Functions of the Membrane-Associated and Cytoplasmic Malate Dehydrogenases in the Citric Acid Cycle of Corynebacterium glutamicum

doi:10.1128/JB.182.24.6884-6891.2000

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Journal of Bacteriology, December 2000, p. 6884-6891, Vol. 182, No. 24
0021-9193/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Functions of the Membrane-Associated and Cytoplasmic Malate Dehydrogenases in the Citric Acid Cycle of Corynebacterium glutamicum

Douwe Molenaar,^* Michel E. van der Rest, André Drysch, and Raif Yücel

Biotechnologisches Zentrallabor, Geb. 25.12, Heinrich-Heine-Universität, D-40225 Düsseldorf, Germany

Received 17 May 2000/Accepted 21 September 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Like many other bacteria, Corynebacterium glutamicum possesses two types of L-malate dehydrogenase, a membrane-associatedmalate:quinone oxidoreductase (MQO; EC 1.1.99.16) and a cytoplasmicmalate dehydrogenase (MDH; EC 1.1.1.37) The regulation of MDHand of the three membrane-associated dehydrogenases MQO, succinatedehydrogenase (SDH), and NADH dehydrogenase was investigated.MQO, MDH, and SDH activities are regulated coordinately in responseto the carbon and energy source for growth. Compared to growthon glucose, these activities are increased during growth on lactate,pyruvate, or acetate, substrates which require high citric acidcycle activity to sustain growth. The simultaneous presence ofhigh activities of both malate dehydrogenases is puzzling. MQOis the most important malate dehydrogenase in the physiology ofC. glutamicum. A mutant with a site-directed deletion in the mqogene does not grow on minimal medium. Growth can be partiallyrestored in this mutant by addition of the vitamin nicotinamide.In contrast, a double mutant lacking MQO and MDH does not groweven in the presence of nicotinamide. Apparently, MDH is ableto take over the function of MQO in an mqo mutant, but this requiresthe presence of nicotinamide in the growth medium. It is shownthat addition of nicotinamide leads to a higher intracellularpyridine nucleotide concentration, which probably enables MDHto catalyze malate oxidation. Purified MDH from C. glutamicumcatalyzes oxaloacetate reduction much more readily than malateoxidation at physiological pH. In a reconstituted system withisolated membranes and purified MDH, MQO and MDH catalyze thecyclic conversion of malate and oxaloacetate, leading to a netoxidation of NADH. Evidence is presented that this cyclic reactionalso takes place in vivo. As yet, no phenotype of an mdh deletionalone was observed, which leaves a physiological function forMDH in C. glutamicumobscure.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Recently, we discovered the gene for a relatively unknown type of malate dehydrogenase called malate:quinone oxidoreductase(MQO; (EC 1.1.99.16) [also called "malate dehydrogenase (acceptor)"](22). Like the NAD-dependent malate dehydrogenase (MDH; EC 1.1.1.37),MQO catalyzes the oxidation of malate to oxaloacetate. The enzymeis membrane associated, probably through weak ionic or hydrophobicinteractions. Tightly bound flavin adenine dinucleotide servesas a prosthetic group, and quinones instead of NAD are the electronacceptors of the enzyme. The quinones are subsequently oxidizedby the electron transfer chain. These properties place MQO, likesuccinate dehydrogenase (SDH), both in the electron transfer chainand in the citric acid cycle. The existence of MQO as an enzymaticentity was first proven in 1956 (8). MQO activity was sincethen observed in several bacteria, both gram positive and gramnegative (see references cited in reference 22) but not in archaebacteriaor eucaryotes. After identification (for the first time) of aDNA sequence encoding an MQO in Corynebacterium glutamicum, itwas found that similar sequences with, until then, unknown functionexisted in many other bacteria (see Fig. 1 in references 16and 22).

C. glutamicum possesses both MQO and MDH. Moreover, as shown below, these enzymes are simultaneously present and active. Asa consequence of the fact that the electron acceptors of MDH andMQO differ, the Gibbs standard free energy differences ( $Delta$ G°')of the reactions catalyzed by these enzymes are also very muchdifferent. The $Delta$ G°' of malate oxidation by MDH has a highly positivevalue of +28.6 kJ · mol¹, whereas the $Delta$ G°' of this reaction catalyzed by MQO is $-$ 55.0or $-$ 18.9 kJ · mol¹ depending on whether ubiquinones or menaquinones, respectively,act as acceptors. A consequence of the large difference in $Delta$ G°'would be that MDH and MQO, when active at the same time, catalyzereactions in opposite directions as follows:

(MDH) NADH + H⁺ + oxaloacetate $right-arrow$ NAD⁺ + malate $-$ 28.6

(MQO) MQ + malate $right-arrow$ oxaloacetate + MQH₂ $-$ 18.9

+
+

(Net) NADH + H⁺ + MQ $right-arrow$ NAD⁺ + MQH₂ $-$ 47.5

Here MQ and MQH₂ represent oxidized and reduced menaquinone, respectively. The numerical values are $Delta$ G°' in kilojoules permole. The net reaction equals that of a non-proton-pumping NADH:quinoneoxidoreductase (type II NADH dehydrogenase or NDH). This cyclecould serve as an additional NADH dehydrogenase or could be involvedin regulation of malate or oxaloacetate concentrations. In thepresent paper, we show that this reaction cycle occurs with isolatedmembranes and purified MDH of C. glutamicum, and we present evidencethat the cycle also occurs in vivo. Furthermore, the physiologicalfunction of MQO and MDH was assessed by studying their regulationand the effect on growth of deletion of theirgenes.

These studies are of general interest for bacterial physiology since genes encoding MQO and MQO activity have been found inmany gram-positive and -negativebacteria.

	MATERIALS AND METHODS

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Strains, growth, and media. Plasmids and strains used in this study are listed in Table 1. C. glutamicum was cultivated at 30°C.

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TABLE 1. Strains and plasmids

Tryptone-yeast extract medium (2 × TY) was described before (29). The design of the minimal medium used in this study wasbased on minimal media for Corynebacterium described in otherstudies (17, 18), and on the Neidhardt minimal medium forenterobacteria (23). It was modified to optimize growth rate,to guarantee pH stability over a long period of growth, and toprevent the formation of precipitates, thereby correcting threemajor disadvantages of minimal media previously used for growthof C. glutamicum. A fourth advantage of this medium, which provedinstrumental in the discovery, described below, of the nicotinamide-dependentgrowth of the $Delta$ mqo mutant, is the fact that it reproducibly allowsgrowth of C. glutamicum after inoculation at very low celldensities.

Two trace-element solutions, TE1 and TE2, were prepared as described previously (22). The minimal medium consisted of (perliter) 8.37 g of 3-[N-morpholino]-propanesulfonic acid (MOPS),0.72 g of N-tris[hydroxymethyl]-methylglycine (Tricine), 4.05g of NH₄Cl, 1 g of KCl, 0.3 g of K₂HPO₄, 0.23 g of MgCl₂ · 6H₂O,50 mg of CaCl₂ · 2H₂O, 0.2 g of EDTA, 50 mg of K₂SO₄, 15 mg ofprotocatechuate, and 0.2 mg of biotin. MOPS, Tricine, NH₄Cl, andKCl were prepared together as a 10-fold concentrated stock solution.The other components were prepared individually as 100-fold concentratedstock solutions, except for protocatechuate, which was added indry form during medium preparation, and biotin, which was storedat $-$ 20°C as a 1,000-fold stock solution. The EDTA stock solutionwas titrated to pH 7 with NaOH. The medium (1 liter) was preparedby first diluting 100 ml of the solution containing MOPS, Tricine,NH₄Cl, and KCl and 10 ml of the EDTA solution in 700 ml of distilledwater. Subsequently, 3 ml of TE1 and 1 ml of TE2 were added, andfinally all other components were added. The medium was titratedto pH 7.0 with NaOH, the volume was adjusted to 900 ml with water,and the medium was filter sterilized. Carbon and energy sourceswere added from 10-fold concentrated and filter-sterilized stocks.If necessary, these stocks had been adjusted to pH 7 with NaOH.For the preparation of minimal medium agar plates, the mediumwas prepared twofold concentrated and was mixed with an equalvolume of autoclaved liquid agar (30 g/liter ofwater).

For growth measurements, a colony was suspended in 2 ml of minimal medium without carbon source. A few microliters of thissuspension was transferred with an inoculating loop to 2 ml ofminimal medium with carbon source. These cultures were used toestablish whether mutants were able to grow or were used as apreculture for measurements of growth rate on the correspondingcarbon sources. In the latter case, the preculture was dilutedto a final optical density at 600 nm between 0.05 and 0.1 into10 ml of minimal medium with carbon source in a 50-ml conicalflask. The air contact-surface/volume ratio in these flasks atrest was 2 cm²/ml. The culture was incubated in a rotary shaker at 200 rpm.Under these conditions, growth was exponential at least up toan optical density of 10. The growth rate was calculated by least-squaresfitting of the exponential growth equation to thedata.

Purification of MDH. MDH was purified from raw cell extract in four steps: a streptomycinsulfate precipitation, an anion-exchange purification,and a dye affinity purification repeated twice. Wild-type C. glutamicumwas cultivated for 16 h in 400 ml of 2× TY medium. The cells wereharvested, washed twice in 50 mM K-phosphate (pH 7.5) with additional1 mM dithiothreitol and 2 mM EDTA, and resuspended in the samebuffer at a concentration of 0.25 g (wet weight)/ml (total volumeapproximately 20 ml). The suspension was passed three times througha French press cell at 165 MPa. Cell debris was removed by centrifugationfor 10 min at 75,000 × g and 4°C. A 10% (wt/vol) streptomycinsulfatesolution was slowly added, while being stirred, to the supernatantup to a final concentration of 0.75%. The extract was left onice for 15 min and subsequently centrifuged for 10 min at 15,000× g and 4°C. The clear supernatant was transferred to dialysistubing and was dialyzed twice for 1.5 h at 4°C against 1 literof 10 mM K-phosphate (pH 7.5) with additional 1 mM dithiothreitoland 2 mM EDTA (buffer A). The dialysate was cleared by centrifugationfor 15 min at 75,000 × g and 4°C. It contained approximately 10mg of protein/ml.

For anion-exchange chromatography, a Resource-Q column (Pharmacia) with a 1-ml column volume was used. Purification was performedat 4°C. The column was loaded with 15 mg of protein and washedwith 4 ml of buffer A. The protein was eluted with a linear NaClgradient, from 0 to 1 M, in buffer A and with a total volume of15 ml. MDH activity eluted from the column at approximately 0.5M NaCl. The fractions containing more than 10% of the total MDHactivity were combined and desalted by gel filtration on a PD-10column(Pharmacia).

Affinity chromatography was performed with the dye ligand reactive brown 10 cross-linked to agarose (Sigma). A column witha volume of 2.5 ml was loaded with 10 mg of protein or less andwas subsequently washed with 6 column volumes of 10 mM K-phosphate(pH 7.5). MDH was eluted with the same buffer supplemented with1 mM NADH. The MDH preparation was desalted by gel filtrationon a PD-10 column, and the dye affinity purification and desaltingwere repeated once more. The resulting MDH preparation was concentratedusing a centrifugal filter device with a 10-kDa cutoff filter(Amicon). The preparation contained only one protein of 33 kDaas judged by sodium dodecyl sulfate-polyacrylamide gelelectrophoresisof 50 µg of protein and subsequent staining with Coomassie brilliantblue. To stabilize the MDH activity, bovine serum albumin (1-mg/mlfinal concentration) was added, and the preparation was storedat $-$ 20°C. Under these conditions, the activity did not significantlydecrease over at least 3months.

Construction of site-directed mutants. A defined chromosomal deletion of the mqo gene was constructed as follows. A 3,174-bp DNA fragment excised from pRM30 (22)using SalI and XbaI containing the 1,500-bp open reading frame(ORF) encoding MQO was inserted into the integration vector pK19MobSacBusing the same enzymes. Preceding this ligation, the HindIII sitehad been removed from the vector by filling in using T4 DNA polymerase.The resulting plasmid, pK19MI1, was partially digested with HindIII.By religation, the 766-bp SalI/HindIII fragment containing the5' end of the mqo gene and the 1,341-bp HindIII/XbaI fragmentcontaining the 3' end of the mqo gene were joined to form an mqoORF with a 1,067-bp internal deletion. The resulting plasmid,pK19MI3, was used to replace the mqo gene in wild-type C. glutamicumaccording to the procedure of Schäfer et al. (30). Successof the deletion procedure was checked by PCR of the chromosomaltemplate. The resulting $Delta$ mqo strain did not possess detectableMQO activity as measured with 2,6-dichlorophenolindophenol (DCPIP)as the electronacceptor.

Insertion mutants of the ndh gene were constructed as follows. A 0.39-kbp fragment of the ndh gene was amplified from chromosomalDNA of the wild type by PCR with degenerative primers designedto hybridize with conserved stretches in known ndh genes. Theprimers used were 5'-CCGCTGCT(G/C)TACCA(A/G)GTGGC-3' and 5'-CCGGT(G/C)GGGCC(A/C)GC(G/C)CCGAC-3'.Annealing was performed at 53°C. The fragment was cloned in vectorpBluescript II SK(+) opened with EcoRV. An 0.34-kbp BamHI fragmentisolated from this plasmid was cloned into pEM1. The resultingplasmid, pEMndh_int, was used to create insertion mutants in C.glutamicum wild-type and $Delta$ mqo strains by the simplified transformationprotocol described in the work of Van der Rest et al. (39),resulting in strains ndh::pEMndh_int and $Delta$ mqo ndh::pEMndh_int, respectively.Other parts of the ndh gene were cloned by plasmid rescue (24)from the ndh::pEMndh_int insertion mutant (R. Yücel, unpublishedresults). These fragments were sequenced on bothstrands.

Insertion mutants of the mdh gene encoding cytoplasmic MDH (EC 1.1.1.37) were constructed as follows. A 0.47-kbp fragmentof the mdh gene was amplified from chromosomal DNA of the C. glutamicumwild-type strain by PCR with degenerative primers. One primerwas designed using the N-terminal amino acid sequence of the purifiedMDH protein from C. glutamicum (A. Drysch, unpublished results).The other primer was designed to hybridize with a conserved stretchin known mdh genes. The primers used were 5'-AA(AG)GT(CT)AC(CT)GT(CT)AC(CT)GG(CT)-3'and 5'-CG(AG)TT(AG)TG(AG)TC(AGC)A(AG)(AG)CG-3'. Annealing wasperformed at 63°C. The amplified fragment was cloned in vectorpBluescript II SK(+) (Stratagene) opened with EcoRV. The fragmentwas excised from this plasmid with BamHI and HindIII and clonedin vector pEM1 opened with the same enzymes. The resulting plasmid,pEMmdh_int, was used to create insertion mutants in C. glutamicumwild-type and $Delta$ mqo strains (39), resulting in strains mdh::pEMmdh_intand $Delta$ mqo mdh::pEMmdh_int, respectively. The mdh insertion mutantsdid not possess MDHactivity.

A defined chromosomal deletion of the mdh gene was constructed as follows. A 1,503-bp DNA fragment containing the 984-bp mdhORF was amplified using the oligonucleotides 5'-GTGGATCCTGCGCTTGGACATGCCAG-3'and 5'-CGCTCTAGATTAGAGCAAGTCGCG-3'. The first oligonucleotideintroduces a BamHI site 505 bp in front of the mdh ORF, and thesecond introduces an XbaI site 4 bp following the TAA stop codonof the mdh ORF. The amplified fragment was digested with BamHI,XbaI, and XhoII. The XhoII digestion removes a 395-bp internalfragment from the mdh ORF. By religation, a 645-bp BamHI/XhoIIDNA fragment containing the 5' end of the mdh ORF and a 456-bpXhoII/XbaI DNA fragment containing the 3' end of the mdh ORF werejoined to form an mdh ORF with a 395-bp internal deletion. Thisfragment was inserted into the integration vector pK19MobSacBopened with BamHI and XbaI. The resulting plasmid pK19 $Delta$ mdh wastransformed by electroporation into wild-type C. glutamicum (39).Deletion mutants of mdh were selected according to the proceduredescribed above for mqo deletion mutants. The resulting $Delta$ mdh straindid not possess detectable MDH activity. The $Delta$ ndh_int mutationwas introduced in this strain as described above for the wildtype.

Measurement of the membrane-bound dehydrogenase activities. Cultures growing exponentially on 50 ml of minimal medium with carbon source were placed on ice for 10 min after reachingan optical density at 600 nm between 2 and 3. They were centrifugedfor 5 min at 4,000 × g and 4°C. The supernatant was discarded,and the pellets either were frozen in liquid nitrogen and storedat $-$ 20°C or were processed immediately. Membrane fragments wereisolated from these cells as described before (22). The activitiesof the dehydrogenases for NADH, D- or L-malate, D- or L-lactate,and succinate associated with these membranes were measured withDCPIP as an electron acceptor and in the presence of a 1 mM concentrationof the substrate (22). NADH dehydrogenase activity was alsomeasured by observing the decrease in absorption at 340 nm overa certain period. The absorption coefficients used were 22 and6.3 cm¹ · mM¹ for DCPIP and NADH,respectively.

Measurement of intracellular NAD and NADH concentrations. Cells were extracted by thoroughly mixing 1 ml of culture with either 1 M HClO₄ or 1 M KOH containing 50% ethanol. The finalpH of the extracts was 1 and 12.4 for the acid and alkaline extracts,respectively. The acid and alkaline extracts were incubated at55°C for 8 and 5 min, respectively. They were subsequently cooledon ice and carefully neutralized with 2 M KOH or 1 M HCl. Theconcentration of the pyridine nucleotides in the extracts wasmeasured with the cycling assay (6), and intracellular concentrationswere calculated by assuming an intracellular volume of 1.5 µl· mg¹ (dry mass). The dry mass was estimated by measuring the opticaldensity at 600 nm and assuming that an optical density equal to1 corresponds to 0.34 mg (dry mass) · ml¹ (28).

Measurement of cytoplasmic malate and lactate dehydrogenases. Exponentially growing cells (50 ml of medium; optical density at 600 nm between 2 and 3) were harvested and washed with 50mM K-phosphate, pH 7.5, as described above and resuspended in0.7 ml of this buffer. The cells were broken by sonication for5 min on ice with a Branson B15 sonifier, equipped with a microtipat a 30% duty cycle and 30% of maximal output. Debris was removedby centrifugation for 15 min at 28,000 × g. The MDH activity inthe extract was measured in the direction of malate oxidationor oxaloacetate reduction according to the method of Smith (35),except that 3-amino-1-propanol instead of diethanolamine was usedas a buffer. D-or L-lactate dehydrogenase was measured in thedirection of lactate oxidation as described by Wahlefeld (40).

Measurement of extracellular organic acids. Organic acids produced by cultures were quantified by chromatography of the culture supernatant in 5 mM H₂SO₄ on a 300- by8-mm organic acid resin column (Chromatography Service). The identityof the acids was confirmed by standard enzymatic assays of theculture supernatants (5).

Protein determination. Protein was determined with bicinchoninic acid according to a protocol adapted from the work of Smith et al. (36). Whenprotein was determined in membrane fragment preparations, theassay solution contained an additional 0.5% (mass/vol) sodiumdodecylsulfate.

Nucleotide sequence accession number. The complete sequence of the ndh gene has been deposited in the EMBL data bank under accession no. AJ238250.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Activity of NADH, succinate, and malate dehydrogenases during growth on various substrates. The activities of the membrane-bound dehydrogenases, NADH dehydrogenase, SDH (EC 1.3.99.1), and MQO, differ, depending onthe carbon and energy source (Fig. 1). The citric acid cycle (ortricarboxylic acid [TCA] cycle) enzymes MQO and SDH are more activeduring growth on L-lactate, acetate, and pyruvate. For example,MQO and SDH activities are, by a factor of 3.4 (±0.4) and 1.8(±0.1), respectively, higher during growth on acetate than onglucose. The cytoplasmic MDH is regulated in a similar manner,and a positive correlation between MDH and MQO activities is observed(Fig. 1). Thus, it is shown that MDH and MQO are present at thesame time in C. glutamicum and that their activities are coordinatelyregulated.

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FIG. 1. Specific dehydrogenase activities in cells grown on various substrates. The NADH dehydrogenase (NADH-dh), SDH, MQO, and MDH activities were determined in cells from the exponential growth phase growing on various carbon sources. The values are the averages of two independent experiments in which the activities were determined in duplicate. The error bars indicate the overall sample standard deviations of the four measurements. Note that the values of the specific activities cannot be directly compared because MDH activity is standardized with respect to total protein in the cleared cell extract, whereas MQO activity is standardized with respect to total membrane protein. Moreover, MDH activity was assayed in the direction of malate oxidation at pH 9.2. Lactate is L-lactate.

NADH dehydrogenase is regulated differently from these TCA cycle enzymes. Its activity might be partly correlated with thedegree of reduction of the substrate. The dependency on the degreeof reduction of the substrate is apparent from the very high activityfound in cells growing on mannitol. Complete oxidation of thissubstrate generates an extra reducing equivalent (NADH) comparedto oxidation of glucose orfructose.

Properties of the $Delta$ mqo mutant. An MQO-negative mutant (DM22) generated by random mutation with 1-methyl-3-nitro-1-nitrosoguanidine (NTG) was described before(22). The mutant grew more slowly than the wild type on severalsubstrates tested (D. Molenaar, unpublished data). This phenotypeallowed the cloning of the mqo gene by complementation. Sequencingof the mqo gene from DM22 confirmed the existence of a deleteriousmutation, consisting of a single base-pair mutation leading toan internal stop codon. However, since the plasmid-borne mqo genewas not able to fully complement the phenotype, it was suspectedthat DM22 might carry additional mutations. This is not uncommonin strains generated by NTG mutagenesis. Therefore, to be ableto discern the physiological effects of the deletion of mqo alone,a site-directed mutant, $Delta$ mqo, was constructed. Assaying for MQOactivity confirmed its absence in thisstrain.

This mutant does not grow on the minimal medium described in Materials and Methods, except when nicotinamide is added (Fig.2). Other supplements tested, but not stimulating growth, werethe vitamins riboflavin, folic acid, d-pantothenic acid, thiamine,pyridoxine, and p-aminobenzoic acid and the amino acid aspartate.For growth on glucose, fructose, mannitol, pyruvate, and lactate,1 mg of nicotinamide liter¹ is sufficient to let $Delta$ mqo attain the same optical density asthat of the wild type after 48 h of incubation. Still, even inthe presence of 1 mg of nicotinamide liter¹, $Delta$ mqo grows more slowly than the wild type. During growth onglucose, a small but significant reduction of the growth rateby approximately 10% was observed. The defect was very pronouncedin the case of growth on acetate (75% reduction) or pyruvate (40%reduction), substrates during growth on which the MQO activityis relatively high (Fig. 1). The activities of the NADH dehydrogenase,SDH, and MDH in strain $Delta$ mqo do not differ significantly from thosein the wild type when grown on the substrates referred to in Fig.1 (data not shown).

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FIG. 2. Complementation of $Delta$ mqo by mdh when cells grow in the presence of nicotinamide. Strains were streaked on minimal medium agar with 1% (wt/vol) glucose, and where indicated, 1 mg of nicotinamide liter¹ was added. Plates were incubated for 4 days.

Properties of the $Delta$ mdh single and the $Delta$ mdh $Delta$ mqo double mutants. Insertion mutations of the mdh gene were made in the wild type and in $Delta$ mqo. The single mutant $Delta$ mdh did not have an observablephenotype when tested for growth on glucose, fructose, lactate,acetate, or succinate, neither when growth on plates was scorednor when the growth rate in liquid medium was measured. The $Delta$ mdh $Delta$ mqo double mutant, however, was unable to grow on these substratesin defined medium, even in the presence of nicotinamide (Fig.2). This indicates that MDH is able to complement the absenceof MQO activity but only when $Delta$ mqo is supplied with nicotinamide.Apparently, the function of MQO, that is, the oxidation of malateto oxaloacetate, is taken over by MDH in these cells. An obviousreason for the nicotinamide dependence of $Delta$ mqo would be that itleads to an increased concentration of NAD in the cell, enablingMDH to oxidize malate. As can be seen in Table 2, addition ofnicotinamide indeed causes an increase in intracellular NAD andNADH concentrations. Although the [NAD]/[NADH] ratio decreasesfrom 4.4 in the absence of nicotinamide to 2.8 at 1 mg of nicotinamideliter¹, the sevenfold increase of the NAD concentration might have afavorable effect on the kinetics of MDH which suffices to enablemalate oxidation by the enzyme. The low growth rates of $Delta$ mqo evenin the presence of nicotinamide are, nevertheless, indicativeof the difficulties the organism has with this backup solution,which are likely to be due to the unfavorable thermodynamics ofthe reaction.

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TABLE 2. NAD and NADH concentrations in C. glutamicum grown in the presence of different nicotinamide concentrations

Properties of the $Delta$ ndh_int single and the $Delta$ mqo $Delta$ ndh_int and $Delta$ mdh $Delta$ ndh_int double mutants. C. glutamicum possesses highly active membrane-bound NADH dehydrogenase (Fig. 1). In order to gain evidence for the hypothesisthat MQO and MDH catalyze opposite reactions in the citric acidcycle and consequently catalyze a net NADH dehydrogenase reaction,the membrane-bound NADH dehydrogenase had to be inactivated. Forthis purpose, we disrupted the ndh gene, which encodes a typeII NADH dehydrogenase, expecting that possibly also a nuo homolog,encoding type I NADH dehydrogenase, might have to be disrupted.However, membranes isolated from strains carrying the ndh disruption,when grown on 2× TY medium, did not possess detectable NADH dehydrogenaseactivity, neither when assayed with DCPIP nor when NADH consumptionwas observed directly by measuring the absorption at 340 nm. Thisindicates that a type II NADH dehydrogenase (NDH), the non-proton-pumpingenzyme encoded by the ndh gene, is under these conditions theonly active membrane-bound NADH dehydrogenase. This mutant growsat a slightly lower rate than does the wild type (Table 3).

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TABLE 3. Growth of wild type and mutants by scoring of colonies on minimal medium agar supplied with different carbon sources after 24 or 48 h of incubation^a

Escherichia coli mutants lacking both type I and II membrane-bound NADH dehydrogenases have clear phenotypes (7, 42).Since they are unable to regenerate NAD by respiration, thesemutants grow mainly fermentatively and excrete large amounts oflactate (41). They are also unable to grow on mannitol, sincefermentative growth on this substrate is not possible. As a diagnosticindicator of the absence of NADH dehydrogenase activity, growthof the C. glutamicum double mutant $Delta$ mqo $Delta$ ndh_int was tested onmannitol. Although this mutant lacked all known NADH dehydrogenaseactivities, it did grow slowly on mannitol. It also did not excretelactate during growth on glucose. An explanation for this phenomenonwould be that, similar to the MQO-MDH cycle, a cyclic reactioninvolving lactate and pyruvate catalyzed by an NAD-dependent lactatedehydrogenase and membrane-bound quinone-dependent lactate dehydrogenasecould constitute an alternative NADH dehydrogenase (see Discussion).In the $Delta$ mqo, $Delta$ ndh_int, and $Delta$ mqo $Delta$ ndh_int strains, the membrane-boundL-lactate dehydrogenase was more active than in the wild typeby a factor of 1.5, 1.8, and 2.3, respectively. Neither the membrane-boundD-lactate dehydrogenase nor the cytoplasmic lactate dehydrogenaseactivities were increased in these strains. A significant differenceof $Delta$ mqo $Delta$ ndh_int from the single mutants was that it excreted fumarateand malate to high concentrations (Table 4). This may be explainedby assuming that the TCA cycle is almost completely blocked inthe double mutant due to the fact that the MQO is absent and thatthe backup function of MDH is restricted by high NADH concentrationsdue to the absence of NADH dehydrogenase.

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TABLE 4. Extracellular products after growing for 16 h on minimal medium with 2% glucose as carbon source and containing 1 mg of nicotinamide · ml¹

The fact that only the double mutants $Delta$ mqo $Delta$ ndh_int and $Delta$ mdh $Delta$ ndh_int display a clear temperature-sensitive phenotype (Fig.3) is indirect evidence for the limited NADH dehydrogenase capacityin this mutant compared to the single mutants. For the interpretationof these results, an observation for Mycobacterium smegmatis isof importance. In M. smegmatis, a bacterium containing MQO asthe only malate dehydrogenase, the disruption of ndh causes growthinhibition at high temperatures (21) and also causes isoniazidresistance. Isoniazid sensitivity and temperature resistance canbe restored by introducing MDH from the closely related Mycobacteriumbovis in these mutants, thus restoring an NADH dehydrogenase activitycatalyzed by native MQO and the foreign MDH. Although corynebacteriaand mycobacteria are evolutionary closely related, C. glutamicumwild type is not sensitive toward isoniazid. However, C. glutamicummutant strains display a behavior similar to that of M. smegmatisat elevated temperatures, although in this case MQO and MDH areboth innate.

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FIG. 3. Temperature-sensitive phenotype of $Delta$ mqo $Delta$ ndh_int and $Delta$ mdh $Delta$ ndh_int double mutants. The strains were streaked on 2× TY agar, and plates were incubated for 3 days at the temperatures indicated. Strains with the integration disruption $Delta$ ndh_int (upper halves) were streaked on plates containing an additional 25 µg of kanamycin ml¹ to prevent the growth of revertants.

It has been proposed by others that membranes of C. glutamicum also possess an NADPH dehydrogenase activity with an optimumat pH 5.5 (20). We could measure a similar activity in our assaysystem at pH 7. However, NADPH dehydrogenase activity was completelyabsent in the $Delta$ ndh_int mutant. This result indicates that NADPHdehydrogenase is a minor activity of NDH and is not likely tobe due to a separate NADPH-specific dehydrogenase, as was proposedby Matsushita et al. (20).

Properties of purified MDH. Assaying malate oxidation by MDH is usually performed at high pH, since, the proton beinga product of the reaction, the free energy difference is morefavorable under these conditions than at neutral pH. Of course,for the physiological function the activity of the enzyme at neutralpH is of interest. Although malate oxidation with NAD as the electronacceptor is thermodynamically unfavorable, an MDH might stillbe able to catalyze malate oxidation at a substantial rate underthe proper conditions, i.e., relatively low NADH and oxaloacetateconcentrations. The assay of malate oxidation by MDH quickly runsinto equilibrium at pH 7.5, as early as attainment of 2 µM oxaloacetateand NADH in the assay used here with starting concentrations of1 mM malate and 0.1 mM NAD. This amount of NADH is hardly detectable,and therefore, in the simple assay at pH 7.5 no malate oxidationby purified MDH was observed. A low activity of maximally 18 U· mg¹ was observed only when a sink for oxaloacetate in the form ofglutamate oxaloacetate transaminase together with glutamate wasadded to the reaction mixture. On the other hand, the rate ofoxaloacetate reduction catalyzed by MDH at pH 7.5 is 770 U · mg¹. At pH 9.5, the specific activities were 60 and 1,020 U · mg¹ for malate oxidation and oxaloacetate reduction,respectively.

MDH from C. glutamicum was also able to catalyze the NADPH-dependent reduction of oxaloacetate. Similar observations withrespect to pyridine nucleotide specificity have been made previouslyfor other MDHs (4).

In vitro reconstitution of the cyclic reaction between MDH and MQO. Membranes isolated from the $Delta$ ndh_int mutant have no observable NADH dehydrogenase activity (Fig. 4). When malate and purifiedMDH from C. glutamicum are added to these membranes, an apparentNADH dehydrogenase activity can be observed. This activity isdependent on the presence of MQO, since the reaction could notbe reconstituted with membranes from the double mutant $Delta$ mqo $Delta$ ndh_int.

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FIG. 4. In vitro reconstitution of NADH dehydrogenase activity using membrane fragments and purified MDH. Membrane fragments were isolated from cells grown on 2× TY medium with 1% (wt/vol) glucose. Absorption by NADH was recorded at 340 nm. The reaction mixture contained 50 to 150 µg of membrane protein per ml, 0.2 mM NADH, and where indicated 175 ng of purified MDH ml¹. The reaction was started by adding 1 mM malate.

Since MDH also catalyzes the NADPH-dependent oxaloacetate reduction, an apparent NADPH dehydrogenase activity could also bereconstituted with the system (data notshown).

Inhibition of SDH by oxaloacetate. Oxaloacetate is a known inhibitor of a number of enzymes in central metabolism, notably of SDH, for which examples exist inprocaryotes as well as eucaryotes (2). The possible role ofMQO and MDH in controlling the cytoplasmic oxaloacetate concentrationprompted us to study the effect of oxaloacetate on SDH in C. glutamicum.The Michaelis constant for succinate of C. glutamicum SDH is approximately20 to 30 µM. The modulation of SDH by oxaloacetate is complexbut is basically a competitive type of inhibition (2). Fromthe results of inhibition experiments, a competitive inhibitionconstant by oxaloacetate of 0.15 to 0.22 µM could be deduced.This illustrates the potential importance of oxaloacetate as aregulator of TCA cycle activity in C. glutamicum.

The inhibition of MQO by oxaloacetate was also assessed. A significant effect of oxaloacetate was observed only at very highconcentrations, with the activity inhibited by 50% at 8 mM oxaloacetate.Based on the equilibrium constant for the MDH-catalyzed reaction,such high free oxaloacetate concentrations can hardly be expectedin the cell (see Discussion). Therefore, the inhibition of MQOby oxaloacetate is probably not of physiologicalsignificance.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

The observation of in vitro NADH dehydrogenase activity catalyzed by MQO and MDH and the observation of the temperature sensitivityof the $Delta$ mqo $Delta$ ndh_int double mutant support the hypothesis thatMQO and MDH catalyze opposite reactions in vivo. More evidenceis supplied by two observations from the literature. A study byMiesel et al. (21) indicated that isoniazid resistance in M.smegmatis is often associated with mutations which inactivatethe type II NADH dehydrogenase. Isoniazid resistance is thoughtto be caused by the high NADH/NAD ratio in these mutants. Expressingthe wild-type ndh gene from a plasmid restored isoniazid sensitivityin an NDH-negative mutant. Interestingly, isoniazid sensitivitywas also restored in this mutant by expressing the heterologousmdh gene from the related species M. bovis. Bearing in mind thatM. smegmatis possesses only MQO and no MDH of its own (26),we propose that the expression of a heterologous MDH in M. smegmatiscauses the above-mentioned cyclic reaction to occur, resultingin a net NADH dehydrogenase reaction. The explanation by Mieselet al. (21) that MDH alone might oxidize NADH is incomplete.This would require a continuous source for oxaloacetate and asink for malate and thereby a considerable reorganization of centralmetabolism.

The situation with respect to MQO and MDH is reminiscent of the D-lactate dehydrogenases found in E. coli. This organism possessesa cytoplasmic NAD-dependent enzyme (EC 1.1.1.28) and a membrane-boundD-lactate:quinone oxidoreductase (12). Also in this case, theoxidation of a 2-hydroxy acid is involved, and the standard freeenergies of the reactions are comparable to those of the respectivemalate dehydrogenases. The NAD-dependent oxidation of lactatehas a positive $Delta$ G°' (equal to +25.0 kJ · mol¹) whereas the ubiquinone-dependent reaction has a negative $Delta$ G°'(equal to $-$ 58.6 kJ · mol¹). Consequently, the physiological function of the NAD-dependentlactate dehydrogenase is in most cases to reduce pyruvate, whereasthe quinone-dependent enzyme is exclusively involved in the oxidationof lactate. The gene (dld) encoding D-lactate:quinone oxidoreductasein E. coli was accidentally cloned in an attempt to clone thendh gene. When overexpressed from a plasmid, dld was able to complementthe phenotype of an ndh mutation (41). The ndh mutant excreteslarge quantities of D-lactate since, being unable to dispose ofreducing equivalents in another way, it grows in a fermentativemode. In contrast, the ndh mutant strain overexpressing D-lactate:quinoneoxidoreductase did not excrete lactate. The authors concludedthat the NAD-dependent D-lactate dehydrogenase and the D-lactate:quinoneoxidoreductase together function as an NADHdehydrogenase.

Why do some organisms use MQO to catalyze malate oxidation, whereas others apparently use MDH (see accompanying article aboutE. coli)? An obvious advantage of using MQO is the highly negative $Delta$ G°' of malate oxidation by this enzyme compared to the highlypositive $Delta$ G°' of the reaction catalyzed by MDH. In fact, malateoxidation by MDH has the highest $Delta$ G°' value of all reactions incentral metabolism, that is, glycolysis and the citric acid cycle.The next highest value ( $Delta$ G°' = +24 kJ · mol¹) is for the aldolase reaction. Since this reaction is one-sidedbimolecular, a less extreme situation with respect to productconcentrations exists than that for MDH. To illustrate this, itcan be calculated that the ratio [oxaloacetate]/[malate] at pH7 and 30°C has to be smaller than 1.2 × 10⁵ times the [NAD]/[NADH] ratio if MDH oxidizes malate. The [NAD]/[NADH]ratio can be on the order of 1 in bacterial cells, for example,under conditions of low oxygen tension (10). Assuming a malateconcentration on the order of 10³ M, the oxaloacetate concentration under these conditions wouldhave to be on the order of 10⁸ M or less. Oxaloacetate is an important precursor in gluconeogenesisand in the synthesis of amino acids of the aspartate branch. Furthermore,it is the substrate of citrate lyase in the citric acid cycle.A very low oxaloacetate concentration might cause a growth limitationby limiting the reaction rates of one or more enzymes using oxaloacetateas a substrate. Higher levels of MDH would not improve this situationbecause the oxaloacetate concentration would be limited by theequilibrium of the MDH reaction. The problem of the unfavorableequilibrium of the MDH-catalyzed malate oxidation has been recognizedbefore, and an alternative solution in the form of substrate channelinghas been proposed for mitochondria. Here the reactant oxaloacetateor NADH would be transferred directly from MDH to citrate synthaseor NADH dehydrogenase, respectively, thus directly coupling areaction with an unfavorable $Delta$ G°' to one with a favorable $Delta$ G°'(9, 11, 27, 37). The fact that the biosynthetic and energy-generatingpathways take place in separate compartments may also providepart of the solution for this problem ineucaryotes.

Using an MQO instead of an MDH may allow an organism to attain a high TCA cycle flux independently of the NADH/NAD and malate/oxaloacetateratios. Thus, MQO may be of importance for a robust TCA cycleflux under adverse conditions. Such conditions could be low electronacceptor concentrations, limiting concentrations of carbon sources,or growth on carbon sources requiring a high TCA cycle flux forthe generation of metabolic energy. In C. glutamicum, MQO is importantduring growth on organic acids, in particular, acetate, as reflectedby its high activity and the severe effect on growth of an mqodeletion. Similarly, it was noticed that mqo disruption in Pseudomonasfluorescens impaired its ability to colonize tomato roots (L.C. Dekkers, personal communication). Under these circumstances,this organism probably grows on organic acids excreted by theplant (19). Nevertheless, bacteria like E. coli are able toattain a high growth rate on acetate using MDH (accompanying paper).This may, however, require more restricted and optimized conditions,in particular of aeration, to maintain a high TCA cycle fluxrate.

Another situation in which an organism might benefit from the use of an MQO is when it faces continuous or occasional lowintracellular pH. The MDH reaction produces a proton, and thereforeits $Delta$ G°' becomes even more unfavorable at low pH. This situationmight, for example, apply to Helicobacter pylori (16).

Energetically, the subsequent reactions of malate oxidation by MDH and NADH oxidation by NDH are equivalent to the MQO reactionalone, because the net reactions are the same. The situation wouldbe different when an organism expresses the proton-pumping (typeI) NADH dehydrogenase because then, in the net reaction, protonswould be pumped by MDH and the type I NADH dehydrogenase, makingin principle more metabolic energy available than with the MQOreaction. However, this energy gain might be possible only atthe expense of a low oxaloacetate concentration, as explainedabove.

In bacteria like M. smegmatis (26), H. pylori (16), Neisseria meningitidis (13, 38), and several Pseudomonas species(25), which possess only MQO and no (known) MDH, the functionof MQO seems clear. In those species, it is the only enzyme whichis able to directly oxidize malate to oxaloacetate in the TCAcycle. However, the presence of two malate dehydrogenases as inC. glutamicum, E. coli, and many other bacteria, is puzzling (3,8, 14, 15). In some cases, like that of E. coli (see accompanyingpaper), the activity of MQO may not be high enough to be of importanceor may be induced only under special conditions. However, as shownabove in C. glutamicum MDH and MQO activities are high and coordinatelyregulated on different carbon and energy sources. This suggestsa similar or cooperative metabolic function of MDH and MQO. However,whereas the deletion of mqo is deleterious in this species, thefact that deletion of the mdh gene in C. glutamicum has no effecton growth indicates that the latter has no physiological functionunder the circumstances tested. Consequently, although it is verylikely that MQO and MDH catalyze opposite reactions, neither theoxidation of NADH nor the potentially regulatory role of the cyclein regard to oxaloacetate and malate concentrations seems to beof importance. It was shown that in an MQO deletion strain MDHcan take over the function of MQO when the cells are suppliedwith sufficient nicotinamide. This implies that, under circumstanceswhere MQO does not function, MDH might serve as abackup.

	ACKNOWLEDGMENTS

We thank Andreas Burkovski for discussion, Yiulia Bertsova for drawing our attention to the literature concerning E. colilactate dehydrogenases, and Linda Dekkers for discussion and sharingunpublished information withus.

This research was funded by the Bundesministerium für Bildung, Wissenschaft, Forschung und Technologie in Germany (project0316712).

	FOOTNOTES

^* Corresponding author. Mailing address: Biotechnologisches Zentrallabor, Geb. 25.12, Heinrich-Heine-Universität, Universitätsstraße1, D-40225 Düsseldorf, Germany. Phone: 49 211 811 1482. Fax:49 211 811 5370. E-mail: molenaar{at}rz.uni-duesseldorf.de.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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1.	Abe, S., K. Takayama, and S. Kinoshita. 1967. Taxonomical studies on glutamic acid producing organisms. J. Gen. Appl. Microbiol. (Tokyo) 13:279-301.
2.	Ackrell, B. A. 1974. Metabolic regulatory functions of oxalacetate. Horiz. Biochem. Biophys. 1:175-219[Medline].
3.	Asano, A., T. Kaneshiro, and A. F. Brodie. 1965. Malate-vitamin K reductase, a phospholipid-requiring enzyme. J. Biol. Chem. 240:895-905[Free Full Text].
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