Plant Physiol. (1999) 121: 263-272

Carbon Metabolism in Spores of the Arbuscular Mycorrhizal Fungus Glomus intraradices as Revealed by Nuclear Magnetic Resonance Spectroscopy¹

Berta Bago, Philip E. Pfeffer^*, David D. Douds Jr., Janine Brouillette, Guillaume Bécard, and Yair Shachar-Hill

United States Department of Agriculture-Agricultural Research Service, Eastern Regional Research Center, 600 East Mermaid Lane, Wyndmoor, Pennsylvania 19038 (B.B., P.E.P., D.D.D., J.B.); Unité Mixte de Recherche, Centre National de la Recherche Scientifique (Strasbourg, France)/Université de Paris-Sud 5546, Pôle de Biotechnologie Végétale, 24 chemin de Borde-Rouge 31326, Castanet Tolosan, France (G.B.); and New Mexico State University, Department of Chemistry and Biochemistry, Las Cruces, New Mexico 88001 (Y.S.-H.)

	ABSTRACT

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Arbuscular mycorrhizal (AM) fungi are obligate symbionts that colonize the roots of over 80% of plants in all terrestrial environments. Understanding why AM fungi do not complete their life cycle under free-living conditions has significant implications for the management of one of the world's most important symbioses. We used ¹³C-labeled substrates and nuclear magnetic resonance spectroscopy to study carbon fluxes during spore germination and the metabolic pathways by which these fluxes occur in the AM fungus Glomus intraradices. Our results indicate that during asymbiotic growth: (a) sugars are made from stored lipids; (b) trehalose (but not lipid) is synthesized as well as degraded; (c) glucose and fructose, but not mannitol, can be taken up and utilized; (d) dark fixation of CO₂ is substantial; and (e) arginine and other amino acids are synthesized. The labeling patterns are consistent with significant carbon fluxes through gluconeogenesis, the glyoxylate cycle, the tricarboxylic acid cycle, glycolysis, non-photosynthetic one-carbon metabolism, the pentose phosphate pathway, and most or all of the urea cycle. We also report the presence of an unidentified betaine-like compound. Carbon metabolism during asymbiotic growth has features in between those presented by intraradical and extraradical hyphae in the symbiotic state.

	INTRODUCTION

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Fossil evidence (Taylor et al., 1995) and molecular phylogenetic studies (Simon et al., 1993) indicate that 400 million years ago the roots of land plants were colonized by ancestors of modern arbuscular mycorrhizal (AM) fungi. Today, more than 80% of land plants still acquire nutrients from soil using arbuscular mycorrhizas, reflecting the evolutionary success of this mutualistic symbiosis (Jakobsen, 1995; Smith and Read, 1997). During arbuscular mycorrhiza formation, plant and fungus integrate structurally and functionally to become a single supraorganism (Azcón-Aguilar and Bago, 1994) whose physiological capacities are superior to those of either organism alone (Jakobsen, 1995). This integration improves nutrient uptake by the plant and allows the heterotrophic, obligately symbiotic fungus to complete its life cycle. Understanding AM physiology has practical and fundamental significance, but requires first a knowledge of the metabolism of each partner.

Carbon metabolism of AM fungi has been reviewed by Jakobsen (1995). Lipids are the major form of carbon in AM fungal spores, hyphae, and vesicles (Cox et al., 1975), comprising 45% to 95% of the spore C pool, depending on the species (Beilby, 1983; Jabaji-Hare, 1988; Bécard et al., 1991). Triacylglycerides account for most of the lipids in spores (Beilby and Kidby, 1980; Jabaji-Hare, 1988; Gaspar et al., 1994). During spore germination (AM fungal asymbiotic growth), the triacylglyceride content remains constant for approximately 5 d (Bécard et al., 1991; Gaspar et al., 1994), after which time it decreases (Beilby and Kidby, 1980; Gaspar et al., 1994), probably through the activity of a membrane-bound lipase (Gaspar et al., 1997). At the same time, an increase in phospholipids is observed during germ tube growth (Beilby and Kidby, 1980). This latter result, together with the incorporation of label from ¹⁴C-acetate into triacylglycerides during spore imbibition, led Beilby (1983) to suggest that lipid synthesis and breakdown occurred simultaneously during AM fungal asymbiotic growth.

The dominant storage carbohydrates detected in AM fungal hyphae and spores are glycogen and trehalose (Amijee and Stribley, 1987; Bécard et al., 1991; Bonfante et al., 1994; Shachar-Hill et al., 1995; Bago et al., 1998; Pfeffer et al., 1999). In vivo C-NMR studies revealed that such carbohydrates were formed by the AM fungus Glomus etunicatum shortly after providing colonized leek roots with ¹³C-labeled Glc (¹³C-Glc) (Shachar-Hill et al., 1995). Half of the trehalose stored in G. etunicatum spores is broken down during the 5 d after germ tube emergence, indicating that this carbohydrate sustains fungal growth at the very early stages of germination (and prior to lipid breakdown) (Bécard et al., 1991). CO₂ also seems to play an important role in AM fungal axenic growth: Bécard and Piché (1989) found a 10-fold increase in Gigaspora margarita germ tube development when a 0.5% CO₂ atmosphere was supplied.

Assays of enzymatic activities have indicated the presence of several metabolic pathways during asymbiotic growth of Glomus mosseae (Macdonald and Lewis, 1978) and Gi. margarita (Saito, 1995). Of the glycolytic enzymes, phosphofructokinase (EC 2.7.1.11) and glyceraldehyde-P dehydrogenase (EC 1.2.1.12) have been detected (Macdonald and Lewis, 1978; Saito, 1995). The presence of the tricarboxylic acid cycle (TCA) enzymes malate dehydrogenase (EC 1.1.1.37) and succinate dehydrogenase (EC 1.3.5.1) has also been demonstrated (Macdonald and Lewis, 1978; Saito, 1995). The activity of Glc-6-P dehydrogenase (EC 1.1.1.49) (Macdonald and Lewis, 1978; Saito, 1995) was found to be higher in germinated spores of Gi. margarita than in intraradical hyphae (Saito, 1995), suggesting a role for the pentose phosphate pathway (PPP) in the developing spore. More recently, the presence of the enzyme 3-phosphoglycerate kinase (EC 2.7.2.3) has been revealed by differential RNA display in G. mosseae germinating spores and mycorrhizal roots (Harrier et al., 1998). This enzyme is implicated in both glycolysis and gluconeogenesis.

Recently, Pfeffer et al. (1999) used AM monoxenic cultures of Glomus intraradices and Ri T-DNA-transformed carrot (Daucus carota) roots to study C metabolism in the symbiotic state. That study indicated that uptake, transport, and metabolism are very different in the intraradical and extraradical parts of AM fungi in the symbiotic state. Whereas intraradical fungal structures take up carbon (as hexose) and synthesize lipids, the extraradical mycelium does neither. Since earlier results indicated differences in the metabolism of the AM fungus when growing in symbiosis or asymbiotically (Harrison and van Buuren, 1995; Shachar-Hill et al., 1995), the aim of the present work was to extend our knowledge of the sources and fates of C compounds during AM fungal spore germination and the metabolic pathways connecting both.

	MATERIALS AND METHODS

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Production and Labeling of Spores

Spores and extraradical hyphae from the fungal compartment were recovered by blending the solidified medium in sodium citrate solution (10 mM) at high speed for 45 s in a commercial blender (Waring). Fungal tissue was collected on a 38-µm sieve and rinsed with water. Spores from the fungal compartments of three plates were combined for each sample. For ungerminated spore samples, fungal tissue was frozen at 80°C immediately after collection. Spores were germinated while incubating in liquid M medium (Bécard and Fortin, 1988) without Suc for 14 d (32°C in 2% CO₂, in the dark). When prelabeled spores were germinated, no carbon source was added to the liquid medium. ¹³C-labeled substrates (99% ¹³C-enriched) were added as filter-sterilized solutions to the M medium of unlabeled spores for a final concentration of 25 mM for ¹³C₁- or ¹³C_1,2-Glc, ¹³C₁-Fru, or ¹³C₁-mannitol experiments and to 4 mM for ¹³C₁- or ¹³C₂-acetate experiments. For ¹³CO₂ labeling, unlabeled spores were incubated at room temperature in the presence of 2% ¹³CO₂ (generated by addition of a 50% solution of lactic acid to solid K₂¹³CO₃ in a sealed 6-L desiccator). In all cases more than 80% of the spores germinated within 3 d and formed a macroscopically visible diffuse mycelium during the incubation period. After incubation, the fungal material was recovered and frozen at 80°C until carbohydrate and lipid extraction.

Extraction and NMR Sample Preparation

To extract neutral lipids and fatty acids, the solid residue remaining after MeOH/H₂O extraction was freeze-dried and re-extracted in 30 to 40 mL of boiling isopropyl alcohol for 20 min. After filtering, the solvent was removed by evaporation under a stream of nitrogen. These extracts were dissolved in ²H chloroform for NMR analysis.

NMR Spectroscopy

¹³C spectra were accumulated with 80° pulse angles, WALTZ-¹H decoupling, and a recycle time of 4.2 s (MeOH extracts) or 13.2 s (isopropyl alcohol extracts). For ¹H spectra, 80° pulses and recycle times of 4.5 s were used; when necessary, 12-s recycle times were employed to prevent distortion of the relative intensities of the ¹H-¹²C and ¹H-¹³C signals (London, 1988). Total acquisition times for both ¹³C and ¹H extracts were between 12 and 36 h depending on the concentration of each sample.

The identification of peaks in ¹³C and ¹H spectra was made from literature values (Gunstone et al., 1977, for lipids; Fan, 1995, for all other metabolite assignments), via comparison of spectra of purified compounds (e.g. trehalose in Fig. 1A) or natural abundance (n.a.) signals of unlabeled tissue extracts (e.g. Fig. 1B), by spiking extracts with purified compounds, and/or by analyses of H and ¹H-¹³C correlation spectra (Pfeffer et al., 1999). ¹³C chemical shifts were referenced to the signals of C₁-trehalose (T₁, 94.1 ppm) or chloroform (77.0 ppm). ¹H signals were referenced to water (4.67 ppm at 35°C) or to the chloroform peak (7.24 ppm). Carbon and proton shifts were expressed in parts per million with respect to tetramethylsilane at 0 ppm.

View larger version (22K): [in this window] [in a new window]   Figure 1. 13C-n.a. signals of trehalose (A) and an isopropyl alcohol extract of unlabeled AM fungal spores (B). Insets, Chemical structure of trehalose and of a triacylglyceride showing the correspondence between the different C positions and their chemical shift in the NMR spectra.

Quantification of ¹³C-Labeling

View larger version (20K): [in this window] [in a new window]   Figure 2. 13C-NMR spectra of MeOH/H2O extracts of asymbiotic fungal tissue following different treatments. A, Spores prelabeled but not germinated. Inset, 1H spectrum of the same sample showing the 1H resonance of the unidentified betaine-like compound and the upfield 13C-1H satellite used for measuring the 13C content in this compound. B, Asymbiotic tissue prelabeled as in A and then germinated for 14 d without external label. C, Unlabeled spores germinated for 14 d in the presence of 25 mM 13C1-Glc. Inset, 1H spectrum of the same sample showing the 1H resonance of trehalose and a 13C-1H satellite used for measuring the 13C content in the C1 position. D, Unlabeled spores germinated for 14 d in the presence of 13CO2. E, Same as D, except germinated in the presence of 4 mM 13C1-acetate. F, Same as E, except 13C2-acetate. T1 to T6, Trehalose resonances (C1-C6); w, choline; v, GAB-betaine; n, unidentified signal.

View larger version (21K): [in this window] [in a new window]   Figure 3. 13C-NMR spectra of isopropyl alcohol extracts. A, Spores prelabeled with 13C1-Glc and germinated for 14 d in liquid M medium with no carbon. Inset, 1H spectrum of the same sample showing the 1H resonance of the 13Glyc1, 3 and the downfield 13C-1H satellite used for measuring its 13C content. B, Unlabeled spores germinated for 14 d in M minus C liquid medium in the presence of 13C1-Glc. Boxed inset, Spectrum expanded to better detect the signals of interest.

	RESULTS

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Labeling in Fungal Carbohydrate

Levels of ¹³C-labeling (percent in excess of n.a.) for each C position of fungal trehalose (T₁-T₆) following various labeling treatments are shown in Table I. In prelabeled, non-germinated spores (Fig. 2A), labeling was found in all C positions, with T₁, T₆, T₅, and T₃ having the most incorporation of label. When C-prelabeled spores were germinated without exogenous label, a similar pattern was observed in trehalose with slight decreases in T₁ and T₃ labeling (Fig. 2B; Table I).

Spores germinated for 14 d showed different ¹³C-labeling patterns depending on the substrate provided. Spores exposed to ¹³C₁-Glc (Fig. 2C) or ¹³C₁-Fru (not shown) yielded trehalose mostly labeled in T₁ (Table I). We observed no evidence of scrambling of the label provided as T₁ into the T₆ position. These results were confirmed when using ¹³C_1,2-Glc as a substrate (Table I), with most of the label being found in the T₁ and T₂ positions. Incubation with ¹³C_1,6-mannitol produced no labeling in trehalose or elsewhere (not shown). Spore germination in the presence of either ¹³CO₂ or ¹³C₁-acetate yielded trehalose with the highest labeling found in the T₄ position (Fig. 2, D and E; Table I). In these two treatments the T₃ position was also highly labeled, T₂ and T₁ were less so, and T₆ and T₅ were either minimally labeled or unlabeled. In contrast, upon exposure to ¹³C₂-acetate, detected fungal trehalose displayed a very different labeling pattern, with T₄ containing the least amount of label and T₆ and T₅ having the highest (Fig. 2F; Table I). This latter labeling pattern closely resembles the one observed for prelabeled, germinated spores (Table I).

Splittings (multiplets) observed in trehalose peaks, particularly for experiments with ¹³C₂-acetate (Fig. 2F) but also in extracts of ¹³C₁-acetate and ¹³CO₂ labeled samples (Fig. 2, D and E), were due to homonuclear coupling between ¹³C nuclei at adjacent carbon positions of the same molecules. These couplings arising from multiply-labeled molecules are expected when a product such as hexose is made from more than one molecule of labeled substrate.

The ¹³C spectra of MeOH/H₂O extracts also showed evidence of labeling in two amino acids: Glu and Arg. The small signals from Glu (Fig. 2, A, B, and F) showed that it was labeled in  and  carbons in prelabeled, germinated spores, whereas labeling was only detected in the  carbon in prelabeled, nongerminated spores. Spores germinated in ¹³C₁-acetate had labeling in the CO position (182.0 ppm, not shown), and the ones germinated in ¹³C₂-acetate had labeling in the , , and  positions of Glu. The C spectra also showed consistent labeling of Arg. Spectra from prelabeled, germinated spores showed labeling at the , , , and  carbons of Arg; unlabeled spores germinated in the presence of ¹³C₁-Glc showed labeling at the  and  carbons; ¹³CO₂ resulted in labeling in the terminal CN and carboxyl positions; C₁-acetate labeled CH₂ and carboxyl groups; and ¹³C₂-acetate labeled the , , and  carbons (Fig. 2; Table I). Notably, no Arg signals were found in spectra of prelabeled, non-germinated spores.

A single resonance with a chemical shift of 52.9 ppm in the ¹³C spectra of MeOH/H₂O extracts of prelabeled spores (germinated or not) arises from an unknown compound (Fig. 2, A and B, [CH₃]₃N⁺). This ¹³C signal was shown (by ¹H and ¹H-¹³C correlation spectra, see ``Materials and Methods'') to arise from a carbon with attached protons whose signal in the ¹H spectrum is a singlet at 3.25 ppm (Fig. 2A, inset). The ¹³C and ¹H-chemical shifts and ¹³C-¹H-coupling (145 Hz) are similar to those of methyl groups of betaines ([CH₃]₃N⁺). Signals from this putative (CH₃) ₃N⁺ group were also detectable in spectra of unlabeled spores germinated in ¹³C₁-Glc (Fig. 2C) and ¹³C_1,2-Glc (not shown). Estimations of the ¹³C content of this group (Table I) were carried out by ¹H-¹³C-satellite measurements (Fig. 2A, inset). The (CH₃)₃N⁺ peak of this betaine-like compound showed approximately 8% ¹³C enrichment in prelabeled spores (either germinated or not), but less than 2% in ¹³C₁-Glc labeling experiments, whereas in other treatments the (CH₃) ₃N⁺ peak corresponded to n.a. signals.

Labeling in Fungal Lipids

	DISCUSSION

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The fact that AM fungi do not grow axenically has puzzled and frustrated researchers for over three decades. Limitations in the metabolism or uptake of carbon in the asymbiotic state have been proposed to explain this failure (for review, see Azcón-Aguilar et al., 1998). To test this possibility it is necessary to define which pathways, if any, may be deficient in the germinating spore. To this end, we have compared the labeling patterns in different products of metabolism with the patterns expected from the operation of known metabolic pathways. Figure 4 summarizes our interpretation of the results by showing the flow of labeled C from each substrate provided to each product detected via key intermediate compounds whose presence is implied but which were not detected.

View larger version (26K): [in this window] [in a new window]   Figure 4. A simplified scheme of the AM fungal metabolic pathways revealed active in the present study. Labeled substrates provided in different experiments are shown in boxes, products detected are shown in capital letters, and certain metabolic intermediates or pools whose presence is inferred but were not detected are shown in italics. 1, Trehalose synthesis from Glc phosphate and UDP-Glc; 2, trehalose breakdown by trehalase; 3, the PPP (also known as the hexose monophosphate pathway); 4, gluconeogenesis, starting with PEP and involving reversal of glycolysis with several differences; 5, glycolysis (the Embden-Meyerhoff-Parnas pathway); 6, non-photosynthetic one-carbon metabolism, typically involving tetrahydrofolate (THF) and S-adenosyl Met as carriers of the methyl groups; 7, lipolysis: storage lipid (tryacylglycerides) breakdown to glycerol and fatty acids, and subsequent glyoxysomal fatty acid -oxidation to acetyl CoA; 8, Dark fixation of CO2 by pyruvate carboxylase to oxalocetate (8a) or carbamoyl P synthethase (8d); 9, glyoxylate cycle (or shunt) involving the production of glyoxylate from acetyl-CoA units via part of the TCA cycle; the glyoxylate is condensed with acetyl-CoA (from triacylglyceride degradation) to form triose and CO2; 10, TCA (also known as the Krebs cycle); 11, Arg synthesis by enzymes of the urea cycle including the incorporation of carbon from carbamoyl P.

Trehalose as an Indicator of Hexose Metabolism

Hexose Uptake and Utilization

Dark Fixation of ¹³CO₂ and Gluconeogenesis

Glyoxylate Cycle

The labeling pattern of trehalose extracted from germinating spores incubated with ¹³C₁-acetate was similar to that observed in ¹³CO₂ labeling experiments (Table I). This could arise from the liberation (as ¹³CO₂) of the labeled C₁ carbon of acetate via the TCA cycle (pathway 10 of Fig. 4) followed by dark re-fixation of the released ¹³CO₂, as indicated above. However, the same labeling pattern is also predicted by the conversion of acetate to triose via the glyoxylate cycle (Fig. 4, pathways 9, 4, and 1).

The results of labeling with ¹³C₂-acetate suggest that both of these mechanisms occur. The glyoxylate cycle transfers label supplied in C₂ of acetate to carbons 6, 1, 5, and 2 of trehalose (following pathways 9, 4, and 1 of Fig. 4), and the labeling observed in carbons 3 and 4 can be accounted for by release of label as CO₂ (via second and further turns of the TCA cycle) and its refixation (Fig. 4, pathways 8a, 8b, 8c, 4, and 1). The very high level of labeling reached in trehalose when ¹³C₂-acetate was provided (close to 80% in T₆) indicates a high metabolic flux from acetyl-CoA to hexose. Such a high flux would be expected if most of the intracellular hexose during the asymbiotic phase were made from storage lipids (sequentially following pathways 7, part of 10, 9, and 4 of Fig. 4).

Results from prelabeled spores are also consistent with conversion of lipid to trehalose during spore germination. The fatty acids in prelabeled spores are labeled predominantly in the even-carbon positions of the fatty acid chains (Pfeffer et al., 1999) and thus yield C₂-labeled acetyl CoA, as would be expected of ¹³C₂ acetate. Indeed, the relative enrichment in different positions of the trehalose from prelabeled, germinated spores (Table I) is similar to that after ¹³C₂-acetate labeling.

PPP

Amino Acid Synthesis

There are a number of possible roles for Arg during AM fungal spore germination. One of them is as a charge balance for polyphosphates (Cramer et al., 1980; Cramer and Davis, 1984; Bücking et al., 1998). However, the state of polyphosphates in mycorrhizal fungi has been the subject of considerable debate (Kulaev, 1979; Martin et al., 1985; Orlovich and Ashford, 1993; Bücking et al., 1998), and in our view, there is still no conclusive evidence that Arg (or other basic amino acids in the fungal vacuole) is bound to these macromolecules. Other possible explanations for the observed formation of Arg during germination include roles in nitrogen storage, as a compatible osmolyte, and as a possible form of N transferred to the host.

A Betaine-Like Compound

Absence of Storage Lipid Synthesis

Carbon Metabolism in the Asymbiotic versus the Symbiotic AM Fungus

	FOOTNOTES

   Received March 24, 1999; accepted June 9, 1999.

	ACKNOWLEDGMENT

We thank Dr. Kathleen Valentine of the University of Pennsylvania NMR facility for obtaining some of the ¹³C-¹H satellite spectra.

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