284

Biochimica

et Biophysics

0 Elsevier

Scientific

Acta,

Publishing

424 (1976) 284-295 Company, Amsterdam

- Printed

in The Netherlands

BBA 56714

ISOLATION AND PARTIAL CHARACTERIZATION GANGLIOSIDES

HEIKKI

OF HUMAN KIDNEY

RAUVALA

Department of Medical Helsinki 17 (Finland).

(Received

August

Chemistry,

University

of Helsinki,

Siltavuorenpenger

10 A, SF-001

70

4th, 1975)

Summary 1. Eight gangliosides were purified from chloroform/methanol extracts of human kidneys by using modified Folch partition, dialysis, ethanol precipitation, silicic acid column chromatography and preparative thin-layer chromatography. 2. By thin-layer chromatographic behaviour and gas-liquid chromatographic determinations the main gangliosides in human kidney are N-acetylneuraminyllactosylceramide (74% of total) and di-N-acetylneuraminyllactosylceramide (19% of total). 3. Five hexosamine-containing fractions were isolated. Four of them were homogeneous on thin-layer chromatography, and one contained two gangliosides. By gas-liquid chromatography-mass spectrometry it was shown that two gangliosides (together 5% of total) contain glucosamine, and one (1% of total) contains galactosamine. The other of the glucosamine gangliosides contains fucose in addition to the usual sugars found in gangliosides. Of the two remaining hexosamine positive fractions (together 1% of total) one was homogeneous on thin-layer chromatography, the other contained two gangliosides. These two fractions contained both glucosamine and galactosamine. 4. The main long-chain base in all fractions was sphingosine.

Introduction

shown

The complexit,y of the ganglioside patterns in extraneural tissues has been [ 11. Usually, the gangliosides containing lactose as their neutral carAbbreviations GlcNAc,

Svennerholm GMaa

and

nomenclature:

N-acetylglucosamine; [41

is used

Gal,

galactose:

NeuNAc, for

gangliosides.

(N-acetylneuraminyllactosylceramide)

The

nomenclature

sion

[ 5.61.

used

for long-chain

Glc,

glucose;

N-acetylneuraminic The and bases

and

hematosides as GMsb

GalNAc.

acid. of

The

bovine

N-acetylgalactosamine:

shorthand kidney

nomenclature were

designated

(N-glycolylneuraminy~actosylceramide).

oligosaccharides

is that

proposed

by

IUB

Commis-

of as

285

bohydrate portion predominate in extraneural tissues [2,3] . Because of the scarcity of the material and the difficulties in the isolation procedures, relatively few reports have been published concerning the more complex extraneural gangliosides. Wiegandt and Bucking have developed a method to release the sialo-oligosaccharides from gangliosides, and have found a wide variety of gangliosides in several extraneural tissues by their method [3]. In this work, an attempt was made to isolate especially the more complex gangliosides from human kidney as intact molecules. A simplified isolation method was developed, and in addition to the gangliosides containing neuraminyl- and di-neuraminyllactose, five hexosamine-containing ganglioside fractions could be isolated. A preliminary characterization of the ganglioside fractions is presented. Experimental Materials

Human kidneys were obtained at autopsy and stored at -2O”C, if not used immediately. The brain gangliosides used as reference on thin-layer chromatography were made available by Professor E. Klenk (Physiologisch-Chemisches Institut der Universitat Koln, Germany), the hematosides of bovine kidof Medical Chemistry, ney (GM3, and GM3i, ) by Dr. K. Puro (Department University of Helsinki, Finland), the mixture of pig brain gangliosides, and the disialoganglioside of pig brain by Dr. P. Maury (Department of Medical Chemistry, University of Helsinki, Finland). L-fucose, D-galactose, D-glucose, D-mannose, 2-acetamido-2-deoxy-D-galactose, 2-acetamido-2-deoxy-D-glucose, N-acetylneuraminic acid, N-glycolylneuraminic acid, inositol and O-P-D-galactopyranosyl-(1 -+ 4)D-glucopyranose (lactose) were purchased from commercial sources. Other sugars used for standardization of gas-liquid chromatographic determinations were gifts: 2-acetamido2-deoxy-O-P-D-galactopyranosyl( 1 -+ 3)-D-galactopyranose from Dr. D. Shapiro (Rehovoth, Israel), 0-a-L-fucopyranosyl-( 1 + 2)-O-P-D-galactopyranosyl-( 1 + 4)-D-glucopyranose (2’-fucosyllactose), O-O-D-galactopyranosyl-( 1 + 3)-%acetamido-2-deoxy-O-/3-D-glucopyranosyl-(1 + 3)-O-fl-D-galactopyranosyl(1 -+ 4) D-glucopyranose (la&o-N-tetraose) and 0-a-N-acetylneuraminyl-(2 --f 6)-O-p-~galactopyranosyl (1 + 4)-D-glucopyranose (6’-iV-acetylneuraminyllactose) from Dr. A. Gauhe (Heidelberg, Germany). 0-cu-N-acetylneuraminyl-( 2 + 3)-0-@-D -galactopyranosyl-( 1 -+ 4)-D-glucopyranose (3’-N-acetylneuraminyllactose) was prepared in this laboratory [7] . Organic solvents were of analytical reagent quality. Trimethylchlorsilane (Fluka A.G.) and hexamethyldisilazane (Fluka A.G.) were distilled before use. Pyridine was distilled from KOH and stored over a molecular sieve. Absorbents for column chromatography were silicic acid (Anasil-S, Analytical Engineering Laboratories, Inc., Hamden, Conn.) and cellulose (Whatman powder, standard grade, W and P, Bolston, Ltd.), and for thin-layer chromatography silica gel G (E. Merck, A.G., Darmstadt). Dowex 1 X 8 (200/400 mesh) and Dowex 50 X 8 (200/400 mesh) were purchased from Fluka A.G. Preparation

of gangliosides

Capsules and pelvices were removed

from human

kidneys by coarse dissec-

286

tion. The kidney tissue was rinsed and made bloodless by washing several times with 0.9% saline. The rinsed tissue was homogenized in cold acetone and dried to acetone powder. The lipids were extracted and partitioned in the Folch system as described before [8,9]. The lower phases were discarded, the upper phases were dialyzed at -+4”C against running tap water and concentrated by rotary evaporation below 40” C. For further purification, crude ganglioside was dried and precipitated from ethanol at -20°C for 24 h in the concentration of 30 mg of gangliosides per 100 ml of ethanol. In some experiments, cellulose column chromatography [ 91 was used instead of ethanol precipitation. Preparation of gangiioside fractions The gangliosides were separated by chromatography on silicic acid columns using continuous chloroform/methanol/water gradients with a mixing chamber of constant volume [ 91. The separation of gangliosides was monitored by neuraminic acid determinations and by thin-layer chromatography. Final purification was achieved by preparative thin-layer chromatography. Gangliosides were detected by spraying with water. In addition, samples of wet silica gel were transferred to another glass plate, which was sprayed with resorcinol HCl. The more apolar gangliosides were usually well detected already with water, but for more polar gangliosides resorcinol HCl detection was essential. Detection of bands in water sprayed plates was aided by ultraviolet light. Analytical methods Neuraminic acid was determined by the method of Svennerholm [lo], as modified by Miettinen and Takki-Luukkainen [ 111, for crude lipid extracts ion exchange purification was used [ 121. Hexosamine was detected by a modified Elson-Morgan reaction [ 131. Thin-layer chromatography was performed using silica gel G plates. The bands containing neuraminic acid were detected by resorcinol HCl spray [lo] . (NH,),SO,/(NH,)HSO, solution was used as a general spray reagent [14]. The solvents were: (A) chloroform/methanol/water (60/35/B), (B) chloroform/ methanol/2.5 M NH,OH (60/35/B), (C) n-propanollwater (7/3), (D) n-propanel/water/concentrated ammonia (6/2/l) [15]. Gas-liquid chromatography was performed with a Perkin-Elmer 900 gas chromatograph (Perkin-Elmer Corporation, Norrwalk, Conn., U.S.A.) equipped with a flame ionization detector. Gas-liquid chromatography-mass spectrometry was performed with a Varian Aerograph 1700 gas chromatography combined to a Varian MAT CH-7 mass spectrometer equipped with Spectra System 100 MS data processing system (Varian MAT, Bremen, Germany). The energy level of the ions was 70 eV, the ionizing current was 300 pamp. The mass range covered was from m/e 40 to m/e 800. The ratios of fucose, galactose, glucose, galactosamine and glucosamine were determined on 1% OV-225 column (2 m X 3 mm, internal war) as alditol acetates after acetol.ysis and hydrolysis [ 16-191. In addition, the monosaccharides, neuraminic acid and long-chain bases were quantitated in a single gasliquid chromatographic run on 2.2% SE-30 column (2 m X 3 mm, internal diameter) as Me JSi ethers after methanolysis [20-221. Identification of the Me,Si ether peaks was achieved by comparison with standard monosaccharides

and with long-chain bases obtained after methanolysis of bovine kidney hematosides [ 231. Identification of the gas-liquid chromatographic peaks was aided by mass spectrometry. Molar responses of monosaccharides were determined by using di-, tri- and tetrasaccharides as reference compounds. The species of neuraminic acid was determined after weak acid hydrolysis (0.05 M Hz S04, 80°C 90 min) by thin-layer chromatography and by gas-liquid chromatography [ 241. Results Purification

of gangliosides

from other lipids

When extracting the lipids from acetone powder by chloroform/methanol 2/l and l/2 mixtures [9], 1.0 mg neuraminic acid/100 g wet tissue weight was obtained, which corresponds to 5.6 mg/lOO g dry tissue weight. After a modified Folch partition and dialysis [9], the gangliosides were still extensively contaminated with neuraminic acid free lipids. To achieve satisfactory separations on silicic acid columns, it was found necessary to purify the gangliosides further from other lipids. This could be achieved by cellulose column chromatography, as described before [9,25]. The precipitation of gangliosides from cold ethanol was found to be a more convenient method in large scale purification. About 30 mg of gangliosides was precipitated in 100 ml ethanol at -20°C for 24 h, centrifuged and the ethanol-soluble part decanted. 86% of the neuraminic acid was found in the precipitate. The loss was mainly due to hematoside. None of the other gangliosides was selectively lost to the ethanol-soluble fraction. When tested with a mixture of pig brain gangliosides, 93% of neuraminic acid was in the precipitate, and selective loss of any ganglioside was not observed on thin-layer chromatography. The better yield for brain gangliosides probably reflects the fact that gangliosides having longer carbohydrate chains prevail in brain as compared with the kidney gangliosides.

Fig. 1. Separation of human kidney gangliosides (19 mg, as NeuNAc) on silicic acid column (60 9). The followed by elution was carried out by a continuous chloroform/methanol/water gradient (-----_) methanol/water 9/l (v/v) (- - - - - -). Fractions l-5 were collected according to neuraminic acid determinations and thin-layer chromatographic analysis. The ratios of chloroform. methanol and water (v/v/v) were: 200 ml, 64/31/4.8; 600 ml, 64/31/4.9; 1000 ml. 64/31/5.0; 1400 ml 61/33/6.1.

288

Fractionation of gangliosides fractions 70-80 mg of gangliosides

and

carbohydrate

composition

of

individual

was transferred to an Anasil-S column (60 g). After the chloroform/methanol/water gradient the column was eluted with 1 1 of methanol/water (9/l). This step was essential for complete recovery of the most polar fractions, which did not usually separate as distinct peaks. A typical elution pattern of gangliosides in silicic acid column chromatography is shown in Fig. 1. The corresponding 5 fractions from 11 silicic acid chromatographic runs were pooled and rechromatographed. Preparative thin-layer chromatography was used in the final purification in either solvent A or B, except for fraction 5, which was purified in solvent D. Recovery of NeuNAc from preparative thin-layer chromatography was 90% or somewhat more (elution was performed three times with chloroform/methanol/water, 5/4/l). A thin-layer chromatogram of the seven ganglioside fractions purified from human kidney is shown in Fig. 2. The percentage distribution of gangliosides was calculated on the basis of neuraminic acid determinations after silicic acid chromatography and after preparative thin-layer chromatography for those gangliosides, which were not separated with column chrcmatography. The amount of neuraminic acid per mole of ganglioside was determined by gas-liquid chromatography as Me 3Si ethers, and the percentage distribution of gangliosides was finally calculated on the molar basis. Fraction 1. This fraction contained ganglioside I, which was homogeneous on thin-layer chromatography in the four solvents used (see above) and moved with hematoside GM3 a. It was Elson-Morgan negative, and no hexosamines were found in gas-liquid chromatography. The only sialic acid by thin-layer

-SOLVENT

*e: ) ‘dP

Fig. C,

2. GM*:

Thin-layer D.

mixture

chromatogram of

human

of brain

human

kidney

gangliosides.

gangliosides Soivent

B. Spray:

I-VIII.

FRONT

References:

resorcinol

HCl.

A.

GM3a;

B. GM3b;

289

chromatography and gas-liquid chromatography after mild acid hydrolysis was N-acetylneuraminic acid. As Me 3Si derivatives the ratio of galactose : glucose : neuraminic acid was 1.0 : 0.9 : 0.8. This ganglioside is therefore a hematoside, and comprises 74% of human kidney gangliosides. Fraction 2. This fraction was composed of gangliosides II and III. After separation of these gangliosides, they were both homogeneous on thin-layer chromatography in solvents A-D. The properties of these gangliosides on thinlayer chromatography were peculiar. In solvents A and D they moved behind ganglioside IV (which corresponds to di-N-acetylneuraminyllactosylceramide of bovine kidney in its thin-layer chromatographic behaviour and sugar composition). In solvent B ganglioside II moved ahead of ganglioside IV and ganglioside III moved slightly behind ganglioside IV, while in solvent C both ganglioside II and ganglioside III moved ahead of ganglioside IV. Both of these gangliosides were Elson-Morgan positive. In addition to galactose, glucose, and neuraminic acid, II and III contained glucosamine and ganglioside III fucose. Identification of glucosamine was achieved by gas-liquid chromatography-mass spectrometry. In gas-liquid chromatography as Me ,Si derivatives and as alditol acetates, the retention times of the amino sugar peaks corresponded to N-acetylglucosamine. By mass-spectrometry the structure of methyl 2-acetamido-2-deoxy-tri-OMe 3Si-hexoside was established according to the data of Karkkainen and Vihko [26]. The mass spectra of the amino sugar peaks were also found to be identical to those obtained from the gas-liquid chromatographic peaks of authentic N-acetylglucosamine. Three gas-liquid chromatographic peaks identical in the retention times and the ratios of the peak areas to those obtained from fucose were found in ganglioside III. The mass soectral characteristics were also identical to those of fucose. Ganglioside.111 was sprayed with (NH,), SO, /(NH,)HSO 4 solution in addition to recorcinol HCl, to detect any organic impurities which could convey fucose to the fraction. Ganglioside III was homogeneous also by this detection method. N-acetylneuraminic acid was found to be the only sialic acid by thin-layer chromatography and gas-liquid chromatography after mild acid hydrolysis. The ratio of galactose : glucosamine : glucose : neuraminic acid was for ganglioside II (in parentheses as alditol acetates) 2.0 : 1.1 : 0.8 : 1.0 (2.0 : 0.9 ; 0.8). The ratio of fucose : galactose : glucose : glucosamine : neuraminic acid in ganglioside III was 0.6 : 2.0 : 0.9 : 0.7 : 0.9 (0.8 : 2.0 : 1.0 : 0.9). Gangliosides II and III accounted together for 5% of human kidney gangliosides (about equal amounts of both). Fraction 3. This fraction contained ganglioside IV, which was the other major ganglioside in human kidney. Ganglioside IV had the characteristic thinlayer chromatographic properties reported by Puro for di-N-acetylneuraminyllactosylceramide [ 91. On the basis of the Elson-Morgan reaction and gas-liquid chromatography this ganglioside does not contain amino sugars. Only N-acetylneuraminic acid was found in thin-layer chromatography and gas-liquid chromatography. As Me3Si derivatives in gas-liquid chromatography the ratio of galactose : glucose : neuraminic acid was 1.0 : 0.8 : 1.9. The carbohydrate structure of this ganglioside is therefore the same as that of di-hr-acetylneuraminyllactosylceramide isolated by Puro from bovine kidney [ 21. Ganglioside IV comprised 19% of human kidney gangliosides. Fraction 4. Gangliosides IV, V and VI were found in this fraction. Gan-

290

glioside V was purified to give a homogeneous band on thin-layer chromatography. The thin-layer chromatographic properties of V resembled to those of ganglioside GD, b. The Elson-Morgan reaction was positive. The presence of galactosamine was verified as described for glucosamine in gangliosides II and III. As before, N-acetylneuraminic acid was the only sialic acid. The ratio of galactose : glucose : galactosamine : neuraminic acid (as Me,Si derivatives) was 2.0 : 1.0 : 1.0 : 1.9. These data suggest that ganglioside V could have the same kind of carbohydrate structure as the brain disialoganglioside. Ganglioside V comprised 1% of human kidney gangliosides. Fraction 5. Gangliosides VI, VII and VIII were found in this fraction (and a small amount of ganglioside V). Two fractions were well separated in solvent D. Ganglioside VI was purified from the slower moving fraction to give a homogeneous band in solvents A-D. The slower band, though quite homogeneous in solvent D, revealed two recorcinol positive spots close to each other in solvents A-C. These were named gangliosides VII and VIII in order of decreasing thin-layer chromatographic mobility. Because of lack of material, gangliosides VII and VIII could not be purified to homogeneous fractions. The thinlayer chromatographic behaviour of ganglioside VI in the solvents used was near to gangliosides GD, b and GT 1, gangliosides VII and VIII moved near the trisi~ogangliosides of brain on thin-layer chromatography. The Elson-Morgan reaction was positive for ganglioside VI and for the mixture of VI1 and VIII. By gas-liquid chromatography-mass spectrometry, ganglioside VI and the mixture of gangliosides VII and VIII contain both glucosamine and galactosamine. The only sialic acid found on thin-layer chromatography after mild acid hydrolysis was N-acetylneuram.inic acid. The ratio of galactose : glucose : galactosamine : glucosamine : neuraminic acid in ganglioside VI was (as Me,Si ethers) 2.0 : 1.3 : 0.5 : 0.5 : 1.9. Therefore, this fraction contains either a ganglioside with galactosamine and glucosamine in the same molecule or it is still a mixture of two gangliosides. The carbohydrate ratios in the mixture of VII and VIII (as Me,Si derivatives) were galactose : glucose : galactosamine : glucosamine : neuraminic acid, 2.0 : 1.0 : 0.9 : 0.2 : 1.3. About 0.5% of human kidney gangliosides was due to ganglioside VI and about 0.5% to the mixture of VII and VIII. Composition of long-chain bases After methanolysis in dry HCl . methanol, acetylation and trimethylsilylation, long-chain basis were converted mainfy to 1,3-di-0-Me,Si-NAc and 1,3,4tri-O-Me~Si-NAc derivatives, which were eluted in gas-liquid chromato~aphy after neuraminic acid (Fig. 3). Because of by-product formation in dry HCl methanol [27] (mainly 0-methylation), dry methanolysis is not usually used for long-chain base determinations. However, by adding the peaks having m/e 174 in their mass spectra (m/e 174 is common to various species of long-chain bases, Fig. 4), the response of long-chain bases was fairly constant in gas-liquid chromatography (the peak area of long-chain bases as related to glucose was 0.5 in ganglioside I of human kidney). For various species of long-chain bases, a diagnostic peak [28] arises from the cleavage of the molecule between carbon atoms 2 and 3 (m/e 311 for 1,3-di-O-Me 3Si-NAc derivative of sphingosine and m/e 253 for l-0-Me,Si-3-0-Me-NAc derivative of sphingosine, Fig. 4). For tri-

291

Long-than

bases

III

30

50 TIME

(min)

10

Fig. 3. Gas-liquid chromatograms of trimethylsilylated monosaccharides and long-chain bases obtained in dry methanolysis (0.75 M HCl * methanol, 20 h, 80°C). A, hematoside GM3a from bovine kidney; B. ganglioside III from human kidney. I,II,l-O-MesSi-3-0-Me-NAc derivatives of long-chain bases (mainly from sphingosine); lII.IV.1.3-di-0-Me3Si-NAc derivatives of long-chain bases (III, mainly from sphingosine; IV, mainly from dihvdrosphingosine and sphingosine): V.1.3,4-tri-O-Me~Si-NAr derivatives of long-chain bases (mainly from phytosphingosine). Conditions: 2.2% SE-30, temperature programmed at 4”Cimin from 140 to 240°C. inositol as internal standard.

hydroxybases [ 291, a similar cleavage was also observed, but the cleavage between carbon atoms 3 and 4 favoured (for 1,3,4-tri-0Me,Si-NAc derivative of phytosphingosine m/e 401 and m/e 174 from the cleavage between carbons 2 and 3 and m/e 299 and m/e 276 from the cleavage between carbons 3 and 4, Fig. 4). In the conditions used, IV-acetylation was complete. The most prominent by-product was the 30methylated 4-sphingenine (Fig. 4). The long-chain bases of hematoslde GMja from bovine kidney were used as reference in gasliquid chromatography and gas-liquid chromatography-mass spectrometry. The main the long-chain bases in hematoside GM3, were by this method phytosphingosine and sphingosine, which is in agreement with the analysis of the oxidation products by lead tetraacetate [23]. In all fractions of human kidney gangliosides the main long-chain base was spingosine. Trihydroxybases were found in much smaller amounts than in bovine kidney hematosides (Fig. 3 and Fig. 4). Because of lack of material, identification of the minor fractions of long-chain bases was not attempted in this study.

0

50

50.

lLdu,,,l.l.l

/’

13

73

,73

100

!

132

132

‘P

$63 116 \

91 103

116

of long-chain bases. Above, derivative of sphingosine);

L

106~

Fig. 4. Mass spectra 1-0-MejSi-3-0-Me-NAc

F

?.

2

z iii

YD

50.

100

114

,,

!,l

200

&IL.&

167

.l,,,, 185

216

1,

2p .L

276

mle

.._...

241 /

I

253(t$1741

300

]31,,-,74~9o,

299 W2761

1

,:;‘“:‘-“““,,

M-575

L

401 : 174

: tOCH3

; 0-CH2

253 :174 CH=;Wi 3

:

NH : COCH3

OSiMea

400

.L

:

441

426 (r~9o~59)

I 276

500

: COW3

470(M~g0~,5) 1

299

CH3-(CH2),2-CH2-$H; CtifCH-CHpOStMe3 Me3St0 v+lO: NH

KH2),Z

401 (M-1741

366 (y-591;

360lM-32-151 1

CH3-

M=427

Me+O/

560 Ct$ 151

1

peak III/A of Fig. 3 (mainly 1,3-di-0-MejSi-NAc derivative of sphingosine); middle, peak I/B of Fig. 3 (mainly below, peak V/A of Fig. 3 (mainly 1,3,4-tri-O-Me3Si-NAc derivative of phytosphingosine).

147 I=’

141

174

211

311 NM.174) 1 292W90-103)

311 174

+ CH3~(CH2),iCH=CH-“iCH-CH20S,Me3

M=465

293

Discussion Isolation of gangliosides from extraneural tissues in reasonable yields for structural study is laborious and time consuming. In the handling of relatively large amounts of starting material, it is desirable to lessen the number of chromatographic runs. Therefore, an ethanol precipitation step was introduced after the Folch partition. This step gave an 86% recovery of neuraminic acid, and removed small molecular substances which leak into the upper phase during the Folch partition. Dialysis may be used to remove small molecular organic substances, but it was partially ineffective in this case, perhaps because gangliosides tend to form micelles with these [30]. When precipitated in ethanol after the modified Folch partition and dialysis, the gangliosides were fractionated fairly well on silicic acid columns, and showed minimal or no contamination on thin-layer chromatography. Recently, phosphotungstic acid precipitation has been recommended to purify the ganglioside preparation from small molecular organic contaminants in the water layer of chloroform/methanol/water partition [31]. The amount of neuraminic acid extracted from human kidneys by chloroform/methanol 2/l and l/2 mixtures was considerably lower than that reported for rat, rabbit, pig and bovine kidneys [1,9], i.e. 5.6 mg/lOO g dry weight compared with 13, 13, 16 and 16 mg/lOO g dry weight, respectively. This is a real difference, because there were no essential differences in experimental procedures. According to Martensson [ 32,331, the ganglioside content of human kidney is 0.24 pmol/g dry weight, which is somewhat more than the value calculated from the data of this work (0.17 pmol ganglioside/g dry weight). The dominating ganglioside in human kidney was N-acetylneuraminyllactosylceramide (hermatoside), which is in agreement with reports concerning several extraneural tissues [ 341. The corresponding hematoside containing N-glycolylneuraminic acid was another major ganglioside in bovine kidney [2], but could not be found in human kidney. The absence of N-glycolylneuraminic acid was confirmed for all ganglioside fractions of human kidney, which is in accordance with previous studies on extraneural human gangliosides [3] . The hematoside containing N-acetylneuraminic acid constituted about the same percentage of gangliosides in human kidney as the sum of hematosides GM3 a and GMs,, in bovine kidney [9]. The other major fraction was di-N-acetylneuraminyllactosylceramide, which also was the major ganglioside, after hematosides, in bovine kidney [2,9]. A glucosamine-containing ganglioside was first described in bovine erythrocytes and spleen [ 351, Glucosamine-containing oligosaccharides liberated from ganglioside preparations have been found in human spleen, kidney and liver and in bovine extraneural tissues [ 3,34,36]. Glucosamine has also been found in the gangliosides of human erythrocytes [37], human platelets [38], bovine platelets [ 391, human, bovine and rabbit plasma [40], human newborn brain, peripheral nerve, skeletal muscle, serum and red blood cells [41]. In this work, two gangliosides containing glucosamine as their only hexosamine were isolated. The other of these gangliosides contains fucose, which was unequivocally identified by gas-liquid chromatography-mass spectrometry. Fucose could

294

not be separated from this ganglioside by preparative thin-layer chromatography, and the homogeneity could also be confirmed by analytical thin-layer chromatography in four quite different solvents. These facts suggest that fucose exists in the same glycolipid molecule as neuraminic acid, which is an unusual structural feature. Fucose, galactose, glucose, glucosamine and neuraminic acid have also been found in A and B active glycolipid preparations [42,43]. However, the highly purified A and B glycolipids do not contain neuraminic acid [ 441. Wiegandt has found an H active oligosaccharide containing fucose, galactose, glucose, galactosamine and neuraminic acid from gangliosides of bovine liver [36]. In addition to these two glucosamine-containing gangliosides, a disialoganglioside containing galactosamine and a homogeneous ganglioside fraction containing both galactosamine and glucosamine were isolated. Gangliosides with two hexosamine moieties are not known to exist, and the possibility remains that the fraction containing both galactosamine and glucosamine is still a mixture. Ganglioside structures are often inferred from their thin-layer chromatographic mobilities using brain gangliosides as standards. This work shows quite clearly that these kinds of interpretations can lead to erroneous conclusions. For example, ganglioside III was near to ganglioside G, , a in its thin-layer chromatographi~ behaviour, although it, contains only one sialic acid, and gangliosides VII and VIII moved with brain trisialog~~liosides, although the mixture of these gangliosides contains only 1.32 neuraminic acids per molecule. The dominant long-chain base in all ganglioside fractions was 4sphingosine, as in neutral glycolipids of human kidney [45]. Compared with bovine kidney gangliosides, clearly less trihydroxybases were found in all fractions of human kidney gangliosides. Acknowledgements The technical assistance of Mrs. Liisa Kuivalainen and Mrs. Hilkka Rijnkkij is greatly appreciated. This work was supported by the Sigrid Juselius Foundation and the National Research Council for Medical Sciences, Finland. References 1

Pure,

K..

2

Pure,

K.

3

Wiegandt.

4

Svennerholm.

5

IUPAC-IUB Eur.

6

P. and

H. and

Biicking,

7

Huttunen.

8

Folch,

9

Pure,

21.

Svennerholm. Miettineo.

12

Svennerholm,

Eur.

of

10,

Biochim.

Biophys.

Acta

187,

‘23~-235

401-413 J. Biochem.

15.

287.-292

613-623

Biochemical

Nomenclature

The

(CBN)

Nomenclature

the

Nomenclature (CBN),

of

Organic

Tentative

Chemistry

Rules

for

(CNOC)

Carbohydrate

and

(1966)

Ann.

M. and

SIoane

Acta

I3

Miettrnen,

T.A.

Zimiriski.

T. and

Exp.

Stanley, Sand.

Biochim.

24.

(1961)

Acta Sand.

Borowski.

BioI.

Fenniae

G.H.

(1957) Acta

I.-T.

(1959)

Chem. J. Clin.

E. (1966)

44.

Supul.

J. Bioi.

12

Chem.

226,

497-509

13-22

Biophys.

Takki-Luukkainen.

L. (1958)

14

Med.

Chem.

I,. (1957) ‘I’. and

of

IUPAC-IUB

Nomenclature

455--477

(1970)

11

(1970)

187,

Lipids

(1967)

31

Nomenclature

Lees,

10

on

2, 127--l

J.K.

J.. K.

W.W.

(1969)

Acta

J. Neurochem.

Commission

Commission

J.K.

Biophys.

I,. (lV63)

Biochemical

Biochem.

Hut&men,

Biochxm.

J. Riochem.

IUPAC on

Maury. (196V)

Stand. Lab.

12,

24.

604-611

Acta

Chem.

Stand.

547-554

Invest.

J. Chromatog.

13,

Suppl.

23.

13

480.-482

13,

856-858

Commission (1971)

Eur.

J.

295

15

Penick.

16

Sawarderker,

R.J..

17

Kim,

18

Bjiirndal. Young.

20

Sweeley. Bhatti. Pun),

25

T.,

Rouser.

G.. ed.),

R.E.

and

A.

l,edeen. Kntchevsky.

Chem.

J.R.

(1970)

New

Gaver.

R.C.

and

Sweeley.

C.C.

(1965)

J. .4m.

011 Chem.

28

Gaver,

R.C.

and

Sweeley.

C.C.

(1966)

J. Am.

Chem.

29

Thorpe,

Svennerholm. Dunn.

32

MPrtensson,

E..

Percy,

33

MBrtensson.

E.

(1969)

in Progress

in the

367-407.

Pergamon

Press.

X,

Part

4, pp.

34

Wiegandt.

35

Kuhn.

36

Wiegandt,

37

Wherrett.

38

Marcus,

39

Etzrodt.

H. (1968)

40

Yu.

and

41

MPnsson.

and

Adv.

Wiegandt.

H. (1973) J.R. A.J.,

R.K.

Pullman,

Lipid

Res.

II. (1964)

222.

339-347

393-400 Chromatographic

Analysis

(Marinetti.

10,

113-120 Sot.

42.

88,

294-298

3643.

3647

6. 887-897

239~-250

I,. (1966) Chetmstry

of

11.1,. and

&Tier.

Acta L.B.

Univrrslty

(1972)

J. Lipid

J.,

Y.-T..

Li,

Acta

Paedlatr.

Fats

and

Stand.

other

Llpids

55.

l-9

(Holman,

R.T..

ed.),

Vol.

Oxford 19b, Chem.

%. Physiol. Biophys.

R.W.

Acta

9, 249-289

Biochim.

Holmgren.

187.

Sot.

Z. Naturforsch.

Dissertation.

Lcdern.

17.

Svennerholm.

IIoppe-Seyler’s

(1973)

J.-E..

Sand.

258-274

1801-1804

2.3, 293m-295

A. and

H. (1971)

R.

Chem.

J. Neurochem.

Res.

Biochemistry

30

(1974)

Acta

(1967)

31

A.

I,. (1963)

C.C.

Biophys.

in I.ipid

Klrkkiilnen.

Sweeley.

21.

Yorh

26

and

Carbohyd.

20,

Sand.

279.-287

506--516

.4. (1967)

Dekker.

Bmchem.

116.

1602-1607

1009~~1018

Acta

11.

37.

1192-1200

Biochim.

Res.

Actd

Chem.

1461-1466

J. 125.

Biophvs.

Yamamoto.

246.

36.

Blochem.

Marcel

1~. (19ti9)

Chem.

Chem.

27

S.R.

Vihko,

Anal.

Acta

J. Lipid

G. and 99-m162.

Biophys.

Anal.

(1967)

Biochim.

(1970)

Blochim.

(1965)

J.G.

J. Biol.

(1971)

(1969)

A.

S. (1967)

Anal.

Clamp.

J.R.

R.W.

1’01. I. pp. J. and

and

Clamp.

P~ercr.

(1971)

B. (1964)

(1966)

Jeanes,

Svensson.

S.-I.

Walker.

R.H.

and

T.11. and

B. and

Kerlnen.

and

McClucr. J.H.

Liao.

Chambers,

K. nnd

and

Hakomori.

and

R.E.

R.K.

G.\‘..

B..

and

C.C.

Chambers, Yu.

Shame.

H.J.

22 23

M.H.

Sloanecker.

11.. Lindberg.

21

24

d.S.,

J.H.,

19

Melsler.

326.

(1972) of

80~.-81 354.

1049~~1056

63-73 J. Clin.

Invest.

51.

2602--2612

Kdln

Res.

13.

\‘amer.

680-686

M.-T.

and

Svennrrholm,

L.

(1974)

Med.

Biol.

52.

240-243 42

Ilakomori,

S.-l.

and

43

Hakomori.

S.-l.

(1970)

44

Hakomori.

S.-l.

and

Press,

York

45

New

Martensson,

I?. (1965)

Strycharz. Chem. Kobata,

G.D.

(1968)

Phys.

Lipids

A.

Biochim.

(1974) Biophys.

Biochemistry

7. 12’79

-1286

5. 96-115

in The Acta

Antigens 116.

(Sela.

296-308

M..

ed.),

Vol.

Il.

pp.

79-140,

Academic

Isolation and partial characterization of human kidney gangliosides.

1. Eight gangliosides were purified from chloroform/methanol extracts of human kidneys by using modified Folch partition, dialysis, ethanol precipitat...
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