 13 8
4 22 18 20 4 13 9 3
species
were 1-18
: O//2-
T, trace. All values are molW.
6 26 11 17 10 10 5 5
mays
Mesophyl
Bundle sheath
6 31 2 26 5 8 6 4
6 39 1 23 6 7 10 3
phosphatidylglycerol was composed for a considerable amount of the molecular species esterified with 16 : 0 at C-2 position and an unsaturated fatty acid at C-l position. Molecular species compositions of phosphatidylcholine and phosphatidylinositol The molecular species compositions of phosphatidylcholine and phosphatidylinositol (Tables VI and VII) were similar to those from non-photosynthetic tissues [11,17,18]. Fatty acid composition of phosphatidic acid No remarkable differences were found in the fatty acid composition of phosphatidic acid (Table VIII). It is unlikely that phosphatidic acid was formed by hydrolysis of phospholipids by phospholipase D in leaves, since A3-trans-16 : 1 was not detected.
TABLE
VII
MOLECULAR
SPECIES
COMPOSITION
OF PHOSPHATIDYLINOSITOL
Molecular species less than 5% were omitted from the Table. These molecular 18 : 1. l-18 : l//2-18 :l, 1-18 : l//2-18 : 2, 1-18 : l//2-18 : 3, 1-18 : 2//2-18
species were and 1-18
:2
:
1-18 : O//22//2-18 : 3.
T, trace. All values are mol%. Molecular C-l 16 16 18 16 18 18
species
s. oleracea
G. max
0. sativa
c-2
: O//18 : O//l8 : O//l8 : O//18 : O//l8 : 3//18
:1 :2 :2 :3 :3 :3
* Phosphatidylinositol
13 40 2 32 T 8 content
T 35 10 42 13 T of the lipids
T 10 1 58 10 20 from
bundle-sheath
z. mays Mesophyll
Bundle
4 40 9 35 7 T
-
cells was trace as described
sheath *
in Table
I.
18 TABLE
VIII
FATTY
ACID
ND,
detected;
not
Fatty
COMPOSITION T, trace.
OF All
s. oleracea
acid
PHOSPHATIDIC
values
ACID
are %.
*
G. max
0.
sativa
z.
may.5 Bundle
Mesophyll
14
:0
16
: 0
A3-tram-16
I
:I
-
18: 0 18 : 1 18:
2
18
:3 :3
16
* Phosphatidic
21
37
34
31
ND
ND
ND
ND
9
6
6
2
4
7
7
32
acid
content
of lipids
from
T
T
T
33
2
29
38
27
17
24
27
ND
ND
ND
ND
S. oleracea
was trace
as described
sheath
in Table
I.
Discussion The positional specificity of 16 : 0 in galactolipids of spinach was determined to be the C-2 position by using pancreatic [20] and Rhizopus [21] lipase, but specific positional distribution of this fatty acid at C-l position was also described by using pancreatic lipase [22]. We determined the galactolipid molecular species by gas-liquid chromatography/mass spectrometry analysis as described in Methods, and 16 : 0 was found to be in C-l position. The discrepancy may be due to the differences between analytical methods. The molecular species composition of phosphatidylglycerol was unique. Haverkate and van Deenen [lo] described the molecular species composition of phosphatidylglycerol extracted from the leaves of S. olerucea. In their experiments, A3-truns-16 : 1 was located at C-2 position and the 1-18 : 312-A3truns-16 : 1 species was the most abundant one. Our results are consistent with theirs. The other major molecular species in their results were the 1-18 : 31216 : 0 and 1-16 : 002-18 : 2 species. In our experiments, the molecular species containing unsaturated fatty acids and 16 : 0 were only 1-unsaturated12-16 : 0 species. Probably, the 1-16 : O//2-unsaturated fatty acyl species which they detected might be obtained from phosphatidylglycerol of the other intracellular organelles in the leaf cells. It has been assumed that A3-truns-16 : 1 is produced from the esterified 16 : 0 of phosphatidylglycerol [23]. The species containing 16 : 0 in Table V may be precursors of the species containing A3tram-16 : 1. Therefore, we may conclude that almost all of the C-2 positions of the molecular species of phosphatidylglycerol are esterified with A3-truns16 : 1 and its precursors. Probably, phosphatidylglycerol esterified with A3truns-16 : 1 at C-2 position may be required for thylakoid membrane function. Acknowledgement This work was supported by a grant for Scientific Research from the Ministry of Education of Japan.
19
References 1 Poincerot, R.P. (1973) Arch. Biochem. Biophys. 159, 134-142 2 Mackender, R.O. and Leech, R.M. (1974) Plant Physiol. 53.496-502 3 Poincerot, R.P. (1976) Plant Physiol. 58, 595-598 4 Jensen, R.G. and Bassham, J.A. (1966) Proc. Natl. Acad. Sci. 56, 1095-1101 5 Woo, K.C.. Anderson. J.M., Boardman, N.K., Downton, W.J.S., Osmond. C. and Tborne, S.W. (1970) Proc. Natl. Acad. Sci. 67, 18-25 6 Poincerot, R.P. and Peter. R.D. (1974) Plant Physiol. 54, 780-783 7 Bligh, E.G. and Dyer, W.J. (1959) Can. J. Biochem. Physiol. 37, 911-917 8 Allen, F., Good, P., Davis. H.F. and Fowler, S.D. (1964) Biochem. Biophys. Res. Commun. 15, 424~ 430 9 Kito, M., Ishinaga, M., Nishihara, M., Kato. M., Sawada. S. and Hata, T. (1975) Eur. J. Biochem. 54, 55--63 10 Haverkate. F. and van Deenen, L.L.M. (1965) Biochim. Biophys. Acta 106. 78-92 11 Nishihara, M. and Kito. M. (1978) Biochim. Biophys. Acta. 531, 25m-31 12 Noda. M. and Fujiwara, N. (1967) Biochim. Biophys. Acta 137, 199-201 13 Rougban, P.G. and Batt, R.D. (1968) Anal. Biochem. 22, 74 -88 14 Keenan, R.W., Schmidt, G. and Tanaka, T. (1968) Anal. Biochem. 23, 555-566 15 Kean, E.L. (1968) J. Lipid Res. 9, 319.-327 16 Stumpf. P.K. (1975) in Recent Advances in the Chemistry and Biochemistry of Plant Lipids. PP. 95m113. Academic Press, New York 17 Gregor, H.D. (1977) Phytochemistry 16,953-955 18 Gregor, H.D. (1977) Chem. Phys. Lipids 20. 77-85 19 Cronan. J.E., Jr. (1978) Ann. Rev. Biochem. 47, 163.. 189 20 Safford, R. and Nichols B.W. (1970) Biochim. Biophys. Acta 210. 5744 21 Sieberg, H.P. and Heiz, E. (1977) Z. Naturforsch. 32C. 193-205 22 Auling. G., Heinz, E. and Tulloch, A.P. (1971) Hoppe-Seylers Z. Physiol. Chem. 352, 905412 23 Getz. G.S. (1970) Adv. Lipid Res. 8, 175-223
Biochimica et Biophysics @ Elsevier/North-Holland
Acta, 617 (1980) Biomedical Press
12-19
BBA 57492
LIPID MOLECULAR MEMBRANES
MASATERU Research
NISHIHARA,
Institute
(Received
SPECIES
KAZUSHIGE
for Food Science,
June 18th,
COMPOSITION
OF THYLAKOID
YOKOTA
Kyoto
and MAKOTO
University,
Uji, Kyoto
KIT0 611 (Japan)
1978)
Key words: Lipid composition; (Chloroplast membrane)
Molecular
species; Galactosyl
acylglycerol;
Phospholipid;
Summary Lipid molecular species compositions of chloroplast thylakoid membranes of mesophyll cells from Spinacia oleracea, Glycine max, Oryza sativa and Zea mays and of bundle sheath cells from Zea mays have been quantitatively determined. No significant difference in the lipid molecular species composition was found among the five membrane sources. The predominant molecular species of monogalactosyldiacylglycerol was the l-linolenoyl1.2linolenoyl species. The l-linolenoyl12-linolenoyl and l-palmitoylQ2-linolenoyl species were the major molecular species of digalactosyldiacylglycerol. 6-Sulfoquinovosyldiacylglycerol was mainly composed of the palmitoyl//linolenoyl and palmitoyl// linoleoyl species. Almost all of the C-2 position of phosphatidylglycerol were esterified with the palmitoyl or A3-trans-hexadecenoyl residue. The molecular species compositions of phosphatidylcholine and phosphatidylinositol were basically similar to those of membranes in non-photosynthetic tissues.
Introduction Lipid composition of chloroplasts is extremely different from those of other intracellular organelles. Glycolipid is the major lipid class, and phospholipid is a minor component. Chloroplasts are composed of thylakoid and envelope membranes. Although monogalactosyldiacylglycerol and digalactosyldiacylglycerol
.4bbreviations: 16
:
3,
a-linolenic
14
: 0.
myristic
7,10,13-hexadecatrienoic acid.
acid; acid;
16 18
: 0, : 0.
palmitic stearic
acid; acid;
A3-trans-16 18
: 1, oleic
:
1,
acid;
A3-trans-hexadecenoic 18
: 2.
linoleic
acid;
acid; 18
: 3,
13
are the major components of these membranes [ 1,2], 6-sulfoquinovosyldiacylglycerol and phosphatidylglycerol are localized in the thylakoid membranes [l-3]. It is interesting to compare the lipid molecular species composition of the thylakoid membranes from several plant species for an understanding of the function of the membranes in photosynthesis. In this paper, we describe the lipid molecular species compositions of the thylakoid membranes prepared from Spinacia oleracea, Glycine max, Oryza sativa and Zea mays. Materials and Methods Chemicals. Phospholipase C (Bacillus cereus) was purchased from Calbiothem. Phospholipase AZ (Crotalus admanteus) was from Boehringer Mannheim. Heptadecanoic acid was the product of Applied Science. Thin-layer plates (Art. 5721, 5724 and 11845) were purchased from Merck. Plant material. Spinach (S. oleracea L. var. Viroflay, 42 days old), soybean (G. max L. merr. var. Tsurunoko, 42 days old), rice plant (0. sativa L. var. Nipponbare, 40 days old) and maize (2. mays L. var. Honey Buntum, 45 days old) were used for experiments. These plants were grown in the experimental farm of the Research Institute for Food Science, Kyoto University. Preparation of thylakoid membranes and lipid extraction. The leaves of S. oleracea, G. max and 0. satiua and 2. mays leaves were homogenized at 3°C according to Jensen and Bassham [ 41 and Woo et al. [ 51, respectively, just after the leaves were picked off the plants. Intact chloroplasts were prepared from mesophyll cells [4] and bundle sheath cells [ 51. The envelope membranes were removed by osmotic shock [6] and the thylakoid membranes were purified by differential centrifugation [2]. Lipids were extracted by the method of Bligh and Dyer [ 71. Lipid extract was washed twice with 2 M KCl. Separation and purification of lipid classes. Lipid classes were purified by using DEAE-cellulose column chromatography [ 81 followed by thin-layer chromatography. The solvent systems used for the purification of each lipid by thin-layer chromatography were as follows: monogalactosyldiacylglycerol by CHC1&H30H/CH3COCH3/H,0/CH$OOH (200 : 50 : 60 : 5 : 2, v/v), digalactosyldiacylglycerol, phosphatidylcholine, phosphatidylinositol and phosphatidic acid by CHC1&H30H/CH3COOH (65 : 25 : 8, v/v), 6-sulfoquinovosyldiacylglycerol and phosphatidylglycerol by CHC13/CH30H/28% NH,OH (200 : 120 : 15, v/v). Phospholipase reaction. Phospholipids were hydrolyzed by phospholipase C [ 91 or phospholipase AZ [lo]. Analysis of molecular species. Analysis of phospholipid molecular species composition was carried out as previously [9,11]. Further resolution of the phosphatidylglycerol molecular species composition was performed by using phospholipase AZ [lo]. The molecular species of monogalactosyldiacylglycerol and digalactosyldiacylglycerol were separated on AgNO,-plates [9] by using CHC1&H30H/Hz0 (120 : 47 : 8, v / v ) as a developing solvent. Separation of the 6sulfoquinovosyldiacylglycerol molecular species on AgN03-plate was performed by using a solvent system CHC1&H30H (250 : 100, v/v) after the lipid had been acetylated by acetic anhydride and pyridine [9]. The visualiza-
14
tion of the subfractions on the plates was performed as previously [9]. Lipid was extracted from each subfraction by using CHC13/CH30H (2 : 1, v/v) after the subfraction had been scraped off from the plate. Fatty acid methyl esters were prepared from the lipid extract and analyzed by gas-liquid chromatography [ 111. For the quantitative analysis, a known amount of heptadecanoic acid had been added to each subfraction before it was scraped off from the plate. Positional distribution of fatty acids in the molecular species was determined by gas-liquid chromatography/mass spectrometry analysis of monoacetyldiacylglycerol [ 91. The monoacetyldiacylglycerol was prepared from 1,2diacylglycerol [9] which was the product of 2% H,S04-hydrolysis of galactolipids [ 121. For the determination of the 6-sulfoquinovosyldiacylglycerol molecular species, fatty acid composition of each subfraction was analyzed. Determination of lipid composition. An appropriate amount of lipid extract was applied on a thin-layer plate and separated by two-dimensional chromatography [ 111. Sugar [ 131, phosphorus [ 141 and sulfur [15] were determined in separated subfractions. Results Lipid composition
Thylakoid membranes in mesophyll cells of S. oleracea, G. max, 0. sativa and 2. mays are composed of stroma and grana lamellae, but the membranes of 2. mays bundle-sheath cells lack grana lamellae. These thylakoid membranes had similar lipid compositions except for those from the bundle-sheath cells (Table I). Major lipids were monogalactosyldiacylglycerol (38-44%), digalactosyldiacylglycerol (24-30%), 6-sulfoquinovosyldiacylglycerol (14-18s) and phospholipids (15-19s). Phosphatidylglycerol was the major class of phospholipids. The lipid composition of bundle-sheath cells is different from those of mesophyll cells. The most remarkable difference is the high content of phosphatidic acid. It is unlikely that phosphatidic acid was produced by hydrolysis of phospholipids by phospholipase D in leaves during preparation of lipids as we will describe afterwards. Although unidentified glycolipid subfractions were TABLE LIPID ND,
I COMPOSITION
not
detected;
OF T. trace.
Lipids
THYLAKOID AU values
MEMBRANES are mol%.
s. oleracea
G. max
0.
satiua
z. mays Mesophyll
Bundle
Monogalactosyldiacylglycerol
38
39
44
40
30
Digalactosyldiacylglycerol
29
28
24
30
23
14
17
14
10
11
11
8
10
10
Phosphatidylcholine
3
3
3
1
6
Phosphatidylinositol
1
2
1
1
T
Phosphatidylethanolamine
ND
ND
Phosphatidic
T
6-Sulfosuinovosyldiacylglycerol lB Phosphatidylglycerol
acid
3
T
ND 3
4
2 19
sheath
15
TABLE
II
MOLECULAR
SPECIES
Molecular 2-18 ND,
species
: 1,
: O//2-18
1-16
not
detected;
Molecular
species
C-l 16 18 18
less
COMPOSITION than
5%
: 2,
1-18
T. trace.
All
s.
OF
were
: O//2-18 values
MONOGALACTOSYLDIACYLGLYCEROL
omitted
from
: 2.
the
Table.
: O//2-18
1-18
: 3,
These 1-18
molecular
: l//2-18
and
oleracea
G. nwx
1-16
: O//
:
2//2-18
: 3.
z. moys
sotiua
0.
MesophyU
:3 :3 :3
were
1-18
are mol%.
c-2
: O//18 : 3//18 : 3//16
species
:3
Bundle
2
6
55
82
89
92
83
36
ND
ND
ND
ND
1
4
sheath
I
detected on a thin-layer plate, the sum of sugar content of the subfractions was less than 5% of that of the known glycolipids. Phosphorus could not be detected in any unidentified subfractions. Sulfur was only detected in the subfraction of 6-sulfoquinovosyldiacylglycerol. Galactolipid molecular species composition The galactolipid molecular species compositions are shown in Tables II and III. The predominant molecular species of monogalactosyldiglyceride of the five thylakoid membranes was the 1-18 : 312-18 : 3 species. The lipid from 5’. olerucea contained the molecular species of which C-2 position was esterified with 16 : 3, a lower homologue of 18 : 3 [16]. Thus, the molecular species of monogalactosyldiacylglycerol was basically composed of the 1-18 : 312-18 : 3 species except that of S. oleracea. The 1-18 : 312-18 : 3 and 1-16 : 012-18 : 3 species were the most abundant species in digalactosyldiacylglycerol. However, the amount of the 1-18 : 31216 : 3 species in digalactosyldiglyceride of S. olerucea was much smaller than that in monogalactosyldiglyceride. 6-Sulfoquinovosyldiacylglycerol molecular species composition It was impossible to convert 6-sulfoquinovosyldiacylglycerol to monoacetyldiacylglycerol, since diacylglycerol was not formed from this lipid by 2% TABLE
III
MOLECULAR
SPECIES
Molecular 18
: 1.
species l-18
less
: O//2-18
COMPOSITION than : 2,
5%
1-18
were
:
l//2-18
OF
DIGALACTOSYLDIACYLGLYCEROL
omitted
from
:3
and
1-18
the
Table.
:
2112-18
These
: 3.
molecular ND.
not
species
detected;
were
: O//2-
1-16
T. trace.
All
values
are mol%. Molecular C-l 16 16 18 18 18
species
s.
oleraceo
G. max
satiua
0.
c-2
: O//18 : O//18 : O//18 : 31118 : 3//16
z. mays Mesophyl
:2 :3 :3 :3 :3
6 13 1 64 6
T 24 7
11 13 4
1 24 2
Bundle 8 19 T
64
66
69
64
ND
ND
ND
ND
sheath
16
TABLE
IV
MOLECULAR Molecular 18
SPECIES species
less
:3
18
: l//18
Molecular
and
COMPOSITION than
:
2//18
5%
:
were
OF
3. T, trace.
from
All
the
values
Table,
These
molecular
species
were
0.
sativa
16 16 16 18
: O//16 : O//l8 : O//18 : O//18 : O//18
: 0
T
T
:1 :2 :3 :3
7
3
15
10
75
71
T
: O//18
:
2,
%. mays Mesophyll
16
18
are mol%.
G. max
s. oleracea
species
6-SULFOQUINOVOSYLDIACYLGLYCEROL
omitted
29 T 8 63
14
T
Bundle
T
T
T
T
33
33
62
67
T
sheath
T
H,S04-hydrolysis. Therefore, we could not determine the positional distribution of fatty acids in the molecular species subfractions obtained by thin-layer chromatography (Table IV). No similarity was detected between the molecular species compositions of 6-sulfoquinovosyldiacylglycerol and galactolipids. The 18 : 3118 : 3 species was not detected. Major molecular species were the 16 : 0118 : 3 and 16 : 0118 : 2. The 16 : 0116 : 0 species was one of the major molecular species of 6*ulfoquinovosyldiacylglycerol from 0. sutiua. Phosphatidylglycerol molecular species composition Table V shows the molecular species composition of phosphatidylglycerol. The molecular species composition was different from those of other phospholipids in the thylakoid membranes. The species of which C-2 position was esterified with 16 : 0 and A3-trans-16 : 1 were the major molecular species. Generally, saturated and unsaturated fatty acids are distributed in phospholipid molecules in such a way that a saturated fatty acid is esterified to C-l position and unsaturated fatty acid to C-2 position [9,11,17-191. However, TABLE
V
MOLECULAR
SPECIES
Molecular 16 1-18
: 0.
species 1-18
: l//2-18
Molecular
16
: O//16 : 0 : O/lA3-trans-16 : O//A3-trans-16 : l//16 : 0 : l//A3-trans-16 : 21116 : 0 : 2//63-trans-16 : 31116 : 0 : 3/lA3-trans-16 : 21118 : 3
18 18 18 18 18 18 18
5%
s.
species c-2
18
COMPOSITION than
were
OF
oleracea
PHOSPHATIDYLGLYCEROL
omitted
: O//2-18 : 1, 1-18 : O//2-18 : 3, 1-18 : 2112-18 : 2 and
C-l
16
less
from
:
2,
1-18
the
Table.
These
: l//2-18 : 1, : 3112-18 : 3 T, trace. l-18
G. l?mY
0. satiua
molecular
l-18 All
z.
values
4
: :
1 1
:1
10
T 43
18 19
T
15
T
3
3
5
1
28
5
T 39 13 7 14
: 3,
Bundle 34 22 1 T 1
1
17
5
1
5
6
2
8
3
2
T
2
4
10 T
4
1
T
3
10 T
l-18 : O//2: l//2-18 : 2,
are mol%.
5
16
were l-18
mays
Mesophyll
:1 :1
species
: O//2-18
4 21
sheath
17 TABLE
VI
MOLECULAR Molecular 18
: 1,
:
1-18
Molecular C-l
SPECIES COMPOSITION
species
less than
l//2-18
species
:
l,l-18
s.
OF PHOSPHATIDYLCHOLINE
5% were omitted
:
l//2-18
:2
from
and 1-18
G. max
oleracea
the Table.
: l//2-18
These molecular
: 3.
0. satiua
z.
C-2
16 : O//18 16 : O//18 18 : O//l8 16 : O//18 18 : O//18 18 : 21118 18 : 21118 18 : 3//18
:1 :2 :2 :3 :3 :2 :3 :3
10 18 2 21 3 1 13 8
4 22 18 20 4 13 9 3
species
were 1-18
: O//2-
T, trace. All values are molW.
6 26 11 17 10 10 5 5
mays
Mesophyl
Bundle sheath
6 31 2 26 5 8 6 4
6 39 1 23 6 7 10 3
phosphatidylglycerol was composed for a considerable amount of the molecular species esterified with 16 : 0 at C-2 position and an unsaturated fatty acid at C-l position. Molecular species compositions of phosphatidylcholine and phosphatidylinositol The molecular species compositions of phosphatidylcholine and phosphatidylinositol (Tables VI and VII) were similar to those from non-photosynthetic tissues [11,17,18]. Fatty acid composition of phosphatidic acid No remarkable differences were found in the fatty acid composition of phosphatidic acid (Table VIII). It is unlikely that phosphatidic acid was formed by hydrolysis of phospholipids by phospholipase D in leaves, since A3-trans-16 : 1 was not detected.
TABLE
VII
MOLECULAR
SPECIES
COMPOSITION
OF PHOSPHATIDYLINOSITOL
Molecular species less than 5% were omitted from the Table. These molecular 18 : 1. l-18 : l//2-18 :l, 1-18 : l//2-18 : 2, 1-18 : l//2-18 : 3, 1-18 : 2//2-18
species were and 1-18
:2
:
1-18 : O//22//2-18 : 3.
T, trace. All values are mol%. Molecular C-l 16 16 18 16 18 18
species
s. oleracea
G. max
0. sativa
c-2
: O//18 : O//l8 : O//l8 : O//18 : O//l8 : 3//18
:1 :2 :2 :3 :3 :3
* Phosphatidylinositol
13 40 2 32 T 8 content
T 35 10 42 13 T of the lipids
T 10 1 58 10 20 from
bundle-sheath
z. mays Mesophyll
Bundle
4 40 9 35 7 T
-
cells was trace as described
sheath *
in Table
I.
18 TABLE
VIII
FATTY
ACID
ND,
detected;
not
Fatty
COMPOSITION T, trace.
OF All
s. oleracea
acid
PHOSPHATIDIC
values
ACID
are %.
*
G. max
0.
sativa
z.
may.5 Bundle
Mesophyll
14
:0
16
: 0
A3-tram-16
I
:I
-
18: 0 18 : 1 18:
2
18
:3 :3
16
* Phosphatidic
21
37
34
31
ND
ND
ND
ND
9
6
6
2
4
7
7
32
acid
content
of lipids
from
T
T
T
33
2
29
38
27
17
24
27
ND
ND
ND
ND
S. oleracea
was trace
as described
sheath
in Table
I.
Discussion The positional specificity of 16 : 0 in galactolipids of spinach was determined to be the C-2 position by using pancreatic [20] and Rhizopus [21] lipase, but specific positional distribution of this fatty acid at C-l position was also described by using pancreatic lipase [22]. We determined the galactolipid molecular species by gas-liquid chromatography/mass spectrometry analysis as described in Methods, and 16 : 0 was found to be in C-l position. The discrepancy may be due to the differences between analytical methods. The molecular species composition of phosphatidylglycerol was unique. Haverkate and van Deenen [lo] described the molecular species composition of phosphatidylglycerol extracted from the leaves of S. olerucea. In their experiments, A3-truns-16 : 1 was located at C-2 position and the 1-18 : 312-A3truns-16 : 1 species was the most abundant one. Our results are consistent with theirs. The other major molecular species in their results were the 1-18 : 31216 : 0 and 1-16 : 002-18 : 2 species. In our experiments, the molecular species containing unsaturated fatty acids and 16 : 0 were only 1-unsaturated12-16 : 0 species. Probably, the 1-16 : O//2-unsaturated fatty acyl species which they detected might be obtained from phosphatidylglycerol of the other intracellular organelles in the leaf cells. It has been assumed that A3-truns-16 : 1 is produced from the esterified 16 : 0 of phosphatidylglycerol [23]. The species containing 16 : 0 in Table V may be precursors of the species containing A3tram-16 : 1. Therefore, we may conclude that almost all of the C-2 positions of the molecular species of phosphatidylglycerol are esterified with A3-truns16 : 1 and its precursors. Probably, phosphatidylglycerol esterified with A3truns-16 : 1 at C-2 position may be required for thylakoid membrane function. Acknowledgement This work was supported by a grant for Scientific Research from the Ministry of Education of Japan.
19
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