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Journal of Bacteriology, February 1999, p. 1330-1333, Vol. 181, No. 4
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

sn-Glycerol-1-Phosphate-Forming Activities in Archaea: Separation of Archaeal Phospholipid Biosynthesis and Glycerol Catabolism by Glycerophosphate Enantiomers

Masateru Nishihara,¹ Tomoko Yamazaki,² Tairo Oshima,² and Yosuke Koga^1,*

Department of Chemistry, University of Occupational and Environmental Health, Yahatanishi-ku, Kitakyushu 807-8555,¹ and Department of Molecular Biology, Tokyo University of Pharmacy and Life Science, Hachioji, Tokyo 192-0392,² Japan

Received 24 August 1998/Accepted 7 December 1998

	ABSTRACT

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In Methanobacterium thermoautotrophicum, sn-glycerol-1-phosphate (G-1-P) dehydrogenase is responsible for the formation of the Archaea-specific backbone of phospholipids, G-1-P, from dihydroxyacetonephosphate (DHAP). The possible G-1-P-forming activities were surveyed in cell-free extracts of six species of Archaea. All the archaeal cell-free homogenates tested revealed the ability to form G-1-P from DHAP. In addition, activities of G-3-P-forming glycerol kinase and G-3-P dehydrogenase were also detected in four heterotrophic archaea, while glycerol kinase activity was not detected in two autotrophic methanogens. These results show that G-1-P is produced from DHAP by G-1-P dehydrogenase in a wide variety of archaea while exogenous glycerol is catabolized via G-3-P.

	TEXT

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The glycerophosphate (GP) backbone of glycerophospholipid in archaea is sn-glycerol-1-phosphate (G-1-P), which is the enantiomer of its bacterial and eucaryal counterpart (4). So far, no exception to this difference in the stereoconfiguration of GP has been found, and this is one of the most fundamental features of members of each domain. The mechanism of formation of the G-1-P structure of phospholipids in archaea was first studied by in vivo incorporation experiments by Kates et al. in 1970 (5) in Halobacterium cutirubrum. They reported that the tritium label at the 2 position of glycerol was not retained in the glycerol moiety of the lipids after the incorporation, while tritium at the 1 position of glycerol was retained in the lipids. Kakinuma et al. (3) showed that a stereochemical inversion of glycerol moiety took place during lipid biosynthesis from exogenously supplied glycerol. sn-Glycerol-3-phosphate (G-3-P)-specific dehydrogenase and glycerol kinase have been detected in H. cutirubrum cell-free homogenates (15).

On the other hand, Zhang et al. (17) have shown that G-1-P is the direct precursor of the ether lipid, and we have identified G-1-P dehydrogenase as the key enzyme of G-1-P formation in Methanobacterium thermoautotrophicum (9). These results suggest that different mechanisms of G-1-P formation might be operating in extreme halophiles and methanogens. In the present study, we sought to generalize direct G-1-P formation from dihydroxyacetonephosphate (DHAP) in archaea.

Growth of cells and preparation of cell-free homogenates. Cells of Methanobacterium thermoautotrophicum H (8), Methanosarcina barkeri DSM800 (7), Halobacterium salinarum JCM8981 (8), Pyrococcus furiosus JCM8422 (14), and Thermoplasma sp. strain HO-62 (16) were grown as described previously. Pyrococcus sp. strain KS8-1 was grown at 90°C in the medium for heterotrophic hyperthermophilic archaea (11) supplemented with 0.1% yeast extract and 20 g of sulfur/liter. The cells collected at the late logarithmic growth phase were disrupted in 50 mM K-phosphate buffer (pH 7.3) by passage through a French pressure cell at 12,500 lb/in² (86,200 kPa). The supernatant fraction of cell homogenates obtained by centrifugation at 10,000 × g for 15 min was used for experiments. In the case of H. salinarum, 4 M NaCl was included in the buffer. Protein was determined by the bicinchoninic acid method (13).

GP-forming reactions. The reaction mixture (5.0 ml) for DHAP reduction (GP dehydrogenase reaction) contained 10 mM DHAP, 8 mM NADH, 58 mM triethanolamine buffer (pH 7.3), 60 mM KCl, and cell-free homogenate containing 5 to 30 mg of protein. In the case of H. salinarum cell-free homogenates, NADH was replaced by 8 mM NADPH. The reaction mixture (4.0 ml) for glycerol kinase reaction contained 20 mM glycerol, 20 mM ATP, 20 mM MgCl₂, 50 mM K-phosphate buffer (pH 7.3), and cell-free homogenate containing 0.5 to 10 mg of protein. NaCl was added to give a concentration of 4 M in the reaction mixtures for H. salinarum. The mixtures were incubated for 16 h at the temperatures indicated in Table 1.

View this table: [in this window] [in a new window]   TABLE 1.   Enantiomeric composition of the product (GP) of DHAP reduction and glycerol phosphorylation catalyzed by cell-free homogenates of various archaeaa

Determination of total and individual GP. After the GP-forming reaction was completed, total GP, G-1-P, and G-3-P were determined by gas-liquid chromatography and by two stereospecific enzymes, respectively. An aliquot of the reaction mixture received 30 µg of icosane as an internal standard, and total GP was trimethylsilylated with an excess of 1,1,1,3,3,3-hexamethyldisilazane and trimethylchlorosilane for 60 min at 110°C before gas chromatography. The lowest limit of determination of this method was 5 nmol of GP.

Another aliquot of the GP-forming reaction mixtures was deproteinized by the addition of perchloric acid and neutralized with KOH. In the case of GP dehydrogenase reaction, the nicotinamide adenine coenzyme in the deproteinized solution was removed by the addition of active carbon. The coenzyme-free solution was used for determination of each GP.

G-1-P was measured by using G-1-P dehydrogenase from Methanobacterium thermoautotrophicum and NAD. A NAD recycling system [3-(4,5-dimethyl-2-thiazolyl)-2,5-diphenyl-2H-tetrazolium bromide] (MTT) (Dojindo Laboratories, Kumamoto, Japan) and thermophilic diaphorase from Bacillus stearothermophilus (Unitika Ltd., Osaka, Japan) were included. The mixture was incubated at 65°C for 90 min. After cooling, the absorbance at 578 nm was read. This method was specific to G-1-P, and G-3-P did not interfere with the G-1-P determination. The lowest limit of determination of this method was 15 nmol of G-1-P. Standard G-1-P was prepared from halobacterial archaeol (diphytanylglycerol) (8). G-3-P was assayed in essentially the same way as in the case of G-1-P measurement except that rabbit muscle G-3-P dehydrogenase and mesophilic diaphorase from Clostridium sp. (Toyobo Co., Ltd., Osaka, Japan) were used. The lowest limit of determination of this method was 2 nmol of G-3-P. Standard G-3-P and racemic -GP were obtained from Nacalai Tesque (Kyoto, Japan). Details of the above methods will be published elsewhere.

G-1-P dehydrogenase activity. The occurrence of G-1-P dehydrogenase and G-3-P dehydrogenase was examined in cell-free homogenates of six species of archaea, including methanogens, an extreme halophile, a thermoacidophile, and hyperthermophiles. The results are summarized in Table 1. Cell-free homogenates of all archaea tested contained G-1-P-forming activity from DHAP. Among those organisms, Methanobacterium thermoautotrophicum showed the highest specific activity. Cell-free homogenates of Methanobacterium thermoautotrophicum, Methanosarcina barkeri, two strains of Pyrococcus sp., and Thermoplasma sp. contained activities of NADH-dependent reduction of DHAP to G-1-P, while the similar activity of H. salinarum was NADPH dependent. The activities of Methanobacterium thermoautotrophicum and Thermoplasma sp. were also active to NADPH. These results show that all the archaeal species so far measured contained G-1-P dehydrogenase.

Activity of the reverse reaction, that is, G-1-P oxidation by NAD, was detected in cell-free homogenates of Pyrococcus sp. strain KS8-1 even though it was significantly lower than DHAP reduction (data not shown). Although G-1-P oxidation was not detected by the cell-free homogenate of H. salinarum, the activity was able to be observed when G-1-P was incubated with a protein fraction obtained by ammonium sulfate precipitation of the cell-free homogenate, in which G-1-P dehydrogenase was presumed to be concentrated. G-1-P oxidation activity has been reported to be 1/16th of DHAP reduction activity of the same enzyme in Methanobacterium thermoautotrophicum (8).

G-3-P dehydrogenase activity. G-3-P was also detected in the reaction mixture after reaction completed with H. salinarum, Thermoplasma, and Pyrococcus sp. strain KS8-1, and Methanobacterium thermoautotrophicum (Table 1). While in the study reported here, the amount of G-3-P formed when cell-free homogenates of P. furiosus JCM8422 was incubated with DHAP and NADH was negligible, Noguchi et al. (10) observed accumulation of 2% G-3-P of total GP after DHAP and NADH were incubated with cell-free homogenates of the same organism at 51°C for 60 h. Furthermore, a fraction of P. furiosus JCM8422 cell-free homogenate eluted from a column of Cosmogel DEAE (Nacalai Tesque) with 0.2 M KCl showed an activity of G-3-P oxidation by NAD at 65°C. This activity was detected with a NAD recycling system using MTT and thermophilic diaphorase at pH 7.3. It is thus concluded that cell-free homogenates of these organisms also contained NAD-dependent G-3-P dehydrogenase. G-3-P-dependent 2,6-dichlorophenolindophenol reduction was also observed in the Thermoplasma HO-62 cell-free homogenate at 60°C. This activity suggests the presence of flavin-containing G-3-P dehydrogenase in this organism. G-3-P oxidation was confirmed in halobacterial homogenates.

Glycerol kinase activities. Formation of GP was observed when glycerol and ATP were incubated with cell-free homogenates of H. salinarum, two Pyrococcus spp., and Thermoplasma sp. but not with cell-free homogenates of two methanogens (Table 1). All the products of these activities were G-3-P.

It is concluded from the results presented in previous work (10) and in this paper that (i) G-1-P dehydrogenase was present in all the archaea; (ii) G-1-P was not produced by glycerol kinase reaction in any archaea; (iii) heterotrophic archaea (H. salinarum, Pyrococcus spp., and Thermoplasma sp.) contained G-3-P-forming glycerol kinase, while autotrophic archaea (Methanobacterium thermoautotrophicum and Methanosarcina barkeri) did not; and (iv) organisms that contained G-3-P-forming glycerol kinase activity also contained G-3-P dehydrogenase. In Thermoplasma, flavin-linked G-3-P dehydrogenase may also be present.

The fact that only heterotrophic archaea contained a G-3-P-specific enzyme set (both G-3-P dehydrogenase and G-3-P-forming glycerol kinase) is possibly explained as follows. When these heterotrophic archaea utilize glycerol as a carbon or energy source, they would convert glycerol to G-3-P but not to G-1-P. The G-3-P produced would be further metabolized to DHAP by G-3-P dehydrogenase, and reactions connecting DHAP to central metabolic pathways have been already described (2). Therefore, G-3-P pathway would probably be a pathway for glycerol catabolism. In archaea, the catabolic and lipid biosynthetic pathways seem to be separated by enantiomers of GP (Fig. 1). The role of G-3-P dehydrogenase in an autotroph Methanobacterium thermoautotrophicum is not known.

View larger version (22K): [in this window] [in a new window]   FIG. 1.   Possible metabolic pathway of GP in archaea. In autotrophic archaea (e.g., methanogens) triosephosphates (DHAP and glyceraldehyde-3-phosphate [GAP]) are synthesized from CO2 and DHAP is converted to G-1-P, which is the sole source of enantiomeric backbone of archaeal polar lipids. Although some autotrophic methanogens (e.g., Methanobacterium thermoautotrophicum) have G-3-P dehydrogenase, this enzyme is not necessary for lipid biosynthesis. In heterotrophic archaea, exogenously supplied glycerol is incorporated and phosphorylated by ATP to form G-3-P, which is catabolized via DHAP. Endogenous DHAP and glycerol-derived DHAP are mixed in the intracellular pool, and some fraction of it is incorporated into lipids. Thus sn-1 and sn-3 carbons of exogenous glycerol are inverted to sn-3 and sn-1 carbon of lipid glycerol backbone, and sn-2 hydrogen of exogenous glycerol is not retained in lipids. G-1-P-DH, G-1-P dehydrogenase; G-3-P-DH, G-3-P dehydrogenase; FDP, fructose diphosphate; GGPP, geranylgeranylpyrophosphate; 2,3-diGG-sn-G-1-P, 2,3-di-O-geranylgeranyl-sn-glycerol-1-phosphate; unsat. archaeol, unsaturated archaeol. The solid arrows indicate the anabolic route and the broken arrows indicate the catabolic route.

Earlier work (3, 5) based on the results of in vivo incorporation experiments for the formation of enantiomeric backbone of phospholipids in H. cutirubrum can be explained as follows. Isotopically labeled glycerol incorporated into halobacterial cells would be phosphorylated to G-3-P by glycerol kinase. The G-3-P should then be dehydrogenated to DHAP by G-3-P dehydrogenase. At this point, ³H at the sn-2 position must be lost. In the intracellular pool of DHAP, [³H]DHAP and unlabeled DHAP provided endogenously would be mixed and be rereduced to G-1-P, which is then incorporated into lipid. Apparent inversion of the glycerol stereostructure (3) should be a phenomenon that can be seen only in the case of the incorporation of exogenously supplied glycerol into lipids but that is not essential for lipid synthesis itself.

Complete genome sequences of three species of archaea recently published (Methanococcus jannaschii [1], Methanobacterium thermoautotrophicum [12], and Archaeoglobus fulgidus [6]) revealed the presence of G-1-P dehydrogenase genes (MJ0712, mt0610, and AF1674, respectively; Table 2). The biosynthetic G-3-P dehydrogenase gene (gpsA) of Bacteria has also been identified in genomes of Methanobacterium thermoautotrophicum and A. fulgidus (mt0368 and AF0871). A glycerol kinase gene (glpK; AF0866) and the catabolic G-3-P dehydrogenase gene (glpA; AF1328) have been found in the genome of a heterotroph A. fulgidus. G-3-P dehydrogenase gene (MJ1411) has been also found in Methanococcus jannaschii, in which glycerol kinase gene is not present. The distribution of the relevant genes is consistent with the conclusion of the present study.

View this table: [in this window] [in a new window]   TABLE 2.   Distribution of genes for GP metabolism in archaea whose complete genome sequences have been reported

	ACKNOWLEDGMENTS

We are grateful to Mami Ohga for the growth of cells of Methanobacterium thermoautotrophicum H, Methanosarcina barkeri DSM800, Halobacterium salinarum JCM8981, and Pyrococcus furiosus JCM8422.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Chemistry, University of Occupational and Environmental Health, Yahatanishi-ku, Kitakyushu 807-8555 Japan. Phone: 81-93-691-7215. Fax: 81-93-693-9921. E-mail: kogay{at}med.uoeh-u.ac.jp.

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Journal of Bacteriology, February 1999, p. 1330-1333, Vol. 181, No. 4
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

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