From the
Department of Plant Sciences, University of Oxford, South Parks Road, Oxford OX1 3RB, United Kingdom, the
Medical Research Council Dunn Human Nutrition Unit, Hills Road, Cambridge CB2 2XY, United Kingdom, and the ||School of Biomedical and life Sciences, University of Western Australia, Crawley 6009 WA, Australia
Received for publication, January 31, 2003 , and in revised form, March 28, 2003.
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ABSTRACT |
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INTRODUCTION |
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An alternative means of attaining a regulated uncoupling of plant mitochondria is via the activity of the mitochondrial uncoupling protein (UCP).1 UCP was first discovered in the brown adipose tissue of mammals where it functions to catalyze an uncoupled respiration of fatty acids to generate heat for thermogenesis (6). Consistent with this role, UCP1 is activated by anionic fatty acids, which are thought to directly participate in its catalytic function (79). Since then, a number of UCP1 homologues have been discovered in mammals (UCP 25), which were initially also assumed to catalyze mitochondrial proton leak (although not necessarily for the generation of heat energy). However, there is still considerable controversy as to whether the UCP1 homologues actually catalyze a proton leak in vivo and the function of these proteins remains to be established (10).
In plants, an activity reminiscent of UCP1 has also been identified (11). This activity was characterized by a reduction in membrane potential of isolated potato mitochondria that was stimulated by anionic fatty acids and inhibited by nucleotides, characteristics that distinguish uncoupling protein from other anion carrier protein-mediated proton leak. Two years later the first plant UCP gene was cloned (StUCP from potato) (12), and since then UCP genes have been identified from Arabidopsis (13, 14), skunk cabbage (15), wheat (16), and rice (17). UCP-like activity has been observed in isolated mitochondria from a number of plant species and the potato UCP activity has been purified and its proton transport properties recovered by reconsitution into liposomes (18). Furthermore, reconstitution of the AtUCP1 gene product into liposomes has provided the first link between a plant UCP gene and proton transport activity (19). However, a recent study has shown that when care is taken to avoid artifacts caused by extraneous effects of nucleotides on other electron transport chain components, the fatty acid-stimulated proton leak of potato mitochondria is not inhibited by nucleotides (20). This casts considerable doubt as to whether UCP contributes in any significant way to proton leak in plant mitochondria.
In this paper we sought to undertake a careful re-examination of the conditions that lead to proton leak in potato mitochondria and to establish under which conditions, if any, UCP contributes to this proton leak. We confirm previous observations that fatty acids stimulate a proton leak in potato mitochondria respiring NADH and that this leak is not inhibited by nucleotides. However, when exogenous superoxide is generated (by the addition of xanthine and xanthine oxidase) an additional proton leak is observed that is sensitive to GTP. This suggests that, as is the case in animals, plant UCP requires the presence of superoxide for full activity (21, 22). We provide further evidence that this fatty acid-dependent, superoxide-stimulated, and nucleotide-sensitive proton leak is related to UCP activity by studying proton leak in mitochondria isolated from transgenic potato plants overexpressing the potato StUCP gene.
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EXPERIMENTAL PROCEDURES |
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Growth of Potato PlantsPotato (Solanum tuberosum L c.v. Desiree) were grown by planting sprouted tubers in 150-mm diameter pots containing general purpose compost. The plants were maintained in a glasshouse at 1625 °C with a 16-h photoperiod of natural daylight supplemented to give a minimum irradience of 150 µE m2 s1. Tubers were harvested after 10 weeks and stored at 4 °C for at least 1 week prior to use.
Production of Transgenic Plants Overexpressing the StUCP cDNAThe full-length StUCP cDNA (12) was cloned into the binary plant expression vector pBinAR (23) between the 35S cauliflower mosaic virus promotor (24) and the polyadenylation signal of the T-DNA octopine synthase gene (25) using standard techniques. The resulting construct was introduced into Agrobacterium tumefaciens and used to transform Solanum tuberosum L c.v. Desiree as described previously (26).
Northern and Western Blot AnalysesTotal RNA was extracted from leaves and analyzed by Northern blot using radiolabeled StUCP as a probe as described previously (12). UCP protein content in isolated mitochondrial samples was assessed by Western blot analysis using an antibody raised against soybean UCP as described in Ref. 27.
Isolation of Potato Tuber MitochondriaAll procedures were done at 4 °C. Approximately 100 g of tuber material was homogenized into 100 ml of extraction medium (0.3 M mannitol, 50 mM Tes-NaOH (pH 7.5), 0.5% (w/v) BSA, 0.5% (w/v) polyvinylpyrrolidone-40, 2 mM EGTA, and 20 mM cysteine) using an electric juice extractor. The resulting homogenate was filtered through Miracloth (CN Biosciences, Nottingham, UK) and centrifuged at 1,500 x g for 5 min. The supernatant was then centrifuged at 18,000 x g for 10 min to recover an organelle pellet. This pellet was resuspended in wash buffer (0.3 M mannitol, 20 mM Tes-KOH (pH 7.5)) and layered onto a stepped gradient of Percoll (Amersham Biosciences Ltd., Little Chalfont, UK) consisting of steps of 50, 28, and 20% (v/v) Percoll with 0.3 M mannitol as an osmoticum. After centrifugation at 43,000 x g for 30 min, mitochondria were recovered from the 28%/50% Percoll interface. Mitochondria were further purified on a second self-forming Percoll gradient consisting of 28% Percoll with 0.3 m sucrose as an osmoticum.
Measurement of Proton ConductanceProton conductance was determined by simultaneous measurement of oxygen consumption and mitochondrial membrane potential using electrodes sensitive to oxygen and the potential-dependent probe, TPMP+ as described previously (28). A reaction chamber of capacity 2 ml was constructed such that the mitochondrial suspension was in contact with both electrodes. Mitochondria (400 µg) were resuspended in 2 ml of assay medium (0.3 M mannitol, 1 mM MgCl2, 100 mM KCl, 10 mM KH2PO4 (pH 7.0) 0.1% (w/v) BSA (fraction V, fatty acid free, Roche Diagnostics Ltd., Lewes, UK)) containing 50 µM xanthine, 1 µM oligomycin, and 0.1 µM nigericin (to collapse the difference in pH across the inner membrane). The electrode was calibrated with sequential additions of TPMP+ to a final concentration of 5 µm. Then NADH was added to a concentration of 1 mM to start the reaction. Membrane potential was progressively inhibited by the addition of KCN to a final concentration of between 0.6 and 70 µM. At the end of each run, 2 µM carbonyl cyanide p-trifluoromethoxyphenylhydrazone was added to dissipate the membrane potential completely, releasing all the TPMP+ back into the medium and allowing correction for any small electrode drift. Linoleic acid (final concentration, 300 µM), GTP (final concentration, 2 mM), xanthine oxidase (0.015 unit; Roche Diagnostics Ltd.) and superoxide dismutase (24 units, CN Biosciences (UK) Ltd., Nottingham, UK) were added as indicated.
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RESULTS |
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Addition of linoleic acid to a concentration of 300 µM (giving a molar ratio of fatty acid to albumin of 20) resulted in an increased rate of proton conductance (Fig. 1a). However, as was previously reported (20), this proton conductance was not inhibited by the addition of GTP (Fig. 1a). Since mammalian UCPs 1 and 2 have been shown to require the presence of superoxide for full activation (21, 22), we investigated the effect of superoxide on the linoleic acid-induced proton conductance (Fig. 1b). We found that in the presence of linoleic acid, superoxide induced an additional proton conductance (compare Fig. 1b with 1a). Furthermore, the addition of GTP reduced this rate of proton conductance back to a level similar to that observed in the presence of linoleic acid alone (Fig. 1, a and b). The superoxide effect was not seen in the absence of linoleic acid (data not shown).
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Proton Conductance in Mitochondria from Transgenic Potato Tubers Containing Increased UCP ContentTransgenic potato plants were generated that expressed the StUCP cDNA (12) under the control of a constitutive promotor (see "Experimental Procedures" for more details of the constructs used to generate transgenic plants). On the basis of an initial screen of StUCP expression in 100 transgenic lines, two independent lines were selected that consistently showed increased abundance of the StUCP mRNA (data not shown). Northern analysis of StUCP mRNA content confirmed the increased expression of StUCP in these two lines (Fig. 2a). These lines contained increased levels of UCP protein (as a proportion of total mitochondrial protein) as determined by immunodetection of the UCP protein with an antibody raised against soybean UCP (27) (Fig. 2b). To quantitate the increase in UCP protein, we established the linearity of response of the UCP antibody to increasing amounts of mitochondrial protein (data not shown) and loaded appropriate amounts of protein such that the signal for each line was within the linear range (Fig. 2c). Band intensity was determined using the Multianalyst software package (Bio-Rad Laboratories Ltd., Hemel Hempstead, UK). Band intensity was expressed per milligram of total mitochondrial protein to give a measure of UCP content. We estimated that line 18 contains 13 times as much UCP as WT and line 63, twice as much. The mitochondrial samples used for this analysis were derived from a pool of three independent mitochondrial isolations of each line and were the same mitochondrial samples used for proton leak assays.
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We investigated the effect of this increased UCP content on proton conductance (Fig. 3). In the presence of linoleic acid alone the proton leak of mitochondria from the two transgenic lines was indistinguishable from wild type (Fig. 3, a and d). However, when xanthine/xanthine oxidase was added (to generate superoxide) in addition to linoleic acid there was an increased rate of proton conductance in mitochondria from the transgenic lines (Fig. 3, b and e). This increased rate of proton conductance was specifically dependent on the presence of superoxide as the addition of superoxide dismutase returned proton leak to wild type levels (Fig. 3b, inset). Furthermore, the superoxide-stimulated proton conductance was completely abolished by the addition of GTP (Fig. 3, c and f). We calculated the rate of proton conductance from the curves shown in Fig. 3 by assuming an H+/O ratio of 6 for oxidation of external NADH. The proton conductance was calculated at a membrane potential of 130 mV. In comparison to wild type there was a statistically significant increase in proton conductance in the transgenic lines (t test; p < 0.05) of 3.0-fold in line 18 and 2.3-fold in line 63 (Table I).
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DISCUSSION |
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We have shown that in the presence of exogenous superoxide, linoleic acid stimulates a proton leak in isolated potato mitochondria that is inhibited by the nucleotide, GTP (Figs. 1 and 3). This is characteristic of UCP activity and suggests that superoxide may be required for full activity of potato UCP, as is the case for mammalian UCPs (21, 22). A reactive oxygen species-dependent uncoupling of wheat mitochondria in the presence of fatty acid has previously been observed, but the nucleotide sensitivity of this effect was not tested (32). To investigate whether superoxide-dependent, fatty acid-stimulated proton conductance is indeed related to the activity of UCP, we examined the effect of increased mitochondrial UCP content in transgenic plants overexpressing the StUCP gene. Mitochondria from two independent transgenic lines contained 13-fold (line 18) and 2-fold (line 63) more UCP protein than WT (Fig. 2). This confirms that overexpression of StUCP results in a measurable increase of UCP protein and that this protein is correctly targeted to the mitochondrion. The rate of proton conductance in mitochondria isolated from these two lines was signficantly higher than WT when assayed in the presence of superoxide and linoleic acid together but unaltered in the presence of linoleic acid alone (Fig. 3). This confirms that superoxide-dependent, linoleic acid-stimulated uncoupling is catalyzed by StUCP. The fact that this UCP-related uncoupling is completely inhibited by GTP (Fig. 3) provides a specifc assay for UCP that can be utilized in future studies. The increase in rate of proton conductance was proportional to the increase in UCP protein content in one of the lines (line 63; proton conductance rate, 2.3-fold WT and UCP protein content, 2-fold WT), providing further evidence that the change in proton conductance is directly linked to UCP. However, in a second line the increase in proton conductance was much less than the increase in UCP protein content (line 18; proton conductance rate, 3.0-fold WT and UCP protein content, 13-fold WT). It is not clear why the relationship is not directly proportional in this line, although it may be related to the greater increase in UCP protein content. Previously, it has been observed that the uncoupling effect of UCP when overexpressed to very high levels is artifactual, presumably due to a misfolding of the UCP protein in the mitochondrial membrane (33). Under such circumstances it is conceivable that the direct relationship between UCP protein content and proton conductance rate may break down. However, the fact that the increased proton conductance in line 18 is completely inhibited by GTP (Fig. 3b) leads us to believe that the additional UCP in line 18 is correctly folded and inserted into the membrane (since if it were not, the resulting artifactual uncoupling would be unregulated). Alternative explanations for the lower than expected increase in proton conductance rate in this line are that some unknown endogenous factor is limiting the proton leak rate or that above 3-fold expression only some of the overexpressed UCP is inserted correctly into the membrane, while the rest has no effect on proton leak rate in these mitochondria.
This work, for the first time, shows that changes in UCP content can affect the rate of proton leak in plant mitochondria providing firm evidence that plant homologues of mammalian UCPs do function as uncoupling proteins in planta. Furthermore, we have demonstrated that xanthine/xanthine oxidase stimulates this proton leak, which suggests that superoxide is required for full activity of potato UCPs. The abolishment of the xanthine/xanthine oxidase effect by superoxide dismutase confirms that is the specific presence of the superoxide anion that is responsible for the activation of UCP. Using the conditions we have described (isolated mitochondria respiring NADH in the presence of nigericin and oligomycin) it is possible to specifically assay UCP as the superoxide-dependent, fatty acid-stimulated proton leak that is inhibited by GTP. Previously, specific assay of UCP in situ in plant mitochondria has been complicated by the possibility that other carrier proteins can also catalyze a fatty acid-dependent proton leak. Thus, nucleotide inhibition is required to demonstrate specificity of the assay for UCP. Often, ATP is used as an inhibitory nucleotide, which can cause problems in interpretation due to its interactions with other components of the mitochondrial respiratory pathway, particularly activation of succinate dehydrogenase in mitochondria respiring succinate (20, 29). When care is taken to avoid these problems, the fatty acid-stimulated proton leak of potato mitochondria is not nucleotide inhibitable, suggesting that it is not catalyzed by UCP (20). However, we have shown that in the presence of exogenous superoxide there is an additional proton leak that is inhibitable by GTP and is specific to UCP. This contrasts with results obtained when a purified potato mitochondria UCP was reconstituted into liposomes (18). In this instance, the purified UCP catalyzed a fatty acid-dependent proton conductance that was inhibitable by nucleotides without any requirement for superoxide. However, it is not clear whether the purified UCP protein used in this study is the same protein as the StUCP gene product, so it is difficult to compare the two experiments. It is possible that different potato UCPs have different properties. Alternatively, the process of reconstituting the UCP protein into an artificial membrane bilayer may have artificially generated sufficient endogenous superoxide (or related molecules) to activate UCP or may have reduced its sensitivity to superoxide or otherwise altered its regulatory properties.
The requirement of a plant UCP for superoxide provides an interesting insight into the biological role of uncoupling proteins in plants. Assuming that there is a functional association between superoxide accumulation and UCP activity, it seems reasonable to argue that UCP may function to reduce reactive oxygen species accumulation. It is known that the mitochondrial electron transport chain is a source of superoxide, mainly as a result of leakage of single electrons to oxygen (34). Conditions that reduce the flow of electrons through the respiratory chain effectively increase the half-life of donor radicals and thereby increase the production of superoxide and associated reactive oxygen species. By facilitating a high rate of respiration, the activity of UCP can reduce the rate of reactive oxygen species production. This role of UCP is consistent with induced expression of UCP genes in dicotyledenous plants by low temperature (12, 14, 15), a stress condition that leads to reactive oxygen species accummulation. An Arabidopsis UCP gene has also been shown to be induced by hydrogen peroxide treatment (35). Indirect evidence for the role of UCP in the prevention of reactive oxygen species production by plant mitochondria is provided by the observation that the addition of linoleic acid to isolated potato mitochondria reduces the rate of production of hydrogen peroxide. Conversely, addition of ATP (to inhibit UCP) increases hydrogen peroxide production (36). At this stage, it is not possible to say whether all UCPs will turn out to be involved in reducing reactive oxygen species production. The Arabidopsis genome contains four putative UCP genes (37), and it is likely that some of these genes may play a different role. Intriguingly, UCP genes from monocotyledenous plants do not appear to be induced by low temperature (16, 17), which may indicate that UCP is not the main mechanism for avoiding mitochondrial oxidative stress in such plants.
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FOOTNOTES |
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¶ Present address: Nestlé Research Center, CH-1000 Lausanne 26, Switzerland.
** To whom correspondence should be addressed: Dept. of Plant Sciences, University of Oxford, South Parks Rd., Oxford OX1 3RB, UK. Tel.: 44-1865-275137; Fax: 44-1865-275074; E-mail: Lee.sweetlove{at}plants.ox.ac.uk.
1 The abbreviations used are: UCP, uncoupling protein; Tes, 2-{[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]amino}ethanesulfonic acid; BSA, bovine serum albumin; AOX, alternative oxidase; WT, wild type; TPMP, triphenylmethylphosphonium.
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REFERENCES |
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