Department of Chemistry, University of Hull, Hull HU6 7RX, UK1
Author for correspondence: Stephen G. Wilkinson. Tel: +44 1482 651152. Fax: +44 1482 466410.
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ABSTRACT |
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Keywords: Pseudomonas echinoides, Sphingomonas, lipids
Abbreviations: DPG, bis(phosphatidyl)glycerol; HPAEC, high-pH anion-exchange chromatography; HVE, high-voltage electrophoresis; L-PE, lysophosphatidylethanolamine; PE, phosphatidylethanolamine; PG, phosphatidylglycerol; TMS, trimethylsilyl
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INTRODUCTION |
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Lipid profiles have found many applications in bacterial chemotaxonomy, including the circumscription of Sphingomonas spp. Distinctive features of these organisms include the absence of 3-hydroxy acids (markers for lipopolysaccharide inter alia), but the presence of 2-hydroxytetradecanoic (2-OH-14:0) and octadecenoic (18:1) acids as major components, together with a range of glycosphingolipids (Yamamoto et al., 1978 ; Yabuuchi et al., 1979
, 1990
, 1999
; Kawahara et al., 1991
; Mizuno et al., 1992
; Takeuchi et al., 1993
, 1994
, 1995
; Kämpfer et al., 1997
). Characterization of the lipids and fatty acids from [P.] echinoides, the object of this study, could therefore clarify the classification of this organism. When this study was almost complete, the results of a detailed chemotaxonomic analysis of [P.] echinoides (including lipid data) and a formal proposal to reclassify the species as S. echinoides were published (Denner et al., 1999
). The results of our own study support and extend these observations.
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METHODS |
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Extraction and fractionation of lipids.
Lipids were extracted by stirring dry cells with chloroform/methanol (2:1, v/v) for 2 h at room temperature. To avoid possible losses of polar glycolipids, no attempt was made to remove non-lipid contaminants from the extracts. Lipid solutions were stored in the dark at -20 °C. Fractions soluble in acetone and hexane were used for the examination of carotenoids and isoprenoid quinones, respectively.
Chromatographic and electrophoretic methods.
In general, TLC separations were carried out on silica gel 60F254 (Merck) with the following solvent systems: A, chloroform/methanol/acetic acid (65:25:10, by vol.); B, chloroform/methanol/acetic acid/water (100:20:12:5, by vol.); C, chloroform/methanol/water (65:25:4, by vol.); D, chloroform/methanol/acetic acid/water (80:12:15:4, by vol.); E, ethyl acetate/pyridine/water (13:5:4, by vol.); F, light petroleum (b.p. 6080 °C)/acetone (19:1, v/v); G, dichloromethane. Aminolipids were detected with ninhydrin, phospholipids with DittmerLester reagent, glycolipids with -naphthol/sulphuric acid and lipids containing 1,2-diol or 1-hydroxy-2-amino groups with periodate/Schiff reagents (Christie, 1982
). Other methods used to detect lipids were exposure to UV light (for isoprenoid quinones) or iodine vapour, and spraying with ethanolic 2',7'-dichlorofluorescein. Reverse-phase TLC of isoprenoid quinones was carried out on RP-18F254 plates (Merck) with solvent H (acetone/acetonitrile, 4:1, v/v). HPLC using a C18 column (25 cm x 4·6 mm) eluted with solvent I (methanol/propan-2-ol, 3:1, v/v) and monitored at 270 nm, was also used to identify the major quinone. High-pH anion-exchange chromatography (HPAEC) of monosaccharides utilized a CarboPac PA100 column in a Dionex DX-300 system. Neutral sugars were eluted with 0·016 M NaOH, amino sugars with 0·25 M NaOH and hexuronic acids with 0·015 M NaOH (20 min) followed by a linear gradient (20 min) to 0·15 M sodium acetate/0·1 M NaOH (10 min).
GLC separations were carried out with either a Carlo Erba Mega 5160 or a Perkin-Elmer Autosystem XL chromatograph, fitted with fused-silica capillary columns (25 m) of BP1 (SGE). Finnigan MAT 1020B and GCQ instruments were used for GLC-MS. Paper chromatography and high-voltage electrophoresis (HVE) were carried out with Whatman no. 1 paper and the following solvents and buffers: E; J, ethyl acetate/pyridine/water/acetic acid (5:5:3:1, by vol.); K, pyridine/acetic acid/water (5:2:43, by vol., pH 5·3); L, pyridine/acetic acid/water (1:10:89, by vol., adjusted to pH 2·7 with formic acid). Detection reagents used were ninhydrin, aniline hydrogenoxalate, alkaline AgNO3 and the reagent of Hanes & Isherwood (1949 ) for phosphate esters.
Studies of polar lipids.
Phospholipids were initially characterized by TLC (solvent systems AD) and by HVE (buffer K) at pH 5·3 of the water-soluble deacylation products. Confirmation of identity and quantitative data were provided by 31P NMR spectroscopy (London & Feigenson, 1979 ), using a JEOL JNM-LA400 spectrometer. Sphingoid bases were released by acid methanolysis (Yano et al., 1982
) of total lipids at 60 °C for 20 h. After extraction of fatty methyl esters with hexane, the hydrolysate was basified (KOH) and re-extracted with hexane/diethyl ether (1:1, v/v). The products were examined by TLC (solvent C, detection with ninhydrin and periodate/Schiff reagents) and, as the trimethylsilyl (TMS) derivatives (Yano et al., 1982
), by GLC-MS. Analysis for lipid carbohydrate (as glucose) was carried out by a modified phenol/sulphuric acid assay (Kushwaha & Kates, 1981
), and the method of Blumenkrantz & Asboe-Hansen (1975
) was applied for the detection of hexuronic acids. Monosaccharide components of lipids were released by hydrolysis with 2 M trifluoroacetic acid at 98 °C for 16 h (Yu Ip et al., 1992
). Neutral sugars were identified by paper chromatography and TLC (both solvent E), HPAEC and GLC of the alditol acetates. The D configuration of glucose was assigned by using D-glucose oxidase (EC 1 . 1 . 3 . 4). Basic and acidic sugars were identified by paper chromatography (solvent J), HVE (buffers K and L) and HPAEC.
Studies of fatty acids.
Fatty acids were released as methyl esters by mild alkaline (Barnes et al., 1989 ) or acid methanolysis (Yano et al., 1982
), or by acid hydrolysis (6·1 M HCl, 100 °C, 4 h) of the lipids followed by reaction with diazomethane. The products were analysed by GLC and by GLC-MS. Saturated and monoenoic esters were separated by argentation TLC (solvent G) and unsaturation was confirmed by hydrogenation. For the location of double bonds, the methyl esters were hydrolysed (Aveldano & Horrocks, 1983
), converted into 3-picolinyl esters (Wait & Hudson, 1985
) and these were also examined by GLC-MS.
Studies of non-polar lipids.
Yellow pigments in extracts from [P]. echinoides were examined by TLC (solvents A and C) and the visible spectrum of a solution in acetone was recorded with a Philips PU8720 scanning spectrophotometer. The presence of isoprenoid quinones was monitored by TLC (solvent F), reverse-phase TLC and HPLC as described above: material isolated by HPLC was examined by MS.
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RESULTS |
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Fatty acid profiles for all three batches of lipid were qualitatively similar: the illustrative data shown (Table 1) were determined for lipid batch B. The profile obtained after mild alkaline methanolysis was dominated by the methyl esters of just two fatty acids, hexadecanoic acid (16:0) and a cis-octadecenoic acid [18:1(c)]. The latter, preponderant component was identified as 18:1(11c) (cis-vaccenic acid) by GLC-MS of the 3-picolinyl ester (Harvey, 1982
; Christie et al., 1987
). Among the minor components was an unsaturated acid, the methyl ester of which had a GLC retention time a little greater than that of methyl octadecanoate but migrated on argentation TLC just ahead of reference cis-monoenoate esters. MS indicated that this was a C19 monoenoic acid (molecular ion with m/z 310). These properties were consistent with a methyl-branched 18:1 acid and MS of the 3-picolinyl ester revealed a spectrum identical to that of the 11-methyloctadec-11-enoic ester from Brevundimonas (Pseudomonas) vesicularis (Wilkinson & Galbraith, 1979
; Barnes et al., 1989
). When fatty esters of [P.] echinoides were prepared by acid methanolysis of the lipids, or by acid hydrolysis followed by treatment of the free acids with diazomethane, a third major component was detected and identified as the ester of 2-hydroxytetradecanoic acid (Table 1
). Failure to release this component by mild alkaline methanolysis pointed to an amide linkage.
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Colorimetric tests indicated the presence in the lipids of carbohydrate, estimated at 6% in batch B (expressed as glucose), including a hexuronic acid. Extensive analyses for monosaccharide components showed a difference between the two lipid batches examined (B and C). Both contained glucuronic acid and glucose, but batch B also contained galactose (the major hexose), glucosamine and probably minor amounts of rhamnose and mannose. When -naphthol/sulphuric acid was used to visualize the parent lipids on TLC, several positive reactions were observed. The most intense spot (RPE
0·4 in solvent A) matched the major glycolipid in S. paucimobilis and was unaffected by mild alkaline methanolysis, consistent with its identification as a glucuronosylceramide (SGL-1; Yabuuchi et al., 1999
). Three less intense bands of lower RF values could correspond to glycosphingolipids produced by further glycosylation and/or non-lipid contaminants. Several other glycolipid bands, with TLC mobilities greater than PE, were detected and could include a monoglycosyldiacylglycerol. Further studies on isolated components are necessary for structural characterization of the unidentified lipids described for [P.] echinoides.
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DISCUSSION |
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Overall, the results of this investigation are in accord with other studies of the carotenoid (Jenkins et al., 1979 ) and other lipid components (Denner et al., 1999
) of [P.] echinoides. In the latter study, the major isoprenoid quinone was identified as Q-10 and the principal fatty acids as 2-OH-14:0, 16:0 and 18:1. Based on the results of two-dimensional (2D) TLC, the major phospholipids were reported as PE and PG; other phospholipids found included an unidentified aminophospholipid and a spot corresponding to SGL-1 was visualized. No further characterization of the polar lipids was apparently attempted, no information on sphingoid base nor monosaccharide composition was presented and the 11-Me-18:1(11) fatty acid was not described. On the other hand, the use of 2D-TLC provided enhanced resolution of the polar lipids and detection of several other unidentified (glyco/phospho)lipids. Both the results of Denner et al. (1999
) and the present study support the transfer of [P.] echinoides to the genus Sphingomonas. Within the genus there is some diversity of lipid composition, e.g. [P.] echinoides lacks the methylated derivatives of PE (including phosphatidylcholine) found in other Sphingomonas spp. (Kämpfer et al., 1997
; Denner et al., 1999
) and there can be significant variations in fatty acid composition. The preponderant 18:1 acid in several species has been listed as 18:1(9) by Yabuuchi et al. (1999
) in contrast to 18:1(11c) found here in [P.] echinoides. In other studies, the relative abundance of individual members of the dominant envelope of GLC peaks [18:1(6t), 18:1(9t), 18:1(11c)] was not reported (Kämpfer et al., 1997
; Denner et al., 1999
). The fatty acid provisionally identified here as 11-Me-18:1(11) has not been found in other Sphingomonas spp. but, interestingly, it (or another methyl-branched monoenoic acid) has been described for the lipids from other organisms (Rhizobium, Bradyrhizobium, Brevundimonas, Caulobacter and Hyphomonas spp.) belonging to the
-subclass of the Proteobacteria (Gerson et al., 1975
; Gerson & Patel, 1975
; MacKenzie et al., 1979
; Andreev et al., 1986
; Barnes et al., 1989
; Abraham et al., 1997
, 1999
).
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Received 8 March 2000;
revised 26 June 2000;
accepted 11 July 2000.